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ORIGA Shock Absorbers PDF

57 Pages·2004·2.01 MB·English
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LINEAR DECELERATION Shock Absorbers Table of Contents Industrial Shock Absorber Data Sheet No. Technical informations 1.70.001E Survey 1.70.001-13E Non-Adjustable Shock Absorber Type SA 10, SA 10S 1.70.002E Type SA 12 1.70.003E Type SA 14, SA 14S, SA 14S2 1.70.004E Type SA 20, SA 20S, SA 20S2 1.70.005E Type SA 20x25, SA 20Sx25, SA 20S2x25 1.70.005E Type SAI 25, SAI 25S, 1.70.006E Type SA 33, SA 33S, SA 33S2, SA 33S3 1.70.007E Type SA 45, SA 45S, SA 45S2, SA 45S3 1.70.008E Type SA 64, SA 64S, SA 64 S2, SA64S3 1.70.009E Adjustable Shock Absorber Type SA 1/4 x 1/2 1.70.100E Type SA 3/8 x 1D 1.70.101E Type SA 1/2 x 1M, SA 1/2 x 2M 1.70.102E Type SA 1/4 x 1, SA 1/4 x 2 1.70.103E Type SA 3/4 x 1, SA 3/4 x 2, SA 3/4 x 3 1.70.104E Type SA 1 1/8 x 2, SA 1 1/8 x 4 1.70.105E Type SA -A 3/4 x 1, SA 3/4 x 2, SA 3/4 x 3 1.70.106E Type SA-A 1 1/8 x 2, SA -A 1 1/8 x 4 1.70.107E SA -A 1 1/8 x 6 Data Sheet No. 1.70.000E-1 LINEAR DECELRATION Industrial Shock Absorbers Adjustable Non-adjustable SMOOTH, CONTROLLED STOPPING A WIDE RANGE OF APPLICATIONS The System Operation Concept OF MOVING LOADS High-pressure hardened HOERBIGER-ORIGA shock absorbers prevent damage to moving parts steel metering tubes – knife-edge orifices for high and to machines and plant: flow efficiency – no readjustment if fluid destructive impact forces are absorbed by controlled linear deceleration. High-pressure metallic temperature changes piston ring Easy replacement of seals on site Adjustor provides settings from "hard" to "soft" and back to "hard" in one turn (360°) Ball-type check valve HOERBIGER-ORIGA reduced while kinetic energy HOERBIGER-ORIGA shock the shortest distance, in the for positive closure SHOCK ABSORBERS levels are dramatically in- absorbers convert the kinetic shortest time and without LET YOU creased. These again have energy generated by the de- sudden peak loads during Extra-long rod bearing for high ■ increase operating to be dissipated in a control- celeration of the load into the stroke. side forces and maximum life led manner. thermal energy. speeds ■ increase operating loads Some commonly used stop- Optimum operating condi- Corrosion-resistant ■ increase system ping devices such as tions are achieved if the return spring as standard energy is dissipated almost performance springs, rubber buffers or ■ increase operating dashpots actually increase uniformly, i.e. if the moving Hardened button mass is brought to a halt in – optional soft pad available reliability shock loading instead of for low-noise, scratch-free ■ reduce stresses on reducing it – they do not operation equipment dissipate energy at a uniform ■ reduce production rate. Viton version also available costs For smooth dissipation of the ■ reduce noise levels kinetic energy we recom- Oil return passages mend the use of hydraulic Wrench flats for easy Precision surfaces guarantee installation shock absorbers. optimum function Hardened steel metering Closed-cell accumulator tube has knife-edge orifices sponge All moving parts in a produc- for high flow efficiency Extra long rod Thread at both ends tion process have to be stop- bearing for high for mounting Precision surfaces ped without damage to them- Full-length body thread smidaex imfourcme sli faend Closed-cell accumulator sponge versatility guarantee optimum function selves or to the stopping – maximum mounting – The oil forced through the devices of the machines and versatility metering holes compresses the – metric or American sponge. Large-diameter hardened Corrosion-resistant