Automotive Fuse Link Definition and Specifications Automotive use links are self-acting break appliances for the protection of electrical devices against unsuitable current loads. The current flow is interrupted by the melting of the fuse wire in which the current flows. The following international regulations and recommendations in their currently valid version are valid for fuse links: DIN 72581 DIN 43560 ISO 8820 UL 275 SAE (Further the level of technology, the details of the actually valid implementation provisions, the safety-principle "human beings, animals and material assets must be protected against danger," as well as the qualification of the installed components should be taken into account - self-responsibility of the manufacturer of electrical devices.
) Selection Explanations and Recommendations The rated voltage (UN) of a fuse link has to be at least equal or higher than the operating voltage of the device or assembly unit which is to be protected with the fuse link. If the operating voltage is very low, the fuse link's natural resistance (voltage drop) must possibly be taken into consideration. The voltage drop (UN) is measured according to standards e.
g. DIN, ISO, JASO, partially maximum values common for Littelfuse are stated as well. The rated current (Irat) of a fuse link should approximately correspond to the operating current of the device or assembly unit which is to be protected (in accordance with the ambient temperature and rated current-definition, which means the permitted continuous currents). Higher ambient temperatures (Tumg) mean additional load for the fuse links.
The heating conditions of the maximum occurring ambient temperature have to be checked, in particular with high rated currents of the fuses, and a strong thermal radiation of components nearby. For such applications, the fuse should be derated in accordance with the following diagram, resp. table (see factor FT): Due to different specifications of rated current the recommended continuous current of the fuse links is max.
80% of their rated current (with an ambient temperature of 23°C), see also the fuse-specific current-carrying capacity (F) on the individual pages of the catalog. The pre-arcing time limits indicate the relation of fusing time to current. (They are presented as an envelope curve for all mentioned rated currents.) The melting integral (I2t) results from the squared melting current and the corresponding melting time.
At excess current with melting times < 5 ms the melting integral remains constant. The data in this catalog are based on 6 or 10 x lrat. The melting integral is an index for the time-current characteristic and informs about the pulse consistency of a fuse link. The mentioned melting integrals are typical values. The breaking capacity (IB) should be sufficient for any operating and error conditions.
The short-circuit current (maximum fault current) to be interrupted by the fuse links at the rated voltage under default conditions must not be higher than the current corresponding to the breaking capacity of the fuse link. The maximum power dissipation (PV) is determined at a load with rated current, after having obtained temperature equilibrum. In operation, these values can occur for some time.
Typical values are indicated and in addition the standard values for fuses that comply with standards. Automotive Fuse Link Selection With regard to the product-safety of the device and the life/reliability of the fuse links, a correct choice is important. Only when choosing correctly and when using as agreed (that means corresponding to the level of technology and the valid recommendations, as well as the specified characteristics shown in the data sheets) under consideration of the safety-principle (that is to say "human beings, animals and intrinsic values must be protected against danger") can a definite function of the fuse links as a protection component (rated breakpoint) be possible.
The personal responsibility of manufacturers of electrical devices is applicable here: "Any person involved in the production of electrical systems or the manufacturing of electrical equipment, included those dealing with the operation of such systems or equipment is, according to the present interpretation of the law individually responsible for every aspect of compliance to the recognized rules and procedures of electrical engineering.
" The necessary voltage rating of a fuse link is established by its required operating voltage (taking into consideration the voltage drop of the fuse link). The current rating of a fuse link (IN Fuse) is established by the max. effective current load (Ioperating max) taking into consideration the ambient temperature (Factor FT) and the varying rated current definitions ("constant current" definition) (see Faktor FI).
The following applies: IN Fuse3 Ioperating max. x FI x FT t-value (current-time-integral).2In case of pulse loading and for semiconductor protection a suitable current rating can also be ascertained with the help of the I The above mentioned two points will help you to ascertain the most suitable current rating of a fuse link and its pre-arcing time limits (if necessary verify experimentally). The necessary breaking capacity of the fuse link is determined by the max.
possible fault current which can occur. In addition to the above-mentioned points, the method of installation is also important for correct fuse link selection (taking into consideration possible approvals). With regard to specific conditions of any particular application (product-safety) it is generally necessary to check the fuse link and/or the thermal circuit breaker or holder in the device which is to be protected under normal and fault conditions! Temperature Rerating Curve Fuse Link Derating Tumg / °C % FT Tumg / °C % FT -25 14 0,877 23 0 1,000 -20 13 0,885 30 -2 1,020 -15 12 0,893 35 -4 1,042 -10 11 0,901 40 -6 1,064 -5 10 0,909 45 -8 1,087 0 9 0,917 50 -10 1,111 5 8 0,926 55 -13 1,149 10 6 0,943 60 -16 1,190 15 4 0,962 65 -19 1,235 20 2 0,980 70 -22 1,282 Fuse Selection for Electronics Applications Many of the factors to consider in fuse selection for electronic applications are listed below.
