|
|
 A NEMA 5–15 plug and receptacle. (Different scales. Blade spacing is 0.5 inches for both.) Note that the receptacle will also accept an ungrounded plug whether polarized or unpolarized.NEMA connectors are connectors used for mains electricity (in North America and other countries) that conform to the standards set by the National Electrical Manufacturers Association. Some types are found in nearly all buildings in the United States. Similar and interchangeable connectors are used in Canada and other countries using the same type of receptacle, although there are some exceptions. NEMA wiring devices are made in current ratings from 15 to 60 A, and electrical potential (voltage) ratings from 125 to 600 V. Different combinations of contact blade widths, shapes, orientation, and dimensions give non-interchangeable connectors that are unique to a particular voltage, current capacity, and grounding system. The dimensional standard for electrical connectors is ANSI/NEMA WD–6 and is available from the NEMA Web site. [1]
: \, @0 Q; `, U% R' J4 ~9 JContents ; ^2 a. k5 O# q
1 NEMA nomenclature 2 Non-locking connectors 2.1 NEMA 1 2.2 NEMA 2 2.3 NEMA 5 2.4 NEMA 6 2.5 NEMA 10 2.6 NEMA 14 2.7 NEMA TT–30 3 Twist-locking connectors 3.1 NEMA L5 3.2 NEMA L6 3.3 NEMA L7 3.4 NEMA L8 3.5 NEMA L9 3.6 NEMA L14 3.7 NEMA L15 3.8 NEMA L16 3.9 NEMA L17 3.10 NEMA L21 3.11 NEMA L22 3.12 NEMA L23 4 Ground fault circuit interrupter (GFCI) receptacles 5 Leak-current detection and interruption (LCDI) plugs 6 Color code 7 Break-away tabs 8 See also 9 References 10 External links |
0 L3 A$ K2 B& f4 ]NEMA nomenclature
. J* {0 X' p @& a& w* A+ S0 I" ZThere are two basic classifications of NEMA device: straight-blade and locking. The straight-blade 5–15 and 5–20 are found nearly everywhere in countries using the NEMA standards, and are intended for supplying lighter-duty, general-purpose electrical devices. Twist-locking types are used for heavy industrial and commercial equipment, where increased resistance to accidental disconnection is required. Numbers prefixed by L are curved-blade, twist-locking connectors; others are straight blade and non-locking.
- @) H9 Z! R0 HThe numeral preceding the hyphen in NEMA nomenclature indicates the configuration, that is, the number of poles, number of wires, voltage, and whether single- or three-phase. A grounding type of device will be described as two-pole, three-wire; or four-pole, five-wire; etc. A non-grounding device will be two-pole, two wire; or three-pole, three-wire; etc. ! Q, F _! ]/ H
The numeral following the hyphen is the rating of the device in amperes. The number is followed by the letter R to indicate a receptacle (female connector) or the letter P to indicate a plug (male connector). , B; Z3 m8 L; x0 q$ |
As an example, the 5–15R is the common 125 V two-pole, three-wire receptacle. The L5–15R, while sharing the same rating, is a locking design which is not physically compatible with the straight-blade 5–15 design. The 5–30 has the same two-pole, three-wire configuration and 125 V rating, but is rated 30 A.
% i1 \5 ?/ q# u, DAlthough there are several non-grounding device types in the NEMA standards, only three of them are in widespread use today. These are the two-pole 1–15, still in use in millions of buildings built before the 1960s, and the three-pole 10–30 and 10–50.
" }9 v+ q3 n2 jThe small hole near the end of the power (non-ground) blades of some NEMA plugs is used for convenience in manufacturing; if present it must be of specified diameter and position.[2] 1 C1 f5 F# Q: B0 i9 _5 P. y
# U2 k1 X% v1 @
Non-locking connectors - B8 p1 n6 o8 i' G" ^ C; U4 }
NEMA non-locking connectors all use blades of various flat and folded shapes (except for the round pins used on grounding connectors) and the plugs can be detached from the receptacles by pulling back on the plug body. The connector families have been designed so that grounding connectors for 120 V and 208/240 V cannot be accidentally intermated.
