Overall Equipment Effectiveness
All Time
24 hours in a day, 7 days in a week. All time refers to every minute of every day.
World-Class OEE
90% Availability 95% Performance 99% Quality 85% OEE A composite OEE number means very little without the total context.
5S
A Lean Manufacturing process that creates an organized work area. 5S has five steps: Sort (eliminate unneeded items), Set (organize remaining items), Shine (clean and inspect the work area), Standardize (document standards for the area), Sustain (apply and audit the standards).
Small Stop
A brief pause in production, but not long enough to be tracked as Stop Time. An alternative term for Idling and Minor Stops in the Six Big Losses. Contributes to OEE Performance.
Visual Factory
A concept for reducing communication waste on the factory floor through the use of real time indicators such as signs, charts, and scoreboards. Andon indicators are often an important tool in the visual factory.
Slow Cycle
A cycle that took longer than the Ideal Cycle Time, but less than a Small Stop. Slow Cycles are a cause for Reduced Speed in the Six Big Losses. Contributes to OEE Performance.
Small Stop Threshold
A dividing point between a Slow Cycle, and one which is considered a Small Stop. Setting a Small Stop Threshold can be used in Cycle Time Analysis to automatically identify Small Stop cycles.
Slow Cycle Threshold
A dividing point between a standard cycle, and one which is considered "slow" (a Slow Cycle). Setting a Slow Cycle Threshold can be used in Cycle Time Analysis to automatically identify slow cycles.
SIC (Short Interval Control)
A factory-floor process for engaging operators and supervisors to maximize OEE by seeking quick improvement opportunities that they can implement in full during the shift. SIC (Short Interval Control) uses Six Big Loss data to enable teams to make ongoing course corrections during the shift.
Focused Improvement
A highly effective process for reducing unplanned stop time. A small cross functional team selects a loss (often from a top loss report), and apply root cause analysis or 5 why analysis to identify potential causes and fixes. Focused Improvement is a technique from Lean Manufacturing and is sometimes known as a kaizen blitz.
Root Cause Analysis
A method of resolving a non-conformance, by tracing back from the end failure to its original (root) cause. The basic tool for understanding and eliminating the sources of productivity losses.
Theory of Constraints
A methodology for improving productivity that was proposed by by Eli Goldratt in his bestselling 1984 novel The Goal. Dr. Goldratt proposed that every complex system, including manufacturing processes, consists of multiple linked activities, one of which acts as a constraint upon the entire system (i.e., the constraint is the "weakest link in the chain").
Brainstorming
A process for creating an expanded world of ideas and possibilities. Brian storming is a divergent problem solving process that is intended to create a broad range of ideas that can then be refined by a root cause process.
Preventive Maintenance
A process from TPM (Total Productive Maintenance) for improving OEE by carrying out maintenance activity based on either calendar time (replacing parts every few months) or loss data (replacing a part one week before it has historically failed).
Autonomous Maintenance
A process from TPM (Total Productive Maintenance) for improving machine OEE by engaging operators to complete routine maintenance, inspection, and lubrication activities.
5 Why Analysis
A simple process originally created by Sakichi Toyoda at the Toyota Motor Company for identifying the root cause behind a particular problem. Start with a problem definition, and keep asking "why" until the root cause is uncovered.
Make Ready
A stage within a changeover process in which machine settings are fine-tuned before production (often based on the inspection of a first-off part). Make Ready events are a type of Planned Stop and affect OEE Availability.
Breakdowns
A type of Unplanned Stop where time is lost due to Equipment Failure (one of the Six Big Losses). Breakdowns are a type of Unplanned Stop and affect OEE Availability.
Fully Productive Time
Actual productive time after ALL losses are subtracted. An OEE score of 100% means that the process is Fully Productive with no Availability Loss, Performance Loss, or Quality Loss.
Down Time
All time where the manufacturing process was intended to be running but was not due to Unplanned Stops (e.g. breakdowns), or Planned Stops (e.g. changeovers). Down Time is also called Stop Time.
