Difference between revisions of "Payloads"

This page gives an overview over the available payload properties, their uses and meaning.

Rotational Axes

Dynamic Model 1 - simple rotary axis

The relevant payload property for this model is:

• payloadInertia - the inertia of the payload in the axis direction relative to the axis location - ${\displaystyle I_{payload}[kg\cdot m^{2}]}$.

Dynamic Model 2 - horizontal crank-arm axis

The relevant payload property for this model is:

• payloadInertia - the inertia of the payload in the axis direction relative to the axis location - ${\displaystyle I_{payload}+L^{2}\cdot M_{payload}[kg\cdot m^{2}]}$.

Dynamic Model 3 - vertical crank-arm axis

The relevant payload properties for this model are:

• payloadMassRMassG - the payload mass times the distance to the center of mass of the payload times gravity - ${\displaystyle M_{payload}\cdot g\cdot L[Nm]}$.
• payloadMassRMassSqIxx - the inertia of the payload in the axis direction relative to the axis location - ${\displaystyle I_{payload}+L^{2}\cdot M_{payload}[kg\cdot m^{2}]}$.

Linear Axes

Dynamic Model 1 - horizontal axis

The relevant payload property for this model is:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.

Dynamic Model 2 - vertical or tilted axis

The relevant payload property for this model is:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.

Dynamic Model 3 - vertical axis with a spring

The relevant payload property for this model is:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.

Scara Robots

Dynamic Model 1

The relevant payload properties for this model are:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.
• payloadInertia - the inertia of the payload in the 4th axis direction relative to the 4th axis location - ${\displaystyle I_{payload}[kg\cdot m^{2}]}$.

Dynamic Model 2

The relevant payload properties for this model are:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.
• payloadInertia - the inertia of the payload in the 4th axis direction relative to the 4th axis location - ${\displaystyle I_{payload}[kg\cdot m^{2}]}$.

Dynamic Model 3

The relevant payload properties for this model are:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.
• payloadInertia - the inertia of the payload in the 4th axis direction relative to the 4th axis location - ${\displaystyle I_{payload}[kg\cdot m^{2}]}$.
• payloadLx - The distance to the center of mass from the 4th axis in the x direction - ${\displaystyle L_{x}[m]}$.
  

When using identification with this model, all of the payload parameters can be found.

Dynamic Model 4

This model is used in identification process in order to identify the payloadMass parameter only, by moving only joint number 3.
The relevant payload property for this model is:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.

Dynamic Model 5

This model is used in identification process in order to identify the payloadInertia and payloadLx parameters, by moving only joint number 4 and very small movements in joints 1 and 2.
The relevant payload properties for this model are:

• payloadInertia - the inertia of the payload in the 4th axis direction relative to the 4th axis location - ${\displaystyle I_{payload}[kg\cdot m^{2}]}$.
• payloadLx - The distance to the center of mass from the 4th axis in the x direction - ${\displaystyle L_{x}[m]}$.
  

Delta Robots

Dynamic Model 1

The relevant payload property for this model is:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.

Puma Robots

Dynamic Model 1

The relevant payload properties for this model are:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.
• payloadInertia - the inertia of the payload in the 6th axis direction relative to the 6th axis location - ${\displaystyle I_{payload,zz}[kg\cdot m^{2}]}$.
• payloadMassRMass - the payload mass times the distance to the center of mass of the payload in the TCP z axis direction - ${\displaystyle M_{payload}\cdot R_{c.m,z}[kg\cdot m]}$.
• payloadMassRMassG - the payload mass times the distance to the center of mass of the payload in the TCP z axis direction times gravity - ${\displaystyle M_{payload}\cdot g\cdot R_{c.m,z}[Nm]}$.
• payloadMassRMassSqIxx - the inertia of the payload in the TCP x axis direction relative to the 5th axis location - ${\displaystyle I_{payload,xx}+R_{c.m,z}^{2}\cdot M_{payload}[kg\cdot m^{2}]}$.

Dynamic Model 2 - Gravity

The relevant payload property for this model is:

• payloadMass - the mass of the payload - ${\displaystyle M_{payload}[kg]}$.