* f G# G/ H/ m& s5 A1 u6 jNEMA wall receptacles can be found installed in any orientation. Neither NEMA, U.S. National Electrical Code nor Canadian Electrical Code specify a preferred orientation, and different orientations may be found in the same building. However, the orientation with the ground pin on the bottom is the most common, which places the neutral pin on the upper left and the hot pin on the upper right. All descriptions below assume this orientation.
' A1 v, V* L, O
4 C& s# K0 J3 d4 S. @; M6 ^NEMA 1
9 X2 p* V [& GAll NEMA 1 devices are two-wire non-grounding devices rated for 125 V maximum. NEMA 1-15P plugs have two parallel flat blades, 1/4 inch wide, 0.06 inch thick, 5/8–23/32 inch long, and spaced 1/2 inch apart, and are commonly found on household lamps and consumer electronics such as clocks and radios. Standards exist for 1–15P, 1–20P and 1–30P plugs, and the 1–15R receptacle. There are no 1–20R and 1–30R receptacles; 1–20P and 1–30P mate with a corresponding NEMA 5 receptacle. Plugs and receptacles may be polarized to preserve the identity of the neutral conductor; the blade connected to neutral will be wider (5/16 inch) than the other, and polarized sockets will only accept a polarized plug in the correct orientation. # Q8 i5 ^- q" |& P- x
3 T4 T {. b/ v' G# V ~
NEMA 2 ! e0 k) }# Y" N+ F! T' ]4 {. a
All NEMA 2 devices are two-wire non-grounding devices rated for 250 V maximum. Although standards exist for 2–15, 2–20 and 2–30, this series is obsolete, and no such devices are currently manufactured. A 2–15P, if one could be found, would plug into a 6–15R or 6–20R (240 V), or a “T-slot” (120 V), with equal ease.
6 p) R8 v$ O4 Q
( k( E+ ^+ \# Q; QNEMA 5
- u( Z& P: H5 _% X/ J J% X 5–20R T-slot receptacle mounted with the ground hole up. The neutral connection is the wider T-shaped slot on the lower right.All NEMA 5 devices are three-wire grounding devices rated for 125 V maximum, with the 5–15, 5–20 and 5–30 being grounded versions of the 1–15, 1–20 and 1–30, respectively. The addition is a 3/16 inch diameter round or U-shaped ground pin, 1/8 longer than the power blades and located 1/4 inch below them. (1/4 inch is edge-to-edge; 15/32 inch center-to-center.) The 20 A plug has the neutral blade rotated 90° and shifted so its inner edge is approximately 1/2 inch from the hot blade. The 5–20R receptacle may have a T-shaped neutral hole, to accept both 5–15P and 5–20P plugs. The 5–30 and 5–50 are uncommon, as twist-locking plugs are generally used for high-current applications. They are larger, with 1 inch between power pins. g0 x1 P, p0 s
The 5–15R is by far the most common electrical outlet in North America in buildings built since the mid-twentieth century. It is usually installed in a duplex configuration (which may be on a common circuit or with each receptacle on a separate circuit, sometimes switched).
- p) L Z+ n0 r! @% K. y ~+ f# m. AThe standard 5–15 (and its two prong counterpart) is sometimes called an “Edison plug” in the film and theatre industry, where it distinguishes it from more specialized theatrical connectors. This is perhaps a reference to the Consolidated Edison Company of New York, which supplies power to most New York theatres.[citation needed] In the photography industry, the 5-15 is known as a "Stinger."
