C09. Turbomolecular Pumps l x s -1. vacuum

Transcription

1 Excerpt from the Product Section Edition May 2005 Turbomolecular Pumps l x s -1 vacuum

2 Turbomolecular Pumps Contents General General Applications Accessories Products and Accessories Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage with Compound Stage Electronic Frequency Converters for Turbomolecular Pumps with Mechanical Rotor Suspension...58 Turbomolecular Pumps with Magnetic Rotor Suspension without Compound Stage with Compound Stage Electronic Frequency Converters for Turbomolecular Pumps with Magnetic Rotor Suspension Other Accessories Vibration Absorber Air Cooling Unit Flange Heater for CF High Vacuum Flanges Fine Filter Solenoid Venting Valve Power Failure Venting Valve Purge Gas and Venting Valve Accessories for Serial Interfaces RS 232 C and RS 485 C

3 General Turbomolecular Pumps General The turbomolecular pumps from Leybold generate a clean high and ultra-high vacuum, are easy to operate and are exceptionally reliable. In connection with a well rated backing pump, pressures below mbar (0.75 x Torr) can be attained. Leybold offers two product lines: 1. TURBOVAC line Turbomolecular pumps with mechanical rotor suspension 2. TURBOVAC MAG line Turbomolecular pumps with magnetic rotor suspension Each of the two product lines contains classic turbomolecular pumps as well as turbomolecular pumps with a compound stage. Leybold is one of the world s leading manufacturer of turbomolecular pumps. Consequently, the TURBOVAC and the TURBOVAC MAG pumps are successfully used in many applications. A list of the most important ones is given in the table Applications in the section General. Principle of Operation The turbomolecular pump is a turbine with blades. By the momentum transfer from the rapidly rotating rotor blades to the gas molecules their initially non-directed thermal motion is changed to a directed motion. TURBOVAC TW 70 H turbomolecular pump with mechanical rotor suspension and dual compound stage TURBOVAC TW 361 turbomolecular pump with mechanical rotor suspension Hence, the pumping process in a turbomolecular pump results from the directed motion of the gas molecules from the inlet flange to the forevacuum port. In the molecular flow range - i.e. at pressures below 10-3 mbar (0.75 x 10-3 Torr) - the mean free path of the gas molecules is larger than the spacing between rotor and stator blades (typically some tenths of a millimeter). Consequently, the molecules collide primarily with the rotor blades with the result that the pumping process is highly efficient. In the range of laminar flow, i.e. at pressures over 10-1 mbar (0.75 x 10-1 Torr) the situation is completely different. The effect of the rotor is impaired by the frequent collisions between the molecules. Therefore, a turbomolecular pump is not capable of pumping gases at atmospheric pressure thus necessitating the use of a suitably rated forevacuum pump. To create the directed motion of the gas molecules, the tips of the rotor blades have to move at high speeds. Hence, a high rotational speed of the rotor is required. In the case of Leybold turbomolecular pumps the rotor speeds vary from about 36,000 rpm for the larger rotor diameters (e.g. TURBOVAC 1000 about 20 cm (7.87 in.)) to 72,000 rpm. for small rotor diameters (e.g. TURBOVAC 50 about 6 cm (2.36 in.)) MAG W 1500 CT turbomolecular pump with magnetic rotor suspension and compound stage 3

4 Turbomolecular Pumps General Characteristic Quantities Pumping speed (volume flow rate), S, [l x s -1 ] The pumping speed for a given type of gas depends on the diameter of the rotor and the high vacuum flange, the rotor/stator design, the rotor speed and the molecular weight of the gas. The pumping speed S is a non-linear function of the inlet pressure p 1 : S = S(p 1 ). Gas throughput, Q, [mbar x l x s -1 ] Gas throughput Q is linked to the pumping speed S and the inlet pressure p 1 through the relationship Q = Q(p 1 ) = p 1 S(p 1 ). The maximum permissible gas throughput Q max is attained at the maximum permissible inlet pressure p 1, max : Q max = Q(p 1, max ). Compression, K For a given type of gas, compression K is defined as the ratio between forevacuum pressure p VV (= pres-sure on the forevacuum side of the turbomolecular pump) and the highvacuum pressure p HV (= pressure on the highvacuum side of the turbomolecular pump): k = k(p VV ) = p VV / p HV = p VV / p HV (p VV ). Compression depends very much on the gas throughput: at a given forevacuum pressure, compression increases when the gas throughput is reduced. Idle compression, K 0 Idle compression K 0 of a turbomolecular pump is defined as the amount of compression of this pump at Zero gas throughput. What is problematic about this definition is the fact that the demanded Zero throughput can never be implemented in practice (finite leak rate, - degassing of sealing components, desorption from wall surfaces). Data on idle compression need therefore to be gained from measurements run at extremely low throughputs. Idle compression of a pump equipped with metal seals is significantly higher compared to the same pump sealed with O-rings. Ultimate pressure (base pressure), p ult, [mbar] The ultimate pressure of a turbomolecular pump is defined as that pressure which is attained in the test chamber 48 hours after a 24 hour degassing period of the measurement system. The ultimate pressure will chiefly depend on the foreline pump used and the type of seal used at the highvacuum flange. TURBOVAC Product Line The TURBOVAC pumps are turbomolecular pumps with mechanical rotor suspension which are used in the pressure range from 10-1 mbar (0.75 x 10-1 Torr) to mbar (0.75 x Torr). Pumping speeds for air vary from 35 l x s -1 (inlet flange diameter = 40 mm (1.57 in.)) to 1,600 l x s -1 (inlet flange diameter = 250 mm (9.84 in.)). Through the compact design, the most reliable ceramics ball bearings and the simplicity of operation, this line of pumps is used in all highvacuum and ultrahigh vacuum areas of application. In particular the TURBOVAC pumps are very successfully operated in mass spectroscopy applications, gas and liquid chromatographic analysis, CD, DVD and hard disk production, manufacturing of large-surface optical layers, and non-corrosive semiconductor fabrication processes. The most important advantages of the TURBOVAC product line are: Oil-free pumps for the generation of clean high and ultra-high vacuum conditions Highly performance in any orientation Highly degree of operating reliability Easy to operate Compact design 4

5 General Turbomolecular Pumps Ceramic Ball Bearings Technology All TURBOVAC pumps are fitted with ceramic ball bearings, i.e. ceramic balls are running in steel races. The bearings are lubricated for life by grease. Ceramic balls are lighter, harder and smoother than balls made of steel. Therefore, with ceramic balls the wear on the races is significantly reduced. Consequently, the lifetime of the bearings, and hence the lifetime of the pump, is increased. The TURBOVAC pumps fitted with grease-lubricated ceramic ball bearings can be mounted in any orientation. As the ball bearing is encapsulated, the grease can not enter the highvacuum space, even if the pump is mounted up-side-down. F 1,2,3 Components supplied with the Turbomolecular Pumps Highvacuum Flange KF, ISO-K and ISO-F models Accessories need to be ordered separately ANSI Models O-ring included in the delivery CF Models Without gaskets 1), but with screws 2) Forevacuum Port Centering rings, O-rings and clamps for all KF type forevacuum flanges are included. Purge / vent ports are blanked-off 1) For CF gaskets, see Product Section C15 2) Only for MAG pumps TURBOVAC MAG Product Line The TURBOVAC MAG pumps are turbomolecular pumps with magnetic rotor suspension which are used in the pressure range from 10-1 mbar (0.75 x 10-1 Torr) to mbar (0.75 x Torr). Pumping speeds for air vary from 300 l x s -1 (inlet flange diameter = 100 mm (3.94 in.)) to 2,000 l x s -1 (inlet flange diameter = 250 mm (9.84 in.)). The TURBOVAC MAG pumps are mostly installed on semiconductor processing lines like etching, CVD, PVD and ion implantation, i.e. in applications where corrosive gases need to be pumped. Also electron beam microscopy is an important area of application for these pumps. The most important advantages of the TURBOVAC MAG product line are: Hydrocarbon-free pumps for the generation of clean high and ultrahigh vacuum conditions High performance in any orientation High degree of operating reliability Extremely low vibration Designed for pumping of corrosive gases A B C D E F F 1 F 2 F 3 High-vacuum flange Forevacuum flange Venting flange Purge gas flange Water cooling connection Electrical connection Connection for DC motor Connection for regulator Connection for axial sensor Flange designations used in this product section 5

6 Turbomolecular Pumps General Use of Turbomolecular Pumps in Analytical Instruments Use of Turbomolecular Pumps in the Area of Semiconductor Processes All modern analytical methods for gas, liquid and plasma analysis like for example GC-MS, LC-MS and ICP-MS rely on mass spectrometers and for this reason require adequate highvacuum conditions. Also in electron microscopes and many surface analysis instruments the production of a highvacuum is essential. In over 90 % of all highvacuum applications, the turbomolecular pump has been found to be ideal. Thanks to the hydrocarbon-free vacuum, most simple operation, compact design and almost maintenance-free operation it has in most cases displaced above all the diffusion pump. On the basis of decades of experience and in cooperation with research facilities and the manufacturers of analytical instruments, Leybold has continually optimized its products. The new TURBOVAC wide range series is a further innovative step forward making available products which are most flexible and reliable. Owing to the modular concept the user may adapt his vacuum system precisely to his requirements perfectly integrate the components within his system and find the most cost-effective system configuration for his needs. In combination with backing pumps like the TRIVAC or Scroll pump, Leybold is able to offer the best vacuum system optimized for all major applications in the area of analytical instrumentation. In the semiconductor industry turbomolecular pumps are used on the following processes, among others: Etching Sputtering Ion implantation CVD Lithography. In these applications pumping of aggressive gases is often required. This may necessitate the use of pumps equipped with a purge gas facility or a magnetic suspension in order to avoid damaged bearings. Especially during metal etching, deposits may occur in the forevacuum space of the turbomolecular pump. In order to prevent this the pumps must be heated to a certain temperature. Such temperature controlled variants are optionally available for the MAG 1500 C, MAG 2000 C, MAG 2800 and MAG In contrast to turbomolecular pumps with mechanical bearings, magnetically levitated pumps provide the advantage that they prevent overheating of the bearings at high gas flows and effectively exclude any damage to the magnetic bearings by aggressive media. In electron microscopes and in lithographic equipment, low vibration levels are exceptionally important. For this reason magnetically levitated turbomolecular pumps should be used here. The recommended backing pumps are either dry compressing EcoDry pumps or rotary vane pumps from the TRIVAC range, possibly fitted with the BCS system. Entire high vacuum equipment of a CD/DVD coating system with TURBOVAC TW 250 S pumps 6

7 General Turbomolecular Pumps Use of Turbomolecular Pumps in the Area of Coating Systems Coating of optical and magnetic storage media, optical components as well as architectural glass requires highvacuum conditions. This is the only way to ensure that the formed layers will be uniform and adhere to the substrate. The way in which the vacuum is generated has a significant impact on the quality of the coating. By pumping the vacuum chamber down to pressures in the range of 10-6 mbar (0.75 x 10-6 Torr), interfering gas and water molecules are removed from the processing chamber. In the case of sputtering the coating process is run in the pressure range between 10-3 and 10-2 mbar (0.75 x 10-3 and 0.75 x 10-2 Torr), and in the case of evaporation coating, pressures below 10-4 mbar (0.75 x 10-4 Torr) are utilized. The turbomolecular pump meets all requirements of the customers as to a hydrocarbon-free vacuum, very simple operation, compact design and almost maintenance-free operation in an almost ideal manner. The range of pumps from Leybold includes des pumps with flange diameters ranging from 40 mm to 250 mm (1.57 in. to 9.84 in.) nominal width. Thus the right pump is available for each application, be it coating of data memories (CD, DVD, hard discs), coating of tools and coating of precision lenses in the area of optical components, displays or architectural glass. High performance glass coating plant Research and Development In the area of research, all types of turbomolecular pumps from Leybold are being used. In the case of particularly stringent requirements such as low vibration levels, a TURBOVAC with magnetic bearings should be selected; the same applies to those applications in which entirely hydrocarbon-free pump systems are required. Nuclear fusion technology 7

8 Turbomolecular Pumps General Pump / Converter Configurations for TURBOVAC Product Line P TURBOVAC 50, TURBOVAC 151, TURBOVAC 361, TURBOVAC 600 C, TURBOVAC 1000 C, TURBOVAC 1100 C Connecting cable, 20 m max. FC PS NT 10, NT 20 Mains cable P TW 70 H, TW 250 S, TW 300, TW 300 H Connecting cable, DC cable, 5 m max. 20 m max. Mains cable FC TDS, TD300 PS 24 V DC P FC DC cable, 20 m max. PS Mains cable TW 70 H, TW 250 S, TW 300, TW 300 H, TW V DC 59 V DC P FC PS Mains cable T 1600, TW 1600 P= Pump FC = Frequency Converter PS = Power Supply 8

9 General Turbomolecular Pumps Notes 9

10 Turbomolecular Pumps General Magnetic Bearings Technology The world-wide success of the TURBOVAC MAG product line results from more than 25 years of experience of Leybold in the development and manufacturing of turbomolecular pumps with magnetically levitated rotors. In 1976 Leybold started the market introduction of the famous TURBOVAC 560 M. This was the first magnetically levitated turbomolecular pump which became commercially available. Nowadays Leybold uses two design principles for the magnetic rotor suspension: 1. One axis with active bearing The rotor is suspended by permanent magnets and by electromagnets. The TURBOVAC 340 M and the MAG 400 are fitted with such a type of rotor suspension. MAG W 1300 C turbomolecular pump with magnetic rotor suspension and compound stage 2. Five axes with active bearings The rotor position is actively controlled by electromagnets in all 5 degrees of freedom. The TURBOVAC MAG 830/1300, MAG 1500, MAG 2000, MAG 2200 and MAG 2800/3200 are equipped with such a bearing system. 10

11 General Turbomolecular Pumps Pump / Converter Configurations for TURBOVAC MAG Product Line One axis with active bearing TMP 340 NT 340 M MAG 400 NT 340 MA Five axis with active bearings Analog Technology: MAG 2000 MAG.DRIVE 2000 Digital Technology: MAG 830/1300 MAG 1500 MAG 2200 MAG 2800/3200 MAG.DRIVE digital 11

12 Turbomolecular Pumps General Application Pumps Applications Analytical Instruments Leak detectors Mass spectrometers Gas chromatography (GC-MS) Liquid chromatography (LC-MS) Quadrupol time of flight (Q-TOF) Matrix assisted laser desorption time of flight (MALDI-TOF) Inductively coupled plasma mass spectrometry (ICP-MS) Electron beam microscopy Coating Data storage / optical Data storage / magnetic Flat panel displays Optical coating Large area coating Decorative coating Metallization Wear protection Metallurgy TV tube manufacturing R & D (Research and Development) Surface analysis UHV / XHV systems Particle accelerators Fusion experiments Space simulation Semiconductor Processes Load locks and transfer chambers Etch CVD PVD Ion implantation , C 1000 C 1100 C T 1600 TW 70 H TW 250 S TW 300 TW 300 H TW 701 TW M MAG 400 C/CT MAG 1500 CT MAG 2000 C/CT MAG W 830/1300 C MAG W 1500 CT MAG W 2200 C MAG W 2000 C/CT MAG W 2800/3200 C/CT 12

