Drive Design Manual Workhorse Poly Chain GT BeltDrives Outmuscle and outlast roller chain in low-speed, high-torque applications. THE DRIVING FORCE IN POWER TRNSMISSION
Low speed. High speed. nd any speed in between. Gates has your total synchronous belt drive system solution! Synchronous belt drives are being used more extensively than ever for the transfer power from one shaft to another, multiplication torque, speed reduction or increase, and synchronization shaft operations. PowerGrip GT The Racehorse. This is the performance choice for a wide variety high-speed (above 00 rpm) drive applications. PowerGrip GT will deliver more power at a lower overall cost than any other rubber synchronous belt drive system available. Gates, the world s recognized leader in synchronous belt technology, continues to meet all your needs for synchronous belts, sprockets and bushings across the broadest range industry applications. Choose from a full line quality products featuring leading-edge technologies that deliver the advantages you re looking for: Reduced downtime Reduced over-all drive cost Reduced drive package size Increased component life Increased performance Energy savings Reduced acquisition costs Reduced transaction costs Increased drive design options New, improved synchronous belt lines. The latest innovations in Gates synchronous drive systems are two redesigned and reengineered belt and sprocket lines. They are the clear winners in overall cost, drive selection options and performance when compared to any other belt drive products on the market today. Poly Chain GT The Workhorse. This is the optimal choice in meeting your needs for low-speed (below 00 rpm), high-torque drive applications. The powerful Poly Chain GT polyurethane belt drive system will outperform roller chain drives and any rubber belt drive system on the market today, delivering the lowest-cost belt drive system available for low-speed, high-torque applications. nd we can prove it!
Taper-Lock sprockets & bushings. Poly Chain GT and PowerGrip GT belt drive systems feature Taper- Lock bushings. dvantages the Taper-Lock system include: Industry-proven robustness True running, concentric Extensive use in roller chain sprockets Easy installation and removal llows compact sprocket hub designs Short length-thru-bore dimensions Flush mount with no protruding hubs Installs with less axial sprocket movement than other bushing systems Made-to-order sprockets. Gates Made-to-Order (MTO) Metal Department supports synchronous MTO sprockets with 90% Requests For Quote (RFQ) provided within hours and % quotes provided within hours. Quoted delivery dates are met at a 97% rate and most deliveries are made within four weeks. Call 00-709-600 for more information. Gates Compass CD-ROM: selection, maintenance, and design tool. The Gates Compass CD-ROM is a powerful tool fering a variety useful information and features. It makes choosing the right drive system fast and easy. Compass contains Design Flex II, Design View and Design OHL for invaluable assistance in product selection, drive design, energy savings calculations, installation and system cost savings. The CD also contains eight instructional videos covering topics such as belt drive Design Flex II troubleshooting, tensioning, safety and installation. The Compass CD-ROM is available through authorized Gates Industrial Power Transmission Distributors. partnership commitment. To ensure that you get the synchronous drive systems that are right for your applications, Gates provides the industry s leading support program and the largest distributor network. You get local inventory availability and a single source for all your needs. You also get access to Gates Product pplication Engineering Support for unmatched design and problem-solving expertise in every aspect synchronous drive operation. You re backed by the industry s largest manufacturer s field sales force, voted number one in a recent Selling Power magazine survey. Your Gates representatives are experts in the products they market and provide a variety in-house and on-site training programs. Nobody is as committed to supporting you as Gates! It s obvious! Gates is your total synchronous drive solution. With industry-leading technologies, a complete line high quality, top-performing products, and unmatched customer support, it s easy to see that Gates is the partner to choose in meeting all your needs for synchronous belt drive systems. Design Design OHL View Taper-Lock is a registered trademark the Reliance Electric Corporation.
Poly Chain GT New Poly Chain GT is Gates most powerful synchronous belt, ideally suited for low-speed (below 00 rpm), high torque industrial applications. This improved belt features a polyurethane body with a robust aramid fiber tensile cord and new nylon tooth facing improvements that enable increased load-carrying capacity. Size for size, space for space, Poly Chain GT transmits up to 0 percent more power than its predecessor. It also permits the design more compact, lighter weight drives that deliver more power in less space than any other belt drive system available. Poly Chain GT is the result innovative state--the-art design and engineering. The body and teeth are made a durable polyurethane compound, specially blended for uncompromising adhesion to the tensile cords and heavy nylon tooth facing, allowing for increased tooth shear strength and excellent flex life. The result is the toughest belt on the market by far, virtually immune to abrasion and chemical attack. Poly Chain GT performs flawlessly, even under the harshest operating conditions. The aramid fiber tensile cords constitute the belt s muscle. The cord provides exceptional flex fatigue life and its high impact strength makes the belt resistant to shock and surge loading. Poly Chain GT drives dramatically reduce maintenance costs, expensive production downtime and noise problems associated with the metal-to-metal contact roller chain drives. The nylon fabric covering the teeth is highly resistant to oil, chemicals, pollutants, corrosion and abrasion, while providing excellent tooth shear strength and durability. Poly Chain GT belts are exceptionally durable and remain fully operational under extreme temperatures ranging from 6 F up to + F (- C to + C).
Patented tooth facing delivers more strength, greater tooth shear strength, reduced friction and eliminates the need for lubrication. Poly Chain GT belt drives are virtually maintenance free. Taper-Lock sprockets & bushings. Poly Chain GT belt drive systems feature a new line sprockets that have been redesigned to carry the new increased belt power ratings. These new sprockets utilize the Taper-Lock bushing system that has been tested and proven in industry for many years. This allows easy sprocket installation and removal and keeps the hubs narrow so the length-thru-bore dimension is less than ever before. Now, Poly Chain GT sprockets will fit on those applications with short shafts, with room to spare. In addition, the left-justified hub design allows shaft mounting close to outboard bearings. This keeps the center load dimension small, so overhung load values are as low as possible lower than any competitive belt drive system. Poly Chain GT is the ideal candidate for low-speed and speed reducer applications. Its high load carrying capacity is unmatched by any competitive belt drive system, allowing drive designs in widths narrower than ever before, approaching roller chain drive systems. Polyurethane compound resists oils, chemicals, pollutants and abrasion. It s tough and performs in temperatures ranging from 6 F to + F. Greater flexibility in design. Poly Chain GT sprocket/bushing systems use less space than conventional sprockets and sheaves. In comparison with most competitive drives (roller chain or rubber), Poly Chain GT belt drives are as little as one-half the width and 0 percent lighter. Yet they can deliver over five times more horsepower than standard rubber synchronous systems in the same space. Savings like these in space and weight allow for a wide latitude in design flexibility. How do you calculate the cost downtime? The normal downtime costs and lost productivity resulting from maintenance and chain replacement could add up to 0 0 ramid fiber tensile cords provide extraordinary load