MY1 Mechanically Jointed Rodless Cylinder

More documents

Recommendations

Info

Series MY1BBefore OperationMechanically Jointed Rodless CylinderBasic TypeSeries MY1B12Maximum Allowable Moment/Maximum Load WeightModelBore size Maximum allowable moment (N·m) Maximum load weight (kg)(mm) M1 M2 M3 m1 m2 m3101620250.82.55.0100.10.30.61.20.30.81.53.05.01521291.03.04.25.80.51.73.05.4MY1B3220 2.4 6.0 40 8.0 8.84040 4.8 12 53 10.6 14506380100781603156159.31937732348951870831201501416.6243020294260The above values are the maximum allowable values for moment and load. Refer to each graphregarding the maximum allowable moment and maximum allowable load for a particular piston speed.Caution on DesignWe recommend installing an external shock absorber when the cylinder is combined withanother guide (connection with floating bracket, etc.) and the maximum allowable load isexceeded, or when the operating speed is 1000 to 1500 mm/s for bore sizes ø16, ø50, ø63, ø80and ø100.Load weight (kg)m1Moment (N·m)F1L1M1 = F1 x L1F2L2m2M2 = F2 x L2F3L3m3M3 = F3 x L3Maximum Allowable MomentSelect the moment from within the rangeof operating limits shown in the graphs.Note that the maximum allowable loadvalue may sometimes be exceededeven within the operating limits shown inthe graphs. Therefore, also check theallowable load for the selectedconditions.Maximum Load WeightMY1B/M1Moment (N·m)5004003002001005040302010543210.50.40.30.20.1100 200 300 400500 1000 1500Piston speed (mm/s)MY1B16MY1B10MY1B100MY1B80MY1B63MY1B50MY1B40MY1B32MY1B25MY1B20MY1B16MY1B/M2Moment (N·m)5040302010543210.50.40.30.20.10.050.04MY1B160.030.02MY1B16MY1B10100 200 300400500 1000 1500Piston speed (mm/s)MY1B100MY1B80MY1B63MY1B50MY1B40MY1B32MY1B25MY1B20MY1B/M3Moment (N·m)2001005040302010543210.50.40.30.2MY1B100MY1B80MY1B63MY1B50MY1B40MY1B32MY1B25MY1B200.1MY1B160.06MY1B16MY1B10100 200 300400500 1000 1500Piston speed (mm/s)MXMTSMYCYMGCXD--X20-Data1. Maximum allowable load (1), static moment (2), and dynamic moment (3) (at the time of impact withstopper) must be examined for the selection calculations.∗ To evaluate, use υa (average speed) for (1) and (2), and υ (collision speed υ = 1.4 υa) for (3). Calculate mmaxfor (1) from the maximum allowable load graph (m1, m2, m3) and Mmax for (2) and (3) from the maximum allowablemoment graph (M1, M2, M3).Sum of guideload factorsΣα = + + ≤1Load weight [m]Maximum allowable load [mmax]Note 1) Moment caused by the load, etc., with cylinder in resting condition.Note 2) Moment caused by the impact load equivalent at the stroke end (at the time of impact with stopper).Note 3) Depending on the shape of the workpiece, multiple moments may occur. When this happens, the sum of theload factors (Σα) is the total of all such moments.2. Reference formula [Dynamic moment at impact]Use the following formulae to calculate dynamic moment when taking stopper impact intoconsideration.m: Load weight (kg)F: Load (N)FE: Load equivalent to impact (at impact with stopper) (N)υa: Average speed (mm/s)M: Static moment (N·m)Note 4)υ = 1.4υa (mm/s) FE = 1.4υa·δ·m·gNote 5)1∴ME = ·FE· L1 = = 4.57υaδmL,3Static moment [M] (1)Allowable static moment [Mmax]υ: Collision speed (mm/s)L1: Distance to the load , s center of gravity (m)ME:Dynamic moment (N·m)δDynamic moment [ME] (2)Allowable dynamic moment [MEmax]: Damper coefficientWith rubber bumper = 4/100(MY1B10, MY1H10)With air cushion = 1/100With shock absorber = 1/100g: Gravitational acceleration (9.8 m/s 2 )Note 4) 1.4υaδ is a dimensionless coefficient for calculating impact force.Note 5) Average load coefficient (= 13): This coefficient is for averaging the maximum load moment at the time ofstopper impact according to service life calculations.3. For detaild selection procedures, refer to pages 8-11-14 to 8-11-15.Select the