Stop Time
All time where the manufacturing process was intended to be running but was not due to Unplanned Stops (e.g. breakdowns), or Planned Stops (e.g. changeovers). Stop Time is also called Down Time.
Countermeasures
An action to counter or mitigate a manufacturing loss. A manufacturing loss may benefit from multiple countermeasures including immediate actions to prevent the loss from getting worse, short term fixes and long term root cause fixes.
Reason Code
An identification number or classification applied to an Event subcategory. Used to tabulate statistics regarding Events. Makes it much easier to get a handle on losses, especially down time loss.
Defect
Any part that is not right first time. Defects may be reworked, or scrapped. All defects are a loss to OEE Quality.
Top Losses
Create an easily understood pareto-style report for quickly identifying losses to OEE. A good top losses report includes all Six Big Losses with Reason Codes for Stop Times to create a balanced perspective on where the team should prioritize their time.
Standardized Work
Document important machine operation and leadership activities to ensure that best practices are consistently captured and followed. It is extremely important that standardized work documents are treated as 'living' documents that are regularly updated as improvements are made.
OEE (Overall Equipment Effectiveness)
Framework for measuring the efficiency and effectiveness of a process, by breaking it down into three constituent components (the OEE Factors). OEE helps you see and measure a problem so you can fix it, and provides a standardized method of benchmarking progress.
Error Proofing
Improve OEE Quality by designing error detection and prevention into processes and equipment. The goal of error-proofing is to eliminate Process Defects and Reduced Yield.
Andon
Indicator above production line to signal production conditions. Often uses green/yellow/red colors to indicate status.
TPM (Total Productive Maintenance)
Maintenance system covering the life of all equipment: planning, manufacturing, maintenance and improving performance. OEE is a metric for defining equipment effectiveness in a TPM program.
First Pass Yield
Making a Good Part, 'right first time' without rejecting it to be scrapped or reworked.
Best Practice
Methods that are considered "state of the art" by the most respected in an industry. Successful companies use different methods than unsuccessful companies.
IDA (Information, Decision, Action)
One of the easiest and most effective ways to improve results by focusing on three factors that drive results (Information, Decisions, and Actions).
OEE Availability
One of the three OEE Factors. Takes into account Availability Loss (any events that stop planned production for an appreciable length of time). Must be measured in an OEE program, usually by recording the duration of Unplanned Stops and Planned Stops.
OEE Performance
One of the three OEE Factors. Takes into account Performance Loss (factors that cause the process to operate at less than the maximum possible speed, when running). Must be measured in an OEE program, usually by comparing Actual Cycle Time (or Actual Run Rate) to Ideal Cycle Time (or Ideal Run Rate).
OEE Quality
One of the three OEE Factors. Takes into account Quality Loss (parts which do not meet quality requirements). Must be measured in an OEE program, usually by tracking Reject Parts.
Availability Loss
One of the three OEE Losses. Availability takes into account Equipment Failures and Setup and Adjustments. An Availability score of 100% means that the process is always running during Planned Production Time.
Performance Loss
One of the three OEE Losses. Performance takes into account Idling and Minor Stops and Reduced Speed. A Performance score of 100% means when the process is running it is running as fast as possible.
Quality Loss
One of the three OEE Losses. Quality is a measure of First Pass Yield and takes into account Process Defects and Reduced Yield. A Quality score of 100% means when the process is running, it is only making good parts.
Production Counts
Parts produced during steady-state production.
Visual OEE
Plant floor real-time display of live OEE data for maximum team involvement. Visual OEE™ displays make improvement everyone's job.
Reject Parts
Produced parts that do not meet quality standards right first time. Calculated by subtracting Good Parts from Total Parts. In the Six Big Losses, Reject Parts are either produced during steady-state production (Process Defects), or on startup after a stop event (Reduced Yield).