carrying capability. For the same weight, they have a higher tensile modulus than steel for incredible strength and virtually zero elongation. Exceptional flex fatigue characteristics combined with the ability to absorb shock loads make Poly Chain GT the ideal drive system choice for low-speed high-torque applications. hundreds if not thousands dollars per drive per year. You have no choice. If you use roller chain drives, you must maintain them or they will break down. Consequently, regular scheduled maintenance on your production equipment must be accomplished to maintain these roller chain drives, ten resulting in extensive downtime. Elimination this downtime would clearly result in increased production output. More horsepower in less space for less cost. From low-speed fractional horsepower drives to more than,00 horsepower, Poly Chain GT drives are unsurpassed in transmitting positive power over a wide range loads, while withstanding power surges and shock loading. Think all the places you could use a drive system like that! Horsepower 0 Poly Chain GT Belt mm Pitch Poly Chain GT mm Pitch #0 Single Roller Chain " Pitch #60 Single Roller Chain /" Pitch #0 Double Roller Chain /" Pitch rpm Horsepower Rating Comparison (Width is approximately for all transmission media) 00 00
Poly Chain GT advantages over roller chain: Long, dependable life Reduced downtime Virtually maintenance free No retensioning Quiet Minimal vibration due to chordal action Virtually no elongation Clean running system No expensive oil baths No lubrication Resistant to chemicals and contaminants Excellent shock load resistance Save big with Poly Chain GT drives: No hidden costs in lost productivity No hidden costs ongoing maintenance Poly Chain GT drives reduce overall costs and can pay for themselves in less than one year Poly Chain GT drives will ten outlast roller chain to The hidden costs roller chain: Expensive drive enclosures Lubrication systems Lubricant cost and disposal Broken chain replacement Worn sprocket replacement Maintenance downtime Safety issues Environmental noise concerns
Poly Chain GT Drives are guaranteed to outperform and outmuscle roller chain and high-performance rubber belt synchronous systems at a lower overall service lifetime cost per drive. nd here s pro! Poly Chain GT Poly Chain GT Dayco Panther Goodyear Eagle Pd HTD..0.09.6..0...60.6.9..0..7.66.09.7.9.7.....0.0 Cost Ratio 0. 0.0 Motor Horsepower 7. 0 0 vg. Cost Ratio 0. 0.0 Motor Horsepower 7. 0 0 vg. Cost Ratio Poly Chain GT/Roller Chain (00 rpm Shaft Speed) Cost Ratio Poly Chain GT/Roller Chain (00 rpm Shaft Speed) Horsepower Per mm Width 0 00 Calculated Overhung Load 0. 0. 0.09 0.06 0.0 0.00 0 Sprocket Grooves Horsepower Per mm Belt Width Light Package Conveyor Example (mm Pitch, 00 rpm Reducer Output Service Factor dded) 0 60 0 0 0 Motor Horsepower 7. Overhung Load Comparison Poly Chain GT vs Eagle Pd and Panther (ll drives designed with comparable diameter sprockets) 6 0 0 6 Horsepower Per mm Width Horsepower Ratings 0.0 0. 0.0 0. 0.0 0. 0.0 0.0 0.00 0 Sprocket Grooves Horsepower Per mm Belt Width Light Package Conveyor Example (mm Pitch, 00 rpm Reducer Output Service Factor dded)..0..0..0 0... 0.0 H.T.D. Panther Belt Drive Systems.0 Eagle Published Horsepower Rating Per Inch Width (mm Sprocket, 6 Groove, 00 rpm Reducer Output) 6 0 6. PCGT 60 00 System Cost For Motor Horsepowers (: Speed Ratio, 0 rpm Reducer Output) Horsepower Ratings 0 60 Drive System Cost 0 0 0 Motor Horsepower 0 6..7 0 H.T.D. Eagle Belt Drive Systems 7. 9. Panther.9 PCGT Published Horsepower Rating Per Inch Width (mm Sprocket, 6 Groove, 00 rpm Reducer Output) 0 0 6 * Because Poly Chain GT belts have the highest capacity, a narrow belt drive can be used, meaning that the center the belt load is closer to the reducer bearing, resulting in less bearing load.
% Belt Life 00 0 00 0 00 0 00 0 0 mm Belt Pitch mm mm Life Performance Indexes Poly Chain GT vs Panther, Eagle and Poly Chain GT mm mm mm Gates Reliability Test TF-6 & TF- Gates Reliability Tests TF-7 & TF- Gates Reliability Tests TF-6 & TF-0 Belt Test Descriptions Dr Competitive Comparisons Dn Test ID Pitch Speed Sprockets Load TF-6 mm 000 rpm T/T High Torque TF-7 mm 000 rpm T/T High Torque TF- mm 70 rpm T/T High Torque TF- mm 70 rpm T/T High Torque TF-0 mm 70 rpm T/T High Torque Note: ll competitive belt tests were conducted in a laboratory environment under identical operating conditions mm Pitch Product Line Comparison Gates Poly Chain GT Goodyear Eagle Pd Dayco RPP Panther Sprocket Diameters 6 6 0 Sprocket Selections Center Distance Range Maximum Speed Ratio Belt Length Selections Belt Length Range Belt Width Selections Total Drive Combinations 0 0..7..09.7. 0.:.0:.7: 0 6 60 0mm 60 00mm 0 00mm --6-6 - ---60,000+ 7,000+,00+ mm Pitch Product Line Comparison Gates Poly Chain GT Goodyear Eagle Pd Dayco RPP Panther Sprocket Diameters Sprocket Selections Center Distance Range Maximum Speed Ratio Belt Length Selections Belt Length Range Belt Width Selections Total Drive Combinations 0. 79.09. 7.0 7.99 9..00: 6.00: 7.7: 9 99 0mm 99 00mm 966 96mm 0-7-6-90- --70-0 0--6-90-0 6,000+,000+ 7,00+ Eagle PD is a trademark The Goodyear Tire & Rubber Company. Dayco and Panther are registered trademarks and RPP is a trademark Dayco Products Inc. 7
The bottom line: Compared to other drive system alternatives to roller chain available today, Poly Chain GT drives fer you: The most compact belt drive system available today Lowest cost drive system at low speed Lowest overhung load generated on speed reducer shafts Longest life, width for width That s why Gates is The Driving Force In Power Transmission! Poly Chain GT vs. Roller Chain Savings Calculator This sample calculator below illustrates the dramatic cost savings a Poly Chain GT drive system compared to a roller chain system. Make the switch to Poly Chain GT Poly Chain GT drives tested in a variety applications lasted longer and required less maintenance than the roller chain or rubber belt drives they replaced. The following industries are ideal for Poly Chain GT drive systems: Lumber, Pulp & Paper Conveyors, repulpers, sentry screens, effluent systems, presses, waxers, chippers, debarkers, slashers, chip n saws, edgers, roll grinders, screw conveyors, flotation cells, cut-f saws, hourglass rolls, dryers, agitators, calendars, pumps, winders Packaging Box makers, carton sealers, case palletizers, and live roll, apron, belt, chain and screw conveyors NNUL COSTS Roller Chain Poly Chain GT Unit Cost New Drive System $ 0. $. Yearly Costs To Maintain Roller Chain: Replacement cost Chain/Belt $.96 $ * Labor $.00 $ * Replacement cost Sprockets $. $ * Labor $.00 $ * Lubrication cost Labor $ 6.0 $ Disposal $? $ Production Downtime $ 00.00 $ Employee Complaints (noise/lost production) $? $ Safety costs (lube on floor, etc.) $? $ nnual Total Cost to Maintain System: $ 9.0 $ 0.00 nnual Total Cost New System: $ 0. $. nnual Total Cost to Maintain System: Pay Back: Poly Chain GT 0.6 Years Cost Systems in Three Years $ 69. $. Savings in Dollars - First Three Years: $ 0.99 Per Drive Cost Systems in Five Years $,0. $ 66. Savings in Dollars First Five Years: $ 9.07 Per Drive *NOTE: Worksheet assumes that roller chain drives are replaced once per year on the average and that a properly designed Poly Chain GT belt (only) should have to be replaced only once every years; hence the yearly replacement costs are calculated at / the component cost. Visit www.gates.com/sync for an online version Food Processing Pumps, bucket elevators, belt conveyors, icing machines, elongators, dough mixers, cookers, mills, bottling machines, meat grinders, hog dehairers luminum/steel Bucket elevators, shot blasters, conveyor drives, scrap cutters, sand seals, drag-out machines, polishers, cooling chambers, muffler furnaces, mandrel stripping rods, spinner cars, gray iron foundries, sand conveyors, bucket elevators, grinders Petrochemical Industries ir coolers, chlorine compressors, processing, centrifuges, dryers, compressors, pumps Sand, Gravel & Concrete Feeder drives, conveyor drives, elevators, screw conveyors Glass Manufacturing/Bottles Conveyors, crushers, grinders, carton sealers, case palletizers nd more! Gates Poly Chain GT belts are protected by U.S. patents,,,,60,9,,6,,,97,79 and U.S. and foreign patents pending.