13 Turbomolecular Pumps Accessories Pumps Accessories Frequency converters Page NT NT NT TURBO.DRIVE S.61 TD Power supply PS , C 1000 C 1100 C T 1600 TW 70 H TW 250 S TW 300 TW 300 H TW 701 TW M MAG 400 C/CT Power supplies for TD S / TD NT 340 M.94 NT 340 MA.96 MAG.DRIVE MAG.DRIVE digital.100 Vibration absorber.102 Air cooling unit.102 Flange heaters for CF flanges.103 Fine filter.103 Venting valves.104 Purge gas and venting valve.104 Power failure venting valve.104 Water cooling Accessories for serial interfaces RS 232 C and RS 485 C.105 MAG 1500 CT MAG 2000 C/CT MAG W 830/1300 C MAG W 1500 CT MAG W 2200 C MAG W 2000 C/CT MAG W 2800/3200 C/CT 13

14 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage TURBOVAC 50 Typical Applications Leak detectors Mass spectrometers Electron beam microscopy TV tube manufacturing Load locks and transfer chambers h B 16 KF Ø d A 10 KF * C h 1 h 2 a B b Top view * drawn offset by 90 Flange 10 KF, for 63 CF version only a b d h h 1 h 2 40 KF mm in ISO-K mm in CF mm in C Technical Features Compact design Operation in any orientation Cooling by convection is sufficient for most applications Air and water cooling can be added easily Oil-free pump for generating clean high and ultrahigh vacuum conditions Dimensional drawing for the TURBOVAC 50 with flange 63 CF 3 10 l x s Pumping Speed N2 He H2 Advantages to the User Space-saving Easy to integrate into complex vacuum systems Low operating costs Highly reliable operation also in processes loaded with particles mbar Inlet Pressure Pumping speed as a function of the inlet pressure (TURBOVAC 50 with flange 63 ISO-K) 14

15 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC 50 Inlet flange Pump housing O-ring sealed O-ring sealed Metal sealed 40 KF 63 ISO-K 63 CF Aluminum Aluminum Stainless steel Pumping speed at 10-3 mbar N 2 I x s -1 He I x s -1 H 2 I x s -1 Max. gas throughput 1) at 10-2 mbar N 2 mbar x I x s -1 He mbar x I x s -1 H 2 mbar x I x s -1 Max. compression when idle N 2 Ultimate pressure with TRIVAC D 2,5 E mbar (Torr) < (< 3.75 x 10-8 ) < (< 3.75 x 10-8 ) < (< 1.5 x ) Max. foreline pressure for N 2 mbar (Torr) (< 0.75 x 10-1 ) (< 0.75 x 10-1 ) (< 0.75 x 10-1 ) Recommended forevacuum pump Run-up time to 95% of nominal speed min TRIVAC D 2,5 E TRIVAC D 2,5 E TRIVAC D 2,5 E Cooling water connection (hose nozzles) (for Part No ) mm (in.) Weight, approx. Max. power consumption Ultimate pressure kg W W ) for continuous operation when water-cooled 15

16 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage Ordering Information TURBOVAC 50 Inlet flange Foreline flange Cooling method Interface 40 KF 16 KF Convection 40 CF 16 KF Convection 63 ISO-K 16 KF Convection 63 CF 16 KF Convection Accessories, necessary for all pumps Electronic frequency converter NT V V Connecting cable NT 10 - pump 3 m (10.5 ft) 5 m (17.5 ft) Accessories, optional Air cooling unit 230 V AC 110 V AC Water cooling kit Flange heater 63 CF, 230 V, 50 Hz 63 CF, 110 V, 60 Hz Vibration absorber 63 ISO-K 63 CF Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No V0063 Part No

17 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Notes 17

18 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage TURBOVAC 151, 151 C ClassicLine Typical Applications Leak detectors Mass spectrometers Data storage Optical coating R & D, e.g. - UHV systems - Particle accelerators Load locks and transfer chambers Technical Features 126 h 3 C B 73 h4 A a79 1 a78 2 E 76 b ø132 d D h 1 h47 2 h 60 C 30 B D F 20 Top view E ø10 d l 76 a Compact design Operation in any orientation Oil-free pump for generating clean high and ultrahigh vacuum conditions C h h h 1 h 2 h 3 h 4 a a 1 a 2 b d d 1 l 063 ISO-K mm in ISO-K mm in CF mm in Dimensional drawing for the TURBOVAC 151 and 151 C Pumping Saugvermögen speed I x s mbar 10-1 N 2 Einlass-Druck Intake Pressure Ar He H 2 Advantages to the User Space-saving Easy to integrate into complex vacuum systems Low operating costs Highly reliable operation also in processes loaded with particles Pumping speed as a function of the inlet pressure (TURBOVAC 151 with flange 100) 18

19 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC 151 Inlet flange 100 ISO-K 100 CF Pumping speed N 2 I x s -1 Ar I x s -1 He I x s -1 H 2 I x s -1 Max. gas throughput N 2 mbar x I x s -1 Ar mbar x I x s -1 H 2 mbar x I x s -1 Compression ratio N 2 He H x x x x x x 10 2 Ultimate pressure mbar (Torr) < 1 x (< 0.75 x ) < 1 x (< 0.75 x ) Max. continuous inlet pressure 1) mbar (Torr) 5 x 10-2 (4 x 10-2 ) 5 x 10-2 (4 x 10-2 ) Max. foreline pressure for N 2 mbar (Torr) 5 x 10-1 (4 x 10-1 ) 5 x 10-1 (4 x 10-1 ) Recommended forevacuum pump from TRIVAC D 4 B to D 16 B from TRIVAC D 4 B to D 16 B Run-up time to 95% speed Purge / vent port Cooling water connection (hose nozzles) Weight, approx. Max. power consumption at ultimate pressure 1) Water-cooled min mm (in.) kg (lbs) VA VA KF 10 KF 10 (0.39) 10 (0.39) 8 (17) 88 (17)

20 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage Ordering Information TURBOVAC 151 Inlet flange Foreline flange Cooling method Item 100 ISO-K 25 KF Water-cooled TURBOVAC ISO-K 25 KF Water-cooled TURBOVAC 151 C 100 CF 25 KF Water-cooled TURBOVAC 151 Accessories, necessary for all pumps Electronic frequency converter NT V AC 120 V AC 100 V AC Connecting cable NT 20 - pump 03 m (10.5 ft) 05 m (17.5 ft) 10 m (35.0 ft) 20 m (70.0 ft) Accessories, optional Air cooling unit 230 V AC 110 V AC Flange heater 100 CF 230 V AC 110 V AC Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No

21 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Notes 21

22 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage TURBOVAC 361, 361 C ClassicLine Typical Applications Leak detectors Mass spectrometers Data storage Optical coating R & D, e.g. - UHV systems - Particle accelerators Load locks and transfer chambers A Top view Technical Features Compact design h 3 h 4 C B a a ød a E D h 2 h 1 h 60 C 30 B D F 20 E l ød 1 b Operation in any orientation Oil-free pump for generating clean high and ultrahigh vacuum conditions C h h h 1 h 2 h 3 h 4 a b d 1 l 100 ISO-K mm in CF mm in ISO-K mm in CF mm in Dimensional drawing for the TURBOVAC 361 and 361 C Advantages to the User Space-saving Easy to integrate into complex vacuum systems Low operating costs Highly reliable operation also in processes loaded with particles 22

23 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC 361 Inlet flange 100 ISO-K 100 CF 160 ISO-K 160 CF Pumping speed N 2 I x s -1 Ar I x s -1 He I x s -1 H 2 I x s -1 Max. gas throughput N 2 mbar x I x s -1 Ar mbar x I x s -1 Compression ratio N 2 He H x x x x x x 10 3 Ultimate pressure mbar (Torr) < 1 x (< 0.75 x ) < 1 x (< 0.75 x ) Max. continuous inlet pressure 1) mbar (Torr) 5 x 10-2 (3.75 x 10-2 ) 5 x 10-2 (3.75 x 10-2 ) Max. foreline pressure for N 2 mbar (Torr) 5 x 10-1 (3.75 x 10-1 ) 5 x 10-1 (3.75 x 10-1 ) Recommended forevacuum pump from TRIVAC D 16 B to D 25 B from TRIVAC D 16 B to D 25 B Run-up time to 95% speed Purge / vent port min KF 10 KF Cooling water connection (hose nozzle) mm (in.) 10 (0.39) 10 (0.39) Weight, approx. Max. power consumption at ultimate pressure 1) Water-cooled kg (lbs) VA VA 12 (26) 12 (26) Torr I x s cfm Pumping speed mbar N2 Intake Pressure Ar He H2 Pumping speed as a function of the inlet pressure (TURBOVAC 361 with flange 100) 23

24 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage Ordering Information TURBOVAC 361 Inlet flange Foreline flange Cooling method Item 100 ISO-K 25 KF Water-cooled TURBOVAC ISO-K 25 KF Water-cooled TURBOVAC 361 C 100 CF 25 KF Water-cooled TURBOVAC ISO-K 25 KF Water-cooled TURBOVAC ISO-K 25 KF Water-cooled TURBOVAC 361 C 160 CF 25 KF Water-cooled TURBOVAC 361 Accessories, necessary for all pumps Electronic frequency converter NT V AC 120 V AC 100 V AC Connecting cable NT 20 - pump 03 m (10.5 ft) 05 m (17.5 ft) 10 m (35.0 ft) 20 m (70.0 ft) Accessories, optional Air cooling unit 230 V AC 110 V AC Flange heater 100 CF 230 V AC 110 V AC Flange heater 160 CF 230 V AC 110 V AC Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No

25 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Notes 25

26 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage TURBOVAC 600 C ClassicLine Typical Applications Load locks and transfer chambers Optical coating Flat panel displays R & D A d225 C* h D* 175 h 1 E B 105 h h h 4 h b a Top view 124,5 a 1 C E * drawn offset by ,7 b 1 F B E 124,5 b D 2 A Technical Features Compact design Operation in any orientation Oil-free pump for generating clean high and ultrahigh vacuum conditions h h 1 h 2 h 3 h 4 h 5 a a 1 b b 1 b 2 l d 160 ISO-K mm in CF mm in Dimensional drawing for the TURBOVAC 600 C Advantages to the User Installation in any orientation Pumping speed l x s He H 2 N 2 Ar Highly reliable due to hybrid ceramic ball bearings Life time lubrication and maintenance-free Option: Purge gas facility Pressure mbar10 Pumping speed for different gases as a function of intake pressure (TURBOVAC 600 C with flange 160 ISO-K) 26

27 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC 600 C Inlet flange 160 ISO-K 160 CF Pumping speed N 2 I x s -1 He I x s -1 H 2 I x s -1 Max. gas throughput N 2 mbar x I x s -1 Ar mbar x I x s -1 Compression ratio N 2 He H < 4 < 4 > x x 10 3 Ultimate pressure mbar (Torr) < (< ) Speed min Run-up time (frequency converter), approx. min 4 Max. continuous inlet pressure 1) (continuous) mbar (Torr) 1 x 10-2 (0.75 x 10-2 ) Max. foreline pressure for N 2 mbar (Torr) 1 x 10-1 (0.75 x 10-1 ) Recommended forevacuum pump for standard operation for purge gas operation Run-up time to 95% speed Purge / vent port Cooling water connection (hose nozzles) Weight, approx. Max. power consumption at ultimate pressure 1) Water-cooled min mm (in.) kg (lbs) VA VA TRIVAC D 25 B / 40 B TRIVAC 40 B 3 10 KF 10 (0.39) 17 (37.5)

28 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage Ordering Information Inlet flange Foreline flange Cooling method Item 160 ISO-K 40 KF Water-cooled TURBOVAC 600 C 160 CF 40 KF Water-cooled TURBOVAC 600 C TURBOVAC 600 C Part No V0015 Part No V0017 Accessories, necessary for all pumps Electronic frequency converter NT V AC 120 V AC 100 V AC Connecting cable NT 20 - pump 03 m (10.5 ft) 05 m (17.5 ft) 10 m (35.0 ft) 20 m (70.0 ft) Part No Part No Part No Part No Part No Part No Part No Accessories, optional Air cooling unit 230 V AC 115 V AC Flange heater 160 CF 230 V AC 110 V AC Part No Part No Part No Part No

29 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Notes 29

30 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage TURBOVAC 1000 C ClassicLine Typical Applications Evaporation and sputtering systems Metallurgy Research systems h h 1) 1 2) 141 A d a d 1 C ) D h 4 2) E B F ) h h 2) 3 1) a 2) Upper view D E 45 B α F (C) α E 141 b A 1) 40 KF, cast base flange 2) 63 KF, screwed in Technical Features Robust rotor design Operation in any orientation Highest pumping speed and throughput h h 1 h 2 h 3 h 4 a a 1 b l d l d CF/40 KF 1) mm in CF/40 KF 1) mm in ISO-K/40 KF 1) mm in ISO-K/63 KF 2) mm in Dimensional drawing for the TURBOVAC 1000 C Pumping speed l x s TURBOVAC 1000 C Pressure mbar 10 Advantages to the User Installation in any orientation Highly reliable due to hybrid ceramic ballbearings Standard model: Venting flange, water cooling Options: Air cooling, purge gas facility Pumping speed for air as a function of intake pressure (TURBOVAC 1000 C with 250 flange) 30

31 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Inlet flange Technical Data TURBOVAC 1000 C 160 ISO-K / 160 CF 200 CF 250 ISO-K Pumping speed N 2 I x s -1 He I x s -1 H 2 I x s -1 Compression ratio N 2 He H > 10 9 > 10 9 > x x x x x x 10 3 Ultimate pressure to DIN mbar (Torr) < < < (< 0.75 x ) (< 0.75 x ) (< 0.75 x ) Speed min -1 (rpm) Run-up time (frequency converter) Run-up time NT 20, approx. Type of bearing Type of lubrication Installation orientation Cooling Weight, approx. Recommended backing pump for standard operation for purge gas operation min min kg (lbs) TRIVAC TRIVAC Hybrid ceramic ball bearings Hybrid ceramic ball bearings Hybrid ceramic ball bearings Grease Grease Grease Any Any Any Water (air) Water (air) Water (air) 25 (55.1) 25 (55.1) 25 (55.1) D 25 B / D 40 B D 25 B / D 40 B D 25 B / D 40 B D 40 B / D 65 B D 40 B / D 65 B D 40 B / D 65 B Ordering Information TURBOVAC 1000 C Inlet flange Foreline flange Cooling method Interface 160 CF 40 ISO-K Water-cooled 200 CF 40 ISO-K Water-cooled 250 ISO-K 40 ISO-K Water-cooled 250 ISO-K 63 ISO-K Water-cooled Part No Part No Part No Part No Accessories, necessary for all pumps Electronic frequency converter NT V AC 120 V AC Connecting cable NT 20 - pump 03 m (10.5 ft) 05 m (17.5 ft) 10 m (35.0 ft) 20 m (70.0 ft) Part No Part No Part No Part No Part No Part No Accessories, optional Air cooling unit 115 V AC Part No

32 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage TURBOVAC 1100 C ClassicLine Typical Applications Data storage Flat panel displays Optical coating Large area coating R & D, e.g. - Fusion experiments - Space simulation Load locks and transfer chambers h h 1 h 3 ød a D A C B E F a 1 h 6 h 2 h 4 h 5 Top view E b F B E D h h 1 h 2 h 3 h 4 h 5 h 6 a a 1 b d 200 ISO-K mm in ISO-K mm in (C) 45 Technical Features Robust rotor design Operation in any orientation Highest pumping speed and throughput Integrated control system for monitoring the temperature of the bearings Oil-free pump for generating clean high and ultrahigh vacuum conditions Dimensional drawing for the TURBOVAC 1100 C Torr 750 Advantages to the User Space-saving I x s Easy to integrate into complex vacuum systems High productivity Pumping Speed mbar 10 N2 Inlet Pressure Ar H2 Low operating costs Highly reliable operation also in processes loaded with particles Pumping speed as a function of the inlet pressure (TURBOVAC 1100 C with flange 250) 32

