CT.ES1- ydraulic Cylinder (Conforms to ISO) Series CS Nominal pressure Pa/Pa Reduced projection area: 6 % or less compared to series C CS/asic Reduced overall length + Stroke CS/ CS C C aximum weight: no more than % or 5% of series C (CS) (CS) Compared to series C, the tie-rod type cylinder of same size. Cylinder with built-in cover and mounting bracket allows easy disassembly and assembly. Tube size + Stroke Overall length ( size) CS CS C - 1 5 3 4 00 51 5 0 31 5 5 5 Conformed to ISO 6 (IS -5:00) Series CS/Pa ø, ø, ø, ø, ø Conformed to ISO 0- (IS -:00) Series CS/Pa ø, ø, ø, ø, ø, ø
Pa ydraulic Cylinder (Conforms to ISO) Series CS ø, ø, ø, ø, ø Type Reed switch Solid state switch 1 agnet for auto switch Nil L Z C T Without uilt-in C S Series type Symbol Nominal pressure Pa ounting types asic Transaxial foot type ront rectangular flange type Rear rectangular flange type ouble clevis ront trunnion Port thread type Nil Rc TN NPT T Special function Prewired connector Electrical entry rommet rommet Indicator light es es Wiring (output) 3-wire (NPN equiv.) -wire ore size mm mm mm mm mm Rod end nut Presence of cusion Load voltage C C Nil Nil N R ow to Order Cylinder suffix Without rod end nut With rod end nut With cushion on both sides Without cushion With front bumper With rear bumper uto switch model Tie-rod mounting 5 pplicable uto / Refer to page 5.3- of est Pneumatics ol. for detailed auto switch specifications. iagnostic indication (-color display) iagnostic indication (-color display) Water resistant (-color indicator) With diagnostic output (-color display) Latch type with diagnostic output (-color display) Lead wire length symbol Stroke Refer to the standard stroke table on the next page. 3-wire (NPN) 3-wire (PNP) -wire 3-wire (NPN) 3-wire (PNP) -wire 4-wire (NPN) 4 4 4 5, 00 5, 5, 5, 0.5 m Nil (Example) 54 3 m L (Example) 54L 5 m Z (Example) 54Z Note) When more than one symbol is to be specified, indicate them in alphabetical order., 00 Z6 Z3 54 5W 5 5P 51 5 5W 5PW 5W 5 5 5L Lead wire length (m) 0.5 (Nil) esides the models in the above table, there are some other auto switches that are applicable. or more information, refer to page. Contact SC for detailed auto switch specifications. 3 (L) 5 (Z) pplicable load IC circuit IC circuit IC Relay, circuit PLC IC circuit Relay, PLC Solid state switches marked with are produced upon receipt of order. -5 /6 /5W can not be mounted to ø,. Number of auto switches Nil S 1 n n uto switch Nil Without auto switch Select an applicable auto switch model from the table below. -Z is not mounted and are supplied loose. (Only the switch mounting brackets for these models are mounted.) Port position Port and cushion valve Symbol Position location viewed from the side of piston rod end thread Nil C E Port on top, cushion valve on the right Port on top, cushion valve on the left Port on top, cushion valve down Port on the right, cushion valve down Port on the right, cushion valve on top Port on the right, cushion valve on the left Piping port Cushion valve Note 1) Refer to table 1 for manufactuability. Note ) iagrams illustrate the view from the rod on the left side of the cylinder dimensions. Table 1 anufacturability Check List by ounting Type and Port Position ounting Port bracket position L Z C T Nil C Note) Note) E Note) : Standard product : ade to order : Not available due to size limitation. Note) Each of C,, E is same as the Nil,, just turned.
ydraulic Cylinder (Conforms to ISO) Pa Series CS Specifications IS Symbol odel ction luid Nominal pressure aximum allowable pressure Proof pressure inimum operating pressure mbient and fluid temperature Piston speed Cushion Thread tolerance Stroke length tolerance With pressure at front side With pressure at rear side Without magnet uilt-in magnet mm or less 1 to mm 51 to 0 mm 1 to 0 mm CS ouble cting: Single Rod eneral mineral hydraulic fluid Pa Pa Pa 0.5 Pa 0. Pa - to C - to C to 0 mm/s Cushion seal IS 6 g/6 0 to +0. mm 0 to +1.0 mm 0 to +1.5 mm 0 to +1.4 mm uto ounting racket Part No. Standard Stroke uto switch model -5 /6-5W -5 /5-5 W/5W -5-5L -5NTL ore size, T-03 T-04 T-06 T- ore size Standard stroke 5 to 0 -Z /Z 4-0 4-0 4-0 S4-5 -5 /6 /5W can not be mounted to ø,. Theoretical Output Unit: N ore size Rod size Operating direction Piston area (mm ) Operating pressure (Pa) 3.5 6 4 66 61 0 4 61 4 4 0 40 31 0 6 63 3 00 6 51 06 35 5 0 53 5 65 51 3 5 50 Theoretical output (N) = Pressure (Pa) x Piston area (mm ) Weight (kg) ore size asic. 3.0 5..0.5 Transaxial foot L. 3. 5..0.0 asic weight (0 stroke) ront flange Rear flange Z.. 3. 3. 5.0 6.00.1.0.0.4 ouble clevis C. 3. 6..0. ront trunnion T. 3. 5...5 dditional weight per strokes 0.06 0.0 0. 0.1 0.
