Deck 3: Process Choice and Layout Decisions in Manufacturing and Services

A cellular layout is another name for a functional layout.

Batch processing is less flexible than a production line and less efficient than a job shop.

A customer service function at an insurance firm that handles claims based on the first letter of the customer's last name is an example of applying group technology to a service operation.

________ gets its name from the fact that items are moved through the different manufacturing steps in groups.

The product-process matrix illustrates that low volume, one-of-a-kind products are ideally suited to a job shop process.

In a supply chain, the output from an upstream process is linked to the adjacent downstream process.

A(n)________ is a highly automated batch process that can reduce the cost of making groups of similar products.

A job shop manufacturing process is better suited to make a variety of products than a continuous flow process.

A batch manufacturing process may be linked only to another batch manufacturing process in a supply chain.

A product-based layout arranges resources sequentially according to the steps required to make a product.

No manufacturing process can be best at everything.

According to the law of variability, the ________ the random variability either demanded of the process or inherent in the process itself or in the items processed, the ________ productive the process is.

Draw the product-process matrix and discuss the placement of each process type

What is a cellular layout and what are its advantages?

According to the law of variability, converting from an assemble-to-order to a make-to-order production process should increase productivity of the manufacturing processes.

Make-to-stock products are typically produced using a production line.

In stark contrast to a product layout, a(n)________ layout is better suited to environments where the process steps can change dramatically from one job or customer to the next.

________ are products that are customized only at the very end of the manufacturing process.

Why are process decisions important?

________ products involve no customization but ________ products are completely customized.

A cellular layout is essentially the opposite of a(n)________ layout.

How can a supply chain operate with multiple different manufacturing processes linked across supply chain partners?

The product process matrix uses a scale of ________ and ________.

Provide an example (other than the one offered in the text)of a supply chain composed of manufacturers using at least three different types of manufacturing processes.

Products that use standard components, but the final configuration of those components is customer-specific, are called make-to-order products.

Activities that take place prior to the point of customization are called upstream activities.

"My tour of the Duff Brewery was the greatest experience of my life," Homer recalled. Lenny's favorite part was the batch process that was evident during the fermenting stage but Carl's favorite part was the high speed continuous flow process evident in the bottling line. "You're both right," Homer declared, "Duff takes both elements to create a(n)________ process."

What are the two types of product-based layouts? What are their similarities and differences and their advantages and disadvantages compared with other types of layouts and processes?

What are the four levels of customization and at what place does each occur in the supply chain?

As the degree of service customization decreases, managers have more opportunity to focus on cost and productivity.

Capability variety is the difference in how customers view an identical service outcome. What some customers might view as economical and thrifty others might view as cheap and poor value.

The back room refers to the part of the service process where the customer is not visible to the other customers waiting for service.

In a service blueprint, the two layers the customer is involved with are the ________ and the ________.

The ________ includes all the value-added physical and intangible activities that a service organization provides to the customer.

In a service package the greater the emphasis on intangible activities is, the more critical is the training and retention of skilled employees and the development and maintenance of the firm's knowledge assets.

Service positioning is based on the three axes of contact, customization, and cost.

The three dimensions of service positioning are the nature of the service package, the degree of customization and the degree of customer contact.

As the degree of customer contact decreases, more of the service package is provided by the ________ room.

The service package continuum ranges from immediate to delayed.

Define the term service package and describe management's focus for each activity.

Service operations compete and position themselves in the marketplace based on the three dimensions - ________, ________, and ________.

In a service blueprint, the line of internal interaction falls between the customer and the onstage service provider.