33 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Inlet flange Technical Data TURBOVAC 1100 C 200 ISO-K 250 ISO-K Pumping speed N 2 I x s -1 Ar I x s -1 He I x s -1 H 2 I x s -1 Max. gas throughput N 2 mbar x I x s -1 Ar mbar x I x s -1 He mbar x I x s -1 H 2 mbar x I x s -1 Compression ratio N 2 Ar H x x x x x x 10 4 Ultimate pressure Max. foreline pressure for N 2 mbar (Torr) mbar (Torr) < 3 x (< 2.2 x ) < 3 x (< 2.2 x ) 0.1 (0.075) 0.1 (0.075) Recommended forevacuum pump Run-up time to 95% speed Purge / vent port Cooling water connection (hose nozzles) Weight, approx. Supply voltage Max. power consumption min mm (in.) kg (lbs) V AC VA TRIVAC D 65 B / EcoDry M15/20 TRIVAC D 65 B / EcoDry M15/ KF 10 KF 10 (0.39) 10 (0.39) 22 (48) 22 (48) Ordering Information Inlet flange Foreline flange Cooling method Interface 200 ISO-K 63 ISO-K Water-cooled 250 ISO-K 63 ISO-K Water-cooled Accessories, necessary for all pumps Electronic frequency converter NT V AC 120 V AC Connecting cable NT 20 - pump 03 m (10.5 ft) 05 m (17.5 ft) 10 m (35.0 ft) 20 m (70.0 ft) Purge / vent valve, 16 KF 24 V DC; 0.6 mbar x I x s -1 = 36 sccm TURBOVAC 1100 C Part No Part No Part No Part No Part No Part No Part No Part No Part No Note for the North and South American Continents: For special application we recommend the TURBOVAC 1000 C. Please contact your sale office 33

34 Turbomolecular Pumps with Mechanical Rotor Suspension without Compound Stage TURBOVAC T 1600 / T 1601 Typical Applications Data storage Flat panel displays Optical coating Large area coating R & D, e.g. - Fusion experiments - Space simulation ød ød Technical Features Frequency converter and power supply integrated h h 2 h 1 h h 2 h 1 h 3 h 3 Robust rotor design Operation in any orientation a Highest pumping speed and throughput ø d 1 ø d Top view Oil-free pump for generating clean high and ultrahigh vacuum conditions a d d 1 h h 1 h 2 h ISO-F mm in ISO-F mm in CF mm in Purge gas and venting valve integrated For special outside influences (only T 1601) Dimensional drawing for the TURBOVAC T 1600 Pumping Speed 10 4 I x s mbar 10 N 2 Inlet Pressure Ar He H 2 Torr 10 Advantages to the User Space-saving Easy to integrate into complex vacuum systems High productivity Low operating costs Highly reliable operation also in processes loaded with particles Pumping speed as a function of the inlet pressure (TURBOVAC T 1600 with flange 250) 34

35 without Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC T 1600 / T 1601 Inlet flange Pumping speed N 2 I x s -1 Ar I x s -1 He I x s -1 H 2 I x s -1 Max. gas throughput N 2 mbar x I x s -1 Ar mbar x I x s -1 He mbar x I x s -1 H 2 mbar x I x s -1 Compression ratio N 2 Ar He H 2 Ultimate pressure mbar (Torr) Max. foreline pressure for N 2 mbar (Torr) Recommended forevacuum pump (alternatively) Run-up time to 95% speed Purge / vent port Cooling water connection Weight, approx. Supply voltage Max. power consumption min kg (lbs) V VA Ordering Information 200 ISO-F 250 ISO-F 250 CF x x x x x x x x 10 2 < 3 x (< 2.2 x ) < 3 x (< 2.2 x ) 0.5 (0.375) 0.5 (0.375) TRIVAC D 65 B + RUVAC WA 501 TRIVAC D 65 B + RUVAC WA 501 TRIVAC D 65 B TRIVAC D 65 B EcoDry M EcoDry M < 10 < 10 G 1/4" G 1/4" G 3/8" G 3/8" 40 (88) 40 (88) TURBOVAC T 1600 Inlet flange Foreline flange Cooling method Interface 200 ISO-F 40 KF Water-cooled 200 ISO-F 40 KF Water-cooled Profibus 250 ISO-F 40 KF Water-cooled 250 ISO-F 40 KF Water-cooled Profibus 250 ISO-F 63 ISO-K Water-cooled 250 CF 40 KF Water-cooled Purge filter Accessories for RS 232 C and RS 485 C interfaces Ordering Information Inlet flange Foreline flange Cooling method Interface 250 ISO-F 40 KF Water-cooled Profibus Accessories for RS 232 C and RS 485 C interfaces Part No V1144 Part No V2144 Part No V1444 Part No V2444 Part No V1544 Part No V1844 Part No see chapter Turbomolecular Pumps, para. Accessories TURBOVAC T 1601 Part No V4444 see chapter Turbomolecular Pumps, para. Accessories 35

36 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage TURBOVAC TW 70 H Typical Applications Mass spectrometers Electron beam microscopy Leak detectors R & D, e.g. - UHV systems Load locks and transfer chambers ød ø d 1 h 1 h Top view a h h 1 d d 1 63 ISO-K mm in CF mm in a Technical Features Integrated or external frequency converter Compact design Operation in any orientation High foreline tolerance Oil-free pump for generating clean high and ultrahigh vacuum conditions Dimensional drawing for the TURBOVAC TW 70 H Pumping speed 10 3 I x s Torr N 2 Ar He H 2 Advantages to the User Space-saving Easy to integrate into complex vacuum systems Allows the use of down-sized forevacuum pumps Low operating costs Highly reliable operation mbar 10 1 Inlet Pressure Pumping speed as a function of the inlet pressure 36

37 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Inlet flange Technical Data TURBOVAC TW 70 H O-ring sealed Metal sealed 63 ISO-K 63 CF Pump housing Aluminum Stainless steel Pumping speed at 10-5 / 10-3 mbar N 2 I x s -1 Ar I x s -1 H 2 I x s -1 He I x s -1 Max. gas throughput 1) at 10-1 mbar N 2 mbar x I x s -1 Ar mbar x I x s -1 H 2 mbar x I x s -1 He mbar x I x s -1 Max. compression when idle N 2 Ar H 2 He Ultimate pressure with two-stage oil-sealed rotary vane vacuum pump TRIVAC D 2,5 E mbar (Torr) with dry compressing scroll vacuum pump SC 5 D mbar (Torr) with diaphragm pump DIVAC 0.8 T mbar (Torr) 60 / / / / / / / / x 10 8 at 14 mbar 1 x at 10 mbar 1 x 10 7 at 14 mbar 4 x 10 3 at 0.2 mbar 2 x 10 5 at 2 mbar < 5 x 10-8 (< 3.75 x 10-8 ) < 2 x (< 1.5 x ) 0.05 ( 0.04) < 5 x 10-9 (< 3.75 x 10-9 ) Max. foreline pressure for N 2 mbar (Torr) 20 (15) 20 (15) Recommended forevacuum pump two-stage oil-sealed rotary vane vacuum pump diaphragm pump oil-free scroll vacuum pump TRIVAC D 2,5 E DIVAC 0,8 T SC 5 D TRIVAC D 2,5 E DIVAC 0,8 T SC 5 D Run-up time to 95% of nominal speed Cooling water connection (option) Weight, approx. with / without frequency converter Supply voltage Max. power consumption Run up / ultimate pressure min kg (lbs) V DC W x G 1/8" 2 x G 1/8" 3.0 (6.62) / 2.3 (5.08) 3.0 (6.62) / 2.3 (5.08) / / 30 1) for continuous operation when water-cooled 37

38 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage Ordering Information TURBOVAC TW 70 H TW 70 H with integrated frequency converter TURBO.DRIVE S Inlet flange Foreline flange Cooling method Interface 63 ISO-K 16 KF Air-cooled RS 485 C 63 ISO-K 16 KF Air-cooled RS 232 C 63 ISO-K 16 KF Water-cooled RS 485 C 63 ISO-K Camozzi coupling 1) Air-cooled RS 485 C 63 ISO-K Camozzi coupling 1) Water-cooled RS 485 C 63 CF 16 KF Air-cooled RS 232 C 63 CF 16 KF Water-cooled RS 485 C TW 70 H without frequency converter TURBO.DRIVE S Inlet flange Foreline flange Cooling method Interface 63 ISO-K 16 KF Convection 63 ISO-K 16 KF Air-cooled 63 ISO-K Camozzi coupling 1) Convection 63 CF 16 KF Convection For operation, one frequency converter TURBO.DRIVE S is necessary Electronic frequency converter TURBO.DRIVE S with heat sink RS 485 C interface RS 232 C interface Connecting cable (TURBO.DRIVE S - pump) 1 m (03.5 ft) 3 m (10.5 ft) 5 m (17.5 ft) Accessories, necessary for all pumps START/STOP switch for manual operation of the turbomolecular pump Power supplies TURBO.POWER 300 TURBO.CONTROL 300 Accessories, optional Water cooling unit with 2 x G 1/8" connection including 2 hose nozzles G 1/8", OD 8 mm for water hose, 2 gaskets (copper) 10 x 14 x 1 Air cooling unit (uses V DC from pump connection) Flange heater 63 CF 230 V, 50 Hz 110 V, 60 Hz Splinter guard 63 ISO-K (course) 63 CF (course) 63 CF (fine) Vibration absorber 63 ISO-K 63 CF Accessories for serial interfaces RS 232 C and RS 485 C Part No V1235 Part No V1236 Part No V1435 Part No V1215 Part No V1415 Part No V2236 Part No V2435 Part No V1934 Part No V1234 Part No V1914 Part No V2934 Part No V0006 Part No V0005 Part No Part No Part No Part No see chapter Turbomolecular Pumps with Mechanical Rotor Suspension, para. Electronic Frequency Converters Part No V0001 Part No V0001 Part No Part No Part No Part No Part No Part No V0063 Part No see chapter Turbomolecular Pumps, para. Accessories 1) Quick coupling for plastic vacuum hoses with an OD of 10 mm. We recommend polyamide hoses 38

39 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension TW 70 H with integrated frequency converter TURBO.DRIVE S Mains Power supply unit 24 V DC cable with shield, 20 m (70.0 ft) max. e.g. TURBO.POWER 300 TURBO.CONTROL 300 TW 70 H and external frequency converterturbo.drive S Mains Power supply unit e.g. TURBO.POWER 300 TURBO.CONTROL V DC cable with shield, 20 m (70.0 ft) max. Frequency converter TURBO.DRIVE S with heat sink Connecting cable, 5 m (17.5 ft) max. The modular concept 63 ISO-K Ø 95 ø Cable length 400 mm Ø TURBO.DRIVE S Part No V1235 TW 70 H with 63 ISO-K flange, air-cooled, foreline connection 16 KF, with frequency converter Part No V1231 TW 70 H with 63 ISO-K flange, water-cooled, foreline connection 16 KF, with frequency converter Part No V1234 TW 70 H with 63 ISO-K flange, air-cooled, foreline connection 16 KF, without frequency converter Selected dimensional drawings for the TURBOVAC TW 70 H versions 39

40 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage TURBOVAC 250 S Typical Applications Analytical instruments Coating R & D b b 1 d d 1 h 100 ISO-K mm in CF mm in Upper view 7,5 105 Technical Features Integrated or external frequency converter Compact design h 1 h 2 h 3 h 4 h ISO-K mm in CF mm in M4 d1 Efficient air-cooling system integrated h h1 h5 h2 b b 1 d h3 h4 Dimensional drawing for the TURBOVAC 250 S without frequency converter Throughput TURBOVAC TW 250 S TRIVAC D 16 B TRIVAC D 8 B Advantages to the User Highest pumping speed and throughput for N 2 and Ar Highest reliability in operation 10-4 ECODRY M 50 Hz mbar Inlet pressure Operation diagram for nitrogen for TURBOVAC TW 250 S 40

41 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC 250 S Inlet flange 100 ISO-K / 100 CF Pumping speed at 10-5 mbar N 2 I x s -1 Ar I x s -1 H 2 I x s -1 He I x s -1 Max. gas throughput, max. N 2 Ar H 2 He Compression ratio N 2 Ar H 2 He Ultimate pressure with two-stage oil-sealed rotary vane pump mbar (Torr) mbar x l x s -1 at 10-1 mbar 1.6 mbar x l x s -1 at 10-2 mbar 1.1 mbar x l x s -1 at 10-1 mbar 2.4 mbar x l x s -1 at 10-1 mbar 3.0 x 10 7 at 3 mbar 1.0 x 10 7 at 6 mbar 5.0 x 10 2 at 0.2 mbar 3.2 x 10 3 at 0.7 mbar < 2 x 10-8 (< 1.5 x 10-2 ) Max. permissible backing pressure for N 2 mbar (Torr) 3 (2.25) Operating speed Run-up time, approx. Forevacuum connection Venting connection Weight without frequency converter with frequency converter min -1 (rpm) min kg (lbs) kg (lbs) KF Thread M (11.0) 5.8 (12.6) Recommended forevacuum pumps TRIVAC Diaphragm pump with an ultimate pressure < 3 mbar and a pumping speed at 3 mbar TRIVAC (at purge gas operation) D 2.5 E upon request D 8 B 41

42 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage Ordering Information TURBOVAC 250 S with integrated frequency converter TDS Inlet flange Cooling method Splinter guard Frequency converter 100 ISO-K Water-cooled TDS / PB 100 ISO-K Water-cooled Course TDS / PB 100 ISO-K Air-cooled Course TDS / PB 100 ISO-K Air-cooled TDS / RS 232 C 100 ISO-K Air-cooled TDS / RS 485 C 100 CF Air-cooled TDS / RS 232 C 100 CF Air-cooled TDS / RS 485 C TURBOVAC 250 S without integrated frequency converter TDS Inlet flange Cooling method Splinter guard Frequency converter 100 ISO-K Air-cooled Course 100 ISO-K Air-cooled Course For operation, one frequency converter TDS is necessary Electronic frequency converter TDS without heat sink with RS 485 C interface with RS 232 C interface Connecting cable TDS pump 1 m (3.5 ft) Power supplies TURBO.POWER 300 TURBO.CONTROL 300 Accessories, necessary for all pumps Venting valve mounting kit Power failure venting valve 220/240 V AC 24 V AC Venting valve 220/240 V AC 110/120 V AC 24 V AC 24 V AC Accessories, optional Water cooling unit with 2x G 1/8" connection including 2 hose nozzles G 1/8", OD 10 mm for water hose, 4 gaskets, 2 blank-off plugs Air cooling unit (uses V DC from pump connection) Flange heater 100 CF, 230 V, 50 Hz 100 CF, 110 V, 60 Hz Splinter guard 100 ISO-K/CF coarse (3.2 x 3.2 mm (0.13 x 0.13 in.)) fine (1.6 x 1.6 mm (0.06 x 0.06 in.)) 160 ISO-K 160 CF Vibration absorber 100 ISO-K 100 CF 160 ISO-K 160 CF Accessories for serial interfaces RS 232 C and RS 485 C TURBOVAC 250 S Part No Part No V0016 Part No V0009 Part No V0011 Part No V0013 Part No V0012 Part No V0014 Part No Part No V0007 Part No V0003 Part No V0002 Part No see chapter Turbomolecular Pumps with Mechanical Rotor Suspension, para. Electronic Frequency Converters Part No Part No Part No Part No Part No Part No Part No Part No V0002 Part No Part No Part No Part No V0101 Part No V0102 Part No Part No Part No V0100 Part No Part No Part No see chapter Turbomolecular Pumps, para. Accessories 42