Series CS Construction C S 1 3 3 6 5 4 5 4 31 0 6 1 Parts List No. 1 3 4 5 6 escription Rod cover ead cover Seal holder Cylinder tube Piston agnet plate Cushion ring Cushion ring nut ushing Piston rod Tie-rod Tie-rod nut Cushion valve alve holder ir release valve Check ball aterial Carbon steel Carbon steel Carbon steel Stainless steel Stainless steel Stainless steel Carbon steel Carbon steel Copper alloy Carbon steel Chromium molybdenum steel Carbon steel lloy steel Carbon steel lloy steel earing steel No. 0 1 3 4 5 6 31 escription Snap ring Set screw Pin Wear ring Scraper Rod seal ack-up ring Piston seal Cylinder tube gasket older gasket alve seal alve holder gasket Cushion seal Piston gasket agnet aterial Carbon tool steel lloy steel Stainless steel Resin NR NR Resin NR NR NR NR NR NR Replacement Parts / Seal its ore size Seal kit no. CS-PS CS-PS CS-PS CS-PS CS-PS Seal kits consists of item 1 to 5 and, and can be ordered by using the seal kit number for each bore size. 3
ydraulic Cylinder (Conforms to ISO) Pa Series CS imensions asic / CS Z + Stroke -RcP P + Stroke C Transaxial oot Type / CSL ir release P + Stroke S + Stroke -RcP L LT L øe ø øe ø ir release SS N Cushion valve S + Stroke ZZ + Stroke N ore size Stroke range C E N N P P S SS Z ZZ 5 to 0 5 65 6 1 5 0 4 4 31 4 3 4 5 4 6 1 1 1 1.5 1.5.5.5.5 5 5 1.5 3/ 0 1.5.5.5 3/ 4 5 4 1/ 1/ 3/4 66 4 6 1 3 6 5 31 3 35 6.5 1 1.5 65 6 6 3 3.5 5.5 C LX 4-øC SS 1 X1 Cushion valve Z + Stroke Z + Stroke ZZ + Stroke X ore size Stroke range C C E L LT LX L P P S SS 5 to 0 5 0 65 3 1 6 1 5 0 4 4 31 4 3 4 5 4 6 1 1 1 1.5 1.5 5.5 3 4.5 5 0 51.5.5 3 64.5 5 6.5 1 5.5.5 5 1 4.5.5 5 5 1.5 0 1.5 4 3/ 3/ 1/ 1/ 3/4 66 1 4 3 6 6 65 6 ore size X1 X 1 Z Z ZZ 6.5.5.5 0 0 4 3 5 5 6 4 6 1 1.5 6 3 3.5 5.5 4
Series CS imensions ront lange / CS Z + Stroke P + Stroke -RcP 4-ø Rear cushion valve ør øe ø X Z ront air release ront cushion valve T SS N ir release S + Stroke ZZ + Stroke N C ir release ore size Stroke range C E T X Z N N P P 5 to 0 5 65 6 1 5 65 6 1 5 0 4 6.6.5 0 6 1 0 0 6 5 1 3 4 3 4 1 6 5 6 1 6 1 4 1 6 1.5 1 1.5.5.5.5 5 5 1.5 3/ 0 1.5.5.5 3/ 4 4 1/ 1/ 4 3/4 66 4 6 ore size R S SS Z ZZ 51 6 1-0.0-0.06-0.0-0.00 5 1 1 35 4 51 5 6.5 65 6 1 1.5 6 3 3.5 5.5 Rear lange / CSZ Width across flats Z + Stroke P + Stroke -RcP ront cushion valve 4-ø øe ø ir release C N ir release S + Stroke ZZ + Stroke N Rear flange air release Rear cushion valve X Z ore size Stroke range C E X Z N N P P S Z ZZ 5 to 0 5 65 6 5 65 6 5 1 1 0 4 6.6 0 6 6 5 4 1 1 0 3.5 0 31 4 3 4 5 4 6 1 1 1 1.5 1.5 1.5 3/ 6.5 1 4 5 0 1.5.5.5 3/ 65 1/ 66 1 6 3 5 1/ 4 3 5 4 4 3/4 6 43 5
ydraulic Cylinder (Conforms to ISO) Pa Series CS imensions ouble Clevis / CSC Width across flats SS + Stroke P + Stroke -Rc P øe ø øc ir release C N Cushion valve S + Stroke ZZ + Stroke N L RR W CX C W ore size Stroke range C C C CX E L N N P P RR S 5 to 0 5 65 6 1 5 0 64 64 3 3 1 0 0 +0.043 0 +0.05 0 0 0 4 4 31 4 3 4 5 4 6 1 1 1 1.5 1.5 3 5 5 1.5 3/ 0 1.5.5.5 3/ 4 5 4 1/ 1/ 3/4 66 4 6 1 3 6 ore size SS W ZZ 1 6.5.5.5 5.5 00.5 6 1.5 65 6 0 03 4 3 ront Trunnion / CST Z + Stroke P + Stroke -RcP øt øe ø ront cushion valve C TX TZ Width across flats ront air release SS N Rear cushion valve ir release S + Stroke ZZ + Stroke N ore size Stroke range C E N N P P S SS T TX TZ 5 to 0 5 65 6 1 5 0 4 4 31 4 3 4 5 4 6 1 1 1 1.5 1.5.5.5.5 5 5 1.5 3/ 0 1.5.5.5 3/ 4 5 4 1/ 1/ 3/4 66 4 6 1 3 6 54 61 6 3-0.0-0.043 55 0-0.00-0.053 5 6 0-0.05 1-0.064 0 4 ore size Z ZZ 6.5 1 1.5 6 3 3.5 5.5 6
Series CS Proper uto ounting Position for Stroke End etection and ounting eight -5 /6-5 (W)/5 (W)/5L s -Z /Z s t t t t Proper uto ounting Position ore size -5 /5-5 /6-5W -5 W/5W -5-5L -5NTL -5L 4.5.5.5 0 3.5 6.5.5.5 3.5.5 Operating Range.5 5 4.5 6.5.5.5.5.5 0 0.5.5 -Z /Z 5 6.5 1.5 3.5 uto ounting eight ore size -5 /6-5W t 3.5 4 s 4.5 54 66.5-5 /5-5 W/5W -5-5L -5NTL t.5.5 3.5 4 s 35.5 3.5 51.5-5L t.5.5 3.5 4 s.5.5 5 64.5 -Z /Z t 3 5 s 3.5 5 inimum uto ounting Stroke uto switch model -5 /6-5W -Z /Z -5 /5-5 W/5W -5L/5NTL -5-5L 4 5 4.5 5.5 ore size.5 4.5 5.5 5.5 6.5.5.5 5.5 6.5 uto switch model (ifferent side and same side), 1 n -5 /6-5 /5-5 W/5 W -5L -5 /5NTL -5W -Z /Z 0 0 (n-) 0+55 n =, 4, 6, (n-) +55 n =, 4, 6, 0+ (n-) n =, 4, 6, esides the models listed in ow to Order, the following auto switches are applicable. Refer to page 5.3- of est Pneumatics ol. for detailed auto switch specifications. uto switch type Part no. Electrical entry eatures -53, Reed -64, 6 rommet (in-line) -Z Without indicator light Solid state -5NTL rommet (in-line) With timer Solid state switches are also available with pre-wired connector. Contact SC for detailed auto switch specifications.
ydraulic Cylinder (Conforms to ISO) Pa Series CS
Pa ydraulic Cylinder (Conforms to ISO) Series CS ø, ø, ø, ø, ø, ø agnet for auto switch Nil L Z C C T TC Without uilt-in C S Series type Symbol Nominal pressure Pa ounting types asic Transaxial foot type ront rectangular flange type Rear rectangular flange type Single clevis ouble clevis ront trunnion Center trunnion Port thread type Nil Rc TN NPT T ore size mm mm mm mm mm mm ow to Order Stroke Refer to the standard stroke table on the next page. Cylinder suffix Nil Nil N R Without rod end nut With rod end nut With cushion on both sides Without cushion With front bumper With rear bumper Note) When more than one symbol is to be specified, indicate them in alphabetical order. 5 pplicable uto / Refer to page 5.3- of est Pneumatics ol. for detailed auto switch specifications. Type Reed switch Solid state switch Special function iagnostic indication (-color display) iagnostic indication (-color display) Water resistant (-color indicator) With diagnostic output (-color display) Latch type with diagnostic output (-color display) Lead wire length symbol Prewired connector Electrical entry rommet rommet Indicator light es es Wiring (output) 3-wire (NPN equiv.) -wire 3-wire (NPN) 3-wire (PNP) -wire 3-wire (NPN) 3-wire (PNP) -wire 4-wire (NPN) 4 4 4 Rod end nut Presence of cusion Load voltage uto switch model Tie-rod mounting Lead wire length (m) esides the models in the above table, there are some other auto switches that are applicable. or more information, refer to page. Contact SC for detailed auto switch specifications. C C 5, 00 5, 5, 5, 0.5 m Nil (Example) 54 3 m L (Example) 54L 5 m Z (Example) 54Z, 00 Z6 Z3 54 5W 5 5P 51 5 5W 5PW 5W 5 5 5L 0.5 (Nil) 3 (L) 5 (Z) pplicable load IC circuit IC circuit IC Relay, circuit PLC IC circuit Relay, PLC Solid state switches marked with are produced upon receipt of order. -5 /6 /5W/Z /Z can not be mounted to ø. Number of auto switches Nil S 1 n n uto switch Nil Without auto switch Select an applicable auto switch model from the table below. -Z is not mounted and are supplied loose. (Only the switch mounting brackets for these models are mounted.) Port position Port and cushion valve Symbol Position location viewed from the side of piston rod end thread Port on top, Nil cushion valve on the right Port on top, cushion valve on the left Port on top, cushion valve down C E Port on the right, cushion valve down Port on the right, cushion valve on top Port on the right, cushion valve on the left Piping port Cushion valve Note 1) Refer to table 1 for manufactuability. Note ) iagrams illustrate the view from the rod on the left side of the cylinder dimensions. Table 1 anufacturability Check List by ounting Type and Port Position ounting Port bracket position Nil C E L Z C T TC Note) Note) Note) : Standard product : ade to order : Not available due to size limitation. Note) Each of C,, E is same as the Nil,, just turned.
