LEC-T1_C LEC-OM08003 // LEC-T1 Series LEC6 LECPA TB Ver2.1 .5 .7 1. .9 1.1 .9 1.9 2.10 1.2 .11 1.11 2. .12 3. .13 3.1 .13 (1).13 (2)Tree .13 3. .14 (1).14 (2)Tree .15 4.16 5. .17 5.1 .18 5.2 .19 (1).19 (2).19 5.3 .20 (1).21 (1-1) LECPLECA 22 (2) .23 (2-1) LECPLECA 23 (2-1-a) TB Ver1.**. 23 (2-1-b) TB Ver2.**. 25 (2-2) LECPLECA 27 (2-2-a) TB Ver1.**. 27 (2-2-b) TB Ver2.**. 29 (2-3) LECPLECA .32 1
Type Model Features Electricalentry (Fetching direction) D-90 D-90A Grommet (In-line) Grommet (In-line) Reed switch Without indicator light, Parallel cord Without indicator light, Cabtire cord 6-2-9 4 Series CJP Construction CJPB6 CJPB10 CJPB15 CJP 6 to 15 (Construction is the same as CJPB 6 to 15.)
Type Model Features Electricalentry (Fetching direction) D-90 D-90A Grommet (In-line) Grommet (In-line) Reed switch Without indicator light, Parallel cord Without indicator light, Cabtire cord 6-2-9 4 Series CJP Construction CJPB6 CJPB10 CJPB15 CJP 6 to 15 (Construction is the same as CJPB 6 to 15.)
9 y !7 q e @0 !0 o @2 @3 !5 u t !8 @1 r @4 w MX MTS MY 12 to 40 CY @7 !1 !7 q !6 !0 @2 @3 o @4 @6 y e r !
Intersection point 2 is obtained. 3000 4000 5000 3000 4000 5000 3.Extend the intersection point 2 rightward or leftward. A Q value of approximately 620 Nl/min is obtained. 1500 2000 1500 2000 4.The 620 Nl/min.theoretical value is multiplied by 1.4 Q = 620 Nl/min. 1.4 Q = 870 Nl/min. 160 1000 1000 Maximum air consumption Q [Nl/min.]
Principles . 7 2 Chapter 8 Specification for Option C 8 1 Specifications . 8 1 8 2 Precautions for the installation and handling of the product . 8 1 Chapter 9 Specification for Option K 9 1 Safety instructions . 9 1 9 2 Specifications . 9 1 Chapter 10 Specification for Option L 10 1 Safety instructions . 10 1 10 2 Specification . 10 1 10 3 Installation of heavy duty auto drain . 10 2 10
9 !1 u !8 !2 @1 Section AA Parts list Material Note No. Description No.
Use the manifold specification sheet to specify. 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 SI unit output no. SI unit output no.
Figures in body of chart are suggested minimum rod diameters Exposed Length of Piston Rod (IN) Tons 10 20 40 60 70 80 100 120 1/2 3/4 1 3/4 13/16 1-1/16 1 5/8 7/8 1-1/8 1-1/4 1-3/8 1-1/2 11/16 15/16 1-3/16 1-3/8 1-1/2 2 3/4 1 1-1/4 1-7/16 1-9/16 1-3/16 3 13/16 7/8 1-1/8 1-3/8 1-9/16 1-5/8 1-7/8 4 15/16 1 1-3/16 1-1/2 1-5/8 1-3/4 2 2-1/4 5 1 1-1/8 1-5/16 1-9/16 1-3/4 1-7/8 2-1/8 2-3/8 7-1/
Figures in body of chart are suggested minimum rod diameters Exposed Length of Piston Rod (IN) Tons 10 20 40 60 70 80 100 120 1/2 3/4 1 3/4 13/16 1-1/16 1 5/8 7/8 1-1/8 1-1/4 1-3/8 1-1/2 11/16 15/16 1-3/16 1-3/8 1-1/2 2 3/4 1 1-1/4 1-7/16 1-9/16 1-3/16 3 13/16 7/8 1-1/8 1-3/8 1-9/16 1-5/8 1-7/8 4 15/16 1 1-3/16 1-1/2 1-5/8 1-3/4 2 2-1/4 5 1 1-1/8 1-5/16 1-9/16 1-3/4 1-7/8 2-1/8 2-3/8 7-1/
for the installation and handling of the product . 8 1 8 2 Specifications . 8 1 Chapter 9 Specification for Option K 9 1 Safety instructions . 9 1 9 2 Specifications . 9 1 Chapter 10 Specification for Option L 10 1 Safety instructions . 10 1 10 2 Specification. 10 1 10 3 Specification of heavy duty auto drain (ADH4000-04). . 10 2 10 4 Installation of heavy duty auto drain . 10 2 10 5 Maintenance
The mounting direction is shown in the diagram below. Mount the solenoid so that it will be on the same side as the single solenoid of the Series VZ3000. 2(A) port of 3 port valve should be 2(B) port of manifold base.