load from within the range oflimits shown in the graphs. Note that themaximum allowable moment value maysometimes be exceeded even within theoperating limits shown in the graphs.Therefore, also check the allowablemoment for the selected conditions.L1υmFEMEMY1B/m1Load weight (kg)200100504030201054321100 200 300 400 500 1000 1500Piston speed (mm/s)MY1B16MY1B10MY1B100MY1B80MY1B63MY1B50MY1B40MY1B32MY1B25MY1B20MY1B16MY1B/m2Load weight (kg)302010543210.50.40.30.20.1100 200 300400500 1000 1500Piston speed (mm/s)MY1B16MY1B10MY1B100MY1B80MY1B63MY1B50MY1B40MY1B32MY1B25MY1B20MY1B16MY1B/m3Load weight (kg)5040302010543210.50.40.30.20.1 MY1B10100 200 300400500 1000 1500Piston speed (mm/s)MY1B100MY1B80MY1B63MY1B50MY1B40MY1B32MY1B25MY1B20MY1B168-11-128-11-13
Series MY1BModel SelectionFollowing are the steps for selecting the most suitable Series MY1B to your application.131. Operating ConditionsCylinder ······································· MY1B32-500Average operating speed υa ···· 300 mm/sMounting orientation ··················Horizontal mountingCushion ······································· Air cushion(δ = 1/100)Calculation of Guide Load FactorW: Workpiece (2 kg)1. HorizontalmountingxMounting Orientationzy2. Wallmounting yP. 8-11-6xzMY1B32-5003. CeilingmountingP. 8-11-55xzyx4. VerticalmountingzP. 8-11-82y2. Load BlockingFor actual examples of calculation for each orientation,refer to the pages above.YWeight and Center of Gravity for WorkpieceZ20XWorkpieceno.WWeightm2 kgX-axis20 mmCenter of gravityY-axis30 mmZ-axis50 mm50Y303. Calculation of Load Factor for Static Loadm1: Weightm1max (from (1) of graph MY1B/m1) = 27 (kg)················································m1Load factor α1 = m1/m1max = 2/27 = 0.07XM1: MomentM1max (from (2) of graph MY1B/M1) = 13 (N·m)············································································m1M1 = m1 x g x X = 2 x 9.8 x 20 x 10 –3 = 0.39 (N·m)Load factor α2 = M1/M1max = 0.39/13 = 0.03M1M2: MomentM2max (from (3) of graph MY1B/M2) = 1.6 (N·m)·········································································M3 = m1 x g x Y = 2 x 9.8 x 30 x 10 –3 = 0.59 (N·m)m1YLoad factor α3 = M2/M2max = 0.59/1.6 = 0.37M28-11-14
Page 4 and 5: Series MY1Model SelectionFollowing
Page 6 and 7: Series MY1Model SelectionFollowing
Page 8 and 9: Series MY18PrecautionsBe sure to re
Page 10 and 11: 8-11-1010
Page 14 and 15: Mechanically Jointed Rodless Cylind
Page 34 and 35: 34MY1MSeriesSlide Bearing Guide Typ
Page 36 and 37: Series MY1MModel SelectionFollowing
Page 40 and 41: Series MY1M40Theoretical Output(N)B
Page 42 and 43: Series MY1M42Cushion CapacityTighte
Page 44 and 45: Series MY1M44Standard Type/Centrali
Page 46 and 47: Series MY1M46Stroke Adjusting UnitW
Page 48 and 49: Series MY1M48Construction: ø16 to
Page 50 and 51: Series MY1CBefore OperationMechanic
Page 62 and 63:
Mechanically Jointed Rodless Cylind
Page 64 and 65:
64MY1HSeriesHigh Precision Guide Ty
Page 66 and 67:
Series MY1HModel SelectionFollowing
Page 68 and 69:
Page 70 and 71:
Series MY1H70Theoretical OutputBore
Page 72 and 73:
Series MY1H72With End LocksRecommen
Page 74 and 75:
Series MY1H74Cushion CapacityTighte
Page 76 and 77:
Series MY1H76Standard Type/Centrali
Page 78 and 79:
Series MY1H78Stroke Adjusting UnitW
Page 80 and 81:
Series MY1H80Side SupportSide suppo
Page 82 and 83:
Series MY1H82Construction: ø16 to
Page 84 and 85:
8-11-8884
Page 86 and 87:
Series MY1HTBefore OperationMechani
Page 88 and 89:
Page 90 and 91:
Page 92 and 93:
Page 94 and 95:
Page 96 and 97:
Series MY1Auto Switch96D-A90(V), D-
Page 98 and 99:
Auto Switch Series MY198Proper Auto
Page 100 and 101:
Auto Switch Series MY1100Proper Aut
show all

MY1 Mechanically Jointed Rodless Cylinder

Create successful ePaper yourself

Delete template?

Save as template?