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Chapter 11 Fasteners and Springs Test

INSTRUCTIONS

ANSWER THE QUESTIONS WITH SHORT, COMPLETE STATEMENTS OR DRAWINGS AS NEEDED.

QUESTIONS

DEFINE THE SCREW THREAD TERMS GIVEN IN QUESTIONS 1 THROUGH 11.

1. Axis

2. Classes of threads

3. Fit

4. Die

5. Major diameter

6. Minor diameter

7. Pitch

8. Tap

9. Tap drill

10. Thread

11. Threads per inch

12. Name and describe three types of taps.

13. Name the three methods of thread representation.

14. What thread representation is most commonly used and why?

15. Why is it common, when possible, to drill deeper than the intended depth of the tap?

16. Why should an internal tap be deeper than the fastener thread?

17. Identify the components of the following metric thread note.

M 2.5 ⨉ 0.45 ⎼ 6g

18. Identify the components of the following unified screw thread note.

7/8 ⎼ 14 UNF ⎼2 B

19. When is the abbreviation LH used at the end of a thread note?

20. What assumption is made about the thread if LH is not placed at the end of the thread note?

21. Identify two functions of thread inserts.

22. What are set screws used for?

23. What type of information is required to completely identify a bolt or screw?

24. Identify two applications for taper pins.

25. Identify two applications for washers.

26. What are retaining rings used for?

27. What is the principal application for keys?

28. How are standard key sizes determined?

29. Define keyseat.

30. What are rivets used for, and how are they applied?

31. Standard thread forming tools generally have lead in chamfers that produce how many incomplete threads on the leading edge of the tool?

32. Define runout.

33. Give two problems that can occur when designing features that do not provide enough allowance for runout or sufficient room for the tool.

34. Define blind hole.

35. Give three reasons why through threaded holes are preferred over blind threaded holes from a manufacturing standpoint.

36. Taper taps generally have how many lead in chamfers?

37. Bottoming taps generally have how many lead in chamfers?

38. Plug taps generally have how many lead in chamfers?

39. Name the type of tap that is the most commonly used production tool for thread forming.

40. Give the minimum formula that you would use when determining pilot hole depth.

41. According to ASME Y14.6, what is the general guideline for the dimension specified on a drawing for thread depth in a blind hole?

42. What does a thread chamfer or countersink in the pilot hole help prevent?

43. Give the specifications for a reasonable chamfer or countersink on the pilot hole.

44. Give the general rule that can be used when designing the minimum tool runout for external threads.

45. External threads should have a lead in chamfer for tooling. Give the general guideline for the applied chamfer diameter for this application.

46. If a relief is used on external threads, the applied relief diameter should not exceed what specification?

47. Identify the two optional provisions that must be used when designing a threaded joint with a shoulder.

48. List the three major functions of pipe threads.

49. Give the drawing angle that is recommended for representing a taper pipe thread.

50. Define self-clinching fastener.

51. Define spring and give the basic design principle.

52. Identify at least three design criteria used in spring design.

53. Describe spring index and explain what the spring index is a factor in determining.

54. Identify at least one design factor related to helix direction.

55. Define coil related to spring terminology, and identify active coils and total coils.

56. Describe deflection related to a compression spring and an extension spring.

57. What is helix direction, and how is helix direction specified?

58. Define spring pitch.

59. Give the basic function of a torsion spring.

60. Describe a flat spring and give at least one use for a flat spring.

61. Give another name for wave springs, and describe the advantage of using wave springs rather than coil springs.

62. Identify and name the national standard that provides detailed descriptions, drafting practices, and examples of most common springs used in manufacturing.

63. No matter which spring representation method is used, several important specifications must accompany the spring drawing. What is this information or specification called, and how is it placed on the drawing? List at least eight items that are included.

64. Briefly explain the application of phantom lines used when drawing a detailed thread representation. Phantom lines can be used to simplify the drafting of repeated detail.

