MY1

F1 -X L2 L1 50 50 50 L3 2040 40 40 30 30 30 Data 20 20 20 1.

Clamp Cylinder with Lock

Auto Switch l1 50 Safety distance (mm) 40 Operational range 30 l1 20 l1 Dangerous range 10 0 5000 10 15000 20 Welding current (A) l2 50 Safety distance (mm) 40 30 l2 l2 Operational range 20 10 0 5000 10 15000 20 Welding current (A) Back page 6 SMC'S GLOBAL MANUFACTURING, DISTRIBUTION AND SERVICE NETWORK EUROPE NORWAY SMC Pneumatics Norway A/S SINGAPORE SMC Pneumatics (S.E.A.)

CY1

Inclined operation (at right angle to direction of operation) Allowable load weight (WA)(kg) 8.

AC Servo Motor Driver LECYM/LECYU Series Compatible LEF  Position control, speed control and torque control Power supply voltage (V) LEJ can be used. 200 to 230 VAC 
Control encoder: Absolute 20-bit encoder LEL Motor capacity (W) (Resolution: 10485

Single phase 200 to 230 VAC, 50/60 Hz Connection terminal: L1, L2 Three phase 200 to 230 VAC, 50/60 Hz Connection terminal: L1, L2, L3 L2 L3 L1C Control power supply Connect the control power supply.

Air Slide Table Series MXP

Wa = 1 x 1.2 = 1.2 Wa = 1 x 1.2 = 1.2 Allowable load mass coefficient : Graph (1) Allowable load mass coefficient : Graph (1) = 1 = 1 Max. allowable load mass Wmax: Table (2) Max. allowable load mass Wmax: Table (2) Wmax = 1.2 1 = 0.2/1.2 = 0.17 Wmax = 1.2 1 = 0.2/1.2 = 0.17 1 = W/Wa 1 = W/Wa Find the load factor of the load mass 1. 3-2 Load Factor of Static Moment M = W x 9.8 (Ln + An)

Battery-less

L2 [mm] L2 [mm] L2 [mm] L2 [mm] 600 600 600 600 Y 400 400 400 400 Mer m 200 200 200 200 0 0 0 0 0 2 4 6 8 10 12 14 0 10 20 30 40 50 0 10 20 30 40 50 60 0 5 10 15 20 25 30 Work load [kg] Work load [kg] Work load [kg] Work load [kg] 2000 2000 2000 2000 Mep 1500 1500 1500 1500 L3 [mm] L3 [mm] L3 [mm] L3 [mm] m 1000 1000 1000 1000 L3 Z 500 500 500 500 0 0 0 0 0 5 10 15 20 25 30 0 2 4 6 8 10

Air Cylinder

Cushion needle (Width across flats 1.5) With air cushion With rod boot l WA WA 8 8 Width across flats B3 45 e JH JW f h Female rod end ZZ + Stroke 3.5 Port Integrated clevis (90)(V) Female thread MM Thread depth A1 H ZZ + Stroke * The dimensions are the same as those for the integrated clevis (E).

Electric Actuator

LECSB1: Single phase 100 to 120 VAC, 50/60 Hz Connection terminal: L1,L2 LECSB2: Single phase 200 to 230 VAC, 50/60 Hz Connection terminal: L1,L2 Three phase 200 to 230 VAC, 50/60 Hz Connection terminal: L1,L2,L3 Do not connect. L1 L2 L2 Main circuit power supply L3 L3 Regeneration converter N P1 P2 N DC reactor Connect between P1 and P2. (Connected at time of shipping.)

Precision Air Slide Table Series MXP ø6, ø10, ø12, ø16, (ø8: new addition, see 8-8-23 ) 1

As a guide, adjust it within the smaller range than the values of L2 dimension in Table (3). Turning the bottom screw is not allowed. Piston rod Table (2) MXP6 MXP10/12/16 L2 L2 L2 (mm) 10 (One side only) 10 (One side only) 9 8 8 8 8 8 Model MXP6-5C MXP6-10C MXP10-10C MXP10-20C MXP12-15C MXP12-25C MXP16-20C MXP16-30C Damage is not allowed. 3.