body plant. thread – When the piston rod is unloaded and chromium-plated The high impact forces have the sponge expands and forces piston rod for high force Precision-machined shoulders to be reduced in a controlled the oil back into the bore, while absorption for accurate positioning and manner: to bring a moving Strong return spring the spring returns the piston to easy rotation for access to the for shortest cycle times its starting position. adjustor load to a standstill, the kinetic energy generated by the movement has to be dissi- Floating piston head with pated. built-in check valve for The heavier the moving load oil flow control during operation and the faster it moves, the higher the kinetic energy. Large-diameter hardened and chromium-plated In automation especially, piston rod for high force shorter and shorter cycle absorption Simplify your design work by Piston rod seal installing our shock absorber times are demanded, so that dimensions on your system. stopping times are greatly Stop collar The file is compatible with all –prevents "bottoming out" popular CAD systems. at end of stroke Data Sheet No. 1.70.001E-2 Data Sheet No. 1.70.001E-3 ABSORBING SHOCKS Shock Absorption Ordinary shock absorbers, The Force/Stroke Diagram Hydraulic dashpot springs, buffers and pneu- clearly shows these effects. Force (N) matic cushioning cannot The shock absorber curve is match the performance of ideal because all the energy Industrial shock absorber HOERBIGER-ORIGA shock is dissipated by linear dece- absorbers. leration without initial impact These shock absorbers or final rebound. Pneumatic match the speed and mass end cushioning of the moving object and Spring bring it smoothly and uni- formly to rest. Springs and buffers, on the other hand, store energy rat- her than dissipate it. Although the moving object is stopped, it bounces back and this leads to fatigue in materials and components which can cause premature breakdown of the machine. Pneumatic cushioning provides a better solution Stroke (s) because the energy is actually converted, but because of the compressibi- Stopping Time lity of air the maximum bra- Both damping units stop the king force is generated at the V (m/s) same mass from the same end of the stroke, which can speed with the same stroke. lead to excessive loads on Therefore they do the same components. work but the industrial shock absorber reduces the Hydraulic dashpot Hydraulic dashpots also stopping time by 60 to 70 %. t cause excessive loads because peak resistance Industrial comes at the beginning of shock absorber the stroke and then quickly t falls away. This generates unnecessarily high braking forces. Stopping time (t) Data Sheet No. 1.70.001E-4 SELECTION OF SHOCK ABSORBER TYPE Selection HOERBIGER-ORIGA shock absorbers are available in two main types, to suit different applications and installation requirements. After selection of the appropriate type, sizing is determined by calculation. COMPACT SERIES WITH in many different ways, e.g. ACCUMULATORS OPTIONS FULL-LENGTH BODY in a tapped blind hole, in a Normally shock absorbers (cid:127) Stop collars for front or THREAD tapped through-hole, in a with internal accumulators rear mounting – these clearance hole in a flange or This compact, space-saving are used. This simplifies provide a positive stop to bracket, etc. series is available in adju- installation by eliminating prevent damage caused stable and non-adjustable external piping and oil by the piston "bottoming versions and can be installed storage. out". However, in applications with They also allow precise short cycle times and high setting of the stroke kinetic energy the oil can length. become