43 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Notes 43

44 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage TURBOVAC TW 300 Typical Applications Mass spectrometers Production of thin films CD and DVD coating R & D, e.g. - UHV systems - Particle accelerators Load locks and transfer chambers Ø a 2 Ø a 1 Top view Technical Features Integrated or external frequency converter Compact design h 2 h h 1 Operation in any orientation Highest pumping speed for Nitrogen and Argon h 3 Highly effective air-cooling unit l b 1 b a Oil-free pump for generating clean high and ultrahigh vacuum conditions a a 1 a 2 h h 1 h 2 h 3 b b 1 l 100 ISO-K mm in ISO-K mm in CF mm in Dimensional drawing for the TURBOVAC TW 300 Pumping Speed 10 3 I x s Torr 750 N 2 Ar He H 2 Advantages to the User Space-saving Easy to integrate into complex vacuum systems High foreline tolerance allows the use of down-sized forevacuum pumps High productivity Low operating costs mbar 10 1 Inlet Pressure Pumping speed as a function of the inlet pressure 44

45 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC TW 300 Inlet flange Pump housing O-ring sealed O-ring sealed Metal sealed 100 ISO-K 160 ISO-K 100 CF Aluminum Aluminum Stainless steel Pumping speed 1) at 10-5 / 10-3 mbar N 2 I x s -1 Ar I x s -1 H 2 I x s -1 He I x s -1 Ultimate pressure (for CF pumps) with two-stage oil-sealed rotary vane vacuum pump TRIVAC D 2,5 E mbar (Torr) with dry compressing scroll vacuum pump SC 15 D mbar (Torr) with diaphragm pump DIVAC 2.5 VT mbar (Torr) 240 / / / / / / / / / / / / 220 < 2 x 10-8 (< 1.5 x 10-8 ) < 2 x 10-8 (< 1.5 x 10-8 ) < 2 x (< 1.5 x ) ( 0.012) < 4 x 10-9 (< 3 x 10-9 ) Max. foreline pressure for N 2 mbar (Torr) < 10 (water-cooled) < 10 (water-cooled) < 5 (air-cooled) Recommended forevacuum pump two-stage oil-sealed rotary vane vacuum pump dry compressing scroll vacuum pump TRIVAC D 2,5 E TRIVAC D 2,5 E TRIVAC D 2,5 E SC 15 D SC 15 D SC 15 D Run-up time to 95% of nominal speed Purge / vent port Cooling water connection (option) Weight, approx. with / without frequency converter Supply voltage Max. power consumption Run up / ultimate pressure min kg (lbs) V DC W KF 16 KF 16 KF 2x G 1/8" 2x G 1/8" 2x G 1/8" 6.8 (15.0) / 6.0 (13.2) 6.8 (15.0) / 6.0 (13.2) 6.8 (15.0) / 6.0 (13.2) / / / 30 1) for continuous operation when water-cooled 45

46 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage Ordering Information TURBOVAC TW 300 TW 300 with integrated frequency converter TD 300 Inlet flange Foreline flange Cooling method Interface 100 ISO-K 16 KF Air-cooled RS 485 C 100 ISO-K 16 KF Water-cooled RS 232/422 C 100 CF 16 KF Water-cooled RS 232/422 C 160 ISO-K 16 KF Water-cooled RS 485 C 160 ISO-K 16 KF Air-cooled RS 485 C TW 300 without frequency converter TD 300 Inlet flange Foreline flange Cooling method Interface 100 ISO-K 16 KF Convection 100 ISO-K 16 KF Air-cooled For operation, one frequency converter TD 300 is necessary Electronic frequency converter TD 300 without heat sink with Profibus with RS 485 C interface with RS 232/422 C interface Connecting cable TD 300 pump 1 m (03.5 ft) 3 m (10.5 ft) 5 m (17.5 ft) Accessories, necessary for all pumps START/STOP switch for manual operation of the turbomolecular pump Power supplies TURBO.POWER 300 TURBO.CONTROL 300 Accessories, optional Water cooling unit with 2x G 1/8" connection including 2 hose nozzles G 1/8", OD 10 mm for water hose, 4 gaskets, 2 blank-off plugs Air cooling unit (uses V DC from pump connection) Flange heater 100 CF, 230 V, 50 Hz 100 CF, 110 V, 60 Hz Splinter guard 100 ISO-K/CF coarse (3.2 x 3.2 mm (0.13 x 0.13 in.)) fine (1.6 x 1.6 mm (0.06 x 0.06 in.)) 160 ISO-K 160 CF Vibration absorber 100 ISO-K 100 CF 160 ISO-K 160 CF Accessories for serial interfaces RS 232 C and RS 485 C Part No V2105 Part No V2106 Part No V2103 Part No V2108 Part No Part No V2101 Part No V0003 Part No V0004 Part No V0003 Part No V0001 Part No Part No Part No Part No see chapter Turbomolecular Pumps with Mechanical Rotor Suspension, para. Electronic Frequency Converters Part No V0002 Part No Part No Part No Part No V0101 Part No V0102 Part No Part No Part No V0100 Part No Part No Part No see chapter Turbomolecular Pumps, para. Accessories 46

47 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension TW 300 (cooled by convection) with integrated frequency converter TD 300 Power supply unit Mains 24 V DC cable, 20 m e.g. (70.0 ft) max. TURBO.POWER 300 TURBO.CONTROL 300 TW 300 (cooled by convection) without integrated frequency converter TD 300 Connecting cable, 5 m (17.5 ft) max. TD 300 with heat sink Drive (X3) HEAT SINK DC 24 V (X4) 24 V DC cable, 20 m (70.0 ft) max. Power supply unit e.g. TURBO.POWER 300 TURBO.CONTROL 300 Mains TW 300 (with air cooling) with integrated frequency converter TD 300 Power supply unit Mains 24 V DC cable, 20 m e.g. (70.0 ft) max. TURBO.POWER 300 TURBO.CONTROL 300 TW 300 (with air cooling) without integrated frequency converter TD 300 TD 300 with heat sink Connecting cable, 5 m (17.5 ft) max. Drive (X3) HEAT SINK DC 24 V (X4) 24 V DC cable, 20 m (70.0 ft) max. Power supply unit e.g. TURBO.POWER 300 Mains TURBO.CONTROL 300 The modular concept 47

48 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage TURBOVAC TW 300 H Typical Applications Mass spectrometers R & D, e.g. - UHV systems - Particle accelerators Load locks and transfer chambers Ø a 2 Ø a 1 Top view Technical Features Integrated frequency converter Compact design h 1 Operation in any orientation h 2 h High pumping speed and compression for light gases Highly effective air-cooling unit l b 1 b h 3 a Oil-free pump for generating clean high and ultrahigh vacuum conditions a a 1 a 2 h h 1 h 2 h 3 b b 1 l 100 ISO-K mm in CF mm in Dimensional drawing for the TURBOVAC TW 300 H Torr Advantages to the User Space-saving Pumping Speed I x s N 2 Ar He H 2 Easy to integrate into complex vacuum systems High foreline tolerance allows the use of down-sized forevacuum pumps Low operating costs mbar 10 1 Inlet Pressure Pumping speed as a function of the inlet pressure 48

49 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC TW 300 H Inlet flange O-ring sealed Metal sealed 100 ISO-K 100 CF Pump housing Aluminum Stainless steel Pumping speed at 10-5 / 10-3 mbar N 2 I x s -1 Ar I x s -1 H 2 I x s -1 He I x s -1 Ultimate pressure (for CF pumps) with two-stage oil-sealed rotary vane vacuum pump TRIVAC D 2,5 E mbar (Torr) with dry compressing scroll vacuum pump SC 15 D mbar (Torr) with diaphragm pump DIVAC 2.5 VT mbar (Torr) 240 / / / / / / / / 230 < 1 x 10-8 (< 0.75 x 10-8 ) < 1 x (< 0.75 x ) ( 0.012) < 1 x 10-9 (< 0.75 x 10-9 ) Max. foreline pressure for N 2 mbar (Torr) < 10 (water-cooled) < 5 (air-cooled) Recommended forevacuum pump two-stage oil-sealed rotary vane vacuum pump dry compressing scroll vacuum pump TRIVAC D 2,5 E SC 15 D TRIVAC D 2,5 E SC 15 D Run-up time to 95% of nominal speed Purge / vent port Cooling water connection (option) Weight, approx. with / without frequency converter Supply voltage Max. power consumption Run up / ultimate pressure min kg (lbs) V DC W KF 16 KF 2x G 1/8" 2x G 1/8" 6.8 (15.0) / 6.0 (13.2) 6.8 (15.0) / 6.0 (13.2) / / 30 49

50 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage Ordering Information TURBOVAC TW 300 H TW 300 H with integrated frequency converter TD 300 Inlet flange Foreline flange Cooling method Interface 100 ISO-K 16 KF Air-cooled RS 485 C 100 CF 16 KF Air-cooled RS 485 C 100 CF 16 KF Air-cooled RS 232 C 100 CF 16 KF Water-cooled RS 485 C Part No V2107 Part No V2102 Part No V2104 Part No Accessories, necessary for all pumps START/STOP switch for manual operation of the turbomolecular pump Power supplies TURBO.POWER 300 TURBO.CONTROL 300 Part No see chapter Turbomolecular Pumps with Mechanical Rotor Suspension, para. Electronic Frequency Converters Accessories, optional Water cooling unit with G 1/8" connection including 2 hose nozzles G 1/8", OD 10 mm for water hose, 4 gaskets, 2 blank-off plugs Air cooling unit (uses V DC from pump connection) Flange heater 100 CF, 230 V, 50 Hz 100 CF, 110 V, 60 Hz Splinter guard 100 ISO-K/CF coarse (3.2 x 3.2 mm (0.13 x 0.13 in.)) fine (1.6 x 1.6 mm (0.06 x 0.06 in.)) Vibration absorber 100 ISO-K 100 CF Accessories for serial interfaces RS 232 C and RS 485 C Part No V0002 Part No Part No Part No Part No V0101 Part No V0102 Part No V0100 Part No see chapter Turbomolecular Pumps, para. Accessories 50

51 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension TW 300 H (cooled by convection) with integrated frequency converter TD 300 Power supply unit Mains 24 V DC cable, 20 m (70.0 ft) max. e.g. TURBO.POWER 300 TURBO.CONTROL 300 TW 300 H (with air cooling) with integrated frequency converter TD 300 Power supply unit Mains 24 V DC cable, 20 m (70.0 ft) max. e.g. TURBO.POWER 300 TURBO.CONTROL 300 The modular concept 51

52 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage TURBOVAC TW 701 Typical Applications Mass spectrometers Data storage Flat panel displays R & D, e.g. - UHV systems - Particle accelerators Load locks and transfer chambers ø d 1 ød l 1 h 1 l Technical Features Integrated frequency converter Operation in any orientation h 2 h 3 h ø d 2 b Highest pumping speed and throughput für Nitrogen und Argon High foreline tolerance allows the use of down-sized forevacuum pumps Dimensional drawing for the TURBOVAC TW 701 Pumping Speed I x s b 1 Top view b b 1 d d 1 d 2 h h 1 h 2 h 3 l l ISO-K mm in CF mm in Torr 10 0 N 2 Ar He H Highly effective air-cooling unit Oil-free pump for generating clean high and ultrahigh vacuum conditions Advantages to the User Space-saving Easy to integrate into complex vacuum systems High productivity Low operating costs Highly reliable operation mbar 10 Inlet Pressure Pumping speed as a function of the inlet pressure 52

53 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC TW 701 Inlet flange 160 ISO-K 160 CF Pumping speed N 2 I x s -1 Ar I x s -1 He I x s -1 H 2 I x s -1 Max. gas throughput N 2 mbar x I x s -1 Ar mbar x I x s -1 He mbar x I x s -1 H 2 mbar x I x s -1 Compression ratio N 2 Ar He H (water-cooled) 5 (water-cooled) x x x x x x x x 10 4 Ultimate pressure Max. foreline pressure for N 2 mbar (Torr) mbar (Torr) < 5.0 x 10-9 (< 3.75 x 10-9 ) < 1.5 x (< 1.1 x ) 14 (10.5) 14 (10.5) Recommended forevacuum pump TRIVAC D 65 B SC 30 D TRIVAC D 65 B SC 30 D Run-up time to 95% speed Purge port min KF 16 KF Cooling water connection 2x G 1/8" (internal threads) 2x G 1/8" (internal threads) Weight, approx. Supply voltage, nominal Max. power consumption kg (lbs) V DC W 19 (42) 19 (42)

54 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage Ordering Information TURBOVAC TW 701 TW 701 with integrated frequency converter Inlet flange Foreline flange Cooling method Interface 160 ISO-K 25 KF Air-cooled RS 232 C 160 ISO-K 25 KF Water-cooled RS 232 C 160 ISO-K 25 KF Air-cooled RS 485 C 160 ISO-K 25 KF Water-cooled RS 485 C 160 ISO-K 25 KF Water-cooled RS 232 C + Profibus 160 CF 25 KF Air-cooled RS 485 C 160 CF 25 KF Water-cooled RS 485 C 200 CF 25 KF Water-cooled RS 232 C (incl. splinter guard) Power supply unit TURBO.CONTROL 700 Part No V0121 Part No V0025 Part No V0024 Part No V0023 Part No V0122 Part No V0027 Part No V0026 Part No V0022 see chapter Turbomolecular Pumps with Mechanical Rotor Suspension, para. Electronic Frequency Converters Accessories, optional Splinter guard 160 ISO-K 160 CF Flange heater 160 CF 230 V AC 110 V AC Vibration absorber 160 ISO-K 160 CF OEM power supply, 59 V DC 59 V DC cable 03 m (10.5 ft) 05 m (17.5 ft) 10 m (35.0 ft) 20 m (70.0 ft) Plug with integrated START/STOP switch Purge gas and venting valve, 24 V DC; 0.6 mbar x I x s -1 = 36 sccm (purge gas pressure, abs.; 1.5 to 6 bar) Accessories for serial interfaces RS 232 C and RS 485 C Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No see chapter Turbomolecular Pumps, para. Accessories Accessories, for the water connection Adaptor G (BPS) 1/8" G (BPS) 1/4" pipe Gasket Adaptor G (BPS) 1/8" 10 mm (0.39 in.) hose nozzle Gasket Adaptor G (BPS) 1/8" NPT 1/8" Gasket Part No (2x required) Part No (2x required) Part No (2x required) Part No (2x required) Part No (2x required) Part No (2x required) 54