For additional guidance please view our Fuse Technology Reference Guide or contact the Littelfuse products representative in your area: Selection Factors Normal operating current Application voltage (AC or DC) Ambient temperature Overload current and length of time in which the fuse must open Maximum available fault current Pulses, Surge Currents, Inrush Currents, Start-up Currents, and Circuit Transients Physical size limitations, such as length, diameter, or height Agency Approvals required, such as UL, CSA, VDE, METI, MITI or Military Fuse features (mounting type/form factor, ease of removal, axial leads, visual indication, etc.
) Fuseholder features, if applicable and associated rerating (clips, mounting block, panel mount, PC board mount, R.F.I. shielded, etc.) Application testing and verification prior to production Littelfuse Fuse Packaging and Part Numbering Systems Definitions and Terms Ambient Temperature: Refers to the temperature of the air immediately surrounding the fuse and is not to be confused with “room temperature.
” The fuse ambient temperature is appreciably higher in many cases, because it is enclosed (as in a panel mount fuseholder) or mounted near other heat producing components, such as resistors, transformers, etc. Breaking Capacity: Also known as interrupting rating or short circuit rating, this is the maximum approved current which the fuse can safely break at rated voltage. Please refer to the interrupting rating definition of this section for additional information.
Current Rating: The nominal amperage value of the fuse. It is established by the manufacturer as a value of current which the fuse can carry, based on a controlled set of test conditions (See RERATING). Catalog Fuse part numbers include series identification and amperage ratings. Refer to the FUSE SELECTION GUIDE section for guidance on making the proper choice. Rerating: For 25ºC ambient temperatures, it is recommended that fuses be operated at no more than 75% of the nominal current rating established using the controlled test conditions.
These test conditions are part of UL/CSA/ANCE (Mexico) 248-14 “Fuses for Supplementary Overcurrent Protection,” whose primary objective is to specify common test standards necessary for the continued control of manufactured items intended for protection against fire, etc. Some common variations of these standards include: fully enclosed fuseholders, high contact resistances, air movement, transient spikes, and changes in connecting cablesize (diameter and length).
Fuses are essentially temperature-sensitive devices. Even small variations from the controlled test conditions can greatly affect the predicted life of a fuse when it is loaded to its nominal value, usually expressed as 100% of rating. The circuit design engineer should clearly understand that the purpose of these controlled test conditions is to enable fuse manufacturers to maintain unified performance standards for their products, and he must account for the variable conditions of his application.
To compensate for these variables, the circuit design engineer who is designing for trouble-free, long-life fuse protection in his equipment generally loads his fuse not more than 75% of the nominal rating listed by the manufacturer,keeping in mind that overload and short circuit protection must be adequately provided for. The fuses under discussion are temperature-sensitive devices whose ratings have been established in a 25ºC ambient.
The fuse temperature generated by the current passing through the fuse increases or decreases with ambient temperature change. The ambient temperature chart in the FUSE SELECTION GUIDE section illustrates the effect that ambient temperature has on the nominal current rating of a fuse. Most traditional Slo-Blo® Fuse designs use lower melting temperature materials and are, therefore, more sensitive to ambient temperature changes.
Dimensions: Unless otherwise specified, dimensions are in inches. The fuses in this catalog range in size from the approx. 0402 chip size (.041”L x .020”W x .012”H) up to the 5 AG, also commonly known as a”MIDGET” fuse (13/32” Dia. x 11/2” Length). As new products were developed throughout the years, fuse sizes evolved to fill the various electrical circuit protection needs. The first fuses were simple, open-wire devices, followed in the 1890’s by Edison’s enclosure of thin wire in a lamp base to make the first plug fuse.
By 1904, Underwriters Laboratories had established size and rating specifications to meet safety standards. The renewable type fuses and automotive fuses appeared in 1914, and in 1927 Littelfuse started making very low amperage fuses for the budding electronics industry. The fuse sizes in following chart began with the early “Automobile Glass” fuses, thus the term “AG”. The numbers were applied chronologically as different manufacturers started making a new size: “3AG,” for example, was the third size placed on the market.