$ R3 @2 f" \+ N" V# _3 W1 {% J" n" z% r6 l' Z
NEMA 6
& N5 y$ c# R6 L# j: O/ oAll NEMA 6 devices are three-wire grounding devices used for 208 V and 240 V circuits and rated for 250 V maximum, with the 6–15, 6–20 and 6–30 being grounded versions of the 2–15, 2–20 and 2–30, respectively. The 6-15 resembles the 5-15, but with collinear horizontal pins, spaced 23/32 inch center-to-center. The 20 A plug has the neutral blade rotated 90°, and the 6–20R receptacle may have a T-shaped neutral hole, to accept both 6–15P and 6–20P plugs. The 30 A plug and socket look similar to the 15 A one but larger. The higher-current versions are rare, with twist-locking plugs and direct wiring more common; generally 6–series non-locking plugs are used for such appliances as large room air conditioners, commercial kitchen equipment, and the occasional home arc welder.
$ O9 `. U! D$ ONEMA 6 devices, while specified as 250 V, may be used for either 208 V or 240 V circuits, generally depending on whether the building has a three-phase or split-phase power supply. Visitors to North America should not regard the NEMA 6–20R or 6–30R found in many hotel rooms as a source of 240 V power, since in most cases, they are supplied with 208 V.
) L' d/ P, q2 {' ^+ b0 g: x/ Q$ O
; H# Q+ ^4 A! s/ X. Y7 }NEMA 10
& _. @$ @# T8 _+ x6 k; A2 v3 m NEMA 10-30NEMA 10 devices are a curious throwback to an earlier time. They are classified as 125/250 V non-grounding, yet they are usually used in a manner that effectively grounds the appliance, though not in a manner consistent with most modern practice. % e- c0 o& I& q* b& T
As commonly used, 10–30 and 10–50 plugs have the frame of the appliance grounded through the neutral blade. This was a legal grounding method under the National Electrical Code for electric ranges and electric clothes dryers from the 1947 to the 1996 edition. Since North American dryers and ranges have certain parts (timers, lights, fans, etc.) that run on 120 V, this means that the wire used for grounding is also carrying current. Although this is contrary to modern grounding practice, such installations remain common in the United States and are relatively safe, because the larger conductors used are less likely to be broken than the smaller conductors used in ordinary appliance cords, and the current carried is small. , K: `: t4 y0 z, q# A
Persons moving their older appliances to newer NEMA-14-equipped buildings (or vice-versa) should have the cords replaced by a qualified electrician.
1 [( M3 Y% `+ G obsolete 125 V, 15 A / 250 V, 10 A duplex outletNEMA 10–20 devices are very rare nowadays. There is also a similar obsolete design, lacking a NEMA configuration number, rated 125 V, 15 A / 250 V, 10 A which is nearly identical to the AS/NZS 3112 standard used in Australia/New Zealand. These are also extremely rare. 9 Y# T" Q" M7 d" R' ^& p
( c1 a1 E/ E- I
NEMA 14
# x. B" ^8 d E# H& n; {8 f+ p6 YNEMA 14–30 and 14–50 receptaclesThe NEMA 14 devices are four-wire grounding devices available in ratings from 15 A to 60 A. Of the straight-blade NEMA 14 devices, only the 14–30 and 14–50 are common. The 14–30 is used for electric clothes dryers and the 14–50 for electric cooking ranges. The voltage rating is 250 V. They are essentially the replacements for the NEMA 10 connectors above with the addition of a separate grounding connection. 6 z/ C! _/ X( S" c" T
All NEMA 14 devices offer two hots, a neutral and a ground, allowing for both 120 V and 240 V (or 120 V and 208 V if the supply system is three-phase rather than split phase). The 14–30 has a rating of 30 A and an L-shaped neutral blade. The 14–50 has a rating of 50 A and a straight neutral blade sized so that it will not fit in the slot of a 14–30.