Load Load Switch 1 Switch 1 Blue [Black] Blue [Black] Brown [Red] Brown [Red] Switch 2 Switch 2 Blue [Black] Blue [Black] Power supply voltage Residual voltage leakage current load impedance Load voltage at OFF = x 2 pcs. x Load voltage at ON = x 2 pcs. = 1mA x 2 pcs. x 3k = 6V = 24V 4V x 2 pcs. = 16V Example: Power supply is 24VDC Voltage decline in switch is 4V Example: Load impedance
Load Load Switch 1 Switch 1 Blue [Black] Blue [Black] Brown [Red] Brown [Red] Switch 2 Switch 2 Blue [Black] Blue [Black] Power supply voltage Residual voltage Leakage current Load impedance Load voltage at OFF = x 2 pcs. x Load voltage at ON = x 2 pcs. = 1mA x 2 pcs. x 3k = 6V = 24V 4V x 2 pcs. = 16V Example: Power supply is 24VDC Voltage decline in switch is 4V Example: Load impedance
-2-9-1A ** XLD100-2-9-1A ** XLD160-2-9-1A ** Assy (4) Initial pumping Standard AS568-020V valve seal (5).
2 !4 q !6 y @3 r !0 o @4 t !0 @4 @1 i e @2 o e @2 !3 i !3 @0 !5 !9 !9 !5 63 or more 12 to 25 50 stroke or less 12 to 25 Over 50 stroke 50 or more Component Parts Component Parts No. Description Material Note Ball bushing Spacer Steel ball Plug Piston seal Rod seal Gasket A Gasket B No.
Rc G NPT Combination with Made to Order is not available. Nil -XF Mounting style -XN B L Basic style Flange style Number of auto switches S Nil 1 pc. Refer to Table (1) below if only foot assembly is required separately. 2 pcs. S (1 auto switch) is shipped with a righthand auto switch. Nil (2 auto switches) is shipped with a right-hand and a left-hand switch.
(4.5) -1.5 (1) -3.5 (-1) -3 (-0.5) -5.5 (-3) -8.5 (-6.5) 4.5 4 7.5 9.5 9 11.5 14.5 3.5 3 6.5 8.5 8 10.5 13.5 0 0 3.5 5.5 5 7.5 10.5 5.5 6 10 11 12 16 14 4.5 5 9 10 11 15 13 1.5 2 6 7 8 12 10 Data Bore size (mm) The dimension inside ( ) is for D-A93.
Load Switch 1 Switch 1 Blue Blue Brown Brown Switch 2 Switch 2 Blue Blue Load voltage at OFF = Leakage current x 2 pcs. x Load impedance = 1 mA x 2 pcs. x 3 k = 6 V Example: Load impedance is 3 k. Leakage current from switch is 1 mA. Power supply Residual Load voltage at ON = voltage voltage x 2 pcs. = 24 V 4 V x 2 pcs. = 16 V Example: Power supply is 24 VDC.
is for 50 to 75 and 100mm stokes, and the bottom dimension is for 125, 150, 175, and 200mm strokes. 40.5 With brake 12 6 3.5 2 1 5 Section F detail (Scale: 2/1) 78 88 Stroke + 216 (Stroke: 50 to 100) Stroke + 233 (Stroke: 125 to 200) Without brake The dimension inside [ ] shows the location at which the home position switch operates. 9 Section F 10 [16.5] 7.5 10 4-M6 x 1 21.5 4-M6 x 1 depth