Other non-glass fuse sizes and constructions were determined by functional requirements, but they still retained the length or diameter dimensions of the glass fuses. Their designation was modified to AB in place of AG, indicating that the outer tube was constructed from Bakelite, fibre, ceramic, or a similar material other than glass. The largest size fuse shown in the chart is the 5AG, or “MIDGET,” a name adopted from its use by the electrical industry and the National Electrical Code range which normally recognizes fuses of 9/16” x 2” as the smallest standard fuse in use.
Industrial Fuses and How They Work View the Littelfuse POWR-GARD Catalog for Complete Fuse Selection Information An important part of developing quality overcurrent protection is an understanding of system needs and overcurrent protective device fundamentals. This section discusses these topics with special attention to the application of fuses. If you have additional questions, call our Technical Support and Engineering Services Group at 1-800-TEC-FUSE (1-800-832-3873).
Why Overcurrent Protection? All electrical systems eventually experience overcurrents. Unless removed in time, even moderate overcurrents quickly overheat system components, damaging insulation, conductors, and equipment. Large overcurrents may melt conductors and vaporize insulation. Very high currents produce magnetic forces that bend and twist bus bars. These high currents can pull cables from their terminals and crack insulators and spacers.
Too frequently, fires, explosions, poisonous fumes and panic accompany uncontrolled overcurrents. This not only damages electrical systems and equipment, but may cause injury or death to personnel nearby. To reduce these hazards, the National Electrical Code® (NEC®), OSHA regulations, and other applicable design and installation standards require overcurrent protection that will disconnect overloaded or faulted equipment.
Industry and governmental organizations have developed performance standards for overcurrent devices and testing procedures that show compliance with the standards and with the NEC. These organizations include: the American National Standards Institute (ANSI), National Electrical Manufacturers Association (NEMA), and the National Fire Protection Association (NFPA), all of which work in conjunction with Nationally Recognized Testing Laboratories (NRTL) such as Underwriters Laboratories (UL).
Electrical systems must meet applicable code requirements including those for overcurrent protection before electric utilities are allowed to provide electric power to a facility. What is Quality Overcurrent Protection? A system with quality overcurrent protection has the following characteristics: Meets all legal requirements, such as NEC, OSHA, local codes, etc. Provides maximum safety for personnel, exceeding minimum code requirements as necessary.
Minimizes overcurrent damage to property, equipment, and electrical systems. Provides coordinated protection. Only the protective device immediately on the line side of an overcurrent opens to protect the system and minimize unnecessary downtime. Is cost effective while providing reserve interrupting capacity for future growth. Consists of equipment and components not subject to obsolescence and requiring only minimum maintenance that can be performed by regular maintenance personnel using readily available tools and equipment.
Overcurrent Types and Effects An overcurrent is any current that exceeds the ampere rating of conductors, equipment, or devices under conditions of use. The term "overcurrent" includes both overloads and short-circuits. Overloads An overload is an overcurrent confined to normal current paths in which there is no insulation breakdown. Sustained overloads are commonly caused by installing excessive equipment such as additional lighting fixtures or too many motors.
Sustained overloads are also caused by overloading mechanical equipment and by equipment breakdown such as failed bearings. If not disconnected within established time limits, sustained overloads eventually overheat circuit components causing thermal damage to insulation and other system components. Overcurrent protective devices must disconnect circuits and equipment experiencing continuous or sustained overloads before overheating occurs.
Even moderate insulation overheating can seriously reduce the life of the components and/or equipment involved. For example, motors overloaded by just 15% may experience less than 50% of normal insulation life. Temporary overloads occur frequently. Common causes include temporary equipment overloads such as a machine tool taking too deep of a cut, or simply the starting of an inductive load such as a motor.
Since temporary overloads are by definition harmless, overcurrent protective devices should not open or clear the circuit. It is important to realize that fuses selected must have sufficient time-delay to allow motors to start and temporary overloads to subside. However, should the overcurrent continue, fuses must then open before system components are damaged. Littelfuse POWR-PRO® and POWR-GARD® time-delay fuses are designed to meet these types of protective needs.
In general, time-delay fuses hold 500% of the rated current for a minimum of ten seconds, yet will still open quickly on higher values of current. Even though government-mandated high-efficiency motors and NEMA Design E motors have much higher locked rotor currents, POWR-PRO® time-delay fuses such as the FLSR_ID, LLSRK_ID, or IDSR series have sufficient time-delay to permit motors to start when the fuses are properly selected in accordance with the NEC®.
