Series VQ Base Mounted Metal Seal/Rubber Seal VQ1000 Series P.1.10-124 P.1.10-128 P.1.10-132 Plug-in Plug lead VQ2000 Series P.1.10-124 P.1.10-128 P.1.10-132 VQ0 Series P.1.10-170 P.1.10-174 VQ1000 Series P.1.10-170 P.1.10-174 P.742 1.10-114 Manifold Variations T L C S Port size SUP EXH port Cylinder port kit kit kit Lead wire Direct electrical entry style Serial transmission unit Terminal box (Terminal block) SY P, R A, B Enables single-wire
45 17.5 Up to 1000 35 27 11 75 134.5 56.5 20 14 16.5 23 63 18 32 20.7 90 12 9 123.5 1/4 119.5 68 45 22 Up to 1000 40 32 13 95 169 72 25 20 19 33 80 22 37 26 102 18 11.5 157 1/4 150 81 55 25 Up to 1000 40 41 16 114 189 89 30 20 19 37.5 100 26 37 26 116 20 17 177 1/4 170 96 Bore size (mm) T N P S V LD LH LS LT LX LY LZ K MM Q H VA W X Y ZZ J 34 32 1/8 27 154 6.5 7 30 198 3.2 32 57 50 6 M10
PI Control Level 1 P control 4 Switches the speed control from PI control to P control.
wire (NPN) 3-wire (PNP) P P A96V A96 s s s s 5V p P P F9NV F9N IC circuit 5V 12V p P P F9PV F9P s p P P 12V F9BV F9B 2-wire s Relay PLC Grommet Yes 24V s 3-wire (NPN) 3-wire (PNP) p P P F9NWV F9NW Diagnostic indication IC circuit 5V 12V p P P F9PWV F9PW 2-color display p P P F9BWV F9BW 2-wire 12V s Lead wire length symbols 0.5m/ Nil (Example) F9NW 3m/ L F9NWL 5m/ Z F9NWZ Solid state switches
) 10 100 Load weight (kg) 10 80 m 63 50 1000 40 32 10 100 100 1000 Speed (mm/s) Series CH2G, CH2H: Load weight for horizontal motion Speed chart (C-rod retraction, pressure 14MPa) 10 100 Load weight (kg) 10 80 63 50 m 1000 40 10 100 100 1000 Speed (mm/s) Series CH2G, CH2H: Load weight for horizontal motion Speed chart (extension, pressure 14MPa) 10 Load weight (kg) 100 10 80 63 m 50 1000
1000 1000 50 40 10 100 0.0 0.0 5.0 Axis 1 Absolute 50 50.00 1000 1000 0 0 10 100 0.0 0.0 0.5 2 Axis 2 Absolute 50 50.00 1000 1000 0 0 10 100 0.0 0.0 0.5 Axis 3 Absolute 50 50.00 1000 1000 0 0 10 100 0.0 0.0 0.5 Movement (ex.)
P.1729 P.1731 P.1732 P.1733 P.1738 P.1739 P.1742 P.1743 P.1744 P.1747 P.1748 P.1752 P.1755 P.1756 P.1760 P.1765 P.1766 P.1769 P.1770 P.1776 P.1781 P.1786 P.1794 P.1796 P.1801 P.1802 P.1803 P.1804 P.1806 P.1806 P.1807 P.1809 P.1817 P.1818 P.1819 P.1820 P.1822 P.1823 P.1829 P.1829 P.1830 P.1831 P.1832 P.1832 P.1833 P.1836 P.1838 P.1839 P.1839 P.1841 P.1844 P.1844 P.1845 P.1848 P.1849 P.1850
The PC or PLC...etc may not be able to monitor a brief change in the P-OT or N-OT signal to P-OT=1 or N-OT=1.
Position data Speed Dwell Auxiliary Model adaptive control 1 1000 1000 80 80 0 0 Speed control 2 2000 2000 100 100 0 0 3 4000 2000 70 60 500 1 4 500 2000 60 70 1000 1 5 2000 80 80 0 0 1000 6 2000 1000 80 80 0 0 Position 7 1000 1000 80 80 0 0 control 8 1000 1000 100 100 0 0 LEC-MR-J3BAT MR-J3BAT 1000 1000 100 100 0 0 (Note 3) CN4 255 2000 2000 80 80 0 0 Position Optional battery (for absolute
L X P Table displacement (m) Table displacement (m) LXPB-200 LXPB-200 1500 1500 LXPB-175 LXPB-175 1000 1000 LXPB-150 LXPB-150 LXPB-125 LXPB-125 LXPB-100 LXPB-100 500 500 LXPB-75 LXPB-75 LXPB-50 LXPB-50 0 Weight (kg) 0 Weight (kg) 1 2 3 4 5 6 1 2 3 4 5 6 Displacement at the section indicated by the arrow when a load is applied to this section with the slide table fully extended.