' l7 V. H g2 L6 }" b/ p# x4 SNEMA 14–50 devices are frequently found in RV parks, since they are used for shore power connections of larger recreational vehicles. Also, it was formerly common for mobile homes to be connected to utility power via a 14–50 device. 0 z: o' i4 o8 I$ [0 g
/ V/ V, ]# j; n" J! I
NEMA TT–30 5 P I3 K: d! p
NEMA TT–30 plug and receptacle. (The center hole on the receptacle is not a contact.)NEMA TT–30 is a 30 A, 125 V recreational vehicle standard which may also be known as RV 30. It is frequently (and sometimes disastrously) confused for a NEMA 10–30. The RV receptacle is common in nearly all RV parks in the United States and Canada, and all but the largest RVs manufactured since the 1970s use this plug. The hot and neutral blades are angled at 45° from vertical and 90 degrees to each other, similar to NEMA 10 devices. The plug is slightly smaller than a NEMA 10 but larger than ordinary 5–15 plugs. The ground pin, however, is round, like those on straight-blade NEMA grounding devices. Referring to the diagram, the orientation is the same as the NEMA 5 plug and socket, with the receptacle neutral on the lower right. Due to the appearance of this plug, many people assume that it is to be wired for 240 V, but this is a 120 V device. Adapters exist with the TT–30 plug on one side and a 5–15 or 5–20 socket on the other side. When the cord is detachable from the RV an L5–30 is usually used on the RV end of the cord. % P, y$ ^$ e# e! T& Q/ H
Twist-locking connectors I" j# U S. S% ~
  % {0 v( O0 C9 a/ }3 y
L21–30 plug and receptacle |
Twist-locking connectors were first invented by Harvey Hubbell III in 1938 and “Twist-Lock” remains a registered trademark of Hubbell Incorporated, although the term is used generically to refer to NEMA locking connectors manufactured by any company. Locking connectors use curved blades. Once pushed into the receptacle, the plug is twisted and its now-rotated blades latch into the receptacle. To unlatch the plug, the rotation is reversed. The locking coupling makes for a very reliable connection in commercial and industrial settings.
2 W d. l( W% y2 @' x' r1 r* [, xLocking connectors come in a variety of standardized configurations that follow the same general naming scheme except that the designations all begin with an “L” for “locking”. Locking connectors are designed so the different voltages and current ratings can not be accidentally intermated[4]. Many specific types exist; only a few are listed below. Other types include miniature locking connectors, and special purpose connectors for boats, 400 Hz circuits such as used for aircraft, and direct-current use.
k8 }! Z3 r$ C3 ?$ b% FOne argument against twist-lock connectors is that in the event that the cable is accidentally pulled too hard, rather than the plug falling out of the receptacle, the exposed conductors may come out of the plug, causing dangerous shorts if the circuit is live. - \( p" J+ ?8 k- L+ Z
2 }. K* P* C: r- F- k
NEMA L5
; P/ ^$ m* J+ B0 n0 X; cNEMA L5 connectors are a series of locking connectors with a maximum specified voltage of 125V. Supply connections are intended to be single-pole L-N-G circuits with a nominal voltage of 120V RMS. . t2 M8 D* u% ]! z- z q) k1 J# S
The L5–30 is a very popular configuration even on circuits not requiring the 30A current capacity, owing to its very rugged construction. The L5–30 is the standard configuration for 120V marine vessel shore power. L5-20P and L5-30P are also commonly used for in-rack power distribution units in the US.
! y6 l) A9 K2 g. E: r9 w/ `% V' j1 O" `6 D
NEMA L6
' ]" l% g& _9 x# ?! ONEMA L6 connectors are used with circuits with a maximum specified voltage of 250V. Supply connections are intended to be two-pole, three wire L-L-G circuits with nominal supply voltage of 240V or 208V depending on phase configuration.
* f7 I- S5 S5 `L6-20 and L6-30 connectors are commonly found on in-rack power distribution units in countries where the mains supply voltage is greater than 120V, and in the US where equipment load is such that the system would benefit from a higher supply voltage (and thus, lower current draw). These connectors are also found where industrial equipment or large power tools are commonplace. 5 m1 E9 Q$ [' i# g0 V- d2 M: `
8 D- A& v, c2 @- v. s7 Z" TNEMA L7 9 @+ G2 j) Q$ h5 v J9 i: `1 L
NEMA L7 connectors are used with circuits with a maximum specified voltage of 277V AC. Supply connections are intended to be single-pole, three-wire L-N-G circuits with a nominal supply voltage of 265V.