R The SFETY POLICY WRNING! Be Safe! Gates belt drive systems are very reliable when used safely and within Gates application recommendations. However, there are specific USES THT MUST BE VOIDED due to the risk serious injury or death. These prohibited misuses include: Primary In Flight ircraft Systems Do not use Gates belts, pulleys or sprockets on aircraft, propeller or rotor drive systems or in-flight accessory drives. Gates belt drive systems are not intended for aircraft use. Lift Systems Do not use Gates belts, pulleys or sprockets in applications that depend solely upon the belt to raise/lower, support or sustain a mass without an independent safety backup system. Gates belt drive systems are not intended for use in applications requiring special Lift or Pro type chains with minimum tensile strength or certified/test tensile strength requirements. Braking Systems Do not use Gates belts, pulleys or sprockets in applications that depend solely upon the belt to slow or stop a mass, or to act as a brake without an independent safety backup system. Gates belt drive systems are not intended to function as a braking device in emergency stop systems. Driving Force in Power Transmission. 9
R The Poly Chain GT Sprocket Specifications Type Type B F F C L C L F-CL F-CL M D O.D. E B O.D. M C Type F C Type BF Type C Type 6 F F-CL C L M F F-CL C L E D B O.D. D B O.D. E C C Type CF Type 6F Driving Force in Power Transmission. 7
Sprocket Number Stock mm Poly Chain GT Sprocket Specifications Number Teeth (ll stock sprockets conform to the metallurgical and mechanical properties noted in STM for Gray Iron castings and STM 6 for Ductile Iron castings.) Diameters Dimensions Pitch O.D Flange Ref. Design Type B C D E F M F-CL MX-S-.06..60 F- 0.00 0.60 0. 0. 0.0 0. 00 0.00.000 0. 0.00 D MX-S--PB.06..60 6F-.79 0.7. 0.6 0. 0 0. MPB 0.00..0 0.00 D MX-S-.06..90 F- 0.00 0.60 0. 0. 0.0 0. 0 0.00. 0.6 0.00 G MX-S--PB.06..90 6F-.0 0.7. 0.6 0. 0 0. MPB 0.00.00. 0.006 D MX-S-.07.7.0 F- 0.00 0.60 0. 0. 0.0 0. 0 0.00. 0.9 0.007 G MX-S--PB.07.7.0 6F-. 0.7. 0.6 0. 0 0. MPB 0.00.70. 0.0 D MX-0S- 0.00.9.0 F- 0.00 0.60 0. 0. 0.0 0. 0 0.00.. 0.009 G MX-0S--PB 0.00.9.0 6F-. 0.7. 0.7 0. 0 0. MPB 0.00.. 0.0 D MX-S-.0..60 F- 0.7.00.00 0 0.0 0 0.00.0. 0.0 D MX-S--PB.0..60 6F-.7 0.7. 0.7 0. 0 0. MPB 0.00.000. 0.00 D MX-S-.09.6.0 F- 0.7.00.00 0 0.0 0 0.00.6. 0.0 D MX-6S- 6.609.6.00 F- 0.7.00.00 0 0.0 0 0.00.6. 0.09 G MX-S-.0.77.0 F- 0.7.00.00 0 0.0 0 0.00.6.7 0.0 G MX-0S- 0.00.97.0 BF-.6 0.7. 0. 0.0 0. 0 0.00..7 0.0 D MX-S-...90 BF-.76 0.7. 0. 0.0 0. 0 0.00.. 0.0 G MX-S-...90 BF-.76 0.7. 0. 0.0 0. 0 0.00..6 0.0 G MX-S-..79.0 BF-.76 0.7. 0. 0.0 0. 0 0.00.. 0.0 G MX-0S- 0.0.90.0 BF-.76 0.7. 0. 0.0 0. 0 0.00..7 0.09 G MX-S-...00 BF-.76 0.7. 0. 0.0 0. 0 0.00..7 0. G MX-6S- 6.6. 6.00 BF-.76 0.7. 0. 0.0 0. 0 0.00.. 0. G MX-60S- 60 6.0.9 6.0 BF-.76 0.7. 0. 0.0 0. 0 0.00. 6. 0.7 G MX-6S- 6 6. 6. 6.70 CF-.7.00 0.7. 0. 0.0 0. 0 0.00.. 0.0 G MX-67S- 67 6.77 6.6 6.70 CF- 6..00 0.7. 0. 0.0 0. 0 0.00.. 0. G MX-7S- 7 7. 7.0 7.00 CF- 6..00 0.7. 0. 0.0 0. 0 0.00..7 0.99 G MX-7S- 7 7.9 7.6 7.90 CF- 6.90.00 0.7. 0. 0.0 0. 0 0.00.. 0.9 G MX-0S- 0.00 7.97.0 CF- 7..00 0.7. 0. 0.0 0. 0 0.00.. 0. G MX-90S- 90 9.0.960 C-.0.00. 0. 0.0 0. 0 0.00..0 0.6 G MX-S-.9.6 C- 0..00. 0. 0.0 0. 0 0.00..0.0 G MX-0S- 0.06.97 C-.96.. 0. 0.0 0. 0 0.00. 7.0.76 G MX-0S- 0.06 7.9 C-.0..7 0. 0.90 0. 7 0.00.6 6.6. G MX-S-.7.9 C- 0.7..7 0. 0.90 0. 7 0.00.6 7.0 7.9 G Material Spec : S - Steel SS - Sintered Steel G - Grey Iron D - Ductile Iron Design Type Suffix: - Solid - Web - rms Bushing Size Bore Sizes Min Max pprox. Wt. (lb) pprox. WR Matl. Spec. Sprocket Number Number Teeth Diameters Dimensions Pitch O.D Flange Ref. Design Type B C D E F M F-CL MX-S-.06..60 F-.6 0.9 0..0 0. 0.60 00 0.00.000 0.6 0.00 D MX-S--PB.06..60 6F-.79 0.9.6 0..0 0 0.60 MPB 0.00.. 0.00 D MX-S-.06..90 F-.9 0.9 0..0 0. 0.60 0 0.00. 0. 0.00 G MX-S--PB.06..90 6F-.0 0.9.6 0..0 0 0.60 MPB 0.00.00. 0.009 D MX-S-.07.7.0 F-. 0.9 0..0 0. 0.60 0 0.00..0 0.00 G MX-S--PB.07.7.0 6F-. 0.9.6 0..0 0 0.60 MPB 0.00.70. 0.0 D MX-0S- 0.00.9.0 F-. 0.9 0..0 0. 0.60 0 0.00.. 0.0 G MX-0S--PB 0.00.9.0 6F-. 0.9.77 0.7.0 0 0.60 MPB 0.00.. 0.00 D MX-S-.0..60 F-. 0.9.00.0 0.0 0.60 0 0.00.0. 0.0 D MX-S--PB.0..60 6F-.7 0.9.77 0.7.0 0 0.60 MPB 0.00.000. 0.06 D MX-S-.09.6.0 F-.66 0.9.00.0 0.0 0.60 0 0.00.6. 0.0 D MX-6S- 6.609.6.00 F-.96 0.9.00.0 0.0 0.60 0 0.00.6.6 0.0 D MX-S-.0.77.0 F-. 0.9.00.0 0.0 0.60 0 0.00.6.9 0.00 G MX-0S- 0.00.97.0 F- 0.97.. 0 0.6 0 0.00..0 0.07 D MX-S-...90 F- 0.97.. 0 0.6 0 0.00.. 0.0 G MX-S-...90 F- 0.97.. 0 0.6 0 0.00..0 0.067 G MX-S-..79.0 F- 0.97.. 0 0.6 0 0.00..7 0.09 G MX-0S- 0.0.90.0 F- 0.97.. 0 0.6 0 0.00.. 0. G MX-S-...00 F- 0.97.. 0 0.6 0 0.00..0 0. G MX-6S- 6.6. 6.00 F- 0.97.. 0 0.6 0 0.00.. 0. G MX-60S- 60 6.0.9 6.0 F- 0.97.. 0 0.6 0 0.00. 6.9 0.7 G MX-6S- 6 6. 6. 6.70 CF-.7.76 0.9..0 0.0 0.60 0 0.00.. 0. G MX-67S- 67 6.77 6.6 6.0 CF- 6..0 0.9.7.0 0. 0.60 7 0.00.6.7 0. G MX-7S- 7 7. 7.0 7.00 CF- 6..0 0.9.7.0 0. 0.60 7 0.00.6 6. 0.7 G MX-7S- 7 7.9 7.6 7.90 CF- 6.90.0 0.9.7.0 0. 0.60 7 0.00.6 6. 0. G MX-0S- 0.00 7.97.0 CF- 7..0 0.9.7.0 0. 0.60 7 0.00.6 7. 0. G MX-90S- 90 9.0.960 C- 7.7.0.7.0 0. 0.60 7 0.00.6.0 0. G MX-S-.9.6 C- 0.00.0.7.0 0. 0.60 7 0.00.6.0.9 G MX-0S- 0.06.97 C-.7..7.0 0. 0.60 7 0.00.6..707 G MX-0S- 0.06 7.9 C-.9 6..00.0 0.0 0.60 00 0.7.0 9.0.0 G MX-S-.7.9 C- 9.6 6..00.0 0.0 0.60 00 0.7.0. 6. G Material Spec : S - Steel SS - Sintered Steel G - Grey Iron D - Ductile Iron Design Type Suffix: - Solid - Web - rms Bushing Size Bore Sizes Min Max pprox. Wt. (lb) pprox. WR Matl. Spec. NOTES: Weights for Minimum Plain Bore (MPB) Sprockets are with minimum bore. Weights and WR for Bushed Sprockets do not include bushings. WR values have lb-ft units. R 7 The Gates Rubber Company