Short-Circuits A short-circuit is an overcurrent flowing outside of its normal path. Types of short-circuits are generally divided into three categories: bolted faults, arcing faults, and ground faults. Each type of short-circuit is defined in the Terms and Definitions section. A short-circuit is caused by an insulation breakdown or faulty connection. During a circuit's normal operation, the connected load determines current.
When a short-circuit occurs, the current bypasses the normal load and takes a "shorter path," hence the term ‘short-circuit'. Since there is no load impedance, the only factor limiting current flow is the total distribution system's impedance from the utility's generators to the point of fault. A typical electrical system might have a normal load impedance of 10 ohms. But in a single-phase situation, the same system might have a load impedance of 0.
005 ohms or less. In order to compare the two scenarios, it is best to apply Ohm's Law (I = E/R for AC systems). A 480 volt single-phase circuit with the 10 ohm load impedance would draw 48 amperes (480/10 = 48). If the same circuit has a 0.005 ohm system impedance when the load is shorted, the available fault current would increase significantly to 96,000 amperes (480/0.005 = 96,000). As stated, short-circuits are currents that flow outside of their normal path.
Regardless of the magnitude of overcurrent, the excessive current must be removed quickly. If not removed promptly, the large currents associated with short-circuits may have three profound effects on an electrical system: heating, magnetic stress, and arcing. Heating occurs in every part of an electrical system when current passes through the system. When overcurrents are large enough, heating is practically instantaneous.
The energy in such overcurrents is measured in ampere-squared seconds (I2t). An overcurrent of 10,000 amperes that lasts for 0.01 seconds has an I2t of 1,000,000 A2s. If the current could be reduced from 10,000 amperes to 1,000 amperes for the same period of time, the corresponding I2t would be reduced to 10,000 A2s, or just one percent of the original value. If the current in a conductor increases 10 times, the I2t increases 100 times.
A current of only 7,500 amperes can melt a #8 AWG copper wire in 0.1 second. Within eight milliseconds (0.008 seconds or one-half cycle), a current of 6,500 amperes can raise the temperature of #12 AWG THHN thermoplastic insulated copper wire from its operating temperature of 75°C to its maximum short-circuit temperature of 150°C. Any currents larger than this may immediately vaporize organic insulations.
Arcs at the point of fault or from mechanical switching such as automatic transfer switches or circuit breakers may ignite the vapors causing violent explosions and electrical flash. Magnetic stress (or force) is a function of the peak current squared. Fault currents of 100,000 amperes can exert forces of more than 7,000 lb. per foot of bus bar. Stresses of this magnitude may damage insulation, pull conductors from terminals, and stress equipment terminals sufficiently such that significant damage occurs.
Arcing at the point of fault melts and vaporizes all of the conductors and components involved in the fault. The arcs often burn through raceways and equipment enclosures, showering the area with molten metal that quickly starts fires and/or injures any personnel in the area. Additional short-circuits are often created when vaporized material is deposited on insulators and other surfaces. Sustained arcing-faults vaporize organic insulation, and the vapors may explode or burn.
Whether the effects are heating, magnetic stress, and/or arcing, the potential damage to electrical systems can be significant as a result of short-circuits occurring. II. Selection Considerations Selection Considerations for Fuses (600 volts and below) Since overcurrent protection is crucial to reliable electrical system operation and safety, overcurrent device selection and application should be carefully considered.
When selecting fuses, the following parameters or considerations need to be evaluated: Current Rating Voltage Rating Interrupting Rating Type of Protection and Fuse Characteristics Current Limitation Physical Size Indication General Industrial Fusing Recommendations Based on the above selection considerations, the following is recommended: Fuses with ampere ratings from 1/10 through 600 amperes When available fault currents are less than 100,000 amperes and when equipment does not require the more current-limiting characteristics of UL Class RK1 fuses, FLNR and FLSR_ID Series Class RK5 current-limiting fuses provide superior time-delay and cycling characteristics at a lower cost than RK1 fuses.
If available fault currents exceed 100,000 amperes, equipment may need the additional current-limitation capabilities of the LLNRK, LLSRK and LLSRK_ID series Class RK1 fuses. Fast-acting JLLN and JLLS series Class T fuses possess space-saving features that make them especially suitable for protection of molded case circuit breakers, meter banks, and similar limited-space applications. Time-delay JTD_ID and JTD series Class J fuses are used in OEM motor control center applications as well as other MRO motor and transformer applications requiring space-saving IEC Type 2 protection.