overheated. In this (cid:127) Soft pad for the hardened case an external steel button – to avoid accumulator should be used surface damage and so that the oil can be cooled reduce noise levels. in the external circuit. SHOCK ABSORBER UNIVERSAL SERIES It is especially suited to RETURN STROKE applications which require This versatile, adjustable several of the same shock (cid:127) Piston rod with return series with various mounting absorbers with the same spring combined with accessories is designed to stroke length. internal accumulator stop heavier loads. (cid:127) Return stroke actuated by compressed air or mechanically, combined with external accumulator. With this version a delayed return stroke is also possible. MOUNTING METHODS can be either built into machines or supplied as HOERBIGER-ORIGA shock accessories. absorbers are designed for a variety of mountings, which (cid:1)(cid:2)(cid:3) Data Sheet No. 1.70.001E-5 THE SELECTION OF SHOCK ABSORBERS Selection CORRECT CHOICE OF ACCUMULATORS Note: HOERBIGER-ORIGA SA-A SHOCK ABSORBER ■Internal accumulator The tank should always be Series shock absorbers The type of shock absorber The fluid displaced by the installed higher than the feature steplessly adjustable and its mounting method are piston compresses a shock absorber and the stroke, time-delay damping mainly determined by the nitrogen-filled, closed-cell connecting pipework should and adjustable rod return application. sponge. be as short as possible. forces. In most applications, shock When the piston is If possible there should also The SA Series is fitted with absorbers with internal unloaded the return spring be a 10 µm filter between the return springs as standard. If accumulators are preferred pushes the piston back to two units. these types are used with an to those with external its rest position. At the If the tank is installed further external accumulator for accumulators. same time the away from the shock absor- better heat dissipation, this Shock absorbers with compressed sponge ber there must be a positive does not need to be internal accumulators are expands and forces the oil circulation system (see pressurized because the supplied prefilled with oil and fluid back into the high diagram) to ensure that the spring returns the rod. therefore ready for immedi- pressure chamber. oil actually flows through the tank and is cooled down. ate use, where as shock ■External accumulator absorbers with external The use of external PISTON ROD RETURN accumulators require additio- accumulators is nal equipment, resulting in recommended where high Piston rod return is actuated higher installation costs. energy conversion is by needed or excess heat ■Return springs SELECTION CRITERIA dissipation is required, In the self-contained units, ■Type of shock absorber e.g. in applications with a built-in spring returns – with internal short cycle times or in the piston rod to its rest accumulator high temperature areas. position when it is unloaded. – with external The external accumulator, accumulator including consisting of an open or ■Air/Oil air/oil tank closed tank, is connected In units with external ■Type of piston rod return to the shock absorber by accumulators an air/oil – return spring pipework. system or a mechanical – air or mechanical The oil heated in the device is used for piston ■Stroke length shock absorber circulates rod return. Use the longest stroke between the tank and the ■Mechanical units possible taking any side shock absorber and is Mechanical rod return is loads into account. therefore continuously mostly used in types with – maximum impact force cooled during operation. a clevis mounting, with reduction