R The Stock mm Poly Chain GT Sprocket Specifications continued Sprocket Number Number Teeth Diameters Dimensions Pitch O.D Flange Ref. Design Type B C D E F M F-CL MX-S-6-PB.06..60 6F-.79.. 0..6 0 0.9 MPB 0.00..0 0.00 D MX-S-6-PB.06..90 6F-.0.. 0..6 0 0.9 MPB 0.00.00.7 0.0 D MX-S-6-PB.07.7.0 6F-... 0..6 0 0.9 MPB 0.00.70. 0.0 D MX-0S-6-PB 0.00.9.0 6F-... 0..6 0 0.9 MPB 0.00..9 0.09 D MX-S-6.0..60 F-...00.6 0.6 0.9 0 0.00.0.7 0.0 D MX-S-6-PB.0..60 6F-.7.. 0..6 0 0.9 MPB 0.00.000. 0.0 D MX-S-6.09.6.0 F-.66..00.6 0.6 0.9 0 0.00.6. 0.06 D MX-S-6-PB.09.6.0 6F-... 0.9.6 0 0.9 MPB 0.00.. 0.07 D MX-6S-6 6.609.6.00 F-.96..00.6 0.6 0.9 0 0.00.6. 0.0 D MX-6S-6-PB 6.609.6.00 6F-... 0.6.6 0 0.9 MPB 0.00..9 0.06 D MX-S-6.0.77.0 F-...00.6 0.6 0.9 0 0.00.6. 0.0 D MX-S-6-PB.0.77.0 6F-... 0.6.6 0 0.9 MPB 0.00. 6.7 0.079 D MX-0S-6 0.00.97.0 F-....6 0.6 0.9 0 0.00.. 0.09 D MX-S-6...90 F-.6...6 0.6 0.9 0 0.00.. 0.06 D MX-S-6...90 F-.6...6 0.6 0.9 0 0.00.. 0.09 G MX-S-6..79.0 F-....6 0.6 0.9 0 0.00.. 0. G MX-0S-6 0.0.90.0 F-....6 0.6 0.9 0 0.00.. 0. G MX-S-6...00 F-.76...6 0.6 0.9 0 0.00.. 0.9 G MX-6S-6 6.6. 6.00 F-.9...6 0.6 0.9 0 0.00. 6. 0. G MX-60S-6 60 6.0.9 6.0 F-...7.6 0. 0.9 7 0.00.6.9 0. G MX-6S-6 6 6. 6. 6.70 F-.7..7.6 0. 0.9 7 0.00.6 0. 0.6 G MX-67S-6 67 6.77 6.6 6.0 DF-.9...7.6 0. 0.9 7 0.00.6 6. 0.07 G MX-7S-6 7 7. 7.0 7.00 DF- 6.9...7.6 0. 0.9 7 0.00.6 7.0 0.6 G MX-7S-6 7 7.9 7.6 7.90 DF- 6.79...7.6 0. 0.9 7 0.00.6 7. 0. G MX-0S-6 0.00 7.97.0 BF-.7..00.6 0. 0.9 00 0.7.0 7.9.0 G MX-90S-6 90 9.0.960 B-.7.00.6 0. 0.9 00 0.7.0..9 G MX-S-6.9.6 C- 9.0.7.00.6 0. 0.9 00 0.7.0.7.76 G MX-0S-6 0.06.97 C-.7 6..00.6 0. 0.9 00 0.7.0 6. 7.9 G MX-0S-6 0.06 7.9 C-. 6..00.6 0. 0.9 00 0.7.0..67 G MX-S-6.7.9 C- 9.6.7.0.6 0.6 0.9..9 9..0 G Material Spec : S - Steel SS - Sintered Steel G - Grey Iron D - Ductile Iron Bushing Size Bore Sizes Min Max pprox. Wt. (lb) Design Type Suffix: - Solid - Web - rms pprox. WR Matl. Spec. Sprocket Number Number Teeth Diameters Dimensions Pitch O.D Flange Ref. Design Type B C D E F M F-CL MX-S-6-PB.06..60 6F-.79.6.6 0.6.9 0.6 MPB.000.. 0.0 D MX-S-6-PB.06..90 6F-.0.6.6 0.6.9 0.6 MPB.000.00. 0.09 D MX-S-6-PB.07.7.0 6F-..6.6 0.6.9 0.6 MPB.000.70. 0.0 D MX-0S-6-PB 0.00.9.0 6F-..6.0 0..9 0.6 MPB.000.. 0.0 D MX-S-6-PB.0..60 6F-.7.6.0 0.9.9 0.6 MPB.000.000 6. 0.0 D MX-S-6.09.6.0 F-.66.6.00.9.9.6 0 0.00.6.6 0.0 D MX-S-6-PB.09.6.0 6F-..6.0 0.9.9 0.6 MPB.000. 6.9 0.070 D MX-6S-6 6.609.6.00 F-.96.6.00.9.9.6 0 0.00.6. 0.0 D MX-6S-6-PB 6.609.6.00 6F-..6.6 0.6.9 0.6 MPB.000..0 0.09 D MX-S-6.0.77.0 F-..6.00.9.9.6 0 0.00.6. 0.06 D MX-S-6-PB.0.77.0 6F-..6.6 0.6.9 0.6 MPB.000. 9. 0. D MX-0S-6 0.00.97.0 F-..6..9.66.6 0 0.00.. 0.067 D MX-0S-6-PB 0.00.97.0 6F-..6.6 0.7.9 0.6 MPB.000.6 0. 0. D MX-S-6...90 F-.6.6..9.66.6 0 0.00..6 0.079 D MX-S-6-PB...90 6F-.79.6.6 0.7.9 0.6 MPB.000.70.6 0.7 D MX-S-6...90 F-.6.6..9.66.6 0 0.00.. 0.6 D MX-S-6-PB...90 6F-.79.6.6 0.7.9 0.6 MPB.000.70. 0.7 D MX-S-6..79.0 F-..6.7.9..6 7 0.00.6. 0. G MX-0S-6 0.0.90.0 F-..6.7.9..6 7 0.00.6 6. 0.96 G MX-S-6...00 F-.76.6.7.9..6 7 0.00.6 6.7 0.9 G MX-6S-6 6.6. 6.00 F-.9.6.7.9..6 7 0.00.6. 0.07 G MX-60S-6 60 6.0.9 6.0 F-..6.00.9 0.9.6 00 0.7.0.9 0.07 G MX-6S-6 6 6. 6. 6.70 F-.7.6.00.9 0.9.6 00 0.7.0 9.9 0. G MX-67S-6 67 6.77 6.6 6.0 F- 6..6.00.9 0.9.6 00 0.7.0.0 0.6 G MX-7S-6 7 7. 7.0 7.00 F- 6..6.00.9 0.9.6 00 0.7.0. 0.7 G MX-7S-6 7 7.9 7.6 7.90 F- 6.90.6.00.9 0.9.6 00 0.7.0..067 G MX-0S-6 0.00 7.97.0 F- 7..6.00.9 0.9.6 00 0.7.0 0.. G MX-90S-6 90 9.0.960 D- 7.9..00.9 0.9.6 00 0.7.0 0..6 G MX-S-6.9.6 D- 9.60..00.9 0.9.6 00 0.7.0.0. G MX-0S-6 0.06.97 D-.0.7.0.9 0..6..9 6. 0.9 G MX-0S-6 0.06 7.9 D-..7.0.9 0..6..9 9.6 9. G MX-S-6.7.9 D- 9..7.0.9 0..6..9 7. 67. G Material Spec : S - Steel SS - Sintered Steel G - Grey Iron D - Ductile Iron Bushing Size Bore Sizes Min Max pprox. Wt. (lb) Design Type Suffix: - Solid - Web - rms pprox. WR Matl. Spec. NOTES: Weights for Minimum Plain Bore (MPB) Sprockets are with minimum bore. Weights and WR for Bushed Sprockets do not include bushings. WR values have lb-ft units. Driving Force in Power Transmission. 7
Sprocket Specifications Sprocket Tolerance Specifications Poly Chain GT sprockets are made to close tolerances. Modifications such as reboring may result in unsatisfactory drive performance. Strict adherence to the standard tolerances (as shown in table below) is highly recommended. Sprocket Outside Diameter and Pitch Outside Diameter Range Over.000 to and including.000 Over.000 to and including 7.000 Over 7.000 to and including.000 Over.000 to and including 0.000 Over 0.000 Outside Diameter Outside Diameter Tolerance + 0.00 0.000 + 0.00 0.000 + 0.006 0.000 + 0.007 0.000 + 0.00 0.000 Pitch To Pitch Tolerance djacent Grooves Sprocket Runout Radial Runout* ccumulative Over 90 Degrees ± 0.00 ± 0.00 ± 0.00 ± 0.00 ± 0.00 ± 0.006 ± 0.00 ± 0.006 ± 0.00 ± 0.007 Total Eccentricity Total Indicator Reading h k w k (mm) (mm) Over to Over to 0 00 00 00 Over 00 * Total Indicator Reading 0.00 0.0 0.00 0.0.000 per inch.0 per mm O.D. O.D. over over 00mm (may not exceed face diameter tolerance) xial Runout* For outside diameters.0 inches and under.. 