Class CC and Class CD series fuses are used in control circuits and control panels where space is at a premium. The Littelfuse POWR-PRO CCMR series fuses are best used for protection of small motors, while the Littelfuse KLDR series fuses provide optimal protection for control power transformers and similar devices. For questions about product applications, call our Technical Support Group at 800-TEC-FUSE.
Fuses with ampere ratings from 601 through 6,000 amperes For superior protection of most general-purpose and motor circuits, it is recommended to use the POWR-PRO® KLPC series Class L fuses. The Class L fuses are the only time-delay fuse series available in these higher ampere ratings. Information on all the Littelfuse fuse series referenced above can be found on the UL/CSA Fuse Classes and Applications Charts found in the Technical Application Guide at the end of the POWR-GARD products catalog.
Industrial Circuit Protection Checklist To select the proper overcurrent protective device for an electrical system, circuit and system designers should ask themselves the following questions before a system is designed: What is the normal or average current expected? What is the maximum continuous (three hours or more) current expected? What inrush or temporary surge currents can be expected? Are the overcurrent protective devices able to distinguish between expected inrush and surge currents, and open under sustained overloads and fault conditions? What kind of environmental extremes are possible? Dust, humidity, temperature extremes and other factors need to be considered.
What is the maximum available fault current the protective device may have to interrupt? Is the overcurrent protective device rated for the system voltage? Will the overcurrent protective device provide the safest and most reliable protection for the specific equipment? Under short-circuit conditions, will the overcurrent protective device minimize the possibility of a fire or explosion? Does the overcurrent protective device meet all the applicable safety standards and installation requirements? Answers to these questions and other criteria will help to determine the type overcurrent protection device to use for optimum safety, reliability and performance.
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This article is about mains power connection devices used in domestic and light commercial environments. For other types, see Industrial and multiphase power plugs and sockets. Plugs and sockets for electrical appliances not hardwired to mains electricity originated in Britain in the 1880s and were initially two-pin designs. These were usually sold as a mating pair, but gradually de facto and then official standards arose to enable the interchange of compatible devices.
British standards have proliferated throughout large parts of the former British Empire. BS 546, Two-pole and earthing-pin plugs, socket-outlets and socket-outlet adaptors for AC (50-60 Hz) circuits up to 250 V is a British Standard for three pin AC power plugs and sockets. Originally published in April 1934, it was updated by a 1950 edition which is still current, with eight amendments up to 1999.
BS 546 is also the precursor of current Indian and South African plug standards. The 5 A version has been designated as Type D and the 15 A as Type M. BS 546 plugs and sockets are still permitted in the UK, provided the socket has shutters. BS 1363, 13 A plugs socket-outlets adaptors and connection units is a British Standard which specifies the most common type of single-phase AC power plugs and sockets that are used in the United Kingdom.
Distinctive characteristics of the system are shutters on the neutral and line (see Concepts and Terminology below) socket holes, and a fuse in the plug. It has been adopted in many former British overseas territories. BS 1363 was introduced in 1947 as one of the new standards for electrical wiring in the United Kingdom used for post-war reconstruction. The plug and socket replaced the BS 546 plug and socket, which are still found in old installations or in special applications.
BS 1363 plugs have been designated as Type G. Concepts and terminology The International Electrotechnical Commission publishes IEC 60050, the International Electrotechnical Vocabulary, which is also available as IEV Online. Generally the plug is the movable connector attached to an electrically operated device's mains cable, and the socket is fixed on equipment or a building structure and connected to an energised electrical circuit.
The plug has protruding pins (referred to as male) that fit into matching apertures (called female) in the sockets. A plug is defined in IEC 60050 as an accessory having pins designed to engage with the contacts of a socket-outlet, also incorporating means for the electrical connection and mechanical retention of flexible cables or cords, a plug does not contain components which modify the electrical output from the electrical input (except where a switch or fuse is provided as a means of disconnecting the output from input).
There is an erroneous tendency to refer to power conversion devices with incorporated plug pins as plugs, but IEC 60050 refers to these as 'direct plug-in equipment' defined as equipment in which the mains plug forms an integral part of the equipment enclosure so that the equipment is supported by the mains socket-outlet. In this article, the term 'plug' is used in the sense defined by IEC 60050. Sockets are designed to prevent exposure of bare energised contacts.
To reduce the risk of users accidentally touching energized conductors and thereby experiencing electric shock, plug and socket systems often incorporate safety features in addition to the recessed contacts of the energized socket. These include plugs with insulated sleeves, sockets with blocking shutters, and sockets designed to accept only compatible plugs inserted in the correct orientation. The term plug is in general and technical use in all forms of English, common alternatives being power plug,electric plug, and plug top.