55 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Notes 55

56 Turbomolecular Pumps with Mechanical Rotor Suspension with Compound Stage TURBOVAC TW 1600 Typical Applications Data storage Flat panel displays Optical coating Large area coating R & D, e.g. - Fusions-Experimente - Space simulation - UHV applications h 10 4 h 3 h 2 h 1 ø d ø d 1 Dimensional drawing for the TURBOVAC TW 1600 h 4 b b ,5 Top view a a b b 1 d d 1 h h 1 h 2 h 3 h ISO-F mm inch ISO-F mm inch CF mm inch a Torr 10 Technical Features Frequency converter and power supply integrated Robust rotor design Operation in any orientation Highest pumping speed and throughput Oil-free pump for generating clean high and ultrahigh vacuum conditions Purge gas and venting valve integrated High foreline tolerance Advantages to the User Space-saving Easy to integrate into complex vacuum systems Pumping Speed I x s N 2 Ar High productivity Low operating costs Operation with dry backing pumps mbar 10 Inlet Pressure Pumping speed as a function of the inlet pressure 56

57 with Compound Stage Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data TURBOVAC TW 1600 Inlet flange 200 ISO-F 250 ISO-F 250 CF Pumping speed N 2 I x s -1 Ar I x s -1 Max. gas throughput N 2 mbar x I x s -1 Ar mbar x I x s Compression ratio k 0 for O-ring sealed pumps N 2 Ar 1 x x x x 10 8 Ultimate pressure Max. foreline pressure for N 2 mbar (Torr) mbar (Torr) < 3 x (< 2.25 x ) < 3 x (< 2.25 x ) 8 (6) 8 (6) Recommended forevacuum pump (alternatively) Run-up time to 95% speed Purge / vent port Cooling water connection Weight, approx. Supply voltage Max. power consumption min kg (lbs) V AC W TRIVAC D 65 B + RUVAC WA 501 TRIVAC D 65 B + RUVAC WA 501 DIVAC 4.8 VT DIVAC 4.8 VT SOGEVAC SV 25 SOGEVAC SV 25 SC 30 D SC 30 D < 10 < 10 G 1/4" G 1/4" G 3/8" G 3/8" 40 (88.3) 40 (88.3) Ordering Information TURBOVAC TW 1600 Inlet flange Foreline flange Cooling method Interface 200 ISO-F 40 KF Water-cooled Profibus 250 ISO-F 40 KF Water-cooled Profibus 250 CF 40 KF Water-cooled Profibus Purge filter Accessories for serial interfaces RS 232 C and RS 485 C Part No V2144 Part No V2444 Part No V2844 Part No see chapter Turbomolecular Pumps, para. Accessories 57

58 Turbomolecular Pumps with Mechanical Rotor Suspension Electronic Frequency Converters TURBOTRONIK NT 10 Technical Features For operating the TURBOVAC 50 turbomolecular pump Bench top unit Also for rack mounting (1/4 19", 3 HU) Controls and indicators on the front panel Inputs for remote control and process controller Freely assignable relays (e.g. to control the backing pumps) Technical Data TURBOTRONIK NT 10 Mains connection, Hz Max. output voltage Overload current limit Permissible ambient temperature Dimensions (W x H x D) Weight, approx. V V A C ( F) mm (in.) kg (lbs) / x to +40 (+32 to +104) 106 x 128 x 233 (4.17 x 5.04 x 9.17) 1.5 (3.3) Ordering Information V (with US plug) V (with EURO plug) Connecting cable pump - converter 3 m (10.5 ft) 5 m (17.5 ft) TURBOTRONIK NT 10 Part No Part No Part No Part No

59 Electronic Frequency Converters Turbomolecular Pumps with Mechanical Rotor Suspension TURBOTRONIK NT 20 Technical Features For operating the TURBOVAC 151 (C), 361 (C), 600 C and 1100 C turbomolecular pump Front panel with membrane keypad and LCD Advantages to the User Remote control and process control via analog and programmable control inputs and outputs Connection for backing pump, venting valve, flange heater and air cooler Operation direct at the unit or via interface Floating connection of external monitoring devices via a terminal strip on the rear Technical Data TURBOTRONIK NT 20 Main connection, Hz; selectable Max. output voltage Overload current limit V V A 85 to x 42 5 Permissible ambient temperature Dimensions (W x H x D) Weight, approx. C ( F) mm (in.) kg (lbs) 0 to +45 (+32 to +113) 213 x 129 x 320 (1/2 19, 3 HU) (8.39 x 5.08 x (1/2 19, 3 HU)) 7 (15.4) Ordering Information TURBOTRONIK NT 20 1) 100 V (with US plug) 120 V (with US plug) 230 V (with EURO plug) Connecting cable pump converter 03 m (10.5) 05 m (17.5) 10 m (35.0 ft) 20 m (70.0 ft) Part No ) Part No Part No Part No ) Part No ) Part No ) Part No ) 1) If NT 20 is being ordered to replace NT 150/360, NT 151/361, then an NT 20 cable must also be ordered. (NT 20 has a round connector on back panel for the connection of the cable, the other controllers used a rectangular connector instead.) 2) Not suitable for driving the TURBOVAC 1100 C 59

60 Turbomolecular Pumps with Mechanical Rotor Suspension Electronic Frequency Converters Only available for purchase in North and South America TURBOTRONIK NT 361 Technical Features For operating the TURBOVAC 361 turbomolecular pumps Sensing of the pump model via a resistance code Operation via pushbuttons Terminal strip for remote control and display functions Technical Data TURBOTRONIK NT 361 Mains connection, 60 Hz Max. power consumption during run-up Power consumption during normal operation, approx. Max. output voltage / run-up current Overload current limit Nominal frequency Permissible ambient temperature V VA VA V / A A Hz C ( F) x 45 / /750 0 to +40 (32 to +104) Dimensions (W x H x D) Weight, approx. mm (in.) kg (lbs) 210 x 129 x 288 (8.27 x 5.08 x 11.34) 8.5 (18.7) Ordering Information 120 V (with US plug) Connecting cable pump - converter 3 m (10.5 ft) 5 m (17.5 ft) TURBOTRONIK NT 361 Part No Part No Part No

61 Electronic Frequency Converters Turbomolecular Pumps with Mechanical Rotor Suspension TURBO.DRIVE S (TDS) for TW 70 H and TW 250 S TURBO.DRIVE S (front side) h h 1 Drive (X3) l HEAT SINK b 1 DC 24 V (X4) b b 1 b 2 h h 1 l mm in Dimensional drawing for the TURBO.DRIVE S (rear side) b b 2 Technical Features Compact size RS 232 C, RS 485 C or Profibus interface Configurations - as a separate frequency converter - integrated within turbomolecular pump Remote control via remote control interface Flexible mounting Cost-effective supply of 24 V DC power Technical Data Input Voltage V DC Max. continuos current A Max. continuos power consumption W TURBO.DRIVE S 24 ± 5% Ambient temperature Dimensions (W x H x D), including heat sink Weight Serial interface C ( F) mm (in.) kg (lbs) +10 to +45 (+50 to +113) 100 x 90 x 100 (3.94 x 3.54 x 3.94) 0.7 (1.55) RS 232 C, RS 485 C or Profibus Ordering Information TURBO.DRIVE S with RS 232 C interface with RS 485 C interface with Profibus with RS 232 C interface and heat sink with RS 485 C interface and heat sink Connecting cable TDS - pump 1 m (03.5 ft) 3 m (10.5 ft) 5 m (17.5 ft) START/STOP switch (for manual operation) Hat rail adaptor as mounting aid Accessories for RS 232 C and RS 485 C interfaces TURBO.DRIVE S Part No V0002 Part No V0003 Part No V0004 Part No V0005 Part No V0006 Part No Part No Part No Part No Part No V0003 see chapter Turbomolecular Pumps, para. Accessories 61

62 Turbomolecular Pumps with Mechanical Rotor Suspension Electronic Frequency Converters TURBO.DRIVE 300 (TD 300) for TW 70, TW 250 S, TW 300 and TW 300 H TURBO.DRIVE 300 (front side) h h 1 Drive (X3) l HEAT SINK b 1 DC 24 V (X4) b b 2 Option b b 1 b 2 h h 1 l mm in Dimensional drawing for the TURBO.DRIVE 300 (rear side) Technical Features Compact size RS 232/422 C or RS 485 C interface Configurations - as a separate frequency converter - integrated within turbomolecular pump Remote control via remote control interface Flexible mounting Cost-effective supply of 24 V DC power Technical Data TURBO.DRIVE 300 Input Voltage V DC Max. continuos current A Max. continuos power consumption W 24 ± 5% Ambient temperature Dimensions (W x H x D) Weight Serial interface C ( F) mm (in.) kg (lbs) +5 to +45 (+41 to +113) 100 x 90 x 100 (3.94 x 3.54 x 3.94) 0.7 (1.55) RS 232/422 C or RS 485 C Ordering Information TURBO.DRIVE 300 with RS 232/422 C interface with RS 485 C interface with Profibus Connecting cable TD pump 1 m (03.5 ft) 3 m (10.5 ft) 5 m (17.5 ft) START/STOP switch (for manual operation) Hat rail adaptor as mounting aid Accessories for RS 232 C and RS 485 C interfaces TURBO.DRIVE 300 Part No V0001 Part No V0003 Part No V0004 Part No Part No Part No Part No Part No V0003 see chapter Turbomolecular Pumps, para. Accessories 62

63 Electronic Frequency Converters Turbomolecular Pumps with Mechanical Rotor Suspension Power Supply PS 700 for TW 701 Turbomolecular Pumps 3 x M4 AIRFLOW h h 1 Technical Features 59 V DC OEM power supply for screw fixing in electrical cabinets l 1 l 2 h 1 b 1 4 x M4 l b 2 b b b 1 b 2 h h 1 l l 1 l 2 mm in Dimensional drawing for the power supply PS 700 Technical Data Power Supply PS 700 Input Mains voltage V DC Max. continuos power consumption W Output Voltage, nominal V DC Max. continuos current A Max. continuos power consumption W Ambient temperature Dimensions (W x H x D) Weight C ( F) mm (in.) kg (lbs) 0 to +70 (+32 to +158) 227 x 63 x 127 (8.94 x 2.48 x 5.0) 2 (4.4) Ordering Information Power Supply PS 700 OEM power supply 59 V DC 59 V DC cable TW 700 power supply 03 m (10.5 ft) 05 m (17.5 ft) 10 m (35.0 ft) 20 m (70.0 ft) Mains cable for OEM power supply, 2 m (7 ft) with EURO plug with US plug, 220 V AC with US plug, 115 V AC (7.5 ft) START/STOP switch for TURBO.DRIVE S (for manual operation) Part No Part No Part No Part No Part No Part No V0001 Part No V1001 Part No Part No Note: See the TPC and TSC controllers in the Product Section C10 Turbomolecular Pump Systems for additinal controllers for the TURBOVAC TW 300 and TW

64 START NORMAL POWER ERROR START 1 0 STOP TURBO.CONTROL 300/700 START NORMAL POWER ERROR START 1 0 STOP TURBO.CONTROL 300/700 Turbomolecular Pumps with Mechanical Rotor Suspension Electronic Frequency Converters Power Supply Units for TURBO.DRIVE S, TURBO.DRIVE 300 and TW 700/ Front view 211 Front view Ø ,1 128,4 122,4 Ø 3, ,1 128,4 122,4 Ø 3,2 Dimensional drawing for the power supply TURBO.POWER 300 Technical Features Cost-effective supply of 24 V DC power for TURBO.DRIVE S and TURBO.DRIVE 300 Plug & play Bench top unit or for cabinet mounting Dimensional drawing for the power supply TURBO.CONTROL 300 Technical Features For supplying 24 V DC power to the TURBO.DRIVE S and TURBO.DRIVE 300 Plug & play Bench top unit or for cabinet mounting Mains switch START/STOP switch for the turbomolecular pump Remote control via remote interface Status indicating LEDs and status relays Dimensional drawing for the power supply TURBO.CONTROL 700 Technical Features For supplying 56 V DC power to the TW 700/701 Plug & play Bench top unit or for cabinet mounting Mains switch START/STOP switch for the turbomolecular pump Remote control via remote interface Status indicating LEDs and status relays 64

65 Electronic Frequency Converters Turbomolecular Pumps with Mechanical Rotor Suspension Technical Data Input Mains voltage Max. power consumption Output Voltage, nominal Max. continuos current Ambient temperature Dimensions (W x H x D) V A V DC A C ( F) mm (in.) Power Supply TURBO.POWER 300 TURBO.CONTROL 300 TURBO.CONTROL V / 50/60 Hz V / 50/60 Hz V / 50/60 Hz to +40 (+32 to +104) 0 to +40 (+32 to +104) 0 to +40 (+32 to +104) 116 x 53 x x 129 x x 129 x 320 (4.57 x 2.09 x 10.24) (8.39 x 5.08 x 12.6) (8.39 x 5.08 x 12.6) Weight kg (lbs) Ordering Information Power supply TURBO.POWER 300 TURBO.CONTROL 300 TURBO.CONTROL 700 DC cable frequency converter - power supply unit 01 m (03.5 ft) 03 m (10.5 ft) 05 m (17.5 ft) 10 m (35.0 ft) 20 m (70.0 ft) Mains cable, 3 m (10.5 ft) with EURO plug with US plug 6-15 P, 220 V AC with US plug, 115 V AC (7.5 ft) Hat rail adaptor as mounting aid 1.5 (3.3) 1.5 (3.3) 2.5 (5.52) Power Supply TURBO.POWER 300 TURBO.CONTROL 300 TURBO.CONTROL 700 Part No V0002 Part No V0001 Part No V V DC power cable 24 V DC control cable 56 V DC control cable Part No V0100 Part No V0100 Part No V0100 Part No V0300 Part No V0300 Part No V0300 Part No V0500 Part No V0500 Part No V0500 Part No V1000 Part No V1000 Part No V1000 Part No V2000 Part No V2000 Part No V2000 Part No V0002 Part No V0002 Part No V0002 Part No V1002 Part No V1002 Part No V1002 Part No Part No Part No Part No V

66 Turbomolecular Pumps with Magnetic Rotor Suspension without Compound Stage TURBOVAC 340 M Typical Applications Gas analysis systems Particle accelerators Electron beam microscopy Research instruments and systems B ød 100 A C F1 h2 h a1 60 B ød1 60 C F E D a b b1 Technical Features Magnetic suspension Absolutely free of any lubricants Low noise and vibration levels Installation in any orientation h4 h5 h6 E F2 F3 h3 Top view Convection cooling Purge gas design h1 a a 1 b b 1 d d 1 h h 1 h 2 h 3 h 4 h 5 h ISO-K mm in CF mm in ISO-K mm in CF mm in Dimensional drawing for the TURBOVAC 340 M I x s Torr Advantages to the User Maintenance-free No batteries are required because of integrated generator mode in case of power Pumping Speed N mbar 10-1 H 2 Inlet Pressure Pumping speed of the TURBOVAC 340 M (100 and 160 ISO-K/CF) as a function of the inlet pressure 66

