Trapezoidal thread forms are screw thread profiles with trapezoidal outlines. They are the most common forms used for leadscrews (power screws). They offer high strength and ease of manufacture. They are typically found where large loads are required, as in a vise or the leadscrew of a lathe. Standardized variations include multiple-start threads, left-hand threads, and self-centering threads (which are less likely to bind under lateral forces). The original trapezoidal thread form, and still probably the one most commonly encountered worldwide, is the Acme thread form (/ˈækmiː/ AK-mee). The Acme thread was developed in 1894 as a profile well suited to power screws that has various advantages over the square thread,[note 1] which had been the form of choice until then. It is easier to cut via either single-point threading or die than the square thread is (because the latter's shape requires tool bit or die tooth geometry that is poorly suited to cutting); it wears better than square (because the wear can be compensated for); it is stronger than a comparably sized square thread; and it makes for smoother engagement of the half nuts on a lathe leadscrew than square does. The trapezoidal metric thread form is similar to the Acme thread form, except the thread angle is 30°. It is codified by DIN 103. While metric screw threads are more prevalent worldwide than imperial threads for triangular thread forms, the imperially sized Acme threads predominate in the trapezoidal thread form. In some cases customers prefer Acme threads for power screws regardless of metric standards used elsewhere in the product.
1 Acme thread characteristics 2 Trapezoidal metric thread characteristics 3 Other trapezoidal threads 4 See also 5 Notes 6 References 7 Bibliography 8 External links
Acme thread characteristics
Basic Acme thread profile
The Acme thread form has a 29° thread angle with a thread height half of the pitch; the apex (or crest) and valley (or root) are flat. This shape is easier to machine (faster cutting, longer tool life) than is a square thread. The tooth shape also has a wider base which means it is stronger (thus, the screw can carry a greater load) than a similarly sized square thread. This thread form also allows for the use of a split nut, which can compensate for nut wear. The line of General Purpose (GP) Acme threads (ASME/ANSI B1.5-1997) are not designed to sustain external radial loads and both the nut and bolt are, ideally, independently supported, the nut by a linear guide and the screw by shaft bearings. This is due to the need to avoid "wedging" of the thread flanks when subjected to radial loads, which would contribute substantially to friction forces and thread wear. However, there is a centralizing Acme-thread standard (also specified in ASME/ANSI B1.5-1997) which caters to applications where the threads are not radially supported, where the roots and crests of opposing threads are designed to come into contact before the flanks do, under radial loads. This adds the requirement that the sum of the allowances and tolerances on the major diameters of nut and bolt be less than the sum of the allowances on the pitch diameters (PD); the drawback is that, for a given amount of end play (axial clearance, due solely to PD deviations), closer tolerances and cleaner work environment are necessitated in the application of a centralizing Acme thread. Compared to square threads, disadvantages of the Acme thread form are lower efficiency due to higher friction and some radial load on the nut (angular offset from square). When created prior to 1895, Acme screw threads were intended to replace square threads and a variety of threads of other forms used chiefly for the purpose of traversing on machines, tools, etc. Acme screw threads are now extensively used for a variety of purposes. Long-length Acme threads are used for controlled movements on machine tools, testing machines, jacks, aircraft flaps, and conveyors. Short-length threads are used on valve stems, hose connectors, bonnets on pressure cylinders, steering mechanisms, and camera lens movement. The thread form shown in the figure is called basic; the actual thread heights on both the internal (nut) and external (bolt) threads differ from P/2 by the difference between two allowances (or clearances):
A root-crest clearance between opposing threads of 0.01-in. minimum evenly-distributed clearance for 10 or less threads-per-inch pitches, 0.005-in. for finer pitches (this is also true for the minor diameters of the centralizing Acme thread, though not its major diameters, where the allowance is made less than the PD allowance) A PD allowance, small compared to the first in the case of the GP and external centralizing Acme threads, but greater in the case of the internal centralizing Acme thread.
The net effect is that the minimum thread heights are greater than basic for the internal and external GP and for the external centralizing, and the maximum height is shorter than basic for the internal centralizing Acme threads. The maximum diameter (within tolerance) at the crest of the screw threads, called the max major diameter of external thread, is that of the basic thread form and equals the "nominal diameter," D, stated in the screw's designation; the minimum diameter (within tolerance) at the crest of the nut thread, called the min minor diameter of internal thread, is that of the basic thread form and equals the nominal diameter minus twice the basic thread height (i.e. D - P). Finally, there also exists a stub Acme-thread standard, identical in all respects to the one just described except for the height of the basic thread being 0.3P.
Standard Acme thread pitches for diameters in Imperial and US customary units
Nominal diameter (in) Pitch (in) Thread density (1/in)
1⁄4 1⁄16 16
5⁄16 1⁄14 14
3⁄8 1⁄12 12
1⁄2 1⁄10 10
5⁄8 1⁄8 8
3⁄4, 7⁄8 1⁄6 6
1, 1 1⁄4 1⁄5 5
1 1⁄2, 1 3⁄4, 2 1⁄4 4
2 1⁄2 1⁄3 3
3 1⁄2 2
Trapezoidal metric thread characteristics In case of the trapezoidal thread form the angle is 30° instead of 29°. All dimensions are in millimeters. Trapezoidal threads are defined as follows by ISO standards:
60 × 9
displaystyle Tr,60times 9
where Tr designates a trapezoidal thread, 60 is the nominal diameter in millimeters, and 9 is the pitch in millimeters. When there is no suffix it is a single start thread. If there is a suffix then the value after the multiplication sign is the lead and the value in the parentheses is the pitch. For example:
60 × 18 ( P 9 ) L H
displaystyle Tr,60times 18(P9)LH
would denoted two starts, as the lead divided by the pitch is two. The "LH" denotes a left hand thread.