ydraulic Cylinder (Conforms to ISO) Pa Series CS Specifications IS Symbol odel ction luid Nominal pressure aximum allowable pressure Proof pressure inimum operating With pressure at rod side pressure With pressure at head side mbient and fluid Without magnet temperature uilt-in magnet Piston speed Cushion Thread tolerance Stroke length tolerance mm or less 1 to mm 51 to 0 mm 1 to 0 mm CS ouble cting: Single Rod eneral mineral hydraulic fluid Pa 0 Pa 4 Pa 0.5 Pa 0. Pa - to C - to C to 0 mm/s Cushion seal IS 6 g/6 0 to +0. mm 0 to +1.0 mm 0 to +1.5 mm 0 to +1.4 mm uto ounting racket Part No. Standard Stroke uto switch model -5 /6-5W -5 /5-5 W/5W -5-5L -5NTL ore size,, T-03 T-04 T-0 T- ore size Standard stroke 5 to 0 -Z /Z 4-0 4-0 S4-0 -5 /6 /5W/Z /Z can not be mounted to ø. Theoretical Output Unit: N ore size Rod size Operating direction Piston area (mm ) 3.5 Operating pressure (Pa) 4 54 343 540 64 4 6 4 66 61 0 006 1 4 61 4 4 0 40 3 5 31 0 6 63 3 00 4 4 6 51 06 35 5 0 4 546 53 5 65 541 3 5 50 4 6 Weight Theoretical output (N) = Pressure (Pa) x Piston area (mm ) (kg) ore size asic 1. 3.0 4.0.. 0. Transaxial foot L 1. 4.00 5.0.65.0 3.3 ront flange 1.0 4. 6.00... asic weight (0 stroke) Rear flange Single clevis Z C 1.0 1. 3.0 3. 5. 5..0.0.4.4 4. 4. ouble clevis C 1. 3. 5..0.4 4. ront trunnion T 1.0 3. 5.0...5 Center trunnion TC 1.0 3.0 5... 5.4 dditional weight per strokes 0.05 0.0 0. 0. 0. 0.4
Series CS Construction C S 1 3 3 6 4 31 5 4 5 0 6 1 Parts List No. 1 3 4 5 6 escription Rod cover ead cover Seal holder Cylinder tube Piston agnet plate Cushion ring Cushion ring nut ushing Piston rod Tie-rod Tie-rod nut Cushion valve alve holder ir release valve Check ball aterial Carbon steel Carbon steel Carbon steel Stainless steel Stainless steel Stainless steel Carbon steel Carbon steel Copper alloy Carbon steel Chromium molybdenum steel Carbon steel lloy steel Carbon steel lloy steel earing steel No. 0 1 3 4 5 6 31 escription Snap ring Set screw Pin Wear ring Scraper Rod seal ack-up ring Piston seal ack-up ring Cylinder tube gasket older gasket alve seal alve holder gasket Cushion seal Piston gasket agnet aterial Carbon tool steel lloy steel Stainless steel Resin NR NR Resin NR Resin NR NR NR NR NR Replacement Parts / Seal its ore size Seal kit no. CS-PS CS-PS CS-PS CS-PS CS-PS CS-PS Seal kits consists of item 1 to 6 and, and can be ordered by using the seal kit number for each bore size.
ydraulic Cylinder (Conforms to ISO) Pa Series CS imensions asic / CS Z + Stroke P + Stroke -RcP øe ø ir release C SS N Cushion valve S + Stroke ZZ + Stroke N ore size Stroke range C E N N P P S SS Z ZZ 5 to 0.. 5 5.3 0 64.3 1. 1 6. 4 4 35 3 4 3 4 0 0 43 4 53 6 6 1 6 1 1 1.5 1.5 1.5 1.5.5 5 5 1.5 1.5 0 1.5 4 51 5 55 66 6 3 1/4 3/ 1/ 1/ 3/4 3/4 3 3 4 4 1 3 1 5 5 5 31 35 5.5 6.5 6 6 1 3.5 3 5 0 51 03 5 Transaxial oot Type / CSL ir release Width across flats S + Stroke P + Stroke -RcP L LT L øe ø C LX 4-øC SS 1 X1 Cushion valve Z + Stroke Z + Stroke ZZ + Stroke X ore size Stroke range C C E L LT LX L P P S SS 5 to 0 4. 3. 5 5.3 0 1 64.3 1 6. 1 6. 6 4 4 35 3 4 3 4 0 0 43 4 53 6 6 1 6 1 1 1.5 1.5 1.5 1.5 31 3 44 5.5 44.5.5.5 3 6.5 4.5 6 4 6 4.5 5 5 1.5 1.5 0 1.5 4 1/4 3/ 1/ 1/ 3/4 3/4 3 3 4 4 1 3 1 54 65 6 ore size X1 X 1 Z Z ZZ 5.5 6.5 6 31 3 0 3 6 6 1 0 0 3 44 3 3.5 3 5 6 5 0 51 03 5
Series CS imensions ront lange / CS 4-ø Z + Stroke P + Stroke -RcP Rear cushion valve ør øe ø X Z ront air release ront cushion valve T SS ir release N S + Stroke ZZ + Stroke N C ir release ore size Stroke range C E T X Z N N P P 5 to 0 5 0 1 1.. 5 5.3 0 64.3 1. 1 6. 4 6.6 0 5 1 5 65 3 0 1 1 1 0 00 4 5 6 3 6 5 0 0 53 6 1 5 1 6 1.5 4 1.5 6 1.5 1 1.5.5 5 5 1.5 1.5 0 1.5 4 3 3 1/4 3/ 3 1/ 4 1/ 3/4 3 3/4 1 ore size R S SS Z ZZ 4 6 4 5-0.05-0.064-0.0-0.06-0.0-0.00 3 1 1 0 6 35 35 4 51 5 5.5 6.5 6 6 1 3.5 3 5 0 51 03 5 Rear lange / CSZ Z + Stroke P + Stroke -RcP ront cushion valve 4-ø øe ø ir release C Width across flats ir release N S + Stroke ZZ + Stroke N Rear flange air release X Z Rear cushion valve ore size Stroke range C E X Z N N P P S Z ZZ 5 to 0.. 5 5 5.3 0 0 64.3 1 1. 1 1 6. 4 6.6 5 1 5 65 3 0 1 1 1 0 00 4 35 3 4 3 4 0 0 43 6 1 4 1 53 1.5 6 1.5 6 1.5 1 1.5 5 5 1.5 1.5 0 1.5 4 51 5 55 66 6 3 1/4 3 5.5 3/ 3 6.5 1/ 4 4 1/ 1 3/4 3 3/4 1 6 6 3 5 6 1 04 0 35 03 5