P.16 5. CN1P.17 PLC 6. CN4I/O P.20 4. P.16 6.4 I/O P.23 12. P.65 ONOFF 2.2 P.7 OFF OFF OFFLED ON STOP ON OFF 79 No.JXC-OMU0004-A 12. P.65 4. P.16 6.4 I/O P.23 3.4 P.14 3.1 P.11 CP.38 2.2 P.7 ALARM ON STOP ON OFF 10 ALARM ALARM ON ON 80 No.JXC-OMU0004-A 16.2 () 2.2 P.7 4.
VQ0 L VQ4 kit VQ5 VQZ VQD P. 2-4-146 P. 2-4-150 P. 2-4-154 Terminal block box L Enclosure IP65 compliant kit Enclosure IP65 compliant Enclosure IP65 compliant W type only P. 2-4-146 P. 2-4-150 P. 2-4-154 P. 2-4-158 C kit P. 2-4-196 P. 2-4-200 P. 2-4-204 Terminal block C kit P. 2-4-196 P. 2-4-200 P. 2-4-204 Terminal block 2-4-117 2-4-118 Cylinder Speed Chart Use as a guide for selection.
(factory-wired) When using a driver built-in regenerative resistor, connect P+ and D. (factory-wired) When using a regenerative option, disconnect P+ and D, and connect the regenerative option to P+ and C. P+/C/D Regenerative option Refer to section 11.2 for details. Symbol Connection target (application) Description Supply the following power to L11 and L21.
Display the error code on LCD. 3 1/2 digits (5 mm-size numerals) Overcurrent, Overpressure, Data error Pressure during 0 clear 0 to 60C (No dewing) 1000 Vp-p, Pulse width 1 s, Rise time 1 ns Between external terminals and housing 1000 VAC, 50/60 Hz for 1 min.
L X P Table displacement (m) Table displacement (m) LXPB-200 LXPB-200 1500 1500 LXPB-175 LXPB-175 1000 1000 LXPB-150 LXPB-150 LXPB-125 LXPB-125 LXPB-100 LXPB-100 500 500 LXPB-75 LXPB-75 LXPB-50 LXPB-50 0 Weight (kg) 0 Weight (kg) 1 2 3 4 5 6 1 2 3 4 5 6 Displacement at the section indicated by the arrow when a load is applied to this section with the slide table fully extended.
W V 2 E = () 2 1000 Note 2) Consider made-to-order products, depending on an operating condition. Determination of pressure (P) when making intermediate stop P Ps P > Ps (Refer to page 8-31-1.) Note 2) (For intermediate stops, refer to page 8-15-74.)
Standard Strokes CHM CHSm Bore size (mm) Standard strokes (mm) 40 50 63 80 100 125 160 25 to 1000 CH2m 25 to 1000 CHA 25 to 1000 25 to 1300 Related 25 to 1500 Equipment 50 to 1300 D-m 50 to 1500 Note) Refer to the stroke selection Table in Technical Data 2, starting with pages 153 and 154 to determine stroke limitation depending on the type of mounting brackets that will be used.
P P1 or Step 2 Step 3 Model selection based on corrected outlet flow rate HA Review operating conditions or increase size. YES In the case of IDG30 and IDG30M (with the element in the initial state), P P1, therefore proceed to Step 7 .
P L I C A B L E A U T O S W I T C H E S See Accessories Section Cushion Stroke (mm) 12 15 15 19 24 30 37 Stroke Tolerance (mm) 1000 +1.8 2700 +1.8 2701 ~ 5000 +2.8 P I P I N G ...
V: Power supply voltage Power consumption P: 1000 [W] Q = P = 1000 [W] P Cooling capacity = Considering a safety factor of 20%, Power consumption 1000 [W] x 1.2 = 1200 [W] e Derive the heat generation amount from the output. w Derive the heat generation amount from the power supply output. Output (shaft power, etc.)