! O: }6 A5 T a2 K9 r0 W* _5 T' fTypically, these connectors are found in commercial or industrial lighting circuits, especially where metal halide lamps are common. $ [! `, L" a# C
; P j& c5 g$ k8 }* I& vNEMA L8 : \+ r0 H* f4 r) f( a) ~8 H8 W- [
NEMA L8 connectors are used with circuits with a maximum specified voltage of 480V AC. Supply connections are intended to be two-pole, three-wire L-L-G circuits with a nominal supply voltage of 460V. & [- Z; F5 B, z2 M) h
2 j, n2 l# x! v! y) vNEMA L9 - |: B% {' `' J2 u3 F, N
NEMA L9 connectors are used with circuits with a maximum specified voltage of 600V AC. Supply connections are intended to be two-pole, three-wire L-L-G circuits with a nominal supply voltage of 600V.
$ V. X! C, r) ~) t! [% C
3 s* z4 f: f& \! wNEMA L14 # u4 O2 i; Q% ~/ m1 X' |( Y& E
NEMA L14 connectors are used with circuits with a maximum specified voltage of 125/250V. Supply connections are intended to be two-pole, four-wire L-L-N-G circuits with a nominal supply voltages of 240V or 208V L-L and 120V L-N. , R2 ~/ }9 y T+ L* Q
These connectors are common on household backup generators.
6 K8 c4 d& |; a! ]2 ^! j2 |$ w8 Q$ ~0 ]8 w- {4 s/ z* [4 w; K
NEMA L15 . B' H( a1 ?8 m2 J
NEMA L15 connectors are used with circuits with a maximum specified voltage of 250V AC. Supply connections are intended to be three-phase, four-wire L-L-L-G circuits with a nominal supply voltage of 208V L-L (standard low-voltage three phase) or 240V L-L (delta three phase).
: V% n4 p* G4 `8 R8 T- P
$ r' m# C2 ?; p( I; u, \* F' DNEMA L16
# |7 k+ |& t& X/ H/ Q0 H m+ ~NEMA L16 connectors are used with circuits with a maximum specified voltage of 480V AC. Supply connections are intended to be three-phase, four-wire L-L-L-G circuits with a nominal supply voltage of 460V.
) b5 D+ {/ p" m* m. H( a1 E0 b/ |. w7 e8 _& m4 q
NEMA L17 , b' m7 X. y0 A1 T) V
NEMA L17 connectors are used with circuits with a maximum specified voltage of 600V AC. Supply connections are intended to be three-phase, four-wire L-L-L-G circuits with a nominal supply voltage of 600V. & y3 }9 e p6 e, K8 b( J7 Z! d
3 n; I; p1 z; Q( D2 u( |# P
NEMA L21 0 W1 q; I* b+ G
NEMA L21 connectors are used with circuits with a maximum specified voltage of 120/208V AC. Supply connections are intended to be three-phase, five-wire L-L-L-N-G circuits with a nominal supply voltage of 208V L-L and 120V L-N. ; T# Y7 a6 T6 Z8 T
These three-phase connections include neutral and ground. The pin in the middle is ground, and the blade with a right angle on the tab is neutral. - [: }4 {, V5 c/ u$ o/ ~ W* z
2 ]3 P7 d9 G/ C' l
NEMA L22 ; K) |' ]9 S0 ~6 n# T8 U5 z7 Y
NEMA L22 connectors are used with circuits with a maximum specified voltage of 277/480V AC. Supply connections are intended to be three-phase, five-wire L-L-L-N-G circuits with a nominal supply voltage of 460V L-L and 265V L-N.
: l* ^1 @, e; V9 d8 m4 |, C5 s
( v2 F/ c) y. \- \3 U: mNEMA L23 # t' s; x, w5 t. ]5 Q2 ?