65. Discuss why the schematic spring representation is not as commonly used as the detailed spring representation.

Chapter 11 Fasteners and Springs Problems

INSTRUCTIONS

1. FROM THE SELECTED PROBLEMS, DETERMINE WHICH VIEWS AND DIMENSIONS SHOULD BE USED TO COMPLETELY DETAIL THE PART. USE SIMPLIFIED REPRESENTATION FOR THREAD REPRESENTATIONS UNLESS OTHERWISE SPECIFIED IN THE INSTRUCTIONS OR BY YOUR INSTRUCTOR. USE DETAILED REPRESENTATION FOR SPRING REPRESENTATIONS UNLESS OTHERWISE SPECIFIED IN THE INSTRUCTIONS OR BY YOUR INSTRUCTOR.

2. Make a multiview sketch to proper proportions, including dimensions and notes.

3. Using the sketch as a guide, draw an original multiview drawing on an adequately sized ASME drawing sheet with border and sheet blocks. Add all necessary dimensions and notes using unidirectional dimensioning.

4. Include the following general notes at the lower left corner of the sheet .5 in. each way from the corner border lines:

NOTES:

1. DIMENSIONING AND TOLERANCING PER ASME Y14.5-2009.

2. REMOVE ALL BURRS AND SHARP EDGES.

Additional general notes can be required, depending on the specifications of each individual assignment. Use the following tolerances for unspecified inch values. A tolerance block is recommended as described in Chapter 2, Drafting Equipment, Media, and Reproduction Methods, and as shown in problems for Chapter 10, Dimensioning and Tolerancing, unless otherwise specified.

|Unspecified Tolerances |

|Decimals |mm |In. |

|X | |±.1 |

|XX | |±.01 |

|XXX | |±.005 |

|ANGULAR | |±30' |

|FINISH |3.2 µm |125 µin. |

For metric drawings, provide a general note that states TOLERANCES FOR UNSPECIFIED DIMENSIONS COMPLY WITH ISO 2768-m. Provide a general note that states SURFACE FINISH 3.2 µm UNLESS OTHERWISE SPECIFIED.

PART 1: PROBLEMS 11.1 THROUGH 11.24

PROBLEM 11.1 (IN.)

Part Name: Full Dog Point Gib Screw

Material: 10-32 UNF-2A .75 long

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PROBLEM 11.2 (in.)

Part Name: Thumb Screw

Material: SAE 1315 steel

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PROBLEM 11.3 (in.)

Part Name: H-Step Threading Screw

Material: SAE 3130

SPECIFIC INSTRUCTIONS: Draw each of the three threads using the representation specified below each thread note.

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PROBLEM 11.4 (metric)

Part Name: Knurled Hex Soc Head Step Screw

Material: SAE 1040

Case Harden: 1.6-mm deep per Rockwell C scale

Finish: 2 µm; black oxide

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PROBLEM 11.5 (in.)

Part Name: Machine Screw

Material: Stainless steel

Finish All Over: 2 µm

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PROBLEM 11.6 (metric)

Part Name: Lathe Dog

Material: Cast iron

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PROBLEM 11.7 (in.)

Part Name: Threaded Step Shaft

Material: SAE 1030

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PROBLEM 11.8 (in.)

Part Name: Washer Face Nut

Material: SAE 1330 steel

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PROBLEM 11.9 (in.)

Part Name: Shoulder Screw

Material: SAE 4320 steel

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PROBLEM 11.10 (in.)

Part Name: Stop Screw

Material: SAE 4320

Hex Depth: .175

Note: Medium diamond knurl at head

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PROBLEM 11.11 (metric)

Part Name: Vise base

Material: Cast iron

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PROBLEM 11.12 (metric)

SPECIFIC INSTRUCTIONS: Create spring drawing based on the following specifications:

Part Name: Compression Spring

Material: 2.5-mm steel spring wire

Ends: Plain ground

Outside Diameter: 25

Free Length: 75

Number of Coils: 16

Finish: Chrome plate

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PROBLEM 11.13 (metric)

Part Name: Flat Spring

Material: 3.5-mm spring steel

Finish: Black oxide

Heat Treat: 1-mm deep Rockwell C scale

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PROBLEM 11.14 (in.)

