Nut (hardware)

A nut is a type of fastener with a threaded hole. Nuts are almost always used in conjunction with a mating bolt to fasten multiple parts together. The two partners are kept together by a combination of their threads' friction (with slight elastic deformation), a slight stretching of the bolt, and compression of the parts to be held together.

In applications where vibration or rotation may work a nut loose, various locking mechanisms may be employed: lock washers, jam nuts, eccentric double nuts,^[1] specialist adhesive thread-locking fluid such as Loctite, safety pins (split pins) or lockwire in conjunction with castellated nuts, nylon inserts (nyloc nut), or slightly oval-shaped threads.

Square nuts, as well as bolt heads, were the first shape made and used to be the most common largely because they were much easier to manufacture, especially by hand. While rare today^{[as of?]} due to the reasons stated below for the preference of hexagonal nuts, they are occasionally used in some situations when a maximum amount of torque and grip is needed for a given size: the greater length of each side allows a spanner to be applied with a larger surface area and more leverage at the nut.

The most common shape today is hexagonal, for similar reasons as the bolt head: six sides give a good granularity of angles for a tool to approach from (good in tight spots), but more (and smaller) corners would be vulnerable to being rounded off. It takes only one sixth of a rotation to obtain the next side of the hexagon and grip is optimal. However, polygons with more than six sides do not give the requisite grip and polygons with fewer than six sides take more time to be given a complete rotation. Other specialized shapes exist for certain needs, such as wingnuts for finger adjustment and captive nuts (e.g. cage nuts) for inaccessible areas.

Nuts come in many sizes. This one is part of the Sydney Harbour Bridge.

History

Nuts and bolts were originally hand-crafted together, so that each nut matched its own bolt, but they were not interchangeable. This made it virtually impossible to replace lost or damaged fixers, as they were all different. Joseph Whitworth in 1841 proposed that a standard should be set, but it did not happen immediately.

In 1851 the Great Exhibition of the Works of Industry of All Nations was to be held in Hyde Park, London, England, and it was decided to build the Crystal Palace as part; this had to be done in 190 days, and at reasonable cost. Research into the remains of the destroyed building in 2024 revealed a major innovation that made this possible. The construction firm responsible, Fox Henderson, decided to use nuts and bolts, but to use standardised sizes, a revolutionary method at the time. This enabled the building to be completed in time. The use of interchangeable nuts and bolts was so successful that the Whitworth standard was widely adopted. A British standard was not formally adopted until 1905.^[2]

Types

There is a wide variety of nuts, from household hardware versions to specialized industry-specific designs that are engineered to meet various technical standards. Fasteners used in automotive, engineering, and industrial applications usually need to be tightened to a specific torque setting, using a torque wrench. Nuts are graded with strength ratings compatible with their respective bolts; for example, an ISO property class 10 nut will be able to support the bolt proof strength load of an ISO property class 10.9 bolt without stripping.

Name	Also known as	Description
Acorn nut (cap nut)	Crown hex nut, blind nut, cap nut, domed cap nut, or dome nut	A nut that has a domed end on one side
Barrel nut	Steel cross dowel or dowel nut, cross dowel (woodworking)	A round slug or formed sheet metal part with threads perpendicular to the length of the nut
Cage nut	Caged nut, captive nut, clip nut	A (usually square) nut in a spring steel cage which wraps around the nut. The cage has two wings that when compressed allow the cage to be inserted into the square holes
Clip-on nut	J-nut or U-nut, sheet metal nut, speed nut (ambiguously)	Designed to be clipped to sheet metal
Coupling nut	Extension nut	A threaded fastener for joining two male threads, most commonly a threaded rod,[1][2] but also pipes
Flange nut	Collar nut	Has a wide flange at one end that acts as an integrated washer
HARDLOCK Nut^[3]	Eccentric Double Nut	A self-lock nut. Improvement of the double nut that uses a wedge principal, eliminating space between threads.
Insert nut	Threaded socket	A threaded socket for a wooden workpiece, similar to a wall anchor.
Knurled nut	Thumb nut	Has a knurled outside surface which facilitates tightening by hand (thumb nut) or secures the nut into a handle or cover (insertion nut)
Sex bolt	Barrel nut, barrel bolt, binding barrel, Chicago screw, post and screw or connector bolt	Has a barrel-shaped flange and protruding boss that is internally threaded
Split nut		Split lengthwise into two pieces (opposed halves) so that its female thread may be opened and closed over the male thread of a bolt or leadscrew
Sleeve nut
Spring nut		Used with strut to join things to the open face thereof. The grooves in its face engage the lips of the open side of the strut channel, while the spring pushes against the opposite side, to hold the nut in place.
Square nut		Four-sided nut. Compared to standard hex nuts, square nuts have a greater surface in contact with the part being fastened, and therefore provide greater resistance to loosening (though also greater resistance to tightening)^{[citation needed]}
Swage nut	Self-clinching nut	Used on sheet metal. It permanently anchors itself to the sheet metal by swaging the surrounding material.
Star nut	Threadless fork star nut	Part of a threadless-style headset used to attach a bicycle fork to a bicycle frame. Semi-permanently anchors itself inside the fork steerer tube. Can be mounted using a star nut setter.
T-nut	tee nut, blind nut (ambiguously)	Used to fasten a wood, particle or composite materials workpiece, leaving a flush surface.
T-slot nut	T-groove nut	Used with a threaded clamp to position and secure pieces being worked on in a workshop
Wedge nut		Used for creating overhanging decks.
Weld nut		Designed to be welded to another object
Well nut	Rawlnut or Rawl nut (proprietary)	Used to blindly fasten a piece and to seal the bolt hole
Wing nut	Butterfly nut	Has two large metal "wings", one on each side, so it can be easily tightened and loosened by hand without tools