0.00 inches For each additional inch outside diameter up through 0.0 inches, add................ 0.00 inches For each additional inch outside diameter over 0.0 inches, add............. 0.000 inches * Total Indicator Reading Sprocket and Bushing Keyseat Shaft Diameter Width w k Depth, h k + 0.0 0.000 Up through 7 (0.) (0.09) 6 (0.07) Over 7 (0.) to and incl. 9 (0.6) (0.) (0.06) Over 9 (0.6) to and incl. 7 (0.) (0.7) (0.09) Over 7 (0.) to and incl. (.) (0.0) (0.) Over (.) to and incl. (.) (0.) (0.6) Over (.) to and incl. (.7) (0.7) (0.) Over (.7) to and incl. (.) (0.00) (0.0) Over (.) to and incl. (.7) (0.6) (0.) Over (.7) to and incl. (.) (0.70) (0.7) Over (.) to and incl. (.7) 7 (0.7) 7 (0.) Over (.7) to and incl. (.0) (.000) (0.00) Over (.0) to and incl. (.0) (.0) (0.6) Balancing Stock Sprockets are statically balanced per MPT (Mechanical Power Transmission ssociation) Standard Practice for Pulley Balancing SPB-6 using the weight based on the following two criteria:. Balance limit (ounces) = Sprocket Weight (lb) x 0.0; or. 0.76 ounce ( grams), whichever is greater. Caution: Stock sprockets should not be used on drives where rim surface speeds exceed 6,00 fpm. Sprocket construction and materials will determine the dynamic balancing requirements the sprocket(s) where rim surface speeds exceed 6,00 fpm. Sprocket Tooth Prile and Surface Quality The Poly Chain GT sprocket tooth prile was designed and developed exclusively by The Gates Rubber Company to operate with the Gates Poly Chain GT Belt. See Engineering Section II-, Tooth Prile, on page 0 for a complete discussion the performance characteristics this new tooth prile. The tooth surface should be free any surface defects and should be 0 micro-inches finish or better. Sprocket Blanks Sprocket blanks can be grooved by Gates for specially designed, made-to-order sprockets. If those sprockets are supplied in blank form, Gates can perform the grooving operation. The blank diameter must be 0.00 larger than the finished sprocket O.D. Contact your local Gates Representative for additional details. Tolerance on width, W k For width up through / (0.00)......... + 0.00, 0.000 inches For width over / (0.00) up through (.000).. + 0.00, 0.000 inches For width over (.000).............. + 0.00, 0.000 inches R 7 The Gates Rubber Company
R The Poly Chain GT Bored-To-Size Sprocket Bore Range Listing mm Pitch Sprockets mm Pitch Sprockets Sprocket Size Minimum Bore Full Keyway Bore Range Shallow Keyway Bore Range Sprocket Size Minimum Bore Full Keyway Bore Range Shallow Keyway Bore Range MX-S- 0.00 0.00 -.06. -. MX-S- 0.00 0.00 -.06. -. MX-S-6 0.00 0.00 -.06. -. MX-S- 0.00 0.00 -..7 -.00 MX-S- 0.00 0.00 -..7 -.00 MX-S-6 0.00 0.00 -..7 -.00 MX-S-6.000.000 -..7 -.00 MX-S- 0.00 0.00 -.00.6 -.70 MX-S- 0.00 0.00 -.00.6 -.70 MX-S-6 0.00 0.00 -.00.6 -.70 MX-S-6.000.000 -.00.6 -.70 MX-0S- 0.00 0.00 -.6.6 -. MX-0S- 0.00 0.00 -.6.6 -. MX-0S-6 0.00 0.00 -.6.6 -. MX-0S-6.000.000 -.6.6 -. MX-S- 0.00 0.00 -.70. -.000 MX-S- 0.00 0.00 -.70. -.000 MX-S-6 0.00 0.00 -.70. -.000 MX-S-6.000.000 -.70. -.000 MX-S-6 0.00 0.00 -.70. -. MX-S-6.000.000 -.70. -. MX-6S-6 0.00 0.00 -.9.000 -. MX-6S-6.000.000 -.9.000 -. MX-S-6 0.00 0.00 -.. -. MX-S-6.000.000 -.. -. MX-0S-6.000.000 -..0 -.6 MX-S-6.000.000 -.7. -.70 MX-S-6.000.000 -.7. -.70 ll Bored-To-Size Sprockets are made-to-order. Check with you local Gates representative or Customer Service for a quote and delivery. MX-S-7.000.000 -.00.6 -.9 MX-S-6.000.000 -.00.6 -.9 MX-S-90.00.00 -.00.6 -.9 MX-S-.00.00 -.00.6 -.9 MX-9S-6.000.000 -.70. -. MX-9S-90.00.00 -.70. -. MX-9S-.00.00 -.70. -. MX-0S-6.000.000 -.70. -. MX-0S-90.00.00 -.70. -. MX-0S-.00.00 -.70. -. MX-S-6.000.000 -.7.9 -. MX-S-90.00.00 -.7.9 -. MX-S-.00.00 -.7.9 -. MX-S-6.000.000 -.7.9 -. MX-S-90.00.00 -.7.9 -. MX-S-.00.00 -.7.9 -. MX-S-6.000.000 -.9.000 -.00 MX-S-90.00.00 -.9.000 -.00 MX-S-.00.00 -.9.000 -.00 MX-S-7.000.000 -.9.000 -.00 MX-S-6.000.000 -.9.000 -.00 MX-S-90.00.00 -.9.000 -.00 MX-S-.00.00 -.9.000 -.00 MX-S-90.00.00 -.0. -. MX-S-.00.00 -.0. -. MX-6S-90.00.00 -.0. -. MX-6S-.00.00 -.0. -. MX-7S-90.00.00 -.6.6 -. MX-7S-.00.00 -.6.6 -. MX-S-90.00.00 -.6.6 -. MX-S-.00.00 -.6.6 -. MX-9S-90.00.00 -.70. -.7 MX-9S-.00.00 -.70. -.7 MX-0S-90.00.00 -.70. -.7 MX-0S-.00.00 -.70. -.7 MX-S-.00.00 -.. -. MX-S-.00.00 -.7. -.000 MX-S-.00.00 -.6.70 -.6 ll Bored-To-Size Sprockets are made-to-order. Check with you local Gates representative or Customer Service for a quote and delivery. Driving Force in Power Transmission. 79
Recommended Re-bore Specifications and Instructions For Minimum Plain Bore (MPB) Sprockets When using MPB Poly Chain GT sprockets in power transmission systems, important guidelines should be followed for proper product finishing and application. Due to the high load carrying capacity and high operating tensions ten found in Poly Chain GT belt drive systems, it is imperative to use and adhere to industry standard practices. When finishing MPB sprockets for high performance belt drive systems, care should be taken to ensure proper functionality and performance. General re-bore instructions and specifications are as follows:. Materials used in Poly Chain GT sprockets are steel, gray iron, and ductile iron. The materials used may vary with the size the sprocket. See the Sprocket Specification Tables, pages 7 thru 77 for specific materials.. The maximum bore diameter specified by the manufacturer for each sprocket size should NOT be exceeded, or a keyway used which reduces the hub thickness to less than its minimum allowable value. See the Sprocket Specification Tables for a listing recommended bore ranges by sprocket size. Bores exceeding the maximum recommended value for a particular sprocket size can adversely affect the structural integrity, thereby reducing their load-carrying capability. The minimum metal thickness between the keyway and hub O.D. should be no less than the set screw diameter specified for the corresponding sprocket size. See Figure. listing minimum set screw diameters is included below. M-S thru S / M-S 7/ M-0S thru S / M-9S thru S / M-6S thru S / M-S thru 0S / M-0S thru S 7/ M-S thru S / Figure Minimum Hub Thickness and Set Screw Placement Guidelines. The fit between a finished sprocket bore and its mating shaft in a power transmission system must not allow relative movement between the bore and the shaft when the drive is subjected to belt tension and torque loads. This is accomplished, in the case plain bore sprockets, with the use set screws and keys and by controlling the fit or clearance between the sprocket bore and its mating