HRX-OM-X084 Description Qty Applicable model Anti-quake bracket A Anti-quake bracket B 2 2 4 4 HRR010-A/W-10/20-Y HRR012/018-A/W-10/20-Y HRR-TK001 Nut (M8) HRR024/030-A/W-20-Y Bolt (M8) HRR050-A/W-20-Y Mounting of anti-quake bracket 1. Remove the cap from M8 stud bolt. (4pcs) 2. Mount the anti-quake bracket A. (Recommended torque : 12.5Nm) 3. Mount the anti-quake bracket B.
3 b b Nm a Nm 1 2 4 XLD-25 1.5 0.3 -40 2.5 -50 6 -63 6 -80 15 -100 20 -160 102 a M M0.2MPa b b O a 19 XL-OMY0002 Revision history 4-14-1, Sotokanda, Chiyoda-ku, Tokyo 101-0021 JAPAN Tel: + 81 3 5207 8249 Fax: +81 3 5298 5362 URL https://www.smcworld.com Note: Specifications are subject to change without prior notice and any obligation on the part of the manufacturer. 2020 SMC Corporation
fluid power -General rules relating to systems IEC 60204-1: Safety of machinery -Electrical equipment of machines (Part 1: General requirements) ISO 10218-1992: Manipulating industrial robots-Safety JIS B 8370: JIS B 8361: JIS B 9960-1: -1) JIS B 8433-1993: *2) 1. 2. 3. 1. 2. 3. 4. 3 A / 1 1.5 *3) *3)1 1 () 4 IP8000ExdBT5 1. 1 IP8000 IP8100 420mADC()*1 23515(420mADC) 0.140.7MPa
Position loop P constant A 140 110 110 1 to 200 B 100 80 80 C 110 80 80 H 80 140 140 Sets the speed loop P constant. *Please perform the actuator operation after changing this parameter setting under the responsibility of the user. Speed loop P constant A 110 140 140 1 to 200 B 120 75 100 C 150 120 120 H 50 80 80 Sets the speed loop I constant.
8370: JIS B 8361: JIS B 9960-1: 1 ) JIS B 8433: *2) 1. 2. 3. 1. 2. 3. 4. 4 - LEC-G Series/ 1 / 1 1.5 5 - 2 21 GWProfibus 1 5 LEC 22 DIN D DIN PR1 Profibus DP V1 G 6 - 23 PLC LEC-T1-3G Profibus (LEC-W2) LEC-GPR1 LEC RS485 Modbus ...
8370: Pneumatic fluid power General rules relating to systems JIS B 8361: Hydraulic fluid power General rules relating to systems JIS B 9960-1: Safety of machinery Electrical equipments of machines (Part 1: General requirements) JIS B 8433-1993: Manipulating industrial robots Safety, etc/ *2) Labor Safety and Sanitation Law, etc.
. 2018 SMC Corporation All Rights Reserved VT317-OMH0002-B
Latching Operation Indicator light A-C ON (Set) Generates vacuum Orange B-C ON (Reset) Stops generation of vacuum Green N.C.
On B side SY3000-37-80A-7 On A side 1 to 8stations SY3000-37-80A-3 On B side SY3000-37-80A-10 On A side 9 to 12stations SY3000-37-80A-6 On B side SS5YJ7-21,41SA SY3000-37-80A-12 On A side 13to16stations SY3000-37-80A-9 On B side Note 1) The above is for station addition or maintenance.
Bore size(mm) Auto switch model 20 50 40 32 25 D-M9(V) D-M9W(V) D-A9(V) Note 1) Note 1) Note 1) Note 1) Note 1) BMA3-020 BMA3-025 BMA3-032 BMA3-040 BMA3-050 (A set of a,b,c,d) (A set of a,b,c,d) (A set of a,b,c,d) (A set of a,b,c,d) (A set of a,b,c,d) Note 2) D-M9A(V) BMA3-020S BMA3-025S BMA3-032S BMA3-040S BMA3-050S (A set of b,c,d,e) (A set of b,c,d,e) (A set of b,c,d,e) (A set of b,c,d
on the part of the manufacturer. 2008 SMC Corporation All Rights Reserved VG300-OMH0002-B
Find the moment of inertia I for the rotation of shaft (B). B 2. I is converted to the rotation of the shaft (A). B 2 r I = m2 2 b a I I = A B Number of teeth=b 5. Solid sphere Position of rotational axis: Through the center of diameter 2 2 r I = m5 27 - Kinetic energy Table (9) shows the allowable kinetic energy of the rotary actuator. The end angular speed is obtained by: Table 9.
The set values for OUT1 are displayed in auto-preset mode as follows: Normal output Reversed output P_1 = A-(A-B)/4 n_1 = B+(A-B)/4 A = Max. pressure H_1 = (A-B)/2 H_1 = (A-B)/2 B = Min. pressure The set values of OUT2 become as follows "_", i.e. "P_2", "n_2", "H_2".
A Hs 32 to 63 D-P3DWA B A Hs Auto Switch Proper Mounting Position Auto Switch Mounting Height (mm) (mm) D-M9 D-M9V D-M9W D-M9WV D-M9A D-M9AV Auto switch model Auto switch model D-A9V D-P3DWA D-M9V D-M9WV D-M9AV D-A9 D-A9V D-P3DWA Bore size (mm) Bore size (mm) B 11 12.5 13 15 16 20 A 11 10.5 12 14 13.5 16.5 B 7 8.5 9 11 12 16 A 6 7.5 9.5 9 12 B 8 8.5 10.5 11.5 15.5 Hs 24.5 26 29 33 38.5
Operating equipment: MHC2-6D A part a b c d e f = 20 (mm) = 3 (mm) = 4 (mm) = 4 (mm) = 5 (mm) = 6 (mm) b c a e B part f d z f1 x.Calculate the inertial moment of the attachment. Assuming the attachment material is aluminium alloy (relative density=2.7), r1= 16.4 (mm).
The most suitable piping position can be selected by choosing each 1 port from A, B, C and combining them.
The most suitable piping position can be selected by choosing each 1 port from A, B, C and combining them.
(Except cushion seal) Cushion ring B Rolled steel Zinc chromated Cushion valve Rolled steel Electroless nickel plated Rod seal SKY-36 SKY-36 SKY-40 @5 @6 NBR Spacer A Rolled steel Zinc chromated Piston seal RPS-125 RPS-140 RPS-160 Spacer B Rolled steel Zinc chromated Replacement Parts (Seal kits) Air releasing valve B Rolled steel Zinc chromated Air releasing valve A Chrome-molybdenum steel
Operating equipment: MHC2-6D A part a b c d e f = 20 (mm) = 3 (mm) = 4 (mm) = 4 (mm) = 5 (mm) = 6 (mm) b c a Courtesy of Steven Engineering, Inc.-230 Ryan Way, South San Francisco, CA 94080-6370-Main Office: (650) 588-9200-Outside Local Area: (800) 258-9200-www.stevenengineering.com e B part f d z f1 x.Calculate the inertial moment of the attachment.
Temperature Data A or B = Series IDUS: Data A Series IDFS: Data B Air pressure Data C = 2 Calculate corrected air flow by using A or B and C. Corrected air flow = (Air flow) (Data A x Data C) Corrected air flow = (Air flow) (Data B x Data C) 3 Select a model having an air flow capacity that is higher than the corrected air flow.