The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time and predecessor as shown in the table. They work a 7 hour day and want to produce at a rate of 360 units per day. What should their takt time be? $$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \text { A } & 45 & \cdots \\\hline \text { B } & 50 & \text { A } \\\hline \text { C } & 40 & \text { A } \\\hline \text { D } & 55 & \text { B, C } \\\hline \text { E } & 40 & \text { D } \\\hline \text { F } & 65 & \text { D } \\\hline \text { G } & 25 & \text { E } \\\hline \text { H } & 35 & \text { F, G } \\\hline\end{array}$$

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 7.5 productive hours available in a day and the manufacturer wishes to produce 400 units. Balance the line by assigning tasks to workstations to fill up as much takt time as possible. Break ties by assigning the longest task first.
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \text { A } & 45 & \cdots \\\hline \text { B } & 50 & \text { A } \\\hline \text { C } & 20 & \text { A } \\\hline \text { D } & 55 & \text { A } \\\hline \text { E } & 15 & \text { D } \\\hline \text { F } & 65 & \text { D } \\\hline \text { G } & 25 & \text { E } \\\hline \text { H } & 35 & \text { B, C, F, G } \\\hline\end{array}$$

-Refer to the scenario above. Without using more than one worker per station, what is the maximum output achievable in the 7.5 hour work day?

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 7.5 productive hours available in a day and the manufacturer wishes to produce 400 units. Balance the line by assigning tasks to workstations to fill up as much takt time as possible. Break ties by assigning the longest task first.
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \text { A } & 45 & \cdots \\\hline \text { B } & 50 & \text { A } \\\hline \text { C } & 20 & \text { A } \\\hline \text { D } & 55 & \text { A } \\\hline \text { E } & 15 & \text { D } \\\hline \text { F } & 65 & \text { D } \\\hline \text { G } & 25 & \text { E } \\\hline \text { H } & 35 & \text { B, C, F, G } \\\hline\end{array}$$

-Refer to the scenario above. What is the takt time?

Name a service business that relies heavily on intangible activities. How does the level of intangibility fit with the degrees of contact and customization?

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 7.5 productive hours available in a day and the manufacturer wishes to produce 400 units. Balance the line by assigning tasks to workstations to fill up as much takt time as possible. Break ties by assigning the longest task first.
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \text { A } & 45 & \cdots \\\hline \text { B } & 50 & \text { A } \\\hline \text { C } & 20 & \text { A } \\\hline \text { D } & 55 & \text { A } \\\hline \text { E } & 15 & \text { D } \\\hline \text { F } & 65 & \text { D } \\\hline \text { G } & 25 & \text { E } \\\hline \text { H } & 35 & \text { B, C, F, G } \\\hline\end{array}$$

-Refer to the scenario above. The process design team realizes that the potential spike in demand for this device requires increased output. They elect to add a seventh worker to their production team at the first station. What is the net effect of adding this worker?

The table depicts a production line that has been balanced with a takt time of 2 minutes. What is the efficiency of this balance? $$\begin{array} { | l | c | c | c | c | c | c | } \hline \text { Workstation } & 1 & 2 & 3 & 4 & 5 & 6 \\\hline \text { Task } & \mathrm { A } , \mathrm { B } & \mathrm { C } & \mathrm { D } , \mathrm { E } , \mathrm { F } & \mathrm { G } , \mathrm { H } & \mathrm { I } & \mathrm { J } , \mathrm { K } , \mathrm { L } \\\hline \text { Time } ( \mathrm { min } ) & 1,1 & 1.8 & 1,0.5,0.4 & 0.9,0.8 & 1.8 & 0.5,0.5,0.6 \\\hline\end{array}$$

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 8 productive hours available in a day and the manufacturer wishes to produce 400 units. Use this information to answer the following question(s).
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \mathrm { J } & 45 & \cdots \\\hline \text { K } & 50 & \mathrm {~J} \\\hline \mathrm { L } & 40 & \mathrm {~J} \\\hline \mathrm { M } & 55 & \mathrm {~K} , \mathrm {~L} \\\hline \mathrm { N } & 40 & \mathrm { M } \\\hline \mathrm { O } & 65 & \mathrm { M } \\\hline \text { P } & 25 & \mathrm {~N} \\\hline \text { R } & 35 & \mathrm { O } , \mathrm { P } \\\hline\end{array}$$

-Refer to the scenario above. What is the theoretical minimum number of stations?

Name two restaurants that score differently on at least two scales in the service positioning space and provide examples of how they differ.