shaft. Cyclical, pulsating, or reversing loads may wear the sprocket bore and/or keyway due to the relative movement between the contacting surfaces the shaft and the bore. The resulting wear may increase the clearance further, if an interference fit is not used. In order to maximize the performance high capacity belt drives using plain bore style sprockets, the following for recommendations presented in Table 7 should be followed: Class Clearance Fits should be used when the transmitted load is smooth in nature. Interference Fits should be used for Poly Chain GT curvilinear drives transmitting cyclical, pulsating, or reversing loads. Table 7 - Recommended Shaft / Bore Fits (Inches) Nominal Bore Range Over - To (Incl.) Shaft Tol. (minus) Clearance Fits Class - Smooth Load Bore Tol. (Plus) Fit Tol. (Plus) Interference Fits Cyclical, Pulsating, Reversing Load Bore Tolerance Range (Minus) Fit Tolerance Range (Minus) 0.7-0.66 0.000 0.000 0.00 0.000 0.000 0.0000 0.000 0.6-0.70 0.000 0.000 0.00 0.000 0.000 0.0000 0.000 0.70 -.00 0.000 0.000 0.00 0.000 0.000 0.0000 0.000.00 -.70 0.000 0.000 0.00 0.000 0.000 0.0000 0.000.70 -.00 0.000 0.000 0.00 0.000 0.000 0.0000 0.000.000 -.700 0.000 0.000 0.000 0.000 0.000 0.0000 0.000.700 -.0000 0.000 0.000 0.000 0.000 0.000 0.0000 0.000.0000 -.00 0.000 0.00 0.00 0.000 0.000 0.0000 0.000.00 -.700 0.000 0.00 0.00 0.000 0.000 0.0000 0.000.700 -.0000 0.000 0.00 0.00 0.000 0.000 0.0000 0.000.0000 -.00 0.000 0.00 0.00 0.00 0.000 0.000 0.000.00 -.700 0.000 0.00 0.00 0.00 0.000 0.000 0.000.700 -.0000 0.000 0.00 0.00 0.00 0.000 0.000 0.000.0000 -.000 0.000 0.00 0.00 0.000 0.00 0.000 0.00.000 -.0000 0.000 0.00 0.00 0.000 0.00 0.000 0.00.0000 -.000 0.000 0.00 0.00 0.00 0.000 0.00 0.000.000-6.000 0.000 0.00 0.00 0.00 0.000 0.00 0.000 Table 7 was extracted in part from GM Standard for Bores and Keyways for Flexible Couplings (Inch Series) GM 900-6 Table.. DO NOT chuck or center the sprocket on guide flanges. St jaws should be used when chucking on the sprocket teeth. Center (indicate) the sprocket using the sprocket tooth O.D. If chucked on the Rim I.D. or Hub O.D., the sprocket should be centered with respect to the sprocket tooth O.D. Guide flanges are permanently mounted and should not be removed. If original flanges must be removed, they should be replaced with NEW flanges. New guide flanges should be attached securely with care using mechanical fasteners such as screws. Note: Improper guide flange reassembly may cause serious personal injury and/or mechanical damage.. Set screw holes in the sprocket hub must be placed properly for maximum holding strength. For both standard and shallow keyseats, two () set screws should be used as illustrated in Figure. The total holding strength the set screws is dependent upon their placement and design. Generally, one screw should be placed directly over the keyway, and the other screw at ninety degrees (90) from the keyway, or at sixty-five degrees (6 ) from the keyway a more recent practice that improves holding power. Sometimes four set screws (or two pair) are used for increased holding strength. R 0 The Gates Rubber Company
R The Recommended Re-bore Specifications and Instructions For Minimum Plain Bore (MPB) Sprockets Figure Set Screw ngles Each set screw should be placed axially a minimum one set screw diameter from the end the sprocket hub extension. See Figure. For recommended set screw tightening torque values see Table below. Table Recommended Tightening Torque Values For Set Screws Set Screw Size Hex Key Size pproximate Installation Torque Values (lb-in) 0 0 7 7 7 0 6 0 7 0 6. fter reboring, the sprocket may require rebalancing. Vibration, noise, reduced bearing life, and undue stresses on the mechanical components in the system could result if improper rebalancing practices are used. See Sprocket Specifications, page 7, for recommended sprocket balancing specifications. 7. Standard square or rectangular keys should be used. See pages - for standard key dimensions. Specifications and tolerances for sprocket eccentricity, parallelism, and balancing, etc. are all presented on Page 7. Driving Force in Power Transmission.
B Position Screw to Tighten Bushing Stock Bushings for Sprockets For removing from Shaft: Bushing Half Hole Threaded Hub Half Hole NOT Threaded Bolt Circle o o o Section - o Taper Included ngle 00 thru 00 Screw for Tightening on Shaft: Hub Half Hole Threaded Bushing Half Hole NOT Threaded B Position Screw to Tighten Bushing For removing from Shaft: Bushing Half Hole Threaded Hub Half Hole NOT Threaded Bolt Circle o G G 60 o o Socket Head Cap Screws B Bolt Circle o o o 60 o Section - For Bushing Removal o 7 o o o o o o Taper Included ngle 0 o thru 00 Screw for Tightening on Shaft: Hub Half Hole Threaded Bushing Half Hole NOT Threaded Bushing Size Section - Torque Capacity (lb-in) o Taper Included ngle Dimensions Hex Head Cap Screws for Bushing Installation 600 7060 TPER-LOCK* BUSHINGS Mounting Screws Bolt Circle B Quantity Size G (deg) Min. Bore R The Gates Rubber Company Bore Range Max Bore Standard Keyseat*** Weight Range (lb) Shallow Keyseat** Max. Bore Min. Bore 00,00.6 0.7. x 0.00 0.7.000 0. 0. 0,00. 0.7. x 0.00.000. 0. 0. 0,600.7.000.70 x 0.00.0 0. 0.6 0,00.0.000. x 0.00.00.6 0. 0.9,00..00. x 0.00.00.6 0.6. 0 7,0.70.0.6 7 x 7 0.00.7. 0.9.7 7,600.7.70.0 x 0.00.0.6..7 00,000.0.000.000 x 0.7.70.0. 6.,00.000.00.0 x 9..0.9..,00.000.00.0 x 9..0.9.0. 00 77,00.70.000.0 x 0..6. 6.7 7. 00 77,00.70.000.0 x 0..6... 0,000 6.7.00 6.0 x 0.9.0.9 9.. 0,000 6.7.00 6.0 x 0.9.0.9. 0. 00 6,000 7.000.000 6.70 7 x 7..00.000..9 600,000 9.0.000 9.000 x. 6.000.0 7.0 7060,000 0.0 6.000 0.000 x.9 7.000 66.0 7.0 * Registered trademark Reliance Electric. ** Key is furnished with each bushing having a shallow keyseat. *** Keys are not furnished with bushings having standard keyseats.