Part Name: Retaining Ring

Material: Stainless steel

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PROBLEM 11.15 (in.)

Part Name: Half Coupling

Material: Ø1.250 C1215 steel

Problem based on original art courtesy TEMCO.

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PROBLEM 11.16 (in.)

Part Name: Collar

Material: SAE 1020

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PROBLEM 11.17 (in.)

Part Name: Bearing Nut

Material: SAE 1040

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PROBLEM 11.18 (in.)

Part Name: Adjustment Screw

Material: SAE 2010 steel

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PROBLEM 11.19 (in.)

Part Name: Screw Shaft

Material: 3/4 hex × 4 1/8 stock mild steel

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PROBLEM 11.20 (in.)

Part Name: Packing Nut

Material: Bronze

A: Spanner slots .250 wide ⨉ .063 deep.

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PROBLEM 11.21 (in.)

Part Name: Pump Pivot Support

Material: Cold rolled mild steel

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PROBLEM 11.22 (in.)

Part Name: Set Screw

Material: Steel

SPECIFIC INSTRUCTIONS: Prepare a detailed drawing from the written instructions below.

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PROBLEM 11.23 (in.)

Part Name: Spiral Torsion Spring

Material: SAE 1060

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PROBLEM 11.24 (in.)

Part Name: Flat Spring

Material: SAE 4063

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Math Problems

PART 2: PROBLEMS 11.25 THROUGH 11.31

PROBLEM 11.25 The taper of a pin is .5:12. What would be the taper for a 5 in. long pin?

PROBLEM 11.26 A lathe operator turns out 9 brass bushings in 2 hours 15 minutes. At the same rate, how many bushings can be turned in 8 hours?

PROBLEM 11.27 Seventeen drills cost $27.50. What would seven drills cost?

PROBLEM 11.28 The scale on a landscape map is 1:50. If two points on the map are 3.5" apart, what is the actual distance between the two points?

PROBLEM 11.29 A crew of twelve people assembles 45 units a day. If production is to be increased to 80 units per day, how many people will be needed?

PROBLEM 11.30 If five dozen shop cloths are enough for six mechanics, how many cloths will be needed for eleven mechanics?

PROBLEM 11.31 A shop manual chain hoist requires a 22-lb pull to lift one ton (2000 lb). How much pull would it take to lift a 1500-lb load

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DRAFTING TEMPLATES

TO ACCESS CADD TEMPLATE FILES WITH PREDEFINED DRAFTING SETTINGS, GO TO THE STUDENT COMPANION WEBSITE, SELECT STUDENT DOWNLOADS, DRAFTING TEMPLATES, AND THEN THE APPROPRIATE TEMPLATE FILE. USE THE TEMPLATES TO CREATE NEW DESIGNS, AS A RESOURCE FOR DRAWING AND MODEL CONTENT, OR FOR INSPIRATION WHEN DEVELOPING YOUR OWN TEMPLATES. THE ASME-INCH AND ASME-METRIC DRAFTING TEMPLATES FOLLOW ASME, ISO, AND RELATED MECHANICAL DRAFTING STANDARDS. DRAWING TEMPLATES INCLUDE STANDARD SHEET SIZES AND FORMATS, AND A VARIETY OF APPROPRIATE DRAWING SETTINGS AND CONTENT. YOU CAN ALSO USE A UTILITY SUCH AS THE AUTOCAD DESIGNCENTER TO ADD CONTENT FROM THE DRAWING TEMPLATES TO YOUR OWN DRAWINGS AND TEMPLATES. CONSULT WITH YOUR INSTRUCTOR TO DETERMINE WHICH TEMPLATE DRAWING AND DRAWING CONTENT TO USE.

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