Locknuts

Many specialised types of nut exist to resist loosening of bolted joints, either by providing a prevailing torque against the male fastener or by gripping against the bolted components. These are generally referred to as locknuts.

Castellated nut
Distorted thread locknut
- Centerlock nut
- Elliptical offset locknut
- Toplock nut
Interfering thread nut
- Tapered thread nut
Jam nut
Jet nut (K-nut)
Keps nut (K-nut or washer nut) with a star-type lock washer
Nyloc plate nut
Polymer insert nut (Nyloc)
Security locknut
Serrated face nut
Serrated flange nut
Speed nut (Sheet metal nut or Tinnerman nut)
Split beam nut
BINX nut^[4]

Gallery

Left to right: Wing, hex, hex flange, and slab weld nuts.
Left to right: Slotted, square (upper), T-nut (lower), cap (or acorn), nylon locking (top and side views), and castellated nuts.
Hexagon nuts.

Standard nut sizes

Metric hex nuts

Nut quotation

Note that flat (spanner or wrench) sizes differ between industry standards. For example, spanner or wrench sizes of fastener used in Japanese built cars comply with JIS automotive standard.

Nominal hole diameter, D (mm)		Pitch, P (mm)		Across flats, A/F (mm)			External diameter; across corners, A/C (mm)	Height, H (mm)
1st choice	2nd choice	Coarse	Fine	ISO	DIN	JIS	External diameter; across corners, A/C (mm)	Hex nut	Jam nut	Nylon nut
1		0.25		2.5
1.2		0.25
	1.4	0.3
1.6		0.35		3.2
	1.8	0.35
2		0.4		4				1.6	1.2	-
2.5		0.45		5				2	1.6	-
3		0.5		5.5			6.4	2.4	1.8	4
	3.5	0.6		6
4		0.7		7	7	7	8.1	3.2	2.2	5
5		0.8		8	8	8	9.2	4	2.7	5
6		1	0.75	10	10	10	11.5	5	3.2	6
	7	1			11			5.5	3.5	-
8		1.25	1	13	13	12	15	6.5	4	8
10		1.5	1.25 or 1	16	17	14	19.6	8	5	10
12		1.75	1.5 or 1.25	18	19	17	22.1	10	6	12
	14	2	1.5	21	22	19		11	7	14
16		2	1.5	24	24	22	27.7	13	8	16
	18	2.5	2 or 1.5		27	27		15	9	18.5
20		2.5	2 or 1.5	30	30	30	34.6	16	10	20
	22	2.5	2 or 1.5	32
24		3	2	36			41.6	19
	27	3	2	41		41
30		3.5	2	46			53.1	24
	33	3.5	2
36		4	3	55			63.5	29
	39	4	3
42		4.5	3
	45	4.5	3
48		5	3
	52	5	4
56		5.5	4
	60	5.5	4
64		6	4