R The Taper-Lock Bushing Bore and Keyseat Information Taper Lock Bushings are available from stock with all popular bores within the bore range each size bushing. The Taper Lock Bushing Keyseat Dimension charts below list the bore range for each bushing and the appropriate keyseat dimensions. Where standard keyseats are indicated, refer to the Standard Keyseat Dimensions chart. Where bores do not permit standard depth keyseats, a flat key the proper dimensions is furnished with the bushing. Taper-Lock Bushing Keyseat Dimensions Bushing Bores Keyseat 00 0.00-0.7 x Standard 0.9 -.000 0 0.00 -.000 Standard.06 -. x 0 0.00 -.0 Standard 0 0.00 -.00 x Standard.6 -.6 x 0.00 -.00 Standard.6 -.6 0 x 0.00 -.7 Standard.9 -. 7 x 0.00 -.0 Standard. -.6 00 0.7 -.70 Standard. -.0 x. -.0 Standard. -.70 7 x Standard Keyseat Dimensions Keyseat Key Shaft Diameter Width Depth Width Depth 0. - 0. 6 0.00-0.6 0.6-0.7 0.9 -.0. -.7. -.70. -.0. -.70. -.0. -.70 7 7 7 7. -.00.6 -.00.6-6.00 6.6-7.00 7.6-9.000 00 00.7 -.9 x. -.0 Standard. -.70 7 x.7 -.9 x. -.6 Standard.6 -.70 7 x.7 -. x. -.6 Standard.6 -.70 7 x.7 -. x.9 -.0 Standard.7 -.00 x.70 -.9 x.9 -.0 Standard.7 -.00 x.70 -.9 x 00. -.00 Standard.7 -.000 x 7 600. - 6.000 Standard 7060.9-7.000 Standard Driving Force in Power Transmission.
Bushing Bore and Keyseat Information continued Specifying English and Metric Keyways Dimensioning and specifying metric keys and keyways varies significantly from the English system. In the English system, it is the standard practice to dimension the keyway, while in the metric system it is common practice to specify the key size. In the English system, the keyway in the hub is dimensioned by the width and depth at the side, but in the metric system the keyway is dimensioned by the width and the depth measured from the radius the shaft to the center the keyway. One the following methods should be used to specify keyways: English: Metric: W x T Keyway W x T Key W x T Key W x h Keyway Unless otherwise noted, the keyway in the shaft is assumed to be standard. lso, T and T are not necessarily equal. The metric system does not refer to keyseat or keyway dimensions as does the English system. Instead, dimensions are given for the key itself which is rectangular in shape, not square, as in the English system. The correct terminology when ordering metric bored bushings with millimeter keyways will be either the following:. Specify standard Keyway. Customer to specify keysize (keyseat to be standard size in shaft) Bushing Metric Bore and Key Dimensions for Taper-Lock Bushings Bore (mm) h H Keyway (WxT) (mm) r W Key Size (ref.) (mm), X. X 00, 9, 0, 6 X. 6 X 6 X. X 7 *, X. X 0, 9, 0, 6 X. 6 X 6, X. X 7, X. X 0, 9, 0, * 6 X. 6 X 6,,, 0 X. X 7 *, * X. X *, 9, 0, 6 X. 6 X 6 0,,, 0 X. X 7,, 0 X. 0 X 0 X. X, X. X, 9, 0, 6 X. 6 X 6 0,,, 0 X. X 7,, 0 X. 0 X 0, X. X, * X. X 9, X. X, 9*, 0, 6 X. 6 X 6,,, 0 X. X 7 7,, 0 X. 0 X 0, X. X,, 0 X. X 9 X. X 0 60, 6* X. X,,, 0* X. X 7 *, *, * 0 X. 0 X 0, * X. X 00,, 0 X. X 9 X. X 0 60, 6 X. X 70*, 7* 0 X.9 0 X * Non-stock, made to order bushing T T T R The Gates Rubber Company
R The Taper-Lock Type Sprocket Installation and Removal. Clean the shaft, bore bushing, outside bushing and the sprocket hub bore all oil, paint and dirt. File away any burrs. Note: The use lubricants can cause sprocket breakage. USE NO LUBRICNTS IN THIS INSTLLTION.. Insert the bushing into the sprocket hub. Match the hole pattern, not threaded holes (each complete hole will be threaded on one side only)., LIGHTLY oil the set screws and thread them into those half-threaded holes indicated by on the diagram above. Note: Do not lubricate the bushing taper, hub taper, bushing bore, or the shaft. Doing so could result in sprocket breakage.. With the key in the shaft keyway, position the assembly onto the shaft allowing for small axial movement the sprocket which will occur during the tightening process. Note: When mounting sprockets on a vertical shaft, precautions must be taken to positively prevent the sprocket and/or bushing from falling during installation. To Install TPER-LOCK Type Bushings. lternately torque the set screws until the sprocket and bushing tapers are completely seated together (at approximately half the recommended torque; see table below). Note: Do not use worn hex key wrenches. Doing so may result in a loose assembly or may damage screws. 6. Check the alignment and sprocket axial runout (wobble), and correct as necessary. 7. Continue alternate tightening the cap screws to the recommended torque values specified in the table below.. To increase the bushing gripping force, hammer the face the bushing using a drift or sleeve (Do Not Hit The Bushing Directly With The Hammer). 9. Re-torque the bushing screws after hammering. 0. Recheck all screw torque values after the initial drive run-in, and periodically thereafter. Repeat steps through 9 if loose.. Loosen and remove all mounting screws.. Insert screws into all jack screw holes indicated by (see figure above). To Remove. Loosen the bushing by alternately tightening the screws in small but equal increments until the tapered sprocket and bushing surfaces disengage. Sprocket Installation Bushing Bolts Torque Wrench Style Qty. Size lb-ft lb-in 00 /-0 x /.6 0 /-0 x /.6 0 /- x /.6 7 0 /- x /.6 7 /- x /.6 7 0 7/- x 7/. 0 7 /- x. 0 00 /- x / 66.7 00 /- x /. 000 /- x /. 000 00 /- x / 700 00 /- x / 700 /-0 x 0 0 /-0 x 0 0 00 7/-9 x / 00 600 /-7 x / 6 70 7060 /-7 x / 6 70 Caution: Excessive bolt torque can cause sprocket and/or bushing breakage. Note: To insure proper bushing/sprocket performance, full bushing contact on the shaft is recommended. Driving Force in Power Transmission.
