Difference between revisions of "KPI"

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Revision as of 10:14, 18 May 2021

Cluster-KPIs

OEE(Overall Equipment Effectiveness)-Potential

$Availability\times Performance\times Quality$

$Availability={\frac {actualproductiontime}{possibleproductiontime}}\times 100$

$Performance={\frac {actualoutput}{possibleoutput}}\times 100$

$Quality={\frac {flawlessproducts}{actualoutput}}\times 100$

Current estimated OEE:

Availability = 77,82 %
Performance = 72,98 %
Quality = tbd

→ $77,82\%\times 72,98\%\times tbd=$

Target OEE:

Availability = 77,82 %
Performance = 72,98 %
Quality = tbd + x%

→ $77,82\%\times 72,98\%\times tbd=$

TCO-Potential

TCO = Acquisition costs + Personnel costs + Energy costs + Maintenance costs + Downtime costs + Running costs (e.g., training courses) + Opportunity costs + Costs for operating materials + Disposal costs + Energy efficiency + CO2 balance

Saving potential energy costs:

Forming process: The forming process accounts for approx. 9.4 % of the energy costs in the processes considered (packaging to forming).

Current estimated TCO:

Current energy consumption of forming process: 15 Ah per 870 mAh cell

Target TCO:

Reduction of energy consumption in the forming process by 20 % results in a reduction of total energy costs by approx. 2 % ( $20\%\times 9.4\%$ )

Project-KPIs

Material consumption per unit

Models can be used to estimate the amount of electrolyte required and to reduce it. In contrast to the active material, a greater potential for reduction is seen here, since the active material has a direct influence on the energy content of the cell. → Contributes to the reduction of production costs (not listed in OEE/TCO)

Current electrolyte consumption:

4 ml per 870 mAh cell

Target electrolyte consumption:

3.5 ml per 870 mAh cell

Energy consumption per unit

The energy consumption per unit can be reduced by optimizing the forming process.

Current energy consumption:

15 Ah per 870 mAh cell

Target energy consumption:

12 Ah per 870 mAh cell

Variable production costs

The variable production costs are composed of the energy, material, scrap and manufacturing costs.

Current variable production costs:

100%

Target variable production costs:

90%

Literature

Rao et al.: Enhancing Overall Equipment Effectiveness in Battery Industries through Total Productive Maintenance, International Journal of Engineering Research in Mechanical and Civil Engineering (2017)

Pettinger, K.-H.; Dong, W.: When Does the Operation of a Battery Become Environmentally Positive? Journal of The Electrochemical Society 164 (2017)

@@ Line 3: / Line 3: @@
 ===OEE(Overall Equipment Effectiveness)-Potential===
 <math>Availability \times Performance \times Quality</math>
 <math>Availability = \frac{actual production time}{possible production time} \times 100</math>
 <math>Performance = \frac{actual output}{possible output} \times 100</math>
 <math>Quality = \frac{flawless products}{actual output} \times 100</math>
@@ Line 26: / Line 29: @@
 ===TCO-Potential===
-TCO = Acquisition costs + Personnel costs + '''Energy costs''' + Maintenance costs + Downtime costs + Running costs (e.g., training courses) + Opportunity costs + Costs for operating materials + Disposal costs + Energy efficiency + '''CO_2 balance'''
+TCO = Acquisition costs + Personnel costs + '''Energy costs''' + Maintenance costs + Downtime costs + Running costs (e.g., training courses) + Opportunity costs + Costs for operating materials + Disposal costs + Energy efficiency + '''CO2 balance'''
 Saving potential energy costs:
@@ Line 82: / Line 85: @@
 ==Literature==
 Rao et al.: Enhancing Overall Equipment Effectiveness in Battery Industries through Total Productive Maintenance, International Journal of Engineering Research in Mechanical and Civil Engineering (2017)
 Pettinger, K.-H.; Dong, W.: When Does the Operation of a Battery Become Environmentally Positive? Journal of The Electrochemical Society 164 (2017)

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