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Free fall
Cylinder drive gravity direction
Cylinder driven counter gravity direction
Motor gravity direction
Motor gravity reverse direction
Beam - Cylinder drive
Beam - Motor drive
Turntable - Cylinder drive
Turntable - Motor drive
Free fall
Motor drive - gravity direction
Motor drive - gravity reverse direction
Air cylinder (hydraulic cylinder) - gravity direction
Air cylinder (hydraulic cylinder) - opposite direction of gravity
Free horizontal movement
Cylinder (hydraulic cylinder) drive
Motor drive
  • Number of Shock Absorbers: Unit
    Weight of object (M): kg
    Impact velocity of object (M): m/s
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Weight of object (M): kg
    Velocity (V): m/s
    Cylinder pressure: Bar
    Cylinder bore dia.: mm
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Weight of object (M): kg
    Velocity (V): m/s
    Motor Rating: KW
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Weight of object (M): kg
    Impact distance of object (M) bottom: m
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Weight of object (M): kg
    Impact distance of object (M) bottom: m
    Velocity (V): m/s
    Motor Rating: KW
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Weight of object (M): kg
    Velocity (V): m/s
    Motor Rating: KW
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Weight of object (M): kg
    Velocity (V): m/s
    Cylinder pressure: Bar
    Cylinder bore dia.: mm
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Weight of object (M): kg
    Velocity (V): m/s
    Cylinder pressure: Bar
    Cylinder bore dia.: mm
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Rotating beam mass: kg
    Rotational angular velocity(ω): rad/s
    Rotating beam length: m
    Distance from rotating shaft center to buffer axis: m
    Distance from rotating shaft center to cylinder shaft center: m
    Cylinder bore dia.: mm
    Cylinder pressure: Bar
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Impact load mass: kg
    Rotational angular velocity(ω): rad/s
    Motor torque: Nm
    Cantilever beam length: m
    Distance from fulcrum to buffer Center: m
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Turntable mass: kg
    Installation load mass: kg
    Rotational angular velocity(ω): rad/s
    Cylinder bore dia.: mm
    Cylinder pressure: Bar
    Disc radius: m
    Distance from fulcrum to buffer Center: m
    Distance from load center of gravity to axis: m
    Distance from cylinder center axis to rotary table center axis: m
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Turntable mass: kg
    Installation load mass: kg
    Rotational angular velocity(ω): rad/s
    Motor torque: Nm
    Disc radius: m
    Distance from fulcrum to buffer Center: m
    Distance from load center of gravity to axis: m
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Rotating beam mass: kg
    Distance from center of mass of rotating beam to fulcrum: m
    Distance from fulcrum to buffer Center: m
    Starting angle: deg
    Impact angle: deg
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Rotational angular velocity(ω): rad/s
    Rotating beam mass: kg
    Rotating beam length: m
    Distance from center of mass of rotating beam to fulcrum: m
    Distance from fulcrum to buffer Center: m
    Distance from cylinder axis to rotating beam axis: m
    Cylinder bore dia.: mm
    Cylinder pressure: Bar
    Starting angle: deg
    Impact angle: deg
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Rotational angular velocity(ω): rad/s
    Rotating beam mass: kg
    Rotating beam length: m
    Distance from center of mass of rotating beam to fulcrum: m
    Distance from fulcrum to buffer Center: m
    Distance from cylinder axis to rotating beam axis: m
    Cylinder bore dia.: mm
    Cylinder pressure: Bar
    Starting angle: deg
    Impact angle: deg
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Rotating beam mass: kg
    Rotational angular velocity(ω): rad/s
    Rotating beam length: m
    Distance from center of gravity of rotating beam to fulcrum: m
    Distance from fulcrum to buffer Center: m
    Motor torque: Nm
    Starting angle: deg
    Impact angle: deg
    Cycles: Times / hour
  • Number of Shock Absorbers: Unit
    Rotating beam mass: kg
    Rotational angular velocity(ω): rad/s
    Rotating beam length: m
    Distance from center of gravity of rotating beam to fulcrum: m
    Distance from fulcrum to buffer Center: m
    Motor torque: Nm
    Starting angle: deg
    Impact angle: deg
    Cycles: Times / hour
Select Adjust mode Product Model Stroke (mm) Effective weight(Kg) External thread Weight Percentage of maximum absorbed energy per time(ET) Percentage of maximum absorbed energy per hour(EIC) length without rubber cap A(mm) length of rubber cap B(mm) piston rod diameter D(mm) impactor diameter E(mm) outer cylinder length F(mm)
  • Input parameter