ydraulic Cylinder (Conforms to ISO) Pa Series CS imensions Single Clevis / CSC SS + Stroke P + Stroke -RcP Cushion valve øc øe ø Width across flats N ir release S + Stroke ZZ + Stroke N L RR CX C ir release ore size Stroke range C C CX E L N N P P RR S SS ZZ 5 to 0.. 5 5.3 0 64.3 1. 1 6. +0.043 0 0 +0.05 0 0 +0.06 0 0 4 4 35 3 4 3 4 0 0 43 4 53 6 6 1 6 1 1 1.5 1.5 1.5 1.5 3 54 5 5 1.5 1.5 0 1.5 4 51 5 55 66 6 3 1/4 3/ 3 1/ 4 1/ 3/4 3 3/4 1 3 5.5 6.5 4 1 1 00 5 6 6 4 1 65 3 ouble Clevis / CSC SS + Stroke P + Stroke -RcP Cushion valve eeper plate øc /f øe ø Width across flats N ir release S + Stroke ZZ + Stroke N L RR CX C C ir release ore size Stroke range C C CX C E L N N P P RR 5 to 0.. 5 5.3 0 64.3 1. 1 6. 0 0 0 43 4 4 35 3 4 3 4 0 0 43 4 53 6 6 1 6 1 1 1.5 1.5 1.5 1.5 3 54 5 5 1.5 1.5 0 1.5 4 51 5 55 66 6 3 1/4 3/ 1/ 1/ 3/4 3/4 3 4 3 1 Tolerances ore size S SS 3 4 1 1 00 5 5.5 6.5 6 6 1 ZZ 4 65 3 ore size C f +0.043 0 +0.05 0 +0.06 0-0.0-0.043-0.00-0.053-0.05-0.064
Series CS imensions ront Trunnion / CST Width across flats Z + Stroke P + Stroke -RcP Rear cushion valve øt øe ø ront cushion valve T C TX TZ T ront air release S S N ir release S + Stroke ZZ + Stroke N ore size Stroke range C E N N P P T TX TZ S SS Z ZZ 44 61 5.. 5 5.3 0 64.3 1 1. 5 to 0 5 1 6. 4 4 35 3 4 3 4 0 0 43 6 1.5 1.5 4 1 1.5 51 53 1.5 5 0 1.5 5 6 1.5 6 1.5 1 1.5 5 4 55 66 6 3 1/4 3/ -0.0-0.043 3 0 6 3 54 5 5-0.00 1/ 4 5-0.053 6 1 4 64 1/ 1 0-0.05 3/4 3-0.064 4 6 3/4 1 0 1 5.5 3.5 6.5 6 3 5 6 1 0 51 03 5 Center Trunnion / CSTC SS + 1/ Stroke P + Stroke -RcP Cushion valve Width across flats øt øe ø ir release C TX T TZ N ir release TT S + Stroke ZZ + Stroke ir release N ore size Stroke range C E N N P P S SS T TT TX T TZ ZZ 5 to 0 5. 65. 5 5 5.3 0 0 64.3 1 1. 1 1 6. 4 4 35 3 4 3 4 0 0 43 6 1.5 1.5 4 1 1.5 51 53 1.5 5 0 1.5 5 6 1.5 6 1.5 1 1.5 5 4 55 66 6 3 1/4 3 3/ 3.5 0 1/ 1/ 4 4 4 1 1 5 3/4 3 3.5 3/4 1 1.5 0-0.0-0.004-0.043-0.00-0.054 0 53 55 5.5 3.5 6 6 6.5 6 5 6 0 1 1 44 3 1 54 1 1 0 51 5
ydraulic Cylinder (Conforms to ISO) Pa Series CS Proper uto ounting Position for Stroke End etection and ounting eight -5 /6-5 (W)/5 (W)/5L s -Z /Z s t t Proper uto ounting Position ore size -5 /6-5W -5 /5-5 W/5W -5L -5NTL -Z /Z ore -5 size -5L.5.5.5.5 1 0.5 0 1.5 3.5.5.5.5 1.5 5 4.5 3.5 5.5.5 Operating Range.5 1 4.5 4.5 6.5.5 3 3 5 31.5.5.5.5 4 4 6.5.5.5 1 4.5 4 3 5.5 t t uto ounting eight -5 /6-5W t 3.5 43.5.5 64.5 s 3.5 43.5 4 5.5 6-5 /5-5 W/5W -5-5L -5NTL t 5 3.5 43.5.5 64.5 s.5.5 5 66-5L t 5 3.5 43.5.5 64.5 s.5 3 4 4.5 6 -Z /Z t.5 4 54.5 61.5 s 3 4.5 54 6.5 uto switch model -5 /6-5W -Z /Z -5 /5-5 W/5W -5L/5NTL -5-5L 4 5 ore size.5.5.5.5.5.5.5.5.5 4.5 5.5 inimum uto ounting Stroke 5 6 4 5 5.5 6.5 6.5.5 uto switch model uto switch mounting number (ifferent side and same side), 1 ounting bracket other than center trunnion 5-5 /6 5+55 (n-) n n =, 4, 6, (ifferent side and same side), 1-5W +55 (n-) n n =, 4, 6, (ifferent side and same side), 1 0-5 /5-5 W/5 W 0+55 (n-) n -5L n =, 4, 6, (ifferent side and same side), 1 0-5 /5NTL 0+55 (n-) n n =, 4, 6, (ifferent side and same side), 1 5 -Z /Z 5+ (n-) n n =, 4, 6, 1 1+55 (n-4) n=4,,, 5 5+55 (n-4) n=4,,, 0 0+55 (n-4) n=4,,, 5 5+55 (n-4) n=4,,, 5 5+55 (n-4) n=4,,, 1 1+55 (n-4) n=4,,, 5 5+ (n-4) n=4,,, 0 0+55 (n-4) n=4,,, 1 1+55 (n-4) n=4,,, 1 1+55 (n-4) n=4,,, 1 1+55 (n-4) n=4,,, + (n-4) n=4,,, Center trunnion 1 1+55 (n-4) n=4,,, 5 5+55 (n-4) n=4,,, 5 5+55 (n-4) n=4,,, 1 1+55 (n-4) n=4,,, 5 5+ (n-4) n=4,,, 5 5+55 (n-4) n=4,,, 1 1+55 (n-4) n=4,,, 1 1+55 (n-4) n=4,,, 5 5+55 (n-4) n=4,,, 1 1+ (n-4) n=4,,, 1 1+55 (n-4) n=4,,, 5 5+55 (n-4) n=4,,, 1 1+55 (n-4) n=4,,, 5 5+55 (n-4) n=4,,, 5 5+ (n-4) n=4,,, esides the models listed in ow to Order, the following auto switches are applicable. Contact SC for detailed auto switch specifications. uto switch type Part no. Electrical entry eatures -53, Reed -64, 6 rommet (in-line) -Z Without indicator light Solid state -5NTL rommet (in-line) With timer Solid state switches are also available with pre-wired connector. Contact SC for detailed auto switch specifications.