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[Bottom mounting] B Pin hole L2 Pin hole D-X B = (0.045 + L2 x 0.0016) [mm] 437 MGP Series High Precision Ball Bushing/MGPA Plate Displacement Amount (Reference Values) Load from lateral direction Displacement MGPA12 MGPA32, 40 0.8 0.4 Plate displacement amount [mm] Plate displacement amount [mm] MGPA12-250 MGPA -400 32 40 0.7 0.35 0.6 0.3 MGPA -300 32 40 MGPA12-150 MGPA12-100 MGPA12-75

Output Specification: RT (Switch output 1 + Switch output 2 + Analog voltage output), Units specification: M (SI units only), Piping Specification: 01 (R 1/8), Option 1: W (Lead Wire w/Connector, 2m Waterproof), Option 2: A (Bracket)

Slider Type/Ball Bushing Bearing

Review of bore size, stroke and L0 W > WA Calculate (WA) from the formula for the tentatively determined bore size F > FA W WA F FA Review with magnet holding force (H) Note 1) Yes Intermediate stop? Note 1) This cylinder cannot perform an intermediate stop using an air pressure circuit in vertical operation.

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Width across flats B1 MM [mm] Size B1 C1 H1 L1 L2 MM 25 22 20.5 8 36 23.5 M14 x 1.5 32 22 20.5 8 40 23.5 M14 x 1.5 63 27 26 11 72.4 39 M18 x 1.5 L1 L2 C1 H1 * The L1 measurement is when the unit is at the retracted stroke end position.

Air Slide Table

Wa = K Wmax Workpiece mounting coefficient K: Fig. (3) Allowable load weight coefficient : Graph (1) Max. allowable load weight Wmax: Table (2) 1 = W/Wa Wa = 1 x 1 x 4 = 4 K = 1 = 1 Wmax = 4 1 = 1/4 = 0.25 Load Factor of the Static Moment 3-2 Rolling Yawing Examine My. My = 1 x 9.8 (10 + 30)/1000 = 0.39 A3 = 30 May = 1 x 1 x 18 = 18 Mymax = 18 K = 1 = 1 2 = 0.39/18 = 0.022 Examine Mr.

MXS

Load rate Ea= K E max Ea=1 0.11=0.11 Work mounting coeficient K: Fig.3 Max. allowable kinetic energy Emax: Table 1 Kinetic energy (E)Allowable kinetic energy (Ea) Possible to use by E=0.0 3 3-1 Load rate of work Calculate static work Wa (N) Wa=1 X 1 X 4=4 K=1 b=1 Wmax=4 a1=1/4=0.25 Wa=K b Wmax Work mounting coeficient K: Fig.3 Allowable load coeficient b: Graph 1 Max.

MXQ

: Table (2) 1 = W/Wa Find the allowable load weight Wa (kg).

Air Slide Table Series MXS

(2) Find the allowable load mass Wa (kg).

Series MXP Precision Air Slide Table

Allowable kinetic energy E max. : Table 1 Possible to use by E=0.018Wa=W max. Calculate allowable load Wa(N). Wa=112=12 =1 W max.=12 1=2/12=0.167 Allowable load coefficient : Graph 1 Calcurate load rate (1) of moment.

MXS Series Air Slide Table

Allowable moment Wmax: Table 2 1=W/Wa Calculate static moment Wa(N) Wa=1 x 1 x 40=40 K=1 =1 Wmax=40 1=10/40=0.25 Calculate load rate 1 of static moment. 3-2 Load rate of static moment Rolling Yawing Calculate static moment M(Nm).

MXF

. (3) Allowable load weight coefficient : Graph (1) Wa = 1 x 1 x 4 = 4 K = 1 = 1 Wmax = 4 1 = 0.5/4 = 0.125 Find the allowable load weight Wa (kg).