Deck 10: Dimensioning

Identify and describe two types of notes.

Local or specific notes-connected to specific features on views. General notes-separate from views and relate to the entire drawing.

Describe running and sliding fits (RC), locational fits (LC, LT, LN), and force fits (FN).

. Running and sliding fits (RC) are intended to provide a similar running performance with suitable lubrication allowance throughout their range of sizes. Locational fits are intended to determine only the location of the mating parts, may be rigid or accurate (as with interference fits), or provide some freedom of location (as with clearance fits). LC-clearance fits; LT-transition fits; LN-interference fits. Force fits (FN) are interference fits maintaining constant bore pressures, varying directly with diameter.

Define unidirectional dimensioning.

Unidirectional dimensioning: All numbers, figures, and notes be lettered horizontally and be read from bottom of drawing.

What is the recommended length-to-height ratio of arrowheads?

Name two classifications of dimensions.

Give the standard height of dimension text.

How should the decimal in numerals be treated?

Define the following terms; examples can be used if appro- priate: actual size; bilateral tolerance; dimension; feature; limits of dimension; specified dimension; tolerance; unilat- eral tolerance.

Describe how holes are located.

Identify a possible disadvantage of chain dimensioning.

Define maximum material condition (MMC).

Discuss proper dimension line spacing.

Should all of the dimension arrowheads on a drawing be the same size?

Specify the ASME document that governs the standard for dimensioning and tolerancing.

How are notes for holes dimensioned on an engineering document?

When all dimensions are metric, what is the general note that should accompany the drawing?

What are the recommended standard units of linear mea- surements on engineering documents?

Define least material condition (LMC).

Describe baseline dimensioning.

Describe a clearance fit.

Describe the surface condition and process used to estab- lish the following surface roughness heights given in mi- crometers: 12.5, 6.3, 3.2, 1.6, 0.80, 0.20, 0.050. Appendix E is a reference in addition to this chapter content.

Describe a delta note and when it is used.

Define forging. (See Chapter 5.)

Where are the general notes placed when using Military standards?

Define parting line.

Discuss the possible results of designing a part with specifi- cations that require overmachining.

Show three examples of the recommended placement of surface finish symbols.

What does it mean when a note such as .010 MAX DRAFT ANGLE is applied to the drawing for a plastic part?

List three factors that influence sheet size selection.

Identify two factors that influence drawing scale selection.

Where are general notes generally placed when using ASME standards?

Identify the units used to measure surface roughness height.

Describe tabular dimensioning.

Explain the difference between jigs and fixtures.

Define surface finish.

Define core. (See Chapter 5.)

Explain the purpose of draft angle on a casting or forging.

Explain what 1DFT means when applied to a dimension.

Define casting. (See Chapter 5.)

What does 2DFT mean when applied to a dimension?

Define and describe the use of progressive dies.

Drill fixtures are sometimes referred to as what?

Briefly explain the purpose of the ISO 9000 Quality Systems Standard.

Briefly explain the use of inspection fixtures.

Briefly describe the function of the ISO 9001.

Why is it important for a tool designer to be a good print reader?

Explain the purpose of the ISO 9000-1.

Describe the function of welding fixtures.

Identify at least four qualities that tools must have.

Give at least five reasons why an organization might want to have an ISO 9000 registration.

Describe the use of drill jigs.

What is the purpose of the ISO 9003 standard?

What is a pickoff jig?

What does ISO stand for?

Describe the ISO 9002 standard.

Explain how machining fixtures work.

Give the name of the organization that represents the United States in the ISO 9000.

Normally a jig or fixture is drawn as an assembly of the unit ready for use, and the workpiece or part to be held is drawn in position. How is the workpiece drawn in relationship to the jig or fixture?

Describe the use of drill fixtures.

Explain the purpose of the ISO 9004-1 standard.

Give the name of the ISO 9001 standard that has been spe- cifically related to the automotive industry.

Name the ISO 9001 standard that has been specifically re- lated to the aerospace industry. Part 2: General Tolerancing

Calculate the shaft and hole limits for a 1.125 in. diameter shaft using an RC4 fit. Show and label the elements of your calculations.

Determine the shaft and hole limits for a 1 in. diameter shaft using an RC4 fit. Show and label the elements of your calculations.

Using standard metric limits and fits with tolerances of close running fits, determine the limits of a 25-mm shaft. Display the required dimension with limits followed by the code in parentheses.

From the following list of given conditions, calculate the limits of the shaft and the limits of the hole. Show and label the elements of your calculations. (Review the allowance calculation formula.)

Name five items that a CADD system needs in order to place a dimension.

Using standard metric limits and fits with tolerances of close running fits, determine the limits of a 30-mm hole. Display the required dimension with limits followed by the code in parentheses.

With standard metric limits and fits using close running fits, determine the limits of a 25-mm hole. Give the required di- mension with limits followed by the code in parentheses.

List at least two reasons why CADD layering can assist the dimensioning process.

Given the following CAD drawing, calculate the allowance. Show and label the elements of your calculation.

Establish the shaft and hole limits for a .25 in. diameter shaft using an RC4 fit. Show and label the elements of your calculations.

By means of standard metric limits and fits with tolerances of close running fits, determine the limits of a 30-mm shaft. Show the required dimension with limits followed by the code in parentheses.

Define layering.