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 8 productive hours available in a day and the manufacturer wishes to produce 400 units. Use this information to answer the following question(s).
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \mathrm { J } & 45 & \cdots \\\hline \text { K } & 50 & \mathrm {~J} \\\hline \mathrm { L } & 40 & \mathrm {~J} \\\hline \mathrm { M } & 55 & \mathrm {~K} , \mathrm {~L} \\\hline \mathrm { N } & 40 & \mathrm { M } \\\hline \mathrm { O } & 65 & \mathrm { M } \\\hline \text { P } & 25 & \mathrm {~N} \\\hline \text { R } & 35 & \mathrm { O } , \mathrm { P } \\\hline\end{array}$$

-Refer to the scenario above. The manager assigns tasks to workstations and breaks ties using a longest operation heuristic. That is, if two or three tasks could be assigned to a given station, the manager assigns the longest task first and then fills in the remaining time at the workstation as completely as possible. Using this approach, what task(s)would be assigned at the fourth station?

The table depicts a production line that has been balanced with a takt time of 2 minutes. What is the percent idle time of this balance? $$\begin{array} { | l | c | c | c | c | c | c | } \hline \text { Workstation } & 1 & 2 & 3 & 4 & 5 & 6 \\\hline \text { Task } & \mathrm { A } , \mathrm { B } & \mathrm { C } & \mathrm { D } , \mathrm { E } , \mathrm { F } & \mathrm { G } , \mathrm { H } & \mathrm { I } & \mathrm { J } , \mathrm { K } , \mathrm { L } \\\hline \text { Time } ( \mathrm { min } ) & 1,1 & 1.8 & 1,0.5,0.4 & 0.9,0.8 & 1.8 & 0.5,0.5,0.6 \\\hline\end{array}$$

The table depicts an production line that has been balanced with a takt time of 2 minutes. Where would you add a worker if you wanted to increase the output rate while keeping six work stations? $$\begin{array} { | l | c | c | c | c | c | c | } \hline \text { Workstation } & 1 & 2 & 3 & 4 & 5 & 6 \\\hline \text { Task } & \mathrm { A } , \mathrm { B } & \mathrm { C } & \mathrm { D } , \mathrm { E } , \mathrm { F } & \mathrm { G } , \mathrm { H } & \mathrm { I } & \mathrm { J } , \mathrm { K } , \mathrm { L } \\\hline \text { Time } ( \mathrm { min } ) & 1,1 & 1.8 & 1,0.5,0.4 & 0.9,0.8 & 1.8 & 0.5,0.5,0.6 \\\hline\end{array}$$

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 7.5 productive hours available in a day and the manufacturer wishes to produce 400 units. Balance the line by assigning tasks to workstations to fill up as much takt time as possible. Break ties by assigning the longest task first.
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \text { A } & 45 & \cdots \\\hline \text { B } & 50 & \text { A } \\\hline \text { C } & 20 & \text { A } \\\hline \text { D } & 55 & \text { A } \\\hline \text { E } & 15 & \text { D } \\\hline \text { F } & 65 & \text { D } \\\hline \text { G } & 25 & \text { E } \\\hline \text { H } & 35 & \text { B, C, F, G } \\\hline\end{array}$$

-Refer to the scenario above. What task(s)should be assigned at the third workstation?

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 7.5 productive hours available in a day and the manufacturer wishes to produce 400 units. Balance the line by assigning tasks to workstations to fill up as much takt time as possible. Break ties by assigning the longest task first.
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \text { A } & 45 & \cdots \\\hline \text { B } & 50 & \text { A } \\\hline \text { C } & 20 & \text { A } \\\hline \text { D } & 55 & \text { A } \\\hline \text { E } & 15 & \text { D } \\\hline \text { F } & 65 & \text { D } \\\hline \text { G } & 25 & \text { E } \\\hline \text { H } & 35 & \text { B, C, F, G } \\\hline\end{array}$$

-Refer to the scenario above. What is the theoretical minimum number of stations that will be used if the line is balanced using the appropriate takt time?