Good Parts
Produced parts that meet quality standards (without rework). The quantity of Good Parts is referred to as Good Count which is used to calculate OEE Quality.
Takt Time
Production rate needed to meet customer demand. Where sales and business planning meets the factory floor.
Speed Loss
Production time lost to equipment running below maximum rated speed. An alternative term for Reduced Speed in the Six Big Losses. Contributes to OEE Performance.
Down Time Loss
Production time lost to unplanned shutdowns. One of the three OEE Losses (reduces OEE Availability). Major focus area for improvement.
SMED (Single-Minute Exchange of Dies)
Program for reducing setup time. Named after the goal of reducing setup times to under ten minutes (representing time with one digit). Often a part of programs to improve OEE Availability.
Lean Manufacturing
Quality philosophy that strives to minimize consumption of resources that add no value to the finished product. OEE can be a key tool and metric in Lean Manufacturing programs.
Rework Parts
Rejected parts that can be reworked and sold to the customer. Reworked parts do not affect the OEE calculation as they were not right first time. OEE does not make a distinction between parts that can be reworked and parts that are scrapped.
Production Rejects
Rejects produced during steady-state production. Another term for Process Defects, and one of the Six Big Losses. Contributes to OEE Quality.
Startup Rejects
Rejects produced while equipment is adjusted for production. An alternative term for Reduced Yield in the Six Big Losses. Contributes to OEE Quality.
Design Cycle Time
See Ideal Cycle Time.
Six Big Losses
Six categories of productivity losses that are almost universally experienced in manufacturing: Equipment Failure, Setup and Adjustments, Idling and Minor Stops, Reduced Speed, Process Defects, and Reduced Yield. Drill down into the three OEE Factors, and you will reach the Six Big Losses. Measure your process with OEE, and improve your process by addressing the Six Big Losses.
Six Sigma
Systematic quality program that strives to limit defects to six standard deviations from the mean. One of the major focuses of Six Sigma is to reduce process variation. In most companies, Quality Loss will be by far the smallest of the OEE Losses. A Six Sigma or equivalent program may be necessary to maintain focus on quality improvements.
TEEP (Total Effective Equipment Performance)
TEEP (Total Effective Equipment Performance) is a performance metric for measuring the true capacity of your manufacturing operation. TEEP takes into account equipment losses (as measured by OEE) and schedule losses (as measured by Utilization). It is calculated by multiplying OEE % by Utilization %.
Actual Run Rate
The actual rate of production, when it is running. In OEE, calculated as Total Count divided by Run Time. Used in calculating OEE Performance. A variation of the calculation uses Actual Cycle Time instead.
Actual Cycle Time
The actual time to produce one part. In OEE, calculated as Run Time divided by Total Count. Used in calculating OEE Performance. A variation of the calculation uses Actual Run Rate instead.
Nameplate Capacity
The design capacity of a machine or process. Used to determine Ideal Cycle Time or Ideal Run Rate.
Reduced Yield
The manufacturing process is producing defective parts (also known as reject parts) during a period of time immediately after an Equipment Failure event or a Setup and Adjustment event. Often this loss is called Startup Rejects. Reduced Yield is one of the Six Big Losses to OEE and affects OEE Quality.
Process Defects
The manufacturing process is producing defective parts (also known as reject parts) during steady-state production. Often this loss is called Production Rejects. Process Defects are one of the Six Big Losses to OEE and affects OEE Quality.
Idling and Minor Stops
The manufacturing process is running, but is experiencing brief pauses in production that are not long enough to be tracked as Equipment Failures. This loss is often called Small Stops. Idling and Minor Stops is one of the Six Big Losses to OEE and affects OEE Performance.
Reduced Speed
The manufacturing process is running, but is running slower than the Ideal Cycle Time. This loss is often called Speed Loss. Reduced Speed is one of the Six Big Losses to OEE and affects OEE Performance.
Changeover
The manufacturing process is scheduled for production and is not running because of a planned Setup, Make Ready, or Adjustment event. Changeovers are a type of Planned Stop and affect OEE Availability.