SAE hex nuts

UTS size	Nominal hole diameter, D			Pitch, P						Across flats, A/F			Across corners, A/C			Height, H
	Nominal hole diameter, D			Coarse (UNC)		Fine (UNF)		Extra fine (UNEF)		Across flats, A/F			Across corners, A/C			Hex nut		Jam nut		Nylon nut
	(in)		(mm)	(in)	(mm)	(in)	(mm)	(in)	(mm)	(in)		(mm)	(in)		(mm)	(in)	(mm)	(in)	(mm)	(in)	(mm)
#0										5⁄32	0.1563	3.969
#1										5⁄32	0.1563	3.969
#2		0.086	2.1844							3⁄16	0.1875	4.763			5.18		1.65
#3										3⁄16	0.1875	4.763			5.10		1.85
#4		0.1120	2.8448							1⁄4	0.2500	6.35			7.05		2.25
#6		0.1380	3.5052							5⁄16	0.3125	7.938			8.95		2.85
#8		0.1640	4.1656							11⁄32	0.3440	8.731		0.386	9.80		3.05
#10		0.1900	4.8260							3⁄8	0.3750	9.525		0.461	11.70		3.10
#12		0.2160	5.4864							7⁄16	0.4375	11.113
1⁄4	1⁄4	0.250	6.350							7⁄16	0.4375	11.113
5⁄16	5⁄16	0.3125	7.9375							1⁄2	0.5000	12.700		0.577
3⁄8	3⁄8	0.375	9.525							9⁄16	0.5620	14.288		0.650
7⁄16	7⁄16									11⁄16	0.6750	17.463
1⁄2	1⁄2	0.500	12.70							3⁄4	0.7500	19.050		0.866
9⁄16	9⁄16									7⁄8	0.8750	22.225
5⁄8	5⁄8									15⁄16	0.9375	23.813		1.083
3⁄4	3⁄4	0.750								1+1⁄8	1.1250	28.575		1.299
7⁄8	7⁄8									1+5⁄16	1.3125	33.338
1	1	1	25.40							1+1⁄2	1.5000	38.100		1.653

Classifications

Hex nuts, recognized by their six-sided shape, and square nuts, with a square form, are commonly used. Steel nuts are strong and great for construction, while stainless steel ones resist rust, perfect for outdoor use. Brass nuts, corrosion-resistant, find their place in electrical and plumbing work. Lock nuts, like nylon-insert or prevailing torque types, prevent loosening due to vibration or torque, catering to specific needs across industries.

Mechanical specifications of Metric/English sized nuts^[5]
Material	Proof strength	Min. tensile yield strength	Min. tensile ultimate strength	Nut class
ISO 898 (Metric)
Low or medium carbon steel	380 MPa (55 ksi)	420 MPa (61 ksi)	520 MPa (75 ksi)	5
Medium carbon steel Q&T	580 MPa (84 ksi)	640 MPa (93 ksi)	800 MPa (116 ksi)	8
Alloy steel Q&T	830 MPa (120 ksi)	940 MPa (136 ksi)	1040 MPa (151 ksi)	10
SAE J995 (English)
Low or medium carbon steel	55 ksi (379 MPa)	57 ksi (393 MPa)	74 ksi (510 MPa)	2
Medium carbon steel Q&T	85 ksi (586 MPa)	92 ksi (634 MPa)	120 ksi (827 MPa)	5
Alloy steel Q&T	120 ksi (827 MPa)	130 ksi (896 MPa)	150 ksi (1034 MPa)	8

Manufacture

The manufacturing process of nuts involves several steps. It begins with the selection of raw materials like steel, stainless steel, or brass, depending on the desired type of nut. The chosen material undergoes heating to make it more malleable, followed by forming or forging processes to create the basic shape of the nut. Threads are then cut or formed onto the nut using specialized machinery. After threading, nuts may undergo additional treatments such as heat treatment or surface finishing to enhance their strength, durability, or appearance. Quality control checks are performed throughout the manufacturing process to ensure that the nuts meet industry standards and specifications.

Nut blanking
Nut threading

References

^ Gong, Hao; Liu, Jianhua; Feng, Huihua (2022-02-01). "Review on anti-loosening methods for threaded fasteners". Chinese Journal of Aeronautics. 35 (2): 47–61. doi:10.1016/j.cja.2020.12.038. ISSN 1000-9361. S2CID 234300791.
^ Ferguson, Donna (16 September 2024). "Solved: the mystery of how Victorians built Crystal Palace in just 190 days". The Guardian.
^ "A reliable locking performance using a two nut design". Fastener + Fixing Technology. Archived from the original on 2022-12-05. Retrieved 2022-03-15.
^ fastenerdata.co.uk, archived from the original on 2018-07-10, retrieved 2019-03-08.
^ Bickford & Nassar 1998, p. 153.

Bibliography

Bickford, John H.; Nassar, Sayed (1998), Handbook of bolts and bolted joints, CRC Press, ISBN 978-0-8247-9977-9.
"Threaded fasteners". Machine Design. 61 (23): 470. 1989.

[1] Gong, Hao; Liu, Jianhua; Feng, Huihua (2022-02-01). "Review on anti-loosening methods for threaded fasteners". Chinese Journal of Aeronautics. 35 (2): 47–61. doi:10.1016/j.cja.2020.12.038. ISSN 1000-9361. S2CID 234300791.

[2] Ferguson, Donna (16 September 2024). "Solved: the mystery of how Victorians built Crystal Palace in just 190 days". The Guardian.

[3] "A reliable locking performance using a two nut design". Fastener + Fixing Technology. Archived from the original on 2022-12-05. Retrieved 2022-03-15.

[fastenerdata.co.uk-4] fastenerdata.co.uk, archived from the original on 2018-07-10, retrieved 2019-03-08.

[5] Bickford & Nassar 1998, p. 153.

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