Where should a business consultant position herself on the three axes of contact, customization, and cost.

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 7.5 productive hours available in a day and the manufacturer wishes to produce 400 units. Balance the line by assigning tasks to workstations to fill up as much takt time as possible. Break ties by assigning the longest task first.
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \text { A } & 45 & \cdots \\\hline \text { B } & 50 & \text { A } \\\hline \text { C } & 20 & \text { A } \\\hline \text { D } & 55 & \text { A } \\\hline \text { E } & 15 & \text { D } \\\hline \text { F } & 65 & \text { D } \\\hline \text { G } & 25 & \text { E } \\\hline \text { H } & 35 & \text { B, C, F, G } \\\hline\end{array}$$

-Refer to the scenario above. How many workstations must be added to increase the output rate to one unit per minute?

Champion Cooling has just signed a contract to assemble window air conditioners for another company. The list of tasks, including time requirements and immediate predecessors, follows. Each task may not be shortened. Initially, the plan was to make 300 units in an eight hour day but as the summer months approach, Champion Cooling finds themselves far behind in total production. They wish to reconfigure their production line in order to produce maximum output. What should their takt time be? $$\begin{array} { | l | c | c | } \hline \text { Task } & \text { Time (min) } & \text { Predecessor } \\\hline \text { Bolt compressor to base } & 5 & \text { None } \\\hline \text { Install coils and lines } & 6 & \text { Bolt compressor to base } \\\hline \text { Install fan motor } & 7 & \text { Install coils and lines } \\\hline \text { Install switch and thermostat } & 5 & \text { Install fan motor } \\\hline \text { Charge system and test } & 10 & \text { Install switch and thermostat } \\\hline \text { Cosmetic detailing } & 7 & \text { Charge system and test } \\\hline\end{array}$$

Which poses the greatest underlying managerial challenges - a service that is extremely high on customization, contact, and tangibility or perchance a service that is extremely low on contact, customization and tangibility? Provide an example of a service that fits each space and defend your answer.

Define the terms front room and back room and describe the roles these processes play in service operations. What must operations managers take into consideration when setting up these two processes?

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 7.5 productive hours available in a day and the manufacturer wishes to produce 400 units. Balance the line by assigning tasks to workstations to fill up as much takt time as possible. Break ties by assigning the longest task first.
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \text { A } & 45 & \cdots \\\hline \text { B } & 50 & \text { A } \\\hline \text { C } & 20 & \text { A } \\\hline \text { D } & 55 & \text { A } \\\hline \text { E } & 15 & \text { D } \\\hline \text { F } & 65 & \text { D } \\\hline \text { G } & 25 & \text { E } \\\hline \text { H } & 35 & \text { B, C, F, G } \\\hline\end{array}$$

-Refer to the scenario above. The process engineer calculates the takt time and examines the task times indicated in the table. He decides to use the minimum cycle time instead and have the workers leave early each day once they have built 400 units. How much earlier would the workers leave?

Use this scenario for the following question(s).
The process design team at a manufacturer has broken an assembly process into eight basic steps, each with a required time, and predecessor as shown in the table. There are 8 productive hours available in a day and the manufacturer wishes to produce 400 units. Use this information to answer the following question(s).
$$\begin{array} { | c | c | c | } \hline \text { Task } & \text { Time } ( \mathrm { sec } ) & \text { Predecessor } \\\hline \mathrm { J } & 45 & \cdots \\\hline \text { K } & 50 & \mathrm {~J} \\\hline \mathrm { L } & 40 & \mathrm {~J} \\\hline \mathrm { M } & 55 & \mathrm {~K} , \mathrm {~L} \\\hline \mathrm { N } & 40 & \mathrm { M } \\\hline \mathrm { O } & 65 & \mathrm { M } \\\hline \text { P } & 25 & \mathrm {~N} \\\hline \text { R } & 35 & \mathrm { O } , \mathrm { P } \\\hline\end{array}$$

-Refer to the scenario above. Operations managers and process engineers design a line that contains seven stations. What is the percentage of idle time?