actuation by another unit via levers. Data Sheet No. 1.70.001E-6 CALCULATIONS FOR SHOCK ABSORBER Calculations SELECTION SELECTION FACTORS EFFECTIVE MASS velocities are very high or The higher the Effective ■How much energy has to Effective Mass is a very very low. Mass, the higher the impact force at the end of the shock be dissipated during each important factor in correctly As a general rule, the next absorber stroke, whereas deceleration stroke (cycle) sizing a shock absorber. larger size of shock absorber ■How much energy has to It indicates whether the is selected if the impact low Effective Mass generates very high impact be dissipated during one shock absorber can be velocity is under 0.3 m/s and/ forces at the beginning of the hour of operation adjusted to perform properly. or the propelling force ■The Effective Mass It also prevents under- or energy (F x S) exceeds 50 % stroke. These two points have to be over-sizing where propelling of the calculated E3 value. considered in the calculation forces are involved or as they can lead to serious damage over a longer period of time.. SYMBOLS FORMULAE Minimum/ maximum Effective Mass is laid down C =Cycles per hour m (cid:127) V2 t =Time in seconds W = ––––––– = [Nm] = m (cid:127) g (cid:127) h [Nm] inertia and free fall for all HOERBIGER-ORIGA 1 2 s =Shock abs. stroke [m] shock absorbers (see Table V, Vi =Impact velocity [m/s] 1 (cid:127) ω2 1.70.001-13). Vt =Velocity of rotating = ––––––– = [Nm] rotating mass 2 Effective Mass is calculated table [m/s] g =Gravitational using the following formula. acceleration [m/s2] m (cid:127) V2 = ––––––i– = [Nm] rotating table d =Cylinder diameter [mm] 4 b =Radius to centre of 2 (cid:127) W gravity [m] M.eff = ––––––3– W = Fp (cid:127) s = [Nm] oder m x g x h for free-falling mass m =Mass [kg] 2 V2 ma =Additional mass [kg] W = W + W [Nm] H =Height [m] 3 1 2 W = W (cid:127) C [Nm/h] Fp =Propelling force [N] 4 3 W =Inertial energy [Nm] Fp = 0,078 (cid:127) d2 (cid:127) P = [N] determines the cylinder force 1 W =Propelling force energy 2 [Nm] 2500 (cid:127) Pm W =Total energy per cycle 3 Fp = ––––––––––– = [N] etermines the working force of an [Nm] V electric motor W =Total energy to be 4 dissipated per hour Vt = ωωωωω (cid:127) a = [m/s] determines the velocity at distance a from [Nm/h] pivot P =Pressure [bar] M =Torque [Nm] V = 2 (cid:127) g (cid:127) H = [m/s] determines the impact velocity of P =Motor power [kW] m a free-falling mass R =Radius to cylinder [m] ωωωωωC =Angular velocity [rad/s] M.eff =Effective Mass µ =Coefficient of friction V (cid:127) b I =Moment of inertia V = ––––––– = [m/s] determines the impact velocity of a [Nm/s] i a rotating mass r =Radius of table [m] D =Distance to shock absorber [m] l = m (cid:127) a2 [Nm/s2] 2r =Diameter of table [m] ααααα =Slope angle [°] 2,6 (cid:127) s t = ––––––– = [s] determines the stopping time in the V course of a stroke 2 (cid:127) W M.eff = ––––––3– = [kg] determines the Effective Mass V2 Data Sheet No. 1.70.001E-7 EXAMPLES OF CALCULATIONS FOR Calculations SHOCK ABSORBER SELECTION Example 1 – Vertical Free-Falling Load Example 3 – Vertical Load Propelled Upwards m = 25 kg m = 450 kg d = 100 mm (2 Cylinders) H = 0.4 m V = 1.2 m/s s = 0.1 m C = 140/h P = 6 bar C = 200/h s = 0.05 m Calculation Calculation W = m (cid:127) g (cid:127) H m (cid:127) V2 450 (cid:127) 1.22 1 = 25 (cid:127) 9.81 (cid:127) 0.4 W1 = –––2–––– = –––––2––––– = 98 Nm = 324 Nm W = m (cid:127) g (cid:127) s 2 = 25 (cid:127) 9.81 (cid:127) 0.05 Fp = 2(0,078(cid:127)d2(cid:127)P) - (g(cid:127)m) m = 13 Nm = 2(0.078(cid:127)1002(cid:127)6) - (9.81(cid:127)450) = 4950 N W = W + W 3 1 2 V = 98 +13 W = F(cid:127)s H = 111 Nm s 