67 without Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Technical Data TURBOVAC 340 M Inlet flange 100 ISO-K 100 CF 160 ISO-K 160 CF Pumping speed N 2 I x s -1 H 2 I x s -1 Speed min -1 Compression ratio N 2 He H x x x x x x 10 3 Ultimate pressure Max. foreline pressure for N 2 mbar (Torr) mbar (Torr) < 10-9 (< 0.75 x 10-9 ) < 10-9 (< 0.75 x 10-9 ) 5 x 10-1 (3.75 x 10-1 ) 5 x 10-1 (3.75 x 10-1 ) Recommended forevacuum pump TRIVAC D 16 B Scroll TRIVAC D 16 B Scroll Run-up time forevacuum flange Purge / vent port min KF 25 KF 10 KF 10 KF Cooling water connections (hose nipple) not required not required Weight, approx. kg (lbs) 16 (35) 16 (35) Ordering Information TURBOVAC 340 M TURBOVAC turbomolecular pump with highvacuum connection flange 100 ISO-K 100 CF 160 ISO-K 160 CF Part No Part No Part No Part No Accessories for all pumps Flange heater 100 CF, 230 V 160 CF, 230 V 160 CF, 110 V Electronic frequency converter TURBOTRONIK NT 340 M 100 V 120 V 230 V Connection line Part No Part No Part No Part No Part No Part No see TURBOTRONIK NT 340 M 67

68 Turbomolecular Pumps with Magnetic Rotor Suspension without Compound Stage TURBOVAC MAG 400 C/CT Typical Applications All major semiconductor processes such as Etch, CVD and Ion Implantation Gas analysis systems Particle accelerators Electron beam microscopy Research instruments and systems Load locks and transfer chambers B 100 A C F 1 h 1 h 3 F 2 h 2 h 4 h 5 E ød D F 3 h a B D a F E Top view a a 1 a 2 b b 1 d h h 1 h 2 h 3 h 4 h 5 mm in a 2 b 1 b Technical Features Magnetic suspension Patented KEPLA-COAT for rotor and stator to prevent corrosion Low noise and vibration levels Installation in any orientation Optimized corrosion-resistant advanced rotor design High temperature and high stress tolerance material Temperature management system (TMS) for etch application Dimensional drawing for the TURBOVAC MAG 400 CT 1000 I x s -1 Advantages to the User Maintenance-free Optimized vacuum performance Pumping Speed N 2 H 2 Resistant against corrosive gases and process by-products Robust against shock-venting Temperature control for metal etch No deposition of etch by products due to TMS mbar Inlet Pressure Pumping speed of the TURBOVAC MAG 400 C/CT as a function of the inlet pressure 68

69 without Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Inlet flange Technical Data TURBOVAC MAG 400 C 400 CT 100 ISO-K 100 ISO-K Pumping speed according to PNEUROP N 2 I x s -1 H 2 I x s -1 Speed (high / low) min -1 Compression ratio N 2 H 2 Ultimate pressure according to DIN mbar (Torr) 240 1) 240 1) 180 1) 174 1) / / x x x x 10 2 < 10-9 (< 0.75 x 10-9 ) < 10-9 (< 0.75 x 10-9 ) Max. foreline pressure for N 2 mbar (Torr) 5 x 10-1 (3.75 x 10-1 ) 5 x 10-1 (3.75 x 10-1 ) Recommended forevacuum pump TRIVAC D 65 BCS Scroll TRIVAC D 65 BCS Scroll Run-up time to 95% speed forevacuum flange Purge / vent port Cooling water connections (hose nipple) min mm (in.) KF 25 KF 10 KF 10 KF 7.5 (0.30) 7.5 (0.30) Weight, approx. kg (lbs) Ordering Information TURBOVAC MAG turbomolecular pump Electronic frequency converter TURBOTRONIK NT 340 MA (120 V) Connection line motor, 3 m (10.5 ft) Connection line bearing, 3 m (10.5 ft) Accessories for the temperature control Purge gas and venting valve 110 V, 50/60 Hz 230 V, 50/60 Hz 024 V DC, 5 W Seal kit 16 (35) 16 (35) TURBOVAC MAG 400 C 400 CT Part No Part No Part No Part No Part No Part No Part No Part No see TURBOTRONIK Part No Part No Part No Part No Part No Part No Part No Part No ) Applies at a speed of min -1 69

70 Turbomolecular Pumps with Magnetic Rotor Suspension without Compound Stage TURBOVAC MAG 1500 CT Typical Applications All major semiconductor processes such as Etch, CVD, PVD and Ion Implantation Load locks and transfer chambers Technical Features Active 5-axis magnetic bearing system Patented KEPLA-COAT for rotor and stator to prevent corrosion Low noise and vibration levels Operation in any orientation h5 ø d ø d1 ø d2 a1 26 a2 70 Advanced rotor design for high throughput Integrated purge gas system h1 h3 h h2 ø d3 h4 Heatband ø d5 b b1 ø d6 b CT versions: Integrated temperature management system Bearing and temperature system are controlled digitally 40 KF a3 Intelligent power control system ø d4 Dimensional drawing for the TURBOVAC MAG 1500 CT a h6 h7 105 a4 Top view a a 1 a 2 a 3 a 4 a 5 b b 1 b 2 d d 1 d ISO-F mm M8 x in M8 x ISO-F mm M8 x in M8 x d 3 d 4 d 5 d 6 h h 1 h 2 h 3 h 4 h 5 h 6 h ISO-F mm in ISO-F mm in a5 60 Advantages to the User Maintenance-free High throughput for all process gases High pumping speed at low pressure High foreline pressure tolerance: up to 1.7 mbar (1.13 Torr) High resistance against corrosive gases Robust against particles and deposits Temperature control up to 90 C (194 F) to avoid condensation Lowest weight and size in its class Application specific design 70

71 without Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Inlet flange Technical Data TURBOVAC MAG 1500 CT 200 ISO-F 250 ISO-F Pumping speed according to PNEUROP N 2 I x s -1 He I x s -1 H 2 I x s -1 Speed min -1 Compression ratio N 2 Ultimate pressure according to DIN mbar (Torr) > 10 8 > 10 8 < 10-8 (< 0.75 x 10-8 ) < 10-8 (< 0.75 x 10-8 ) Max. foreline pressure for N 2 mbar (Torr) 1.7 (1.2) 1.7 (1.2) Recommended forevacuum pump Rotary vane pump or dry compressing pump offering a pumping speed of 100 m 3 /h TRIVAC D 65 BCS TRIVAC D 65 BCS Run-up time forevacuum flange Purge / vent port Cooling water connection (OD of tube) Weight, approx. min VCR nut mm (in.) kg (lbs) < 6 < 6 40 KF 40 KF 1/4" 1/4" 6.4 (0.25) 6.4 (0.25) 32 (70) 32 (70) I x s Pumping Speed N 2 He H mbar Inlet Pressure 10 Pumping speed of the TURBOVAC MAG 1500 C/CT as a function of the inlet pressure 71

72 Turbomolecular Pumps with Magnetic Rotor Suspension without Compound Stage Ordering Information Inlet flange TURBOVAC MAG 1500 CT 200 ISO-F 250 ISO-F TURBOVAC MAG turbomolecular pump Electronic frequency converter MAG.DRIVE digital MAG.DRIVE digital with Profibus interface Part No V0002 Part No V0011 Part No V0013 Part No V0002 Part No V0011 Part No V0013 Plug-in control Part No Part No Connecting cables converter pump 1) 01.5 m (5.25 ft) DRIVE/BEARING 01.5 m (5.25 ft) TMS 05.0 m (17.5 ft) DRIVE/BEARING 05.0 m (17.5 ft) TMS 10.0 m (35.0 ft) DRIVE/BEARING 10.0 m (35.0 ft) TMS 20.0 m (70.0 ft) DRIVE/BEARING 20.0 m (70.0 ft) TMS Part No V0001 Part No V0001 Part No V0004 Part No V0004 Part No V0002 Part No V0002 Part No V0003 Part No V0003 Part No V0001 Part No V0001 Part No V0004 Part No V0004 Part No V0002 Part No V0002 Part No V0003 Part No V0003 Seal kit 250 metal Part No Part No ) further connecting cables can be found under MAG.DRIVE digital in the section Turbomolecular Pumps with Magnetic Rotor Suspension, para. Frequency Converters 72

73 without Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Notes 73

74 Turbomolecular Pumps with Magnetic Rotor Suspension without Compound Stage TURBOVAC MAG 2000 C/CT Typical Applications All major semiconductor processes such as Etch, CVD, PVD and Ion Implantation Load locks and transfer chambers Technical Features Active 5-axis magnetic bearing system Patented KEPLA-COAT for rotor and stator to prevent corrosion Low noise and vibration levels Operation in any orientation Only CT ød 1 ød h 5 Only CT Top view Advanced rotor design for high throughput Integrated purge gas system h 1 h 2 40 Pumping Speed I x s ød 3 h h 4 Only CT h 3 30 Only CT d d 1 d 2 d 3 d 4 d 5 h h 1 h 2 h 3 h 4 h 5 mm in Dimensional drawing for the TURBOVAC MAG 2000 C/CT ød 4 ød 5 CT versions: Integrated temperature management system Advantages to the User Maintenance-free High throughput for all etch gases High pumping speed at low pressure High foreline pressure tolerance: up to 2 mbar (1.5 Torr) High resistance against corrosive gases Robust against particles and deposits Temperature management system to avoid condensation Application specific design N 2 He H Inlet Pressure Pumping speed of the TURBOVAC MAG 2000 CT ( 250) as a function of the inlet pressure 74

75 without Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Technical Data TURBOVAC MAG 2000 C 2000 CT Inlet flange 250 ISO-F 250 ISO-F Pumping speed according to PNEUROP N 2 I x s -1 He I x s -1 H 2 I x s -1 Speed min -1 Compression ratio N 2 Ultimate pressure according to DIN mbar (Torr) > 10 8 > 10 8 < 10-8 (< 0.75 x 10-8 ) < 10-8 (< 0.75 x 10-8 ) Max. foreline pressure for N 2 mbar (Torr) 1.6 (1.2) 1.6 (1.2) Recommended forevacuum pump Rotary vane pump or dry compressing pump offering a pumping speed of 100 m 3 /h TRIVAC D 65 BCS TRIVAC D 65 BCS Run-up time forevacuum flange Purge / vent port Cooling water connection (OD tube) min VCR nut mm (in.) < 8 < 8 40 KF 40 KF 1/4" 1/4" 6.4 (0.25) 6.4 (0.25) Weight, approx. kg (lbs) Ordering Information TURBOVAC MAG turbomolecular pump 68 (150) 68 (150) TURBOVAC MAG 2000 C 2000 CT Part No Part No Electronic frequency converter MAG.DRIVE 2000 Part No V0011 Part No V0011 Plug-in control Connecting cables converter pump 01.5 m (5.25 ft) BEARING 01.5 m (5.25 ft) DRIVE/TMS 05.0 m (17.5 ft) BEARING 05.0 m (17.5 ft) DRIVE/TMS 10.0 m (35.0 ft) BEARING 10.0 m (35.0 ft) DRIVE/TMS 20.0 m (70.0 ft) BEARING 20.0 m (70.0 ft) DRIVE/TMS Seal kit 250 Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No

76 Turbomolecular Pumps with Magnetic Rotor Suspension with Compound Stage TURBOVAC MAG W 830/1300 C Typical Applications Semiconductor processes, like PVD and ion implantation Transfer chambers Particle accelerators Research instruments and systems Coaters E A Top view Technical Features Active 5-axis magnetic bearing system F G H J Ø D Ø B Ø C K M Forevacuum flange Inlet flange A B C D E MAG W 830 C 40 KF 160 ISO-F mm KF 160 ISO-F in MAG W 1300 C 40 KF / 25 KF 200 ISO-F mm KF / 25 KF 250 ISO-F in MAG W 1300 C 40 KF 250 ISO-F mm KF 250 ISO-F in F G H J K L M N MAG W 830 C mm in MAG W 1300 C mm in MAG W 1300 C mm MAG W 1300 C mm O P Q R S T MAG W 830 C mm in MAG W 1300 C mm in MAG W 1300 C mm in L Forevacuum connection Ø N 50 R 30 S O M8 Q P T Digital monitoring of the bearing system Low noise and vibration levels Operation in any orientation Advanced rotor design for high throughput Purge gas system Intelligent power control system Advantages to the User Maintenance-free High throughput for all process gases High pumping speed at low pressure High foreline pressure tolerance: up to 2 mbar (1.5 Torr) Lowest weight and size in its class Application specific design Dimensional drawing for the TURBOVAC MAG W 830/1300 C 76

77 with Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Inlet flange Technical Data TURBOVAC MAG W 830 W 830 C W 1300 W 1300 C 160 CF 160 ISO-F 200 CF 200 ISO-F 250 ISO-F Pumping speed according to PNEUROP N 2 I x s -1 He I x s -1 H 2 I x s -1 Speed min -1 Compression ratio N 2 Ultimate pressure according to DIN mbar (Torr) x 10 8 > 5 x x 10 8 > 10 8 > 10 8 < 1 x < 10-8 < 1 x < 10-8 < 10-8 (< 0.75 x ) (< 0.75 x 10-8 ) (< 0.75 x ) (< 0.75 x 10-8 ) (< 0.75 x 10-8 ) Max. foreline pressure for N 2 with convection cooling with water cooling mbar (Torr) mbar (Torr) 0.2 (0.15) 0.2 (0.15) 2.0 (1.5) 2.0 (1.5) 2.0 (1.5) 2.0 (1.5) 2.0 (1.5) Recommended forevacuum pump Rotary vane pump or dry compressing pump offering a pumping speed of 100 m 3 /h Run-up time forevacuum flange Purge / vent port min TRIVAC TRIVAC TRIVAC TRIVAC TRIVAC D 65 BCS D 65 BCS D 65 BCS D 65 BCS D 65 BCS < 3.7 < 4.0 < 6.0 < 6.0 < KF 40 KF 40 KF 40 KF 40 KF 10 KF / 16 KF 10 KF / 16 KF 10 KF / 16 KF 10 KF / 16 KF 10 KF / 16 KF Cooling water connection (OD tube) Weight, approx. mm (in.) kg (lbs) 1/4" 1/4" 1/4" 6 (0.24) 6 (0.24) 30 (66.2) 32 (70.6) 30 (66.2) 32 (70.6) 32 (70.6) I x s Pumping Speed N 2 He H mbar Inlet Pressure 10 Pumping speed of the TURBOVAC MAG W 1300 C ( 250) as a function of the inlet pressure 77

78 Turbomolecular Pumps with Magnetic Rotor Suspension with Compound Stage Ordering Information Inlet flange TURBOVAC MAG W 830 W 830 C W 1300 W 1300 C 160 CF 160 ISO-F 200 CF 200 ISO-F 250 ISO-F TURBOVAC MAG turbomolecular pump Electronic frequency converter MAG.DRIVE digital MAG.DRIVE digital with Profibus interface Plug-in control Purge gas valve Connecting cable converter pump 1) 01.5 m (5.25 ft) DRIVE/BEARING 03.0 m (10.5 ft) DRIVE/BEARING 05.0 m (17.5 ft) DRIVE/BEARING 10.0 m (35.0 ft) DRIVE/BEARING 20.0 m (70.0 ft) DRIVE/BEARING Connecting cable for purge gas valve 01.5 m (5.25 ft) pump/coverter 03.0 m (10.5 ft) pump/coverter 10.0 m (35.0 ft) pump/coverter Part No. Part No. Part No. Part No. Part No V V V V V0021 Part No. Part No. Part No. Part No. Part No V V V V V V V V V V0013 Part No. Part No. Part No. Part No. Part No Part No. Part No. Part No. Part No. Part No Part No. Part No. Part No. Part No. Part No V V V V V0001 Part No. Part No. Part No. Part No. Part No V V V V V0006 Part No. Part No. Part No. Part No. Part No V V V V V0004 Part No. Part No. Part No. Part No. Part No V V V V V0002 Part No. Part No. Part No. Part No. Part No V V V V V0003 Part No. Part No. Part No. Part No. Part No V V V V V0001 Part No. Part No. Part No. Part No. Part No V V V V V0006 Part No. Part No. Part No. Part No. Part No V V V V V0002 1) further connecting cables can be found under MAG.DRIVE digital in the section Turbomolecular Pumps with Magnetic Rotor Suspension, para. Frequency Converters 78