ydraulic Cylinder uto Specifications Specific Product Precautions e sure to confirm auto switch precautions on pages 31 through before handling auto switches. uto Common Specifications Type Leakage current Operating time Impact resistance Insulation resistance Withstand voltage Reed switch None mbient temperature to C Note 1) Except solid state auto switch with timer (5NTL). Solid state switch 3-wire: µ or less -wire: 1 m or less 1. ms 1ms or less 1) 0 m/s 0 m/s or more at 0 C (between lead wire and case) C for 1 minute (between lead wire and case) 0 C for 1 minute (between lead wire and case) uto ysteresis ysteresis is the distance between the position at which piston movement operates an auto switch to the position at which reverse movement turns the switch off. This hysteresis is included in part of the operating range (one side). operating position (ON) Note) ysteresis uto switch Reed switch: mm or less Solid state switch: 1 mm or less Lead Wire Length Lead wire length indication (Example) 54 L operating position (O) Note) The amount of hysteresis varies with the operating environment and is not guaranteed. Consult with SC regarding applications in which hysteresis becomes a problem. Lead wire length Nil L Z 0.5 m 3 m 5 m Note 1) Lead wire length Z: 5 m applicable auto switches Reed switch: -53 54, -Z3 Solid state switch: ll types are produced upon receipt of order (standard procedure). Note ) The standard lead wire length is 3 m for solid state switches with timer and water resistant -color display solid state switches (0.5 m is not available).
SWITC uto Specifications Contact Protection ox / C-P, C-P 1 <pplicable switch models> -Z Z The above auto switches do not have internal contact protection circuits. Operated load is an induction load. The length of wiring to the load is 5 m or more. The load voltage is C or 00 C. contact protection box should be used in any of the above situations. Otherwise, the life of the contacts may be reduced. (They may stay on continuously.) Internal circuits C-P Surge absorber C-P Zener diodes Choke coil Choke coil (+) urthermore, even in the case of a type having and internal contact protection circuit (-54, 64), if the length of the wiring to the load is extremely long ( cm or more) and a PLC (sequence controller) having a large rush current is used, consult with SC as a contact protection box may be necessary. Specifications/imensions () 4.4 imensions Part No. Load voltage aximum load current C 5 m C-P 00 C.5 m Lead wire length connection side 0.5 m Load connection side 0.5 m C-P 4 C m 3.4 C-P OLT 3 ø3.4.5 Connection To connect a switch unit to a contact protection box, connect the lead wire from the side of the contact protection box marked SWITC to the lead wire coming out of the switch unit. urthermore, the switch unit should be kept as close as possible to the contact protection box, with a lead wire length of no more than 1 meter between them.
Series CS Reed Internal Circuits -53 (-) Reed switch LE diode Resistor Zener diodes (+) -64 ( ) ± Reed switch Surge absorber Choke coil (±) ~ -Z3 LE diode Resistor Reed switch Zener diodes Contact Protection ox C-P C-P (+) (-) -54 (-) -, Z6 Reed switch Reed switch LE diode Resistor Reverse current prevention diode Zener diodes Resistor LE diode Surge absorber C (+) lack C (-) Load Choke coil (+) (-) (+) ~ C power supply -6, Z ( ) ± Indicator light / isplay method ON Operating range O Indicator Reed switch Red reen Red (±) Optimum operating position -5W main circuit Choke coil Reed switch Zener diodes LE (-) Solid State Internal Circuits -5-5PW -5P C (+) C (+) C (+) main circuit -5W -5L main circuit -5L lack C (-) (+) (-) main circuit -5W main circuit -5 lack C (-) C (+) lack C (-) main circuit -5 main circuit -51 lack C (-) (+) (-) main circuit -5NTL C (+) (normal output) lack iagnosis (diagnostic output) Orange C (-) main circuit C (+) (normal output) lack iagnosis (diagnostic output) Orange C (-) main circuit C (+) main circuit lack C (-)
asic Wiring Series CS uto Connections and Examples Solid state 3-wire, NPN main circuit Load lack Solid state 3-wire, PNP main circuit lack Load -wire (Solid state) main circuit Load -wire (Reed switch) Indicator light Protective circuit etc. Load (Power supplies for switch and load are separate.) main circuit Load lack main circuit Load Indicator light Protective circuit etc. Load Examples of Connection to PLC (Programable Logic Controller) Sink input specifications 3-wire, NPN lack Input CO PLC internal circuit -wire type Input Souce input specifications 3-wire, PNP lack Input CO PLC internal circuit -wire type Input s the connection method will vary depending on the PLC input specifications, connect according to the applicable PLC input specifications. CO PLC internal circuit CO PLC internal circuit Connection Examples for N (Series) and OR (Parallel) 3-wire N connection for NPN output (using relays) 1 lack Relay lack Relay Load Relay contact N connection for NPN output (performed with switches only) lack 1 Load lack OR connection for NPN output 1 lack lack Load The indicator lights will light up when both switches are in the ON state. -wire with -switch N connection 1 Load When two switches are connected in series, a load may malfunction because the load voltage will decline when in the ON state. The indicator lights will light when both switches are in the ON state. Load voltage at ON = Power supply voltage - Internal voltage drop pcs. = 4-4 pcs. = Example: Power supply is 4 C. Internal voltage drop in switch is =4. -wire with -switch OR connection (Solid state switches) When two switches Load are connected in parallel, malfunction may 1 occur because the load voltage will increase when in the O state. Load voltage at O = Leakage current pcs. Load impedance =1 m pcs. 3 k = 6 Example: Load impedance is 3 k. Leakage current from switch is 1 m. (Reed switches) ecause there is no current leakage, the load voltage will not increase when turned O. owever, depending on the number of switches in the ON state, the indicator lights may sometimes grow dim or not light up because of the dispersion and reduction of the current flowing to the switches. 0
Series CS Technical ata 1 ore Size Selection Relationship among generated force, bore size and pressure cylinder s generated force will be lower than the theoretical output due to the following factors. (1) Sliding resistance on the cylinder bearings, seals, etc. () Pressure loss in hydraulic equipment and piping (3) rictional resistance in moving parts of machinery It is necessary to select bore sizes considering these factors. When a cylinder is nearly at rest, the relation of generated force, bore size and pressure can be expressed with the following formulas. p1 = µ1 f1 ormula (1) p = µ f ormula () π f1 = P 4 ormula (3) π f = ( -d ) P 4 ormula (4) p1: enerated extension force of cylinder (N) p: enerated retraction force of cylinder (N) f1 : Theoretical extension output (N) f: Theoretical retraction output (N) P : Operating pressure (Pa) : ore size d : Piston rod diameter µ1 : Cylinder extension load pressure coefficient 0. µ : Cylinder retraction load pressure coefficient 0. Selection standards The ratio of the load to the theoretical output is the load factor. It is imperative to understand the relationship between this load factor and the piston speed in order to make the proper bore size selection. Use the table below as a guide for understanding the correlation between load factor and piston speed. Piston speed (mm/s) to 1 to 00 01 to 0 aximum load factor 0% % % Selection Example To find the cylinder bore size that is required to operate: On a load weight of 00N. With operating pressure of Pa. The operating piston speed when the cylinder is extended at 1 mm/s. Piston speed etermine load factor etermine required cylinder output 1 mm/s (initial condition) % (from the table above) Load weight: 00N, Load factor: % Required cylinder output: = 00/0.3 = 66(N) Temporarily decide the bore size based on conditions of operating direction and operating pressure from the theoretical output table. NO Check generated force of cylinder ES ccording to the theoretical output table, the bore size that satisfies the required cylinder output with operating pressure Pa when the operating direction is is ø. omula(1) p1 = µ 1f1 = 0. 