JUST IN TIME PRODUCTION SYSTEMS:Operational Benefits, Kanban Formula

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Production and Operations Management MGT613

Lesson 37

JUST IN TIME PRODUCTION SYSTEMS

We have progressed our discussion on Lean Production Systems and Just In Time Systems and we will

now focus our attention upon Lean Systems in Services, Operational Benefits associated with JIT. We

will also note some of the common Implementation Issues along which the Organizational face while

implementing JIT. We also need to know what single Kanban System is and solve some examples.

Characteristics of Lean Systems: Just-in-Time

Continuous Improvement with the help of Lean Systems is possible if Operations Managers are able

to focus on some of the common characteristics of Lean Systems, which include:

Pull method of materials flow

Consistently high quality

Small lot sizes

Uniform workstation loads

Standardized components and work methods

Close supplier ties

Flexible workforce

Line flows

Maintenance

10.

Automated production

11.

Preventive maintenance

The figure below of a ship sailing through waters is a great representation of an organization

carrying its business with hidden rocks (barriers) like scrap, unreliable suppliers and capacity

imbalance, carrying the threat of sinking the ship. With proper and effective lean production system

philosophy in place, this can be avoided and organization can continue to sail through smooth and

calm waters.

Unreliable

Capacity

Scrap

suppliers

imbalance

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Production and Operations Management MGT613

Lean Systems in Services

Consistently high quality

Uniform facility loads

Standardized work methods

Close supplier ties

Flexible workforce

Automation

Preventive maintenance

Pull method of materials flow

Line flows

Operational Benefits

Reduce space requirements

Reduce inventory investment

Reduce lead times

Increase labour productivity

Increase equipment utilization

Reduce paperwork and simple planning systems

Valid priorities for scheduling

Workforce participation

Increase product quality

Implemental Issues

1. Organizational considerations

a. Human cost of JIT systems

b. Cooperation and trust

c. Reward systems and labour classifications

2. Process considerations

3. Inventory and scheduling

a. MPS stability

b. Setups

c. Purchasing and logistics

Kanban Production Control System

Kanban: Card or other device that communicates demand for work or materials from the preceding

station.

Kanban is the Japanese word meaning "signal" or "visible record".

Paperless production control system.

Authority to pull, or produce comes from a downstream process.

Kanbans also govern the assembly or Parts' movement authorization

Kanban Formula

We can mathematically construct the Kanban Formula, If we designate the following alphabets

N = Total number of containers ( Or Kanban Cards)

D = Planned usage rate of using work center

T = Average waiting time for replenishment of parts

plus average production time for a

container of parts

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Production and Operations Management MGT613

X = Policy variable set by management

- possible inefficiency in the system often called Alpha

C = Capacity of a standard container

DT(1+X)

Often the same formula above is used with the following parameters in mind

N= # cards

D= usage

T = wait + process time

X = efficiency rating

C = bin capacity

Example

A company in Gujranwala is making rubber tyres and tubes. The operations manager has just

completed his MBA from VU and has observed the that factory has inefficient machine group. He

records that the daily demand for 21" tube is 1000 units. The average waiting time for a container of

the same part is 0.5 day. The processing time for the tyre tube container is 0.25 day. A container can

hold 500 units, currently there are 20 containers for this item.

Calculate

1. What is the value of policy variable ALPHA?

2. What is the total planned inventory (work in process and finished goods) for the tyre tube?

3. Suppose that the policy variable Alpha is 0, how many containers would be needed? what is

the effect of policy variable in this problem?

Solution

The given data is

d is 1000 units, w bar = 0.5 day.

P bar= 0.25 day. K= 500 units and Alpha is to be calculated.

We use the equation and substitute values

d( w + p )( 1 +α )

Then with 20 containers in the system and since each container can hold 500 units, the total planned

inventory is 20 (500)= 10,000 units

If Alpha is 0 then on substituting values we have

1000(0.5 +0.25 )( 1 + α )

500 =

(1 + a )=500 X 20 / 1000 (0.75)

(1 + a )=10,000/750=13.33

a =12.33

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Production and Operations Management MGT613

Then with 20 containers in the system and since each container can hold 500 units, the total

planned inventory is 20 ( 500)= 10,000 units

If Alpha is 0 then on substituting values we have

1000(0.5 +0.25 )( 1 + 0 )

500

1000(0.75 )( 1 )

500

K= 750/500= 1.5 or more correctly 2 containers.

Single-Card Kanban System

Each container must have a card.

Assembly always withdraws from fabrication (pull system).

Containers cannot be moved without a kanban.

Containers should contain the same number of parts.

Only good parts are passed along.

Production should not exceed authorization.

Summary

Organizations use different methods and means to signal the need for material replenishment and

production, in this lecture we studied the effective kanban system and learnt how a single card Kanban,

JIT System can be used to control production flow.

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