B Belt Drive Tensioners (Double djustable) H J C E G-BOLT D F G-BOLT Q M TP N P Specifications Tensioned Product Use With Part B C D E F G H J M (Threads) N P Q Weight (lb) 770-00 770-00 mm Pitch Poly Chain GT 0-IDL-BRK.6.0.7.00.06.06 0..0 0.6 -.00..7.7 mm Pitch Poly Chain GT 0-IDL-BRK 6.9..6.00.00.6 0.6..00 -.6.9 0.7 0. Poly Chain GT Idler Sprockets D G C F O.D. J B H E Product Use With Part Poly Chain GT Idler Dimensions Size Designation Belt Width Teeth O.D. B Ref. C D E Ref. F (Threads) 770-700 -IDL-SPK MX-S-.. 0.0 0..6-0.9.7.0 770-70 mm Pitch -IDL-SPK MX-S-.. 0.0..6-0.6.7. 770-70 Poly Chain GT 6-IDL-SPK MX-6S-6 6 6.6.9 0.7.6.6 -.0 770-70 6-IDL-SPK MX-6S-6 6 6.6.9 0.7.9.69-0.69.. 770-00 0-IDL-SPK MX-0S-0 0 0...00.6. -.00. 9.0 770-0 7-IDL-SPK MX-0S-7 7 0...00.06. - 0...0 770-0 mm Pitch Poly Chain GT 6-IDL-SPK MX-S-6 6.. 0.6.. -.00...6 770-0 90-IDL-SPK MX-S-90 90.. 0..0. -.00...7 770-0 -IDL-SPK MX-S- 6.0. 0.9.6. -.09... G Ref. H J Wt. (lb) R 6 The Gates Rubber Company
R The Poly Chain GT Sprocket Diameter Table mm Pitch Sprocket Diameters Grooves Diameters in Diameters in Diameters in Diameters in Diameters in PD OD Grooves PD OD Grooves PD OD Grooves PD OD Grooves PD OD 6.0. 9.7.7 0 0.7 0. 09 77.7 7.97. 9..06...00.00 7.97 0.9 0.6..77.7 6.97. 0. 06.6 0.66 0 0. 7. 9.96.6.06...0..0.0 0.96.9.7 6. 9..96.6 0. 07..66.06 0 6..9.06.......06.06.97 6.66 6.06 7..9.6 09.76..6 9.0 7..06......9.6..07 6 66. 6.6 0.06.6.90.0 7.7 6. 6.60 60.00.607......9.66.6.7 7 6.7 67. 6.60.00.. 90.0.70 6. 6..707.6.6...9.9.66.6.7 7.0 69.70 7.. 6 9.00 7.0 9. 9. 66.69 6.09.07.7.7.6.6.9.9.66.7.7 9 7. 7. 7.70.0 7. 9.9 9.9 9.79 69. 67.6.907...7.7.69.60.67.7.7 0 76.9 7.79 9 0..6.09.9 7 97.9 96. 7.79 70.9.00.9.9...79.70.667.67.7 7.9 77. 60.79.9 9 6.6.0 00. 9. 7 7. 7.7.0.0 6.0.9.9.60.0.767.77.67.9 79.9 6..7 90 9. 7. 9 0.0 0. 76. 7..0. 6. 6.0 9.0.960.90.67..77.0. 6 7. 6. 9.7 0. 0 0. 0.9 9 79. 77..0. 6. 6. 9. 9.060.0.96.9.7 6..9 6 0.. 9..6 0. 06. 0.97 0.7.09.6 6. 6. 9. 9.0..06.0.97 9. 7. 6.97.7 9 6.. 0.67 09.07..9.09.6 6. 6. 9. 9.6...9.076 6 9.67 90.07 6..9 9 9.7 7.77..6 7.06.6.609.6 6.7 6. 9. 9.6..6.9.76 7 9. 9.6 66.07 6.7 9.9 0..76. 9.6.0.709.66 6.67 6. 9. 9.6..69.9.76 96.77 9.7 67 70.6 9.0 96.6.6..7 9. 90.6.0.77 6.77 6.6 9.6 9.6..69.9.76 9 99. 97.7 6 7. 7.6 97 7.0. 6 0.6 9.6 9.70 9.0.90.7 6.7 6.7 9.7 9.66.6.69.0.77 0 0.6 00.6 69 7.7 7. 9 9. 7.9 7.0.0 6 97. 9.6.00.97 6.9 6. 9. 9.76.7.669.60.77 0. 0. 70 7. 76.6 99.0 0.0.9. 7 99.0 9.0.0.07 7.0 6.9 9.9 9.6..770.70.677 06.9 0. 7 0.0 79.0 00.6.0 9.0 6.90 0. 00.7.. 7. 7.0 0.06 9.96.9.70.0.777 09.0 07.90 7..7 0 7.9.9 0.0 9. 9 0.9 0.9.. 7. 7. 0.6 0.06.0.970.9.7.0 0. 7.9.9 0 9.7..9.99 0 07. 0... 7.9 7.6 0.6 0...070.0.97.9.99 7.. 0 6.9 60.69 6.. 09.9 0... 7.9 7.6 0.6 0.6..7..07 6 7.. 7 90.99 9.9 0 6. 6..6 7.0. 0.9.6.9 7.9 7.6 0.7 0.6..7..7 7 9.6.0 76 9. 9.9 0 67. 6.7. 9.6.0..7.69 7.69 7.6 0.7 0.6..7..79. 0.6 77 96.0 9. 06 69.9 6..77.7 7.6.0..79 7.70 7.67 0.67 0.6..7..79 9.7. 7 9.6 97.0 07 7.7 70.7 6..7 0.7.7.9.9 7.0 7.77 0.77 0.66.6.7..79 0 7..7 79 0.7 99.7 0 7.0 7. 7.7 7.7 6.7..0.90 7.90 7.7 0. 0.76.7.67.6.79 * Dimensions are given in inches and millimeters. Inches are shown in black in bold face type. Millimeters are shown in blue in light face type. Stock sprockets are shown shaded. Driving Force in Power Transmission. 7
Poly Chain GT Sprocket Diameter Table mm Pitch Sprocket Diameters Grooves Diameters in Diameters in Diameters in Diameters in Diameters in PD OD Grooves PD OD Grooves PD OD Grooves PD OD Grooves PD OD 7.6.66 79.. 9 6..7 0.9. 7.9.9.7.60 7.96 7. 9.9 9.06 0. 0.9..9 7. 6. 0.7 6.77 9.9 7. 0 9. 7. 0.0...70.06 7.9 9.9 9. 0. 0.9.6.9 9 0..7 60.9 9. 9 9.7 9.7 0.0 0. 7.9 0.99.9.0..0 9.9 9.6 0. 0.9.7.69 70.90.0 6.6 6.6 9 9.0 9. 06.7.97.. 7.0.90.6. 9.9 9.6 0.6 0.90.6.79 7.. 66.0 6. 9 96.6 9.96 07 7.. 9 7.6 6.0 7. 7.0.7. 9.0 9.7 0.7 0.690.96.9 7 7.99 6.9 6. 66.9 96 99. 97. 0 9.67.07 0 60..6 7. 7..7. 9.60 9.7 0. 0.790.06.99 7 0..9 7.0 69.0 97 0.66 00.06 09. 0.6 6.77 6.7 7. 7..7. 9.70 9.67 0.9 0.90.6.09 7.09.9 7.6 7.0 9 0.0 0.60 0.76. 6. 6.7 7. 7..67. 9. 9.7.0 0.99.7.9 7.6.0 7 76.9 7.9 99 06.7 0. 7..7 67.6 66.6 7. 7..7.6 9.9 9...09.7.9 76. 6. 7.7 77. 00 09.0 07.70 9.. 70. 6. 7.6 7...7 0.0 9.9..9.7.9 77 0.7 9. 9. 79.6 0. 0..0 0.0 7.7 7.6.9. 0. 0.0..9 7.7.67 90.. 0.9.79.9. 7. 7.7 9.0.9 0. 0.9..9 mm Pitch Sprocket Diameters Grooves Diameters in Diameters in Diameters in Diameters in Diameters in PD OD Grooves PD OD Grooves PD OD Grooves PD OD Grooves PD OD.7.9 0 7. 7..7.9 6.. 76.6..9.0 7.0 6.90 9. 9.0.9.9.. 9 9. 6..7 79.9 6.9.9 6 9.66 6.6 77. 0..0.97 7.9 7.0 9.99 9.9.0.9.09.99 0.69 0.9 7.7.7 0.6 7. 66 9. 9. 7 7.9.79.6. 7.69 7.9 9.7 9.6.79.69.6.7.. 9.6..0.0 67 9.7 9.77 79.0 9..9.9 7. 7. 9.60 9.0.7.6.60.70.60 9.0 96.0 9. 6 9. 6.7 6 0.0 00. 0 6..7.6.0 7.70 7.60 9. 9.7.90.0.06.96 7.06.6 00. 97.7 7.0. 69 07.9 0.69 60.96..790.60 7.9 7.7 0.000 9.90.06.996..0..7 6 0.99 0.9.7.67 70.9 09. 6. 6.6.96..07 7.96 0.76 0.066..7.7.77.97.7 7 09. 06.6 9 6.9 60. 7.0.60 69. 67.0 6. 6.0.6. 0. 0..7.7.6. 6 0. 7.6.90.0 60 67. 6. 7 0.6.06 7. 7. 6. 6.06.. 0.7 0.7.6..77.67 7..0 9.6.6 6 7. 69.0 7.. 7.79 7.99 6.9 6..97.7 0.70 0.9.0.69.9.0 9. 6. 0. 0.0 6 76.9 7.9 7 9.77 6.97 6. 0. 6.667 6.7.77.66 0.7 0.76.9.7.0.97 9 7.0 7.00 7.7.7 6 0.7 77.9 7.. 7 7.70.90 6. 6.7.9..0 0.9..0.6. * Dimensions are given in inches and millimeters. Inches are shown in black in bold face type. Millimeters are shown in blue in light face type. Stock sprockets are shown shaded. R The Gates Rubber Company