0 = 66(N) > (66N) Theoretical Output Series CS 1 ore size selected Unit: N ore Rod Operating Piston Operating pressure (Pa) size size area direction (mm ) 3.5 4 0 6 66 61 61 0 4 4 4 40 31 3 0 6 63 00 6 51 35 06 5 0 53 541 5 5 65 3 50 Theoretical output (N) = Pressure (Pa) Piston area (mm ) Series CS ore size Rod size Operating direction Piston area (mm ) 4 54 6 4 31 0 6 53 5 Unit: N Operating pressure (Pa) 3.5 4 66 61 4 6 51 06 65 343 61 4 63 35 5 541 3 540 0 0 40 3 00 0 5 50 64 4 006 1 3 5 4 4 4 546 4 6
Series CS Technical ata Stroke Selection (aximum Usable Stroke ased on uckling Strength) Refer to stroke range limit charts regarding rod buckling due to load weight. The values in these tables indicate the maximum stroke that can be used in a situation when air is being supplied while the cylinder is stopped in an intermediate position by an external force acting on the piston rod, or by external stopper, etc. Since the maximum usable stroke varies depending on the diameter of the piston rod and operating conditions, verify the applicability using the stroke range limit chart. Series CS Stroke range limit charts: ore size ø, ø Symbol ounting orientation Symbol ounting orientation Symbol ounting orientation Symbol ounting orientation q w e e r t t y u u i ore size ø 000 5 4 3 1 0 6 0 ore size ø 000 5 1 6 0 4 3 Stroke Stroke 0 0.1 0.5 1 5 0 Load (kn) 0.5 1 5 0 Load (kn)
Series CS Series CS ore size ø 000 6 0 Stroke range limit charts: ore size ø, ø, ø, ø 1 5 4 3 ore size ø 000 0 5 4 3 6 1 Stroke 0 Stroke 0 0.5 1 5 0 Load (kn) 0.5 1 5 0 Load (kn) ore size ø ore size ø 000 0 6 5 1 4 3 000 0 6 1 5 4 3 Stroke 0 Stroke 0 1 5 0 Load (kn) 1 5 0 Load (kn) 3
Series CS Technical ata 3-1 Cylinder Cushion Selection Selection Procedures ind the inertial energy E1 for the load at the cushion seal contact point. Caution Use a cylinder cushion within the maximum absorbed energy range. When used outside the allowable range, it may cause damage to cylinders and peripheral devices. ind the external force applied in the axial direction of the cylinder at the cushion seal contact point. Convert the external force calculated in step above into energy E using the external force energy conversion chart. rom the maximum absorbed energy-pressure chart, find the maximum absorbed energy E for the corresponding cylinder. ES ES ES Confirm E1 + E E. ES Lower the Use larger set pressure. cylinder bore NO NO size. NO Reduce inertial load. NO vailabe for use Install a shock absorber. Calculation Example <esign conditions> Cylinder: Set pressure: Load weight: Piston speed: CS P1: Pa : 0 kg : 0. m/s (at the cushion seal contact point) Load transfer direction: ownwardθ: (External force applied to the cylinder is gravity only) Operating direction: ravitational acceleration : Extended g:. m/s <Calculation> 1. Load inertial energy E1 at the cushion seal contact point E1 = / = 0 0. / =. External force applied in axial direction of the cylinder at the cushion seal contact point = gsin θ = 0. sin = N gsin θ θ g 3. Convert the external force calculated in step into energy E. External force: raw a vertical line from the value of N, the point where this line intersects with the diagonal line 5. is energy caused by external force. E = 5. 4. ind the maximum absorbed energy E for a cylinder. aximum absorberd energy: raw a vertical line from the set pressure Pa, the point where this line intersects with the line for ø (1) is the maximum absorbed energy. E = 1 5. Confirm that E1 + E E. E1 + E = + 5. =. E = 1 E1 + E E Therefore, the cylinder cushion is available for use. 4
Series CS Technical ata 3- aximum bsorbed Energy & External orce and Energy Conversion at Cushion Seal Contact Point aximum absorbed energy pressure and chart in terms of cushion performance characteristics e sure to keep the combined values of kinetic energy of the load operated by the cylinder and the energy generated by the external force within the values that are shown in the bottom chart. External force and energy conversion at cushion seal contact point 0 Energy () 5. 1 0 00 000 External force (N) aximum absorbed energy and pressure Series CS 0 ax. absorbing energy () 1 ø ø ø ø ø 0 1 4 6 Set pressure (Pa) Series CS ax. absorbing energy () ø ø ø ø ø ø 5 1 4 6 Set pressure (Pa)
Series CS Technical ata 4 Piston Speed, Required Oil olume and Piping Size Selection This information is intended to help you find the required fluid volume and piping size to operate a cylinder at a specified speed. Relationship between piston speed and oil volume Q1 = Q = π 6 υ 4 0 π ( d 6 ) υ 4 0 ormula (1) ormula () Effective inside diameter of piping = π 4 Q 1 din 3 ormula (3) Q1 : Required oil volume for extension ( /min) Q : Required oil volume for retraction ( /min) : ore size (cm) d : Piston rod diameter (cm) υ : Piston speed (mm/s) : Oil flow velocity (m/s) Q : Oil volume ( /min) din: Effective inside diameter of piping In general, it is necessary to select a piping diameter that will not allow the oil flow velocity to exceed the values shown in the chart below. If the oil flow velocity exceeds this value, turbulent flow and overheating may occur in conjunction with pressure loss. Oil flow velocity Rubber hose Steel pipe 5 m/s 4.5 m/s 1"(ø5.4) Rubber hose ø 1/"(ø.) Rubber hose 3/"(ø.5) Rubber hose eneral range of rubber hose (max. 5 m/s) eneral range of steel pipe (max. 4.5 m/s) 1 1 /"(ø3.1) Rubber hose 1 1 /4"(ø31.) Rubber hose ø5 ø6 ø1 ø3 3 /4"(ø) Rubber hosec ø 5 /"(ø.3) Rubber hose ø ø ø ø ø ø ø6 ø5 1 /4"(ø6.3) Rubber hose ø4 (Steel pipe I..) 0 0 0 0 00 0 6 5 4 low rate ( /min) Cylinder bore size ø Cylinder bore size ø Cylinder bore size ø Cylinder bore size ø Cylinder bore size ø Cylinder bore size ø 3 6 5 4 3. 0 00 0 0 0 low velocity inside pipe (m/s) Piston speed (mm/s) ow to read the chart: Example) The required flow rate to operate a ø cylincer at a speed of mm/s is appproximately /min. When a 3/" (ø.5) rubber hose is used for piping, the flow velocity in the pipe will be approximately. m/s. 6