Setup and Adjustments
The manufacturing process is scheduled for production and is not running because of a planned event such as a changeover or part change. This loss often includes Changeover, Make Ready events. Setup and Adjustments is one of the Six Big Losses to OEE and affects OEE Availability.
Planned Stop
The manufacturing process is scheduled for production and is not running because of a planned event such as a changeover, setup, or make ready event. Planned Stop time is one of the Six Big Losses to OEE and affects OEE Availability.
Unplanned Stop
The manufacturing process is scheduled for production and is not running because of an event like an equipment failure or material shortage. Unplanned Stops affect OEE Availability.
Equipment Failure
The manufacturing process is scheduled for production and is not running because of an unplanned event such as a machine break down. Equipment Failure is one of the Six Big Losses to OEE and affects OEE Availability.
Material Shortage
The manufacturing process is scheduled for production and is not running because of an unplanned lack of materials. Material Shortages are a type of Unplanned Stop and affect OEE Availability.
Run Time
The manufacturing process is scheduled for production and is running. Run Time is calculated by subtracting down time from planned production time. Run time includes time when the process could be experiencing small stops, reduced speed, and making reject parts.
Capacity
The maximum amount of production available if equipment is fully productive (running at 100% OEE), for All Time (24/7).
Utilization
The percentage of calendar time that is used for production. Utilization is an important part of TEEP. Utilization takes into account the losses of Production Not Scheduled, and Plant Not Open.
Shift Time
The period of time where a shift is scheduled to be running the machine.
Run Rate
The production rate when actually producing (running). Inverse of Cycle Time.
Constraint
The step of the manufacturing process that acts as a bottleneck to the throughput of the entire process. OEE should always be measured at the constraint as it is the slowest step in the process.
OEE Factors
The three constituent elements of OEE (Availability, Performance, and Quality). Often it is more important to focus on the three OEE Factors than the consolidated OEE metric.
OEE Losses
The three types of productivity loss associated with the three OEE Factors (Availability Loss, Performance Loss, and Quality Loss). The goal is to relentlessly work towards eliminating OEE Losses.
Cycle Time
The time to produce one part. Inverse of Run Rate.
Ideal Run Rate
Theoretical maximum production rate. The inverse of Ideal Cycle Time. Used to calculate OEE Performance. A variation of the calculation uses Ideal Cycle Time instead.
Ideal Cycle Time
Theoretical minimum time to produce one part. The inverse of Ideal Run Rate. Used to calculate OEE Performance. A variation of the calculation uses Ideal Run Rate instead.
Net Run Time
Time remaining once Schedule Loss, Availability Loss, and Performance Loss are subtracted from All Time.
Plant Shutdown
Time when the factory has no plans to run production (typically because the factory is closed or has no shifts scheduled). Plant Shutdown is a Schedule Loss to TEEP. Plant Shutdown time is excluded from OEE calculations.
Schedule Loss
Time when the plant is not scheduled for production (e.g. plant shutdown, no orders, breaks and lunches). Schedule loss is excluded from OEE, and is a loss to TEEP.
Equipment Loss
Time when the plant is scheduled to run, but is not Fully Productive due to one of the Six Big Losses to OEE.
Cycle Time Analysis
Tool used to better understand issues that affect Performance. Important to automate logging of Cycle Times for later analysis.
Total Parts
Total of all produced parts (including Defects). The quantity of Total Parts is referred to as Total Count and is used to calculate OEE Performance and OEE Quality.
Planned Production Time
Total time that equipment is expected to produce. Calculated by subtracting Schedule Loss from All Time. Benchmark that OEE is measured against.
Breaks
Unproductive time where the process is scheduled not to run because the crew is scheduled to be away from the line. Breaks are typically excluded from OEE calculations.
WIP
WIP stands for "Work in process". Any semi-manufactured part that is not ready for sale to the customer is WIP.