 The normal technical term for an AC power socket is socket-outlet, but in non-technical common use a number of other terms are used. The general term is socket, but there are numerous common alternatives, including power point,plug socket,wall socket, and wall plug. Modern British sockets for domestic use are normally manufactured as single or double units with an integral face plate and are designed to fit standard mounting boxes.
Electrical sockets for single phase domestic, commercial and light industrial purposes generally provide three electrical connections to the supply conductors. These are termed neutral, line and earth. Both neutral and line carry current and are defined as live parts. Neutral is usually at or very near to earth potential, being earthed either at the substation or at the service entrance (neutral-to-earth bonding is not permitted in the distribution board/consumer unit).
Line (commonly, but technically incorrectly, called live) carries the full supply voltage relative to the neutral. The protective earth connection allows the exposed metal parts of the appliance to be connected to earth, providing protection to the user should those exposed parts inadvertently come into contact with any live parts within the appliance. Historically, two-pin sockets without earth were used in Britain, but their use is now restricted to sockets specifically designated for shavers and toothbrushes.
An adaptor (in the context of plugs and sockets) is defined in IEC 60050 as a portable accessory constructed as an integral unit incorporating both a plug portion and one or more socket-outlet portions. (There is an alternative spelling, adapter, but adaptor is the form usually used in standards and official documents.) Common characteristics There are certain characteristics common to British mains plugs and sockets intended for domestic use.
The brass pins appear relatively solid and large compared to others. British Standards for plugs (with the exception of BS 4573) have always specified side entry flex (entry in other types is usually parallel to the axes of the pins). Since 1934, the contacts of a socket have been specified in terms of the pins of the plug, rather than by specifying the contact dimensions. The pins of both round pin and rectangular pin plugs are arranged in a triangular fashion, the earth pin being the larger and longer pin at the apex.
Earthed sockets are designed to be incompatible with two-pin plugs. Both BS 546 and BS 1363 sockets, when viewed from the front with the earth uppermost, have the line aperture at the lower right. British plugs and sockets regulatory system A Statutory Instrument, the Plugs and Sockets etc. (Safety) Regulations 1987 was introduced to specifically regulate plugs and sockets in the United Kingdom.
This was revised by the Plugs and Sockets etc. (Safety) Regulations 1994. The guidance notes to the 1994 regulations state: The Plugs and Sockets, etc. (Safety) Regulations 1994 (the “Regulations”) were introduced to provide a regulatory regime to address issues regarding consumer safety. There were concerns that consumer safety was compromised by the substantial quantity of counterfeit and unsafe electrical plugs and sockets being placed on the UK market and also by the provision of electrical equipment without an appropriate means to connect it to the mains supply in the consumer’s home.
The regulations include a requirement that all plug types must be tested and certified by a nominated approval body (normally BSI, ASTA-Intertek or NEMKO). They also require that all mains appliances for domestic use in the UK are supplied with approved BS 1363 plugs, but there is an exception for plugs fitted to shavers and toothbrushes which are normally a UK shaver plug (BS 4573) but may also be a Europlug (BS EN 50075).
The regulations also contain a provision for the approval of non-BS 1363 conforming plugs when "the plugs are constructed using an alternative method of construction which provides an equivalent level of safety in respect of any risk of death or personal injury to plugs which conform to BS 1363 and is such that plugs of that type may reasonably be expected to be safe in use." Certifying bodies have used this provision by developing their own standards for novel devices, thus allowing the introduction of innovative developments; an example is the plastic ISOD (insulated shutter opening device) which was originally approved against either an ASTA Standard or the BSI PAS 003 before becoming incorporated into BS 1363-1:1995.
There is no European Union regulation of domestic mains plugs and sockets; the Low Voltage Directive specifically excludes domestic plugs and sockets. EU countries each have their own regulations and national standards and CE marking is neither applicable nor permitted on plugs and sockets. Despite this CE Marking is sometimes fraudulently used, especially on universal sockets. Early history Lampholder plug from 1893 GEC Ltd (London) Catalogue When electricity was first introduced into houses, it was primarily used for lighting.
As electricity became a common method of operating labour-saving appliances, a safe means of connection to the electric system other than using a light socket was needed. According to British Author John Mellanby the first plug and socket in England was introduced by T.T. Smith in 1883, and there were two-pin designs by 1885, one of which appears in the (British) General Electric Company Ltd. catalogue of 1889.