79 with Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Notes 79

80 Turbomolecular Pumps with Magnetic Rotor Suspension with Compound Stage TURBOVAC MAG W 1500 CT Typical Applications All major semiconductor processes such as Etch, CVD, PVD and Ion Implantation Technical Features Active 5-axis magnetic bearing system Bearing and temperature system are controlled digitally Corrosion resistant Low noise and vibration levels Operation in any orientation h5 ø d ø d1 ø d2 a1 26 a Compound rotor design for high pumping speed and foreline pressure Integrated purge gas system h1 h3 h h2 ø d3 h4 Heatband ø d5 b b1 ø d6 b2 CT versions: Integrated temperature management system Intelligent power control system KF a3 Advantages to the User h6 h7 a4 a5 60 Maintenance-free ø d4 a 105 Top view High throughput for all process gases a a 1 a 2 a 3 a 4 a 5 b b 1 b 2 d d ISO-F mm M8 x in M8 x ISO-F mm M8 x in M8 x d 2 d 3 d 4 d 5 d 6 h h 1 h 2 h 3 h 4 h 5 h 6 h ISO-F mm in ISO-F mm in Dimensional drawing for the TURBOVAC MAG W 1500 CT High pumping speed at low pressure High foreline pressure tolerance: up to 2.6 mbar (1.95 Torr) High resistance against corrosive gases Robust against particles and deposits Temperature control up to 90 C (194 F) to avoid condensation Lowest weight and size in its class Application specific design 80

81 with Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Inlet flange Technical Data TURBOVAC MAG W 1500 CT 200 ISO-F 250 ISO-F 200 CF Pumping speed according to PNEUROP N 2 I x s -1 He I x s -1 H 2 I x s -1 Speed min -1 Compression ratio N 2 Ultimate pressure according to DIN mbar (Torr) > 10 8 > 10 8 > 10 8 < 10-8 < 10-8 < (< 0.7 x 10-8 ) (< 0.7 x 10-8 ) (< 0.7 x 10-8 ) Max. foreline pressure for N 2 mbar (Torr) 2.6 (1.95) 2.6 (1.95) 2.6 (1.95) Recommended forevacuum pump Rotary vane pump or dry compressing pump offering a pumping speed of 100 m 3 /h TRIVAC D 65 BCS TRIVAC D 65 BCS TRIVAC D 65 BCS Run-up time to 95% speed forevacuum flange Purge / vent port min VCR nut < 6 < 6 < 6 40 KF 40 KF 40 KF 1/4" 1/4" 1/4" Cooling water connection, hose nipple (OD tube) mm (in.) 6.4 (0.25) 6.4 (0.25) 6.4 (0.25) Weight, approx. kg (lbs) 32 (70.6) 32 (70.6) 32 (70.6) I x s -1 Pumping Speed N2 He H mbar Inlet Pressure 10 Pumping speed of the TURBOVAC MAG W 1500 CT ( 250) as a function of the inlet pressure 81

82 Turbomolecular Pumps with Magnetic Rotor Suspension with Compound Stage Ordering Information TURBOVAC MAG W 1500 CT Inlet flange TURBOVAC MAG turbomolecular pump Electronic frequency converter MAG.DRIVE digital MAG.DRIVE digital with Profibus interface Plug-in control Connecting cable converter pump 1) 1.5 m (5.25 ft) DRIVE/BEARING 1.5 m (5.25 ft) TMS 05 m (17.5 ft) DRIVE/BEARING 05 m (17.5 ft) TMS 10 m (35.0 ft) DRIVE/BEARING 10 m (35.0 ft) TMS 20 m (70.0 ft) DRIVE/BEARING 20 m (70.0 ft) TMS Seal kit 250 metal 200 ISO-F 250 ISO-F 200 CF Part No. Part No. Part No V V V0002 Part No. Part No. Part No V V V V V V0013 Part No. Part No. Part No Part No. Part No. Part No V V V0001 Part No. Part No. Part No V V V0001 Part No. Part No. Part No V V V0004 Part No. Part No. Part No V V V0004 Part No. Part No. Part No V V V0002 Part No. Part No. Part No V V V0002 Part No. Part No. Part No V V V0003 Part No. Part No. Part No V V V0003 Part No. Part No. Part No ) further connecting cables can be found under MAG.DRIVE digital in the section Turbomolecular Pumps with Magnetic Rotor Suspension, para. Frequency Converters 82

83 with Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Notes 83

84 Turbomolecular Pumps with Magnetic Rotor Suspension with Compound Stage TURBOVAC MAG W 2000 C/CT Typical Applications All major semiconductor processes such as Etch, CVD, PVD and Ion Implantation Technical Features Active 5-axis magnetic bearing system Patented KEPLA-COAT for rotor and stator to prevent corrosion Low noise and vibration levels Installation in any orientation Only CT ød h 5 ød 1 h 1 h h 2 40 Only CT h 3 30 Top view ød 4 ød 5 Compound rotor design for high pumping speed and foreline pressure Integrated purge gas system CT versions: Integrated temperature management system Advantages to the User Maintenance-free h 4 High throughput for all etch gases Pumping Speed I x s ød 3 Only CT Only CT d d 1 d 2 d 3 d 4 d 5 h h 1 h 2 h 3 h 4 h 5 mm in Dimensional drawing for the TURBOVAC MAG W 2000 C/CT High pumping speed at low pressure High foreline pressure tolerance: up to 5.3 mbar (4 Torr) High resistance against corrosive gases Robust against particles and deposits Temperature management system to avoid condensation Application specific design N 2 He H mbar Inlet Pressure 10 Pumping speed of the TURBOVAC MAG W 2000 CT ( 250) as a function of the inlet pressure 84

85 with Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Inlet flange Technical Data TURBOVAC MAG W 2000 C W 2000 CT 250 ISO-F 250 ISO-F Pumping speed according to PNEUROP N 2 I x s -1 He I x s -1 H 2 I x s -1 Speed min -1 Compression ratio N 2 Ultimate pressure according to DIN mbar (Torr) > 10 8 > 10 8 < 10-8 (< 0.75 x 10-8 ) < 10-8 (< 0.75 x 10-8 ) Max. foreline pressure for N 2 mbar (Torr) 3.5 (2.63) 3.5 (2.63) Recommended forevacuum pump Rotary vane pump or dry compressing pump offering a pumping speed of 100 m 3 /h TRIVAC D 65 BCS TRIVAC D 65 BCS Run-up time forevacuum flange Purge / vent port Cooling water connection (OD tube) min VCR nut mm (in.) < 8 < 8 40 KF 40 KF 1/4" 1/4" 6,4 (0.25) 6.4 (0.25) Weight, approx. kg (lbs) Ordering Information TURBOVAC MAG turbomolecular pump Electronic frequency converter MAG.DRIVE 2000 Plug-in control Connecting cable converter pump 01.5 m (5.25 ft) BEARING 01.5 m (5.25 ft) DRIVE/TMS 05.0 m (17.5 ft) BEARING 05.0 m (17.5 ft) DRIVE/TMS 10.0 m (35.0 ft) BEARING 10.0 m (35.0 ft) DRIVE/TMS 20.0 m (70.0 ft) BEARING 20.0 m (70.0 ft) DRIVE/TMS 62 (137) 62 (137) TURBOVAC MAG W 2000 C W 2000 CT Part No Part No Part No V0011 Part No V0011 Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No Part No

86 Turbomolecular Pumps with Magnetic Rotor Suspension with Compound Stage TURBOVAC MAG W 2200 C Typical Applications All major semiconductor processes such as Etch, CVD, PVD and Ion Implantation Coaters Versions with CF high vacuum connection Particle accelerators Research instruments and systems Ø A 36.5 M Technical Features Active 5-axis magnetic bearing system D E Ø C Ø B G F 45 H 40 KF J L K 8 Upper View 36 Bearing system are controlled digitally Low noise and vibration levels Operation in any orientation Compound rotor design for high pumping speed and foreline pressure Purge gas system Intelligent power control system A B C D E F G H J K L M 200 ISO-F mm in ISO-F mm in Dimensional drawing for the TURBOVAC MAG W 2200 C Advantages to the User Maintenance-free High throughput for all process gases High pumping speed at low pressure High foreline pressure tolerance: up to 2 mbar (1.5 Torr) 86

87 with Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Inlet flange Technical Data TURBOVAC MAG W 2200 C W ISO-F 250 ISO-F 250 CF Pumping speed according to PNEUROP N 2 I x s -1 Ar I x s -1 H 2 I x s -1 Speed min -1 Compression ratio N 2 Ultimate pressure according to DIN mbar (Torr) > 1 x 10 5 > 1 x x 10 5 < 10-8 (< 0.75 x 10-8 ) < 10-8 (< 0.75 x 10-8 ) < 1 x (< 0.75 x ) Max. foreline pressure for N 2 with convection cooling with water cooling mbar (Torr) mbar (Torr) 0.1 (0.075) 2 (1.5) 2 (1.5) 1 (0.75) Recommended forevacuum pump Rotary vane pump or dry compressing pump offering a pumping speed of 100 m 3 /h TRIVAC D 65 BCS TRIVAC D 65 BCS TRIVAC D 65 BCS Run-up time to 95% speed forevacuum flange Purge / vent port Cooling water connection (OD tube) Weight, approx. min VCR nut mm (in.) kg (lbs) < 10 < 10 < KF 40 KF 40 KF 1/4" 1/4" 1/4" 1/2" 1/2" 1/2" 48 (106) 48 (106) 60 (132.45) I s Pumping Speed N 2 He H mbar Inlet Pressure 10 Pumping speed of the TURBOVAC MAG W 2200 C ( 250) as a function of the inlet pressure 87

88 Turbomolecular Pumps with Magnetic Rotor Suspension with Compound Stage Ordering Information TURBOVAC MAG turbomolecular pump Electronic frequency converter MAG.DRIVE digital MAG.DRIVE digital with Profibus interface Plug-in control Connecting cable converter pump 1) 01.5 m (5.25 ft) DRIVE/BEARING 03.0 m (10.5 ft) DRIVE/BEARING 05.0 m (17.5 ft) DRIVE/BEARING 10.0 m (35.0 ft) DRIVE/BEARING 20.0 m (70.0 ft) DRIVE/BEARING TURBOVAC MAG W 2200 C W 2200 Part No V0011 Part No V0021 Part No V0061 Part No V0011 Part No V0011 Part No V0011 Part No V0013 Part No V0013 Part No V0013 Part No Part No Part No Part No V0001 Part No V0001 Part No V0001 Part No V0008 Part No V0008 Part No V0008 Part No V0004 Part No V0004 Part No V0004 Part No V0002 Part No V0002 Part No V0002 Part No V0003 Part No V0003 Part No V0003 1) further connecting cables can be found under MAG.DRIVE digital in the section Turbomolecular Pumps with Magnetic Rotor Suspension, para. Frequency Converters 88

89 with Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Notes 89

90 Turbomolecular Pumps with Magnetic Rotor Suspension with Compound Stage TURBOVAC MAG W 2800/3200 C/CT Typical Applications All major semiconductor processes such as Etch, CVD, PVD and Ion Implantation Versions with CF high vacuum connection Particle accelerators Research instruments and systems TURBOVAC MAG W 2800 CT (left) and TURBOVAC MAG W 3200 CT (right) E F G l A l D K l B L l C Dimensional drawing for the TURBOVAC MAG W 2800/3200 C/CT J H 30 M 8, 14 depth 40 KF 30 Top view A B C D E F G H J 250 ISO-F mm in CF mm in ISO-F mm in K L M N O 250 ISO-F mm in CF mm in ISO-F mm in l M l N O ,5 42 Technical Features Active 5-axis magnetic bearing system Bearing and temperature system are controlled digitally Corrosion resistant Low noise and vibration levels Installation in any orientation Compound rotor design for high pumping speed and foreline pressure Integrated purge gas system CT versions: Integrated temperature management system Intelligent power control system Advantages to the User Maintenance-free High throughput for all process gases High pumping speed at low pressure High foreline pressure tolerance: up to 2 mbar (1.5 Torr) High resistance against corrosive gases Robust against particles and deposits Temperature control up to 90 C (194 F) to avoid condensation Lowest weight and size in its class Application specific design 90 Leybold Vacuum Gesamtkatalog 2004

91 with Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Inlet flange Technical Data TURBOVAC MAG W 2800 C W 2800 CT W 2800 W 3200 CT 250 ISO-F 250 ISO-F 250 CF 320 ISO-F Pumping speed according to PNEUROP N 2 I x s -1 Ar I x s -1 H 2 I x s -1 Speed min -1 Compression ratio N 2 Ultimate pressure according to DIN mbar (Torr) > 6 x 10 6 > 6 x x 10 9 > 6 x 10 6 < 10-8 < 10-8 < 1 x < 10-8 (< 0.75 x 10-8 ) (< 0.75 x 10-8 ) (< 0.75 x ) (< 0.75 x 10-8 ) Max. foreline pressure for N 2 with convection cooling with water cooling mbar (Torr) mbar (Torr) 0.3 (0.23) 2 (1.5) 2 (1.5) 3 (2.25) 2 (1.5) Recommended forevacuum pump Rotary vane pump or dry compressing pump offering a pumping speed of 100 m 3 /h TRIVAC D 65 BCS TRIVAC D 65 BCS TRIVAC D 65 BCS TRIVAC D 65 BCS Run-up time Forevacuum flange Purge / vent port Cooling water connection Weight, approx. min VCR nut Swagelok tube kg (lbs) < 10 < 10 < 10 < KF 40 KF 40 KF 40 KF 1/4" 1/4" 1/4" 1/4" 1/4" 1/4" 1/4" 1/4" 64 (141.3) 64 (141.3) 75 (165.6) 65 (143.5) I s Pumping Speed N2 He H mbar Inlet Pressure 10 Pumping speed of the TURBOVAC MAG W 3200 C ( 250) as a function of the inlet pressure 91

92 Turbomolecular Pumps with Magnetic Rotor Suspension with Compound Stage Ordering Information Inlet flange TURBOVAC MAG turbomolecular pump Electronic frequency converter MAG.DRIVE digital MAG.DRIVE digital with Profibus interface Plug-in control Connecting cable converter pump 1) 01.5 m (5.25 ft) DRIVE/BEARING 01.5 m (5.25 ft) TMS 03.0 m (10.5 ft) DRIVE/BEARING 03.0 m (10.5 ft) TMS 05.0 m (17.5 ft) DRIVE/BEARING 05.0 m (17.5 ft) TMS 10.0 m (35.0 ft) DRIVE/BEARING 10.0 m (35.0 ft) TMS 20.0 m (70.0 ft) DRIVE/BEARING 20.0 m (70.0 ft) TMS Seal kit 250 metal TURBOVAC MAG W 2800 C W 2800 CT W 2800 W 3200 CT 250 ISO-F 250 ISO-F 250 CF 320 ISO-F Part No. Part No. Part No. Part No V V V V0002 Part No. Part No. Part No. Part No V V V V V V V V0013 Part No. Part No. Part No. Part No Part No. Part No. Part No. Part No V V V V0001 Part No. Part No V V0001 Part No. Part No. Part No. Part No V V V V0008 Part No. Part No V V0008 Part No. Part No. Part No. Part No V V V V0004 Part No. Part No V V0004 Part No. Part No. Part No. Part No V V V V0002 Part No. Part No V V0002 Part No. Part No. Part No. Part No V V V V0003 Part No. Part No V V0003 Part No. Part No. Part No. Part No ) further connecting cables can be found under MAG.DRIVE digital in the section Turbomolecular Pumps with Magnetic Rotor Suspension, para. Frequency Converters 92