Series CS Safety Instructions These safety instructions are intended to prevent a hazardous situation and/or equipment damage. These instructions indicate the level of potential hazard by a label of "Caution", "Warning" or "anger". To ensure safety, be sure to observe ISO 43 Note 1), IS 1 Note ) and other safety practices. Caution : Operator error could result in injury or equipment damage. Warning : Operator error could result in serious injury or loss of life. anger : In extreme conditions, there is a possible result of serious injury or loss of life. Note 1) ISO 43: Pneumatic fluid power -- eneral Rules for Pneumatic Equipment Note ) IS 1: Pneumatic system axiom Warning 1. The compatibility of hydraulic equipment is the responsibility of the person who designs the hydraulic system or decides its specifications. Since the products specified here are used in various operating conditions, their compatibility for the specific hydraulic system must be based on specifications or after analysis and/or tests to meet your specific requirements. The expected performance and safety assurance will be the responsibility of the person who has determined the compatibility of the system. This person should continuously review the suitability of all items specified, referring to the latest catalog information with a view to giving due consideration to any possibility of equipment failure when configuring a system.. Only trained personnel should operate pneumatically operated machinery and equipment. Compressed hydro can be dangerous if handled incorrectly. ssembly, handling or repair of hydraulic systems should be performed by trained and experienced operators. 3. o not service machinery/equipment or attempt to remove components until safety is confirmed. 1. Inspection and maintenance of machinery/equipment should only be performed after confirmation of safe locked-out control positions.. When equipment is to be removed, confirm the safety process as mentioned above. Cut the supply pressure for this equipment and exhaust all residual compressed air in the system. 3. efore machinery/equipment is restarted, take measures to prevent shooting-out of cylinder piston rod, etc. 4. Contact SC if the product is to be used in any of the following conditions: 1. Conditions and environments beyond the given specifications, or if product is used outdoors.. Installation on equipment in conjunction with atomic energy, railway, air navigation, vehicles, medical equipment, food and beverages, recreation equipment, emergency stop circuits, clutch and brake circuits in press applications, or safety equipment. 3. n application which has the possibility of having negative effects on people, property, or animals, requiring special safety analysis.
Series CS ydraulic Cylinder Precautions 1 e sure to read before handling. Warning esign 1. There is a possibility of dangerous sudden action by cylinders if sliding parts of machinery are twisted due to external forces, etc. In such cases, human injury may occur; e.g., by catching hands or feet get caught in the machinery, or damage to the machinery itself may occur. Therefore, the machine should be designed to prevent such dangers.. protective cover is recommended to minimize the risk of personal injury. If a stationary object and moving parts of a cylinder are in close proximity, personal injury may occur. esign the structure to avoid contact with the human body. 3. Securely tighten all stationary parts and connected parts so that they will not become loose. Especially when a cylinder operates with high frequency or is installed where there is a lot of vibration, ensure that all parts remain secure. 4. Cases when a deceleration circuit or shock absorber may be required. When a driven object is operated at high speed or the load is heavy, a cylinder's cushion will most likely not be sufficient to absorb the impact. Install a deceleration circuit to reduce the speed before cushioning, or install an external shock absorber to relieve the impact. In this case, the rigidity of the machinery should also be examined. 5. Consider a possible drop in operating pressure due to a power outage. When a cylinder is used as a clamping mechanism, there is a danger of work pieces dropping if there is a decrease in clamping force due to a drop in circuit pressure caused by a power outage. Therefore, safety equipment should be installed to prevent human injury or damage to machinery. Suspension mechanisms and lifting devices also require for drop prevention measures. 6. Consider a possible loss of power source. easures should be taken to protect against human injury and equipment damage in the event that there is a loss of power to equipment controlled by air pressure, electricity, or hydraulics.. esign circuitry to prevent sudden lurching of driven objects. When hydraulic pressure in a cylinder is zero, the driven object will lurch at high speed if pressure is applied to one side of the piston.therefore, equipment should be selected and circuits designed to prevent sudden lurching because there is a danger of human injury and/or damage to equipment when this occurs.. Consider emergency stops. esign the system so that bodily injury and/or damage to machinery and equipment will not occur when machinery is stopped by a manual emergency stop or a safety device triggered by abnormal conditions.. Consider the action when operation is restarted after an emergency or abnormal stop. esign machinery so that bodily insury or equipment damage will not occur upon restart of operation. When the cylinder has to be reset at the starting position, install manual safely equipment. Warning Selection 1. Check the specifications. The products featured in this catalog are designed strictly for use in industrial oil hydraulic system applications. If the products are used in conditions that are outside the range of pressure and temperature specifications, damage and/or malfunction may occur. o not use in these conditions. (Refer to specifications.) Consult with SC if a fluid other than hydraulic fluid is to be used.. Intermediate stops Since hydraulic cylinders are not guaranteed for zero oil leakage, it may not be possible to hold a stopped position for an extended period of time. 3. Take surge pressure into consideration. Use cylinders which can withstand the surge pressures (maximum allowable pressure) generated in hydraulic systems. (Refer to specifications.) Inside cylinders, pressure may be generated that is higher than the set pressure for the relief valve, e.g., internal pressure due to load inertia or surge pressure when switching valves. Consider these factors and determine the operating pressure so that the pressure generated inside cylinders will be within the maximum allowable pressure. Pressure terminology used in this catalog is defined as follows: Nominal pressure: Pressure assigned to a cylinder for convenient identification.it is not necessarily the same as the operating pressure which guarantees performance under specified conditions. aximum allowable: The maximum allowable value for the pressure that is pressure generated inside cylinders (such as surge pressure). Proof pressure: Test pressure that the cylinder must be able to withstand without lowering system performance when returning to the nominal pressure. inimum operating: inimum pressure at which a horizontally installed pressure cylinder operates with no-load. 4. Take into account compatibility with hydraulic fluids. ydraulic luid Standard mineral hydraulic fluid W/O hydraulic fluids O/W hydraulic fluids Water/lycol hydraulic fluids Phosphate hydraulic fluids Consult with SC. Caution Compatibility 1. Operate within the limits of the maximum usable stroke. The piston rod will be damaged if operated beyond the maximum stroke. Refer to the stroke selection on pages and 3 for maximum strokes.. Operate the piston with in a range such that collision damage will not occur at the stroke end. Operate within a range such that damage will not occur when the piston having inertial force stops by striking the cover at the stroke end. Take load factors and piston speed on page 1 into consideration and determine the operability by referring to the chart under Selection Standards. 3. Use a flow control valve to adjust the hydraulic cylinder drive speed, gradually increasing from a low speed to the desired speed setting.