Gustav Binswanger, a German Jewish immigrant who founded the (British) General Electric Company Ltd, obtained a patent (GB189516898) in 1895 for a plug and socket using a concentric (co-axial) contact system. The earthed consumer plug has several claimants to its invention. A 1911 book dealing with the electrical products of A. P. Lundberg & Sons of London describes the Tripin earthed plug available in 2.
5 A and 5 A models. The pin configuration of the Tripin appears virtually identical to modern BS 546 plugs. In her 1914 book Electric cooking, heating, cleaning, etc Maud Lucas Lancaster mentions an earthed iron-clad plug and socket by the English firm of A. Reyrolle & Company. The 1911 General Electric Company Ltd. (GEC) Catalogue included several earthed sockets intended for industrial use.
British two-pin plugs and sockets Early GEC 2 pin plug and socket as depicted in the 1893 GEC Catalogue The earliest domestic plug and socket is believed to be that patented by T.T. Smith in 1883. This was shortly followed by patents from WB Sayers and G Hookham; these early designs had rectangular plugs with contact plates on either side. In 1885, two-pin plug designs appeared and in 1889 there were two-pin plugs and sockets in the GEC catalogue.
 The 1893 GEC Catalogue included 3 sizes of what was described as Double plug Sockets with capacities described not in amps, but as 1 to 5 lights, 5 to 10 lights and 10 to 20 lights. These were clearly recognisable as two-pin plugs and sockets, but with no indication as to pin size or spacing, they were sold as pairs. The same catalogue included lampholder plugs for both BC and ES lampholders (capacity unspecified), and also a type of two-pole concentric plug and socket (similar to a very large versions of the concentric connectors used for laptop PC power connections) in the 1 to 5 lights and 5 to 10 lights capacities.
Crompton and Company introduced the first two-pin socket with protective shutters in 1893, the Edison Swan Company was also manufacturing two-pin plug and sockets in the 1890s. By the time the 1911 GEC Catalogue was published two pin plugs and sockets were being offered with specifications in amps, but still no indication as to pin size or spacing. The Midget Gauge was rated at 3 A, the Standard Gauge rated at 5 A, and the Union Gauge rated at 10 A.
Also offered were two-way and three-way "T pieces" or multi-way adaptors for the 3 A and 5 A plugs, two way only for the 10 A. Versions of the concentric plug and socket were now offered rated at 5 A and 10 A. At the same time Lundberg were offering the 2.5 A Dot; 5 A Universal and 15 A Magnum, and Tucker were offering a range of 5 A, 10 A and 20 A plugs and sockets. BS 73 Wall plugs and sockets (five ampere two-pin without earthing connection) was first published in 1915, and revised in 1919 with the addition of 15 A and 30 A sizes.
By the 1927 revision of BS 73 four sizes of two-pin plugs and sockets were standardized: 2 A, 5 A, 15 A and 30 A. This was later superseded by BS 372:1930 part 1 Two-pin Side-entry Wall Plugs And Sockets for Domestic Purposes. Following the introduction of BS 4573 in 1970 there were no longer any UK domestic uses for two-pin sockets except for shavers, so BS 372 was renamed ""Two-pin Side-entry Wall Plugs And Sockets For Special Circuits"" and subsequently withdrawn.
Characteristics of BS 73:1927 (BS 372:1930 part 1) two-pin plugs Current rating 30 A 15 A 5 A 2 A Pin diameter 0.312 inches (7.9 mm) 0.278 inches (7.1 mm) 0.200 inches (5.1 mm) 0.140 inches (3.6 mm) Pin length 1.125 inches (28.6 mm) 0.812 inches (20.6 mm) 0.625 inches (15.9 mm) 0.500 inches (12.7 mm) Distance between pin centres 1.25 inches (32 mm) 0.875 inches (22.2 mm) 0.656 inches (16.
7 mm) 0.473 inches (12.0 mm) BS 4573 (UK shaver) Comparison of (top) the BS 4573 shaver plug with its parallel 5.1 mm pins that are 16.66 mm apart with the Europlug with its 4 mm pins converging slightly from a distance of 19 mm apart UK shaver socket marked with shaver symbol. Accepts BS 4573 plugs, also US, Australian and Europlugs. Dual voltage, with isolating transformer. BS 4573 British Standard Specification for two-pin reversible plugs and shaver socket-outlets defines a plug for use with electric shavers, the pin dimensions are the same as those of the 5 A plug specified in the obsolete BS 372:1930 part 1 (as shown in the table above).
