RSH/RS1H G D A Q Rear pressure port Front pressure port B WB W (width across corners I) E (mm) Bore size (mm) N CD CT CZ D E FT FX FZ G H I L O P Q R B A Stroke 50 30 225.5 103.5 20 8 35.5 32 64 20 73 93 16 122 85 44 9 1/8 10 36 14 depth 5 63 246 106 20 10 44.5 40 77 25 90 114 24 140 103 53 11 1/4 12.5 43 30 18 depth 6 80 299.5 135 25 10 44.5 50 98 25 110 138 28 164.5 132 54 13 1/4 12.5 49 40 20 depth
RE A B 0.2 53 REC 67 CX CY MQQ M RHC 4-6.6 through 8-11 depth of recessed area 5 Load carrying direction MK(2) 12 3 RS Q G 28 13 6 10.3 6 RS H A RZQ 12 Conveyor lower limit position MI W S 1 3 R25 CEP1 CE1 Stroke 73 87 CE2 2-P 20 ML2B C J G5-S 16 8 160 CV MVGQ Rear pressure port 16 CC Front pressure port RB J D-X 6.5 23 14 2-Plug 46 2051.5 (Width across corners 62) Data P (Piping port) TN
G RS H A RZQ Rc 1/8 P port MI W S CEP1 CE1 CE2 Rc 1/8 R port C + Stroke B + Stroke A + Stroke ML2B C J G5-S MVGQM, MVGQL Common Dimensions CV Applicable solenoid valve B C DA F G H J K L MM ML NN PW Q R S T V W X YY YL Z Bore size (mm) Standard stroke (mm) MVGQ 40 124 38 M8 x 1.25 20 M8 x 1.25 27 30 106 48 122 10 110 M8 x 1.25 11 17 25 90 26 54 44 16 8 51 CC 25, 50, 75, 100, Series VZ5000
In this way fine pressure variations are detected by the nozzle/flapper type pilot mechanism, and precise pressure adjustment is performed. q i o !4 !5 o SUP side passage OUT side passage SUP side passage !5 OUT side passage IN q IN q w y Bleed Bleed !1 !3 !2 e w r Exhaust SUP(1) OUT(2) SUP(1) OUT(2) u !0 !2 !
Body type Rc 1 8 Plug-in type VVZS3000-P-01-1 Non plug-in type VVZS3000-P-01-2 Rc 1 4 VVZS3000-P-02-1 VVZS3000-P-02-2 Body type Plug-in type AXT625-12A Non plug-in type Part no. Part no. Body type Plug-in type VVZS3000-22A-1 Non plug-in type VVZS3000-22A-2 Part no.
It is calculated using the following formula. r Av = Q (8) P Av : Flow coefficient [m2] Q : Flow rate [m3/s] DP : Pressure difference [Pa] r : Density of fluid [kg/m3] (3) Formula of flow rate It is described by practical units. Also, the flow rate characteristics are shown in Graph (2).
Power consumption P: 1000 [W] Q = P = 1000 [W] Cooling capacity = Considering a safety factor of 20%, 1000 [W] x 1.2 = 1200 [W] V: Power supply voltage HRSH 090 P HRSH Power consumption HRSE HRSE e Derive the heat generation amount from the output. Output (shaft power etc.) W: 800 [W] w Derive the heat generation amount from the power supply output.
3 y o q u e !0 w Component Parts No. q w e r t y u Description Material Description Material No. CG5SR CG5SV Rod cover Stainless steel 304 Water resistant scraper Head cover Stainless steel 304 i Rod seal Cylinder tube Stainless steel 304 o NBR FKM Piston seal Piston rod Stainless steel 304 !0 Valve seal Bumper Urethane !1 Valve retainer gasket Rod end nut Stainless steel 304 !
3 y o q u e !0 w Component Parts No. q w e r t y u Description Material Description Material No. CG5SR CG5SV Rod cover Stainless steel 304 Water resistant scraper Head cover Stainless steel 304 i Rod seal Cylinder tube Stainless steel 304 o NBR FKM Piston seal Piston rod Stainless steel 304 !0 Valve seal Bumper Urethane !1 Valve retainer gasket Rod end nut Stainless steel 304 !
152 198 312 NX 5.8 8.5 10.5 PA 40 60 100 PB 43 67 77 PG 4 6 9 PP 5.3 8 16 P M5 x 0.8 1/8 1/4 "P" indicates cylinder supply ports.
Confirmation of allowable lateral load From the graph, the allowable lateral load at L = 50 mm and P = 0.4 MPa is 18 N. Because 2.1 N < 18 N, it is applicable. 30 20 D2. Confirmation of allowable lateral load In the same way, the lateral load at L = 50 mm and P = 0.4 MPa is 48 N from the graph.
Operation conditions Operation conditions Point of application L Operating pressure P (MPa) Operating pressure P (MPa) Workpiece weight m (Kg) Workpiece weight m (Kg) Workpiece quantity x (Qty.) Workpiece quantity x (Qty.)
Union "Y": KPU 3-Applicable tubing D Effective area mm Note 1) D Model L1 TPH TPS P Applicable tubing O.D. mm Weight g L2 Q M P M M A 10.4 38.8 20.6 10.4 9.7 4 4 7 18 KPU04-00 4 12.8 42.1 22.8 12.8 11.7 10 10 10 19.5 KPU06-00 6 8 15.2 48.7 27.5 15.2 13.7 26 18 17 21.5 KPU08-00 8 4.2 M 18.5 54 30.7 18.5 16.1 24 41 29 26 KPU10-00 10 20.9 57.2 32.9 20.9 18.1 58 46 32 25 KPU12-00 12 Q Note 1)
q e r q e r q e r q e r w w w w 125 Process Gas Equipment / Diaphragm Valve Specific Product Precautions Be sure to read before handling.
Tightening torque for piping Body class Torque (Nm) 2 3 4 5 6 1.5 to 2.0 3.0 to 3.5 7.5 to 9.0 11.0 to 13.0 5.5 to 6.0 17-5-66 5 Series LVQ Integral Fitting Type (Hyper Fittings) Construction Double acting type N.O. type Basic type N.C. type PB PB q q q VC PA PA VDW e e e VQ VX2 A B A B SMC SMC VX A A B A B B Courtesy of Steven Engineering, Inc.-230 Ryan Way, South San Francisco, CA 94080
Approx. 300 F D Approx. 280 D Q F C G (PF) 1/2 C R R E E B A H 2-P Port size 2-P A B H 2-M Port size 2-M Thread depth N L L K K Conduit terminal: T F (Q) 34 25 U R C G (PF) 1/2 E B A H D 2-P Port size (S) 2-M L K N.C.
8 @0 @0 @2 q w r @5 y !5 !6 i q w r @5 y !5 !
Ryan Way, South San Francisco, CA 94080-6370-Main Office: (650) 588-9200-Outside Local Area: (800) 258-9200-www.stevenengineering.com YW QW NW PB PD Q + Stroke PG (2-JJ counterbore, thread depth from bottom KK) Floating bracket mounting thread PC LW 2-P 2-T counterbore depth E H NE NH C NG HG G UU TT A N 2 x 2-P Z + Stroke (Hexagon socket head taper plug) (mm) MM M4 x 0.7 Model MY3A16 MY3A25