2 = 49p50(cid:127)0.1 W = W (cid:127) C V = 495 Nm s 4 3 = 111 (cid:127) 140 m W = W+W = 15540 Nm/h 3 = 3214+4295 V = 2 (cid:127) g (cid:127) H = 819 Nm = 2 (cid:127) 9.81 (cid:127) 0.4 d W = W(cid:127)C 2 4 3 = 2.8 m/s P Cylinder P = 819(cid:127)100 2 (cid:127) W 2 (cid:127) 111 = 81900 Nm/h M.eff = ––––––3– = ––––––– V2 2.82 2(cid:127)W 2(cid:127)819 M.eff = ––––––3– = –––––––– 222 V2 1.22 = ––––––– = 28 kg 7.84 = 1137 kg Select Type: SA1/2 x 2 Select Type: SA11/8x4 Example 2 – Vertical Load Propelled Downwards Example 4 – Moving Load Without Propelling Force m = 450 kg P = 6 bar m = 900 kg V = 1.2 m/s C = 100/h V = 1.5 m/s d = 50 mm s = 0.1 m F = 0 p C = 200/h Calculation m (cid:127) V2 450 (cid:127) 1.22 W = ––––––– = –––––––– s 1 2 2 P = 324 Nm F = (0,078(cid:127)d2(cid:127)P) + (g(cid:127)m) m p = (0.078(cid:127)502(cid:127)6) + (9.81(cid:127)450) V d = 5585 N W = F(cid:127)s 2 p = 5585(cid:127)0.1 m = 558 Nm W = W+W Calculation V 3 = 3214+5258 m (cid:127) V2 900 (cid:127) 1.52 W = W(cid:127)C = 882 Nm W = ––––––– = –––––––––– 4 3 s 1 2 2 = 1012(cid:127)200 W = W(cid:127)C = 202400 Nm/h 4 3 = 1012 Nm = 882(cid:127)100 2(cid:127)W 2(cid:127)1012 = 88200 Nm/h W2 = 0 M.eff = –––V–2––3– = –––1–.5–2––– M.eff = –2–(cid:127)–W–3––– = –2–(cid:127)8–8–2–––– W3 = W1+W2 = 900 kg V2 1.22 = 1012 = 1225 kg Select Type: SA 1 1/8x4 Select Type: SA 1 1/8x4 Data Sheet No.1.70.001E-8 EXAMPLES OF CALCULATIONS FOR Calculations SHOCK ABSORBER SELECTION Example 5 – Moving Load With Propelling Force Example 7 – Moving Load Propelled by Rollers (Conveyor with Chain/Belt Drive) m = 900 kg P = 6 bar V = 1.5 m/s C = 100/h m = 80 kg C = 300/h d = 50 mm s = 0.05 m V = 1.0 m/s s = 0.025 m µ = 0.3 s s d m P m V V Calculation W = W+W Calculation W = W(cid:127)C 3 1 2 4 3 m (cid:127) V2 900(cid:127) 1.52 =1012+58.5 m (cid:127) V2 80 (cid:127) 1.02 = 45.9(cid:127)300 W1 = –––2–––– = –––––2––––– =1070.5 Nm W1 = –––2–––– = –––––2––––– = 13770 Nm/h = 1012 Nm W4 = E3(cid:127)C = 40 Nm M.eff = –––2–(cid:127)W––3– = –2–(cid:127)4–5–.–9––– = 1070.5(cid:127)100 V2 1 F = 0,078(cid:127)d2(cid:127)P W = F(cid:127)s p = 0,078(cid:127)502(cid:127)6 = 107050 Nm/h 2 = 80p(cid:127)0.3(cid:127)9.81(cid:127)0.025 = 91.8 kg = 1170 N 2(cid:127)E 2(cid:127)1070.5 = 5.9 Nm M.eff = –––––3–– = –––––––– V2 1.52 W = F(cid:127)s W = W+W 2 = 11p70(cid:127)0,05 = 951 kg 3 =40+15.92 = 58.5 Nm Select Type: SA 1 1/8x2 =45.9 Nm Select Type: SAI 25 Example 6 – Moving Load Propelled by Motor Example 8 – Load Moving Down a Slope m = 900 kg C = 100/h m = 200 kg C = 100/h V = 1.5 m/s s = 0.05 m ααααα = 15° s = 0.05 m P = 1 kW H = 0.2 m m s m D s H V m V P m ααααα Calculation W = W+W Calculation W = W(cid:127)C 3 1 2 4 3 m(cid:127)V2 900(cid:127) 1.52 =1012+83 W = m(cid:127)g(cid:127)H = 417.91(cid:127)100 W = ––––––– = –––––––––– 1 1 2 2 =1095 Nm = 200(cid:127)9.81(cid:127)0.2 = 41791 Nm/h = 392.4 Nm = 1012 Nm W =W(cid:127)C V = 2 (cid:127) g (cid:127) H F = –2–5–0–0–(cid:127)–P–m– = ––2–5–0–0–(cid:127) –1– 4 = 10395(cid:127)100 W2 = m(cid:127)g(cid:127)sin ααααα(cid:127)s = 2(cid:127)9.81(cid:127)0.2 p V 1.5 = 109500 Nm/h = 200(cid:127)9.81(cid:127)0.26(cid:127)0.05 = 1.98 m/s 2(cid:127)W 2(cid:127)1095 = 1666 N M.eff = –––V–2––3– = –––1–.5–2––– = 25.51 Nm M.eff = –––2–(cid:127)W––3– = –2–(cid:127)4–1–7–.–9–1– V2 1.982 W2 = Fp(cid:127)s = 973 kg W3 = W1+W2 = 213 kg = 1666(cid:127)0.05 = 392,4+25.51 = 83 Nm Select Type: SA1 1/8x2 = 417.91 Nm Select Type: SA 3/4x2 Data Sheet No. 1.70.001E-9

Description:
Type SA 64, SA 64S, SA 64 S2, SA64S3. 1.70.009E. Adjustable Shock Absorber. Type SA 1/4 x 1/2. 1.70.100E. Type SA 3/8 x 1D. 1.70.101E. Type SA
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