Standard trapezoidal thread pitches for metric diameters
Nominal diameter (mm) Pitch (mm) Reference
14, 16 4
24, 28 5 
32, 36 6 
40, 44 7 
48, 52 8 
60 9 
70, 80 10 
90, 100 12 
Other trapezoidal threads For maintaining air conditioning systems using R134a gas, a non standard "ACME" thread is specified for gas canisters.
Thread pitch for R134a gas canisters
Nominal diameter (in) Pitch (in) Thread density (1/in)
1⁄2 1⁄16 16
Simpson, John and Proffitt, Michael, ed.s, "acme", Oxford English Dictionary: Additions Series, vol. 3 (Oxford, England: Oxford University Press, 1997), p. 10. The Acme thread was proposed by Albert Man Powell, then president of the Powell Planer Co. of Worcester, Massachusetts. See:
Powell, A.M. (24 January 1895) "The proposed new screw thread," American Machinist, 18 (4) : 66. Powell, A.M. (24 January 1895) "A new screw thread," American Machinist, 18 (4) : 69–71. For a brief biography of Albert Man Powell (with photograph), see: Rice, Franklin P., The Worcester of Eighteen Hundred and Ninety-Eight: Fifty Years a City (Worcester, Massachusetts: F.S. Blanchard & Co.,1899),pp. 150–151.
The name "Acme thread" was proposed by A. W. [Albert Ward] Handy (1845 October 7 (Bristol, Rhode Island) – 1915 August 27 (Malden, Massachusetts)), who was then a sales representative of the Acme Machinery Co. of Cleveland, Ohio, which made various machine tools. See: (Editorial staff) (3 January 1895) "A proposed new standard screw thread," American Machinist, 18 (1) : 1–2.
^ Bhandari 2007, pp. 202–204 ^ Oberg 1908, p. 30. ^ Jones 1964, pp. 176–177. ^ a b Bhandari 2007, p. 204 ^ a b c Trapezoidal coarse thread ^ a b c Trapezoidal fine thread ^ Green 1996, p. 1703. ^ Bhandari 2007, pp. 203–204 ^ American Society of Mechanical Engineers (1997), ASME B1.5 - 1997 Acme Screw Threads, ASME Press, ISBN 0-7918-2482-9. ^ Shigley, Mischke & Budynas 2003, p. 400 ^ a b c d e f g h Bhandari 2007, p. 205 ^ "Unique Fittings & Label Colors for MVAC Refrigerants". United States Environmental Protection Agency. Retrieved 10 July 2017.
Bhandari, V B (2007), Design of Machine Elements, Tata McGraw-Hill, ISBN 978-0-07-061141-2 . Flather, John Joseph (1895), Rope-driving: a treatise on the transmission of power by means of fibrous ropes (1st ed.), New York, NY, USA: J. Wiley & Sons, LCCN 06034155. Oberg, Erik; Jones, Franklin D.; Horton, Holbrook L.; Ryffel, Henry H. (1996), Green, Robert E.; McCauley, Christopher J., eds., Machinery's Handbook (25th ed.), New York, NY, USA: Industrial Press, ISBN 978-0-8311-2575-2, OCLC 473691581. Jones, Franklin D. (1964), Machine shop training course, 1 (5th ed.), New York, NY, USA: Industrial Press, ISBN 978-0-8311-1039-0. Oberg, Erik (1908), Handbook of small tools: comprising threading tools, taps, dies, cutters, drills, and reamers, together with a complete treatise on screw-thread systems, New York, NY, USA: John Wiley & Sons. Co-edition, 1908, Chapman & Hall, London, UK. Shigley, Joseph E.; Mischke, Charles R.; Budynas, Richard Gordon (2003), Mechanical Engineering Design (7th ed.), McGraw Hill, ISBN 978-0-07-252036-1 .
Standard Acme threads Nominal dimension for trapezoidal thread profiles Trapezoidal coarse thread Trapezoidal fine thread Stub ACME Thread Sizes and Data Chart ASME: Acme Screw Threads B1.5-1997
v t e
v t e
Machining and computing
2.5D CAD CAM G-code Numerical control (NC and CNC) Stewart platform
Drilling and threading
Die head Drill Drill bit Drill bit shank Drill bit sizes Drilling List of drill and tap sizes Tap and die Tap wrench Threading
Grinding and lapping
Abrasive Angle grinder Bench grinder Coated abrasives Cylindrical grinder Diamond plate Flick grinder Grinding Grinding dresser Grinding machine Grinding wheel Jig grinder Lapping Sanding Sharpening stone Spark testing Surface grinder Tool and cutter grinder
Boring Broaching Electrical discharge machining Electrochemical machining Electron beam machining Endmill Engraving Facing Hobbing Jig borer Machine tool Machining Metal lathe Milling cutter Milling machine Pantograph Photochemical machining Planer Reamer Rotary transfer machine Shaper Turning Ultrasonic machining
Angle plate Chuck Collet Fixture Indexing head Jig Lathe center Machine taper Magnetic base Mandrel Rotary table Wiggler
Cutting fluid Machining vibrations Speeds and feeds Swarf Tolerance Tool and die making Tramp oil
Casting Fabrication Forming Jewellery Machining Metallurgy Smithing Tools and termino