    Number of Shock Absorbers (Unit) Weight of object (M)(Kg) Speed of motor driven object (M)(m/s) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Weight of object (M)(Kg) Velocity (V)(m/s) Cylinder pressure(Bar) Cylinder bore dia.(mm) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Weight of object (M)(Kg) Velocity (V)(m/s) Motor Rating(Kw) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Weight of object (M)(Kg) Impact distance of object (M) bottom(m) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Weight of object (M)(Kg) Impact distance of object (M) bottom(m) Velocity (V)(m/s) Motor Rating(Kw) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Weight of object (M)(Kg) Velocity (V)(m/s) Motor Rating(Kw) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Weight of object (M)(Kg) Velocity (V)(m/s) Cylinder pressure(Bar) Cylinder bore dia.(mm) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Weight of object (M)(Kg) Velocity (V)(m/s) Cylinder pressure(Bar) Cylinder bore dia.(mm) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Rotating beam mass(kg) Rotational angular velocity(ω)(rad/s) Rotating beam length(m) Distance from rotating shaft center to buffer axis(m) Distance from rotating shaft center to cylinder shaft center(m) Cylinder bore dia.(mm) Cylinder pressure(Bar) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Impact load mass(Kg) Rotational angular velocity(ω)(rad/s) Motor torque(Nm) Cantilever beam length(m) Distance from fulcrum to buffer Center(m) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Turntable mass(Kg) Installation load mass(Kg) Rotational angular velocity(ω)(rad/s) Cylinder bore dia.(mm) Cylinder pressure (Bar) Disc radius(m) Distance from fulcrum to buffer Center(m) Distance from load center of gravity to axis(m) Distance from cylinder center axis to rotary table center axis(m) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Turntable mass(Kg) Installation load mass(Kg) Rotational angular velocity(ω)(rad/s) Motor torque(Nm) Disc radius(m) Distance from fulcrum to buffer Center(m) Distance from load center of gravity to axis(m) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Rotating beam mass(Kg) Distance from center of mass of rotating beam to fulcrum(m) Distance from fulcrum to buffer Center(m) Starting angle(deg) Impact angle(deg) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Rotational angular velocity(ω)(rad/s) Rotating beam mass(Kg) Rotating beam length(m) Distance from center of mass of rotating beam to fulcrum(m) Distance from fulcrum to buffer Center(m) Distance from cylinder axis to rotating beam axis(m) Cylinder bore dia.(mm) Cylinder pressure(Bar) Starting angle(deg) Impact angle(deg) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Rotational angular velocity(ω)(rad/s) Rotating beam mass(Kg) Rotating beam length(m) Distance from center of mass of rotating beam to fulcrum(m) Distance from fulcrum to buffer Center(m) Distance from cylinder axis to rotating beam axis(m) Cylinder bore dia.(mm) Cylinder pressure(Bar) Starting angle(deg) Impact angle(deg) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Rotating beam mass(Kg) Rotational angular velocity(ω)(rad/s) Rotating beam length(m) Distance from center of gravity of rotating beam to fulcrum(m) Distance from fulcrum to buffer Center(m) Motor torque(Nm) Starting angle(deg) Impact angle(deg) Cycles (times / hour)
  • Input parameter
    Number of Shock Absorbers (Unit) Rotating beam mass(Kg) Rotational angular velocity(ω)(rad/s) Rotating beam length(m) Distance from center of gravity of rotating beam to fulcrum(m) Distance from fulcrum to buffer Center(m) Motor torque(Nm) Starting angle(deg) Impact angle(deg) Cycles (times / hour)
    • Calculation Results
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Moment of inertia of rotating beam(Kg m²)
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Moment of inertia of rotating beam(Kg m²)
    Motor torque (Nm)
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Moment of inertia of rotating beam(Kg m²)
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Moment of inertia of rotating beam(Kg m²)
    Load moment of inertia(Kg m²)
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Moment of inertia of rotating beam(Kg m²)
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Moment of inertia of rotating beam(Kg m²)
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Moment of inertia of rotating beam(Kg m²)
    Motor torque (Nm)
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Calculation Results
    Moment of inertia of rotating beam(Kg m²)
    Motor torque (Nm)
    Kinetic energy(Nm)
    Work done by external force during impact buffer process(Nm)
    Total work of shock absorber process(Nm)
    Energy to be absorbed by the buffer per hour(Nm/h)
    Effective weight of impact to buffer(Kg)
    Force acting on the buffer(N)
    Deceleration(m/s²)
    Maximum impact force(N)
    Technical Parameter
    Product Model
    Adjustment mode
    Buffer Stroke(mm)
    Effective weight(Kg)
    External thread
    Weight
    Maximum absorbed energy per time(Nm/c)
    Percentage of maximum absorbed energy per time(ET)
    Maximum absorbed energy per hour(Nm/h)
    Percentage of maximum absorbed energy per hour(EIC)
    length without rubber cap A(mm)
    length of rubber cap B(mm)
    piston rod diameter D(mm)
    impactor diameter E(mm)
    outer cylinder length F(mm)

    Note: if you need the product simulation curve, please contact the technical personnel of reoshoc。