NEMA L23 connectors are used with circuits with a maximum specified voltage of 347/600V AC. Supply connections are intended to be three-phase, five-wire L-L-L-N-G circuits with a nominal supply voltage of 600V L-L and 347V L-N. v5 o+ D" g: @) a8 C* G+ Y" o
2 y- @$ \7 M- G, t; Y6 S
/ w+ ?& U! S/ Z" @* i( B$ |7 L
Ground fault circuit interrupter (GFCI) receptacles 6 h! w. c! G9 p+ i8 p7 @ t& \
Type B (NEMA 5–15) GFCI receptacleThese versions of the 5–15 receptacle are residual-current devices and have Test and Reset buttons (and sometimes an indicator light). In the U.S. and Canada they are required in many potentially wet locations, including outside outlets, bathrooms, some places in kitchens, basements and crawl spaces.They work by comparing the current going out on the live connector to the current returning on the neutral, and will disconnect the circuit if the difference exceeds 4–6 milliamperes. They are cheaper than GFCI circuit breakers and can be wired to feed additional "downstream" outlets so that putting one GFCI receptacle in a circuit will protect all the plugs, lights and switches downstream from it. They are also recommended for power tool outlets and locations where children might insert conductive objects into the receptacles.
/ k, e5 L7 b$ {" H. ]* u
* V- K& r2 t4 Y6 [$ Y0 W5 ^# dLeak-current detection and interruption (LCDI) plugs
) N# o5 E# q' m6 q5 EBecause portable air conditioners have caused many electrical fires, those sold in the United States now must have leak-current detection and interruption (LCDI) plugs. The cords have a fine wire mesh around the conductors and circuitry to detect any current leaking from the conductors to the mesh, which would happen if the cord was damaged or frayed. These could be NEMA 5–15, 5–20, 6–15, 6–20 or 6–30 plugs, depending on the air conditioner. The plug is equipped with “Test” and “Reset” buttons on the housing. & m; }; D9 I( m9 O
) h3 x8 w/ t( B. \
Color code + N1 f8 O) l9 E3 Y
The color of a NEMA device does not identify the voltage class or power system for the device. Since the colors are not regulated by national standards, the purpose of color-coding a receptacle is set by the building owner. Brown, ivory, white, almond, grey, and black receptacles in the 5–15 configuration are selected to blend with the decor of a room.
* V3 t9 V5 Z: k9 a[li]Blue receptacles may indicate built-in surge suppressors. [/li][li]A red receptacle may indicate a special-service outlet such as one connected to an emergency standby power source. [/li][li]At least one manufacturer makes a yellow receptacle which identifies it as corrosion-resistant. [/li][li]A receptacle with a green dot is a so-called “hospital grade” device; such devices are tested to survive harder use than wiring devices intended for residential or commercial purposes. The NEMA standard does not define green as a color for wiring devices. [/li] A receptacle with an orange triangle is an isolated ground device, where the grounding pin of the receptacle is connected to ground independently of the frame of the receptacle and wiring outlet box. The receptacle itself may be any colour, but contrary to popular belief, a receptacle is no longer an isolated ground device because the receptacle itself is orange, although this was formerly the case in the United States.[5]
: G8 s3 O9 l6 k: f& R; R2 Z0 U f
Break-away tabs ; o4 J/ w1 d/ i D* c
Duplex receptacles usually have break-away tabs to separate the top and bottom halves so that the two outlets can be placed on separate circuits. This may allow for one switched outlet for a lamp, or for two circuits to be used when heavy loads are anticipated. Two branch circuits may share a neutral terminating on duplex receptacles. 6 t2 E9 j1 G: X2 v+ y5 b! }
|
|
/1 
|关于安规|小黑屋|安规QQ群|Archiver|手机版|安规网
( 粤ICP13023453-10 ) 
窥视卡
雷达卡
发表于 2008-12-16 10:36
收藏
分享
好帖
鸡蛋
提升卡
置顶卡
沉默卡
喧嚣卡
变色卡
抢沙发
千斤顶
显身卡
发表于 2008-12-18 10:43