93 with Compound Stage Turbomolecular Pumps with Magnetic Rotor Suspension Notes 93

94 Turbomolecular Pumps with Magnetic Rotor Suspension Electronic Frequency Converters TURBOTRONIK NT 340 M Technical Features For operating the TURBOVAC 340 M turbomolecular pump Compact control unit 1/2 19", 3 HU No batteries are required because of integrated generator mode in case of power failures Front panel with membrane keypad and LCD Advantages to the User Convenient control and monitoring facilities Remote control and process control via analog and programmable control inputs and outputs Connection for backing pump, venting valve and flange heater RS 232 C interface h b b 1 b b 1 h h 1 h 2 mm in l l 1 l 2 l 3 mm in h 1 l 3 h 2 l 2 l l 1 Dimensional drawing for the TURBOTRONIK NT 340 M 94

95 Electronic Frequency Converters Turbomolecular Pumps with Magnetic Rotor Suspension Technical Data Mains connection, Hz; selectable V NT 340 M 100/120/220/240, +10%/-15 % Max. output voltage Overload current limit Permissible ambient temperature Dimensions (W x H x D) Weight, approx. V A C ( F) mm (in.) kg (lbs) 860/ to +45 (+32 to +113) 213 x 129 x 340 (8.39 x 5.08 x 13.39) 7 (15.4) Ordering Information 100 V (mains cord with US plug) 120 V (mains cord with US plug) 230 V (mains cord with EURO plug) Connecting line leading to the connection of the TURBOVAC 340 M 03 m (10.5 ft) 05 m (17.5 ft) 10 m (35.0 ft) 20 m (70.0 ft) NT 340 M Part No Part No Part No Part No Part No Part No Part No

96 Turbomolecular Pumps with Magnetic Rotor Suspension Electronic Frequency Converters TURBOTRONIK NT 340 MA Technical Features For operating the TURBOVAC MAG 400 C/CT turbomolecular pump Compact control unit 1/2 19", 3 HU No batteries are required because of integrated generator mode in case of power failures Front panel with membrane keypad and LCD Advantages to the User Convenient control and monitoring facilities Remote control and process control via analog and programmable control inputs and outputs Connection for backing pump, venting valve and flange heater RS 232 C interface Temperature control for Aluminum etching processes b b 1 b b 1 b 2 b 3 b 4 mm in b b 1 h 1 h3 d d 1 h h h 1 h 2 h 3 h 4 mm in h 1 h3 d d 1 h h 2 b 2 b 3 b 4 l 4 l 3 l l 1 l 2 l 3 l 4 mm in h 2 b 2 b 3 b 4 l 4 l 3 h 4 l 5 l 6 l 7 l 8 mm in h 4 l 2 l l 1 l 5 l 7 l 6 l 8 l 2 l l 1 Dimensional drawing for the TURBOTRONIK NT 340 MA Dimensional drawing for the TURBOTRONIK NT 340 MA with TCU temperature control unit attached 96

97 Electronic Frequency Converters Turbomolecular Pumps with Magnetic Rotor Suspension Technical Data TURBOTRONIK NT 340 MA Mains connection, Hz Power consumption TURBOVAC including connected consumers Max. output voltage Motor / current limiting Magnetic suspension / Current limiting Nominal frequency Overload current limit Permissible ambient temperature V VA VA V / A V / A Hz A C ( F) 120, +10%/-15 % < 400 < / 7 ± 16 / ± 7 860/ to +45 (+32 to +113) Dimensions (W x H x D) Weight, approx. mm (in.) kg (lbs) 213 x 129 x 340 (8.39 x 5.08 x 13.39) 7 (15.4) Ordering Information 120 V (mains cord with US plug) Connecting line leading to the connection of the TURBOVAC MAG 400 C/CT 3 m (10.5 ft) Connecting lines to the Heater (HEATER) 3 m (10.5 ft) Valve (VALVE 3 m (10.5 ft) Temperature control unit (I/O) 3 m (10.5 ft) Pt m (10.5 ft) Accessories for the temperature control Temperature control unit (TCU) Temperature sensor Pt 100 TURBOTRONIK NT 340 MA Part No Part No Part No Part No Part No Part No Part No Part No

98 Turbomolecular Pumps with Magnetic Rotor Suspension Electronic Frequency Converters MAG.DRIVE 2000 MAG.DRIVE 2000 without plug-in control Advantages to the User Designed to operate the TURBOVAC MAG 2000 C/CT and TURBOVAC MAG W 2000 C/CT turbomolecular pumps Easy operation through the controls or the use of plug-in control unit Communication to host computer of the customer via serial interface and conventional interface possible, bus adapter optional MAG.DRIVE 2000 with plug-in control Warning in case the pump is running out of specification Storing of all parameters in the pump s memory Plug-in control Small size and low weight Integrated fan Integrated temperature management system Setting of speed, temperature of the basic flange and other functions b b 1 d h h 1 h 2 h 3 l l 1 l 2 l 3 mm in b 40 l 1 l l 2 ød b 1 h 2 h 1 h h 3 l 3 Dimensional drawing for the MAG.DRIVE

99 Electronic Frequency Converters Turbomolecular Pumps with Magnetic Rotor Suspension Technical Data MAG.DRIVE 2000 Mains connection, 50/60 Hz Current for connected consumers, max. Max. output voltage Nominal frequency V A V Hz , +10%/-15% /60 Permissible ambient temperature Dimensions (W x H x D) Weight, approx. C ( F) mm (in.) kg (lbs) 0 to +45 (+32 to +113) 483 x 213 x 1/2 19" (19.02 x 8.39 x 1/2 19") 10 (22) Ordering Information MAG.DRIVE 2000 Plug-in control Connection line leading to the bearing of the TURBOVAC MAG (W) 2000 C/CT 01.5 m (5.25 ft) 05.0 m (17.5 ft) 10.0 m (35.0 ft) 20.0 m (70.0 ft) motor/tms of the TURBOVAC MAG (W) 2000 C/CT 01.5 m (5.25 ft) 05.0 m (17.5 ft) 10.0 m (35.0 ft) 20.0 m (70.0 ft) Connector for hardware interface 19" installation frame MAG.DRIVE 2000 Part No V0011 Part No Part No Part No Part No Part No Part No Part No Part No Part No upon request Part No

100 Turbomolecular Pumps with Magnetic Rotor Suspension Electronic Frequency Converters MAG.DRIVE digital MAG.DRIVE digital without plug-in control MAG.DRIVE digital with plug-in control Advantages to the User Operation of turbomolecular pumps with magnetically levitated rotors: TURBOVAC MAG W 830/1300 C, TURBOVAC MAG W 1500 C/CT, TURBOVAC MAG W 2200 C and TURBOVAC MAG W 2800/3200 C/CT Easy operation through the controls or the use of plug-in control unit Communication to host computer of the customer via serial interface and conventional interface possible Setting of speed, temperature of the basic flange and other functions Warning in case the pump is running out of specification Storing of all parameters in the pump s memory Plug-in control Small size and low weight Integrated fan Integrated temperature management system magnetic bearing control system b b 1 d h h 1 h 2 h 3 l l 1 l 2 l 3 mm in b 40 l 1 l l 2 ød b 1 h 2 h 1 h h 3 l 3 Dimensional drawing for the MAG.DRIVE digital Connection DRIVE/BEARING Connection TMS 180 Overview connection lines 100

101 Electronic Frequency Converters Turbomolecular Pumps with Magnetic Rotor Suspension Mains connection, 50/60 Hz Current for connected consumers, max. Max. motor voltage Nominal frequency Permissible ambient temperature Dimensions (W x H x D) Weight, approx. Technical Data Ordering Information V A V Hz C ( F) mm (in.) kg (lbs) MAG.DRIVE digital , +10%/-15% /60 0 to +45 (+32 to +113) 483 x 213 x 1/2 19" (19.02 x 8.39 x 1/2 19") 10 (22) MAG.DRIVE digital MAG.DRIVE digital MAG.DRIVE digital with Profibus interface Plug-in control Connection line leading to the DRIVE/BEARING of the TURBOVAC MAG... C/CT Cable outlet Cable outlet pump frequency converter DRIVE/BEARING DRIVE/BEARING PK 01.5 m (5.25 ft) bended 225 straight straight 01.5 m (5.25 ft) straight straight straight 03.0 m (10.5 ft) straight bended 180 straight 03.0 m (10.5 ft) bended 225 straight straight 03.0 m (10.5 ft) straight bended 270 straight 05.0 m (17.5 ft) bended 225 straight straight 05.0 m (17.5 ft) straight straight straight 08.0 m (28.0 ft) bended 225 straight straight 10.0 m (35.0 ft) bended 225 straight straigh 20.0 m (70.0 ft) bended 225 straight straight 23.0 m (80.5 ft) bended 225 straight straight 30.0 m (105 ft) bended 225 straight straight TMS (only for CT versions) Cable outlet Cable outlet pump frequency converter TMS TMS Heater 01.5 m (5.25 ft) bended 225 straight bended m (5.25 ft) straight straight bended m (10.5 ft) bended 225 straight bended m (17.5 ft) bended 225 straight bended m (28.0 ft) bended 225 straight bended m (35.0 ft) bended 225 straight bended m (70.0 ft) bended 225 straight bended 180 Purge / Vent (only for optional purge vent valve Part No ) Cable outlet Cable outlet pump frequency converter TMS Purge Vent 03.0 m (10.5 ft) bended 225 bended bended 10.0 m (35.0 ft) bended 225 bended bended Connector for hardware interface 19" installation frame Part No V0011 Part No V0013 Part No Part No V0001 Part No V0007 Part No V0006 Part No V0008 Part No V0009 Part No V0004 Part No V0010 Part No V0005 Part No V0002 Part No V0003 Part No V0012 Part No V0011 Part No V0001 Part No V0007 Part No V0008 Part No V0004 Part No V0005 Part No V0002 Part No V0003 Part No V0006 Part No V0002 upon request Part No

102 Turbomolecular Pumps with Magnetic Rotor Suspension Accessories Vibration Absorber Vibration absorbers are used to inhibit the propagation of vibrations from the turbomolecular pump to highly sensitive instruments like electron beam microscopes, microbalances or analytical instruments. Ordering Information Vibration absorber 063 ISO-K 66 mm (2.60 in.) long 063 CF 81 mm (3.19 in.) long 100 ISO-K 84 mm (3.31 in.) long 100 CF 100 mm (4.09 in.) long Vibration Absorber Part No V0063 Part No Part No V0100 Part No ISO-K 160 CF 84 mm (3.31 in.) long 104 mm (4.09 in.) long Part No Part No Air Cooling Unit Technical Data Air Cooling Unit Also an air cooling unit is available as a retrofit kit for convection cooling of the TURBOVAC 50 pump with air. This kit can be easily fitted to the pump in each case using the mounting components contained in the kit. Rated power consumption of the air cooling unit when connected to TURBOVAC 50, 151/361 TURBOVAC 600 C Ordering Information W W Air Cooling Unit Air cooling unit for 230 V 110 V TURBOVAC 50 Part No Part No TURBOVAC 151/361 Part No Part No TURBOVAC 600 C Part No Part No

103 Accessories Turbomolecular Pumps with Magnetic Rotor Suspension Flange Heaters for CF Highvacuum Flanges Most TURBOVAC pumps can be baked out in order to improve the ultimate pressure attained in the UHV range. Degassing of the turbomolecular pump will only be useful when simultaneously baking out the vacuum chamber. Technical Data Rated power consumption of the flange heater 063 CF, 100 CF 160 CF Ordering Information Flange heater 063 CF W W Flange Heater Flange Heater 230 V 110 V Part No Part No CF Part No Part No CF Part No Part No Fine Filter Ordering Information Fine Filter A fine filter integrated in the centering ring protects the pump against particles and dust on the highvacuum side. Connection flange of the fine filter 040 KF 063 ISO-K Part No Part No ISO-K Part No ISO-K Part No The following accessories are also available: Vacuum gauge COMBIVAC 2T Part No (see Product Section C16) Delayed venting unit Part No (see Product Section C10) 103

104 Turbomolecular Pumps Accessories Solenoid Venting Valve Technical Data Venting Valve Drive voltage Power consumption Connecting flange V DC W KF Weight, approx. kg (lbs) Ordering Information Solenoid venting valve, normally closed 0.3 (0.66) Venting Valve Part No V0011 Further vent valves available in US. Please contact your US sales office Power Failure Venting Valve Drive voltage Technical Data V DC Power Failure Venting Valve 24 Power consumption W 4 Connecting flange 16 KF Weight, approx. kg (lbs) Ordering Information Power failure venting valve, normally open 0.3 (0.66) Power Failure Venting Valve Part No V0021 Further vent valves available in US. Please contact your US sales office Purge Gas and Venting Valve Connecting flange Technical Data Purge gas and venting valve 10 KF Weight, approx. kg (lbs) Ordering Information Purge gas and venting valve, 230 V 0.2 mbar x l x s -1 (12 sccm) 0.4 mbar x l x s -1 (24 sccm) Purge gas and venting valve, 110 V 0.2 mbar x l x s -1 (12 sccm) 0.7 (1.55) Purge gas and venting valve Part No Part No Part No Purge Gas and Venting Valve Connecting flange Inlet Outlet Technical Data Purge gas and venting valve 1/4" pipe pump specific or 16 KF Purge gas pressure, abs. bar 1.5 to 6.0 Weight, approx. kg (lbs) Ordering Information Purge gas and venting valve, 24 V DC 0.6 mbar x l x s -1 (36 sccm) 0.5 (1.1) Purge gas and venting valve Part No Further 0.6 mbar x l x s -1 valves upon request 104

105 Accessories Turbomolecular Pumps Accessories for Serial Interfaces RS 232 C and RS 485 C Through these accessories many control, monitoring and information capabilities can be implemented in connection with the electronic frequency converters and turbomolecular pumps. The following turbomolecular pumps or electronic frequency converters are supported: TW 70 H / TURBO.DRIVE S TW 250 S / TURBO.DRIVE S / TURBO.DRIVE 300 TW 300, TW 300 H / TURBO.DRIVE S / TURBO.DRIVE 300 TW 701 T 1600, TW 1600 Software Ordering Information Software Turbo.Drive Panel, 3.5 in. floppy 1) Display Unit Part No V0104 1) 1) The panel software can be downloaded from PC Software PC software for Windows 95 or higher Technical Features Convenient graphical user interface Several turbomolecular pumps can be operated in parallel Display, modify, save and compare the parameter lists of the turbomolecular pumps Integration of customer s software Recording parameter data over time (for example, temperatures, rotor frequency) Ordering Information PC software Turbo.Drive Server, CD ROM 1) PC Software Part No V0102 1) 1) The PC software can be downloaded from Adaptor RS 232 C/RS 485 C for Frequency Converter with RS 485 C Interface Ordering Information Adaptor RS 232 C/RS 485 C, mains connection 220 V, 50 Hz, EURO plug Adaptor RS 232 C/RS 485 C Part No V