Manual Spot Welding and Robotic Spot Welding
Spot Welding Operation Cycle Time
Cycle time for the weld operation is the time it takes to create the weld represented by the current GCD.
Weld Time = Arc Time + Gun Manipulation Time
For each Weld GCD, weld time is the sum of the following:
Arc time (see formula)
Gun manipulation time (see formula)
Gun clean time (see formula)
Arc Time = Number of Weld Segments * Spot Weld Time
Arc time is the time for the arcing phase of welding. It is the product of the following:
Number of weld segments (extracted from the CAD model or specified by the user in the Welding dialog)
Spot weld time (specified by the machine property Spot Weld Time)
Gun Manipulation Time = Number of Weld Segments * Gun Placement Time per Segment
Gun manipulation time includes all tasks between welds such as lifting the hood or visor, moving to the next location, repositioning the torch, readying to strike, and so forth. It.is the product of the following:
Number of weld segments (specified by the user or geometry extraction)
Gun placement time per segment (specified by the machine property Gun Placement Time)
Spot Welding Weld Weight
Weld Weight = GCD Volume * Weld Density
The weight of each weld GCD is used to calculate the total assembly weight, which affects expendable tooling costs for Welding, as well as Pick and Place costs. The weight in kilograms of each weld GCD is the product of the following:
GCD Volume (based on geometry extraction or user-specified weld dimensions and weld type)
Weld density: specified in kg/m3 by the machine property Weld Density. aPriori converts this value to kg/mm3.
Spot Welding Accounting Calculations
Amortized Batch Setup =
(Setup Time * (Labor Rate + Direct Overhead Rate)) / Batch Size
This is the per-part cost of setting up one production batch of parts, that is, the batch setup cost amortized over all the parts in the batch. It depends on the following:
Setup time (specified as the machine property Setup Time)
Labor rate (specified by the machine property Labor Rate)
Direct overhead rate (see Direct and Indirect Overhead)
Batch size (specified in the Production Scenario screen of the Cost Guide)
Labor Cost = Labor Time * Labor Rate / Final Yield
Labor cost depends on the following:
Labor time (see formula)
Labor rate (specified by the machine property Labor Rate)
Final yield (see Yields)
Robotic Spot Welding Labor Time = (Operation Weld Times / Number of Weld Heads) *
Number of Operators * Labor Time Standard
Labor time is the product of the following:
Operation weld times: sum of the weld times of all child operations—see Spot Welding Operation Cycle Time.
Number of weld heads: specified by the machine property Number of Weld Heads.
Number of operators: specified by the machine property Number of Operators or by the PSO Number of operators tending to this machine.
Labor time standard: specified as the machine property Labor Time Standard. This multiplier is used to account for otherwise unaccounted for factors that affect labor time, such as operator fatigue or time spent by the operator for cleaning or maintenance.
Manual Spot Welding Labor Time = Operation Weld Times * Labor Time Standard
Labor time is the product of the following:
Operation weld times: sum of the weld times of all child operations—see Spot Welding Operation Cycle Time.
Labor time standard: specified as the machine property Labor Time Standard. This multiplier is used to account for otherwise unaccounted for factors that affect labor time, such as operator fatigue or time spent by the operator for cleaning or maintenance.
Note that for Manual Spot Welding, labor time is independent of the number of operators, and cycle time is assumed to be inversely proportional to the number of operators (see Manual Spot Welding Process Cycle Time).
Robotic Spot Welding Process Cycle Time
Cycle Time = (Operation Weld Times / Number of Weld Heads) * Cycle Time Adjustment Factor
Cycle time depends on the following:
Operation weld times: sum of the weld times of all child operations—see Spot Welding Operation Cycle Time.
Number of weld heads: specified by the machine property Number of Weld Heads.
Cycle time adjustment factor: specified by the cost model variable cycleTimeAdjustmentFactor; 1 in aPriori starting point VPEs. If you want to model an unbalanced, push assembly line, set cycleTimeAdjustmentFactor to a value greater than 1 in order to account for the cost of extra buffer capacity.
Note that indirect overhead depends on cycle time, while direct overhead depends on labor time. Cycle time contributes to part cost only via indirect overhead.
Manual Spot Welding Process Cycle Time
Cycle Time = (Labor Time / Number of Operators) * Cycle Time Adjustment Factor
Cycle time depends on the following:
Labor time (see Manual Spot Welding Labor Time in Spot Welding Accounting Calculations).
Number of operators: specified by the machine property Number of Operators. Note that cycle time is inversely proportional to the number of operators.
Cycle time adjustment factor: specified by the cost model variable cycleTimeAdjustmentFactor; 1 in aPriori starting point VPEs. If you want to model an unbalanced, push assembly line, set cycleTimeAdjustmentFactor to a value greater than 1 in order to account for the cost of extra buffer capacity.
Note that indirect overhead depends on cycle time, while direct overhead depends on labor time. Cycle time contributes to part cost only via indirect overhead.
Spot Welding Expendable Tooling Calculation
Expendable Tooling Cost = Weld Weight *Wire Cost per Unit / Final Yield
Expendable tooling cost accounts for the cost of the welding wire for assembly. It depends on the following:
Weld Weight (see Spot Welding Weld Weight)
Wire cost per unit mass (specified by the machine property Wire Cost)
Final yield (see Yields)