Series CS ydraulic Cylinder Precautions e sure to read before handling. Selection 4. Provide intermediate supports for long stroke cylinders. Provide intermediate supports for cylinders with long strokes to prevent piston rod damage due to sagging of the piston rod, deflection of the tube, vibration, and external loads. Caution 1. ake sure to align the axis center of the piston with the load and direction of movement when connecting. When not properly aligned, twisting of the piston rod and tubing may occur, and damage may be caused due to wear on areas such as the inner tube surface, bushings, piston rod surface and seals. llow for decentering of the axis either by aligning the axis center or using a floating joint.. When an external guide is used, connect the piston rod end and the load in such a way that there is no interference at any point within the stroke. 3. o not scratch or gouge the sliding parts of the cylinder tube by striking or grasping it with other objects. Cylinder bores are manufactured to precise tolerances, so that even a slight deformation may cause faulty operation. 4. o not use until you verify that the equipment can operate properly. ollowing mounting, repairs, or conversions, verify correct mounting by conducting suitable function and leakage tests after piping and power connections have been made. 5. Instruction manual The product should be mounted and operated after the instruction manual is thoroughly read and its contents are understood. eep the instruction manual where it can be referred to as needed. Caution ounting 1. Preparation before piping efore piping is connected, it should be thoroughly blown out with air (flushing) or washed to remove chips, cutting oil and other debris from inside the pipe.. Wrapping of pipe tape When screwing together pipes and fittings, be certain that chips from the pipe threads and sealing material do not get inside the piping. lso, when sealant tape is used, leave 1.5 to thread ridges exposed at the end of the pipe. Expose approx. threads Piping Wrapping direction Sealant tape 3. Set up so that air cannot accumulate inside piping. Caution 1. Readjust using the cushion needle. Cushion needles are adjusted at the time of shipment. When the cylinder is put into service, the cushion needles should be readjusted based on factors such as the size of the load and the operating speed. When the cushion needles are turned clockwise, restriction of the air flow becomes greater and thus the cushioning effect also increases.. o not operate with the cushion needle in a fully closed condition. This will contribute to the generation of surge pressure, and the cylinder or equipment can be damaged. Caution Cushion ir Release 1. Operate after opening the air release valve and completely releasing any internal air. Residual air can cause a malfunction.. When adjusting the air release, do not loosen the plug too much. Use caution, since loosening the plug too much may cause it to fly out or fluid to blow out, posing a danger of human injury. Warning ydraulic luid 1. Use clean fluid. o not use deteriorated fluid or fluid containing foreign matter, moisture or corrosive additives, as this can cause the malfunction and damage or corrosion of parts. Caution 1. Install hydraulic fluid filters. Provide your hydraulic system with hydraulic fluid filters with a filtration degree of µm or finer. Refer to SC s hydraulic filter specifications.. Use the product within the specified range of fluid and ambient temperature. Take measures to prevent freezing, since moisture in hydraulic fluid will freeze at 0 C or below, and this may cause damage to seals and lead to a malfunction. 3. Use hydraulic fluid with a viscosity grade equivalent to ISO or. Operating Environment Warning 1. o not use in environments where there is a danger of corrosion. Refer to the construction drawings regarding cylinder materials.. Install a protective cover if the product is to be used in a dusty environment or where it will be exposed to chips and spatter.
Series CS ydraulic Cylinder Precautions 3 e sure to read before handling. Warning aintenance 1. Perform maintenance inspection according to the procedures indicated in the instruction manual. If handled improperly, malfunction and damage of machinery or equipment may occur.. Removal of equipment When machinery is removed, first ensure that there are measures in place to prevent the fall or sudden, erratic movement of driven objects and equipment. Then cut off the air supply and electric power, and reduce the pressure in the system to zero. When machinery is restarted, proceed with caution after confirming that appropriate measures are in place to prevent cylinders from sudden movement. Caution 1. Perform periodic maintenance on filters installed in a hydraulic system in order to keep the oil clean. If the oil used in hydraulic cylinders contains foreign matter, parts such as the piston seals and rod seals will be damaged.
Series CS uto Precautions 1 e sure to read before handling. Warning 1. Check the specifications. Read the specifications carefully and use this product appropriately. The product may be damaged or malfunction if it is used outside the range of specifications of load current, voltage, temperature or impact.. Take precautions when multiple cylinders are used close together. When two or more cylinders with auto switches are lined up in close proximity to each other, magnetic field interference may cause the switches to malfunction. aintain a minimum cylinder separation of mm. 3. onitor the length of time that a switch is ON at an intermediate stroke position. When an auto switch is placed at an intermediate position of the stroke and a load is driven at the time the piston passes, the auto switch will operate, but if the speed is too great, the operating time will be shortened and the load may not operate properly. The maximum detectable piston speed is: (mm/s) = uto switch operating range Load operating time (ms) In case of a high piston speed, it is possible to extend the operating time of the load by using an auto switch (5NT) with a built-in off delay timer (approximately 00 ms). 4. eep wiring as short as possible. <Reed switches> s the length of the wiring to a load gets longer, the rush current at switching ON becomes greater, and this may shorten the product s life. (The switch will stay ON all the time.) 1) or an auto switch without a contact protection circuit, use a contact protection box when the wire length is 5 m or longer. ) Even when an auto switch has a built-in contact protection circuit, if the lead wire length is m or more, the rush current cannot be adequately absorbed and the life of the switch may be shortened. Contact SC, as it is also necessary in this case to connect a contact protection box to extend the switch life. <Solid state switches> 3) lthough wire length should not affect switch function, use a wire that is m or shorter. 5. onitor the internal voltage drop of the switch. <Reed switches> 1) es with an indicator light If auto switches are connected in series as shown below, take note that there will be a large voltage drop because of internal resistance in the light emitting diodes. (Refer to internal voltage drop in the auto switch specifications.) [The voltage drop will be n times larger when n auto switches are connected.] Even though an auto switch operates normally, the load may not operate. Load esign and Selection 0 Similarly, when operating below a specified voltage, although an auto switch may operate normally, the load may not operate. Therefore, the formula below should be satisfied after confirming the minimum operating voltage of the load. Supply voltage Internal voltage > drop of switch ) If the internal resistance of a light emitting diode causes a problem, select a switch without an indicator light (odel - 6, -Z). <Solid state switches> 3) enerally, the internal voltage drop will be greater with a - wire solid state auto switch than with a reed switch. Take the same precautions as in 1). lso note that a C relay is not applicable. 6. onitor leakage current. <Solid state switches> With a -wire solid state auto switch, current (leakage current) flows to the load to operate the internal circuit even when in the O state. Operating current of load (O condition) > Leakage current inimum operating voltage of load If the condition given in the above formula is not met, it will not reset correctly (stays ON). Use a 3-wire switch if this specification cannot be satisfied. oreover, leakage current flow to the load will be n times larger when n auto switches are connected in parallel.. o not use a load that generates surge voltage. <Reed switches> If driving a load such as a relay that generates a surge voltage, use a switch with a built-in contact protection circuit or use a contact protection box. <Solid state switches> lthough a zener diode for surge protection is connected at the output side of a solid state auto switch, damage may still occur if the surge is applied repeatedly. When a load, such as a relay or solenoid, which generates surge is directly driven, use a type of switch with a built-in surge absorbing element.. Cautions for use in an interlock circuit When an auto switch is used for an interlock signal requiring high reliability, devise a double interlock system to avoid trouble by providing a mechanical protection function, or by also using another switch (sensor) together with the auto switch. lso perform periodic maintenance inspections and confirm proper operation.. Ensure sufficient clearance for maintenance activities. When designing an application, be sure to allow sufficient clearance for maintenance and inspections. 31