 Unlike the original, the plug has insulated sleeves on the pins. Electric toothbrushes in the UK are normally supplied with the same plug. The sockets for this plug are rated at (and limited to) 200 mA. BS 4573 has no explicit specification for the plug rating, but Sheet GB6 (BS 4573, dated 2002-06-03, written by BSI committee) of IEC 60083 states that a rating of 0.2 A applies to all BS 4573 accessories.
The BS 4573 socket is suitable for use in dry areas only, so is now rarely used. It is more usual to find shaver supply units meeting BS EN 61558-2-5 which include an isolation transformer and usually accept multiple two-pin plug types including BS 4573, Europlug and Australian. The isolation transformer often includes a 115 V output, and will then accept two-pin US plugs also. Shaver supply units must also be current limited, BS EN 61558-2-5 specifies a minimum rating of 20 VA and maximum of 50 VA.
 BS 4573 and BS EN 61558-2-5 both require sockets to be marked with the shaver symbol defined in the IEC Standard 60417-5225, the words "shavers only" are also often used but not required. British three-pin (round) plugs and sockets Illustration of "Tripin" 3-pin earthed plug dated 1911. Note that the plug has the basic characteristics of the modern BS 546 plug, three round pins, the earth pin being longer and thicker than the other two, and with a side cable entry.
In the early 20th century, A. P. Lundberg & Sons of London manufactured the Tripin earthed plug available in 2.5 A and 5 A models. The Tripin is described in a 1911 book dealing with the electrical products of A. P. Lundberg & Sons and its pin configuration appears virtually identical to modern BS 546 plugs. The first British standard for domestic three-pin plugs was BS 317 Hand-Shield and Side Entry Pattern Three-Pin Wall Plugs and Sockets (Two Pin and Earth Type) published in 1928.
This was superseded in 1930 by BS 372 Side-Entry Wall Plugs and Sockets for Domestic Purposes Part II which states that there are only minor alterations from BS 317. In 1934, BS 372 Part II was in turn superseded by the first edition of BS 546 Two-Pole and Earthing-Pin Plugs and Socket Outlets. BS 546:1934 clause 2 specifies interchangeability with BS 372 Part II which includes the same four plug and socket sizes.
(BS 372 Part I was a standard for two-pin non-earthed plugs which were never included in BS 546 and which were incompatible due to different pin spacings.) Also in 1934 the 10th Edition of the IEE’s “Regulations for the Electrical Equipment of Buildings” introduced the requirement for all sockets to have an earth contact. Prior to BS 546, British Standards for domestic plugs and sockets included dimensional specifications for the socket contact tubes.
In BS 546 there are no dimensions for socket contacts, instead they are required to make good contact with the specified plug pins. Before the introduction of BS 317, GH Scholes Ltd (Wylex) introduced (in 1926) an alternative three-pin plug. in three sizes, 5 A, 10 A and 15 A with a round earth pin and rectangular live pins, a fused 13 A version of this continued to be available after the introduction of BS 1363, illustrating that BS 546 was not used exclusively at any time.
Although still permitted by the UK wiring regulations, BS 546 sockets are no longer used for general purposes. Some of the varieties remain in use in other countries and in specialist applications such as stage lighting. When BS 546 was in common use domestically in the UK the standard did not require sockets to be shuttered, although many were. The current revision of the standard allows optional shutters similar to those of BS 1363.
Current UK wiring regulations require socket outlets installed in homes to be shuttered. BS 546 BS 546 3-pin plugs. Left to right: 15 A, 5 A and 2 A. There are four ratings of plug and socket in BS 546, (2 A, 5 A, 15 A and 30 A). Each has the same general appearance but they are different physical sizes to prevent interchangeability, they use pin spacing which is also different from the two pin plugs specified in BS 372, so earthed plugs will not fit into unearthed sockets, and vice versa.
Plugs fitted with BS 646 fuses have been optional since the original BS 546:1934 with maximum fuse ratings of 2 A in the 2 A plug, and 5 A in the 5 A, 15 A and 30 A plugs. In practice most BS 546 plugs are unfused with fused versions being unusual and expensive. The 15 ampere (A) sockets were generally given a dedicated 15 A circuit. Multiple 5 A sockets might be on a 15 A circuit, or each on a dedicated 5 A circuit.
Lighting circuits fused at 5 A were generally used to feed the 2 A sockets. Adaptors were available from 15 A down to 5 A and from 5 A down to 2 A so in practice it was possible for an appliance with the smallest size of flex to be protected only by a 15 A fuse. This is a similar level of protection to that seen for portable appliances in other countries, but less than the protection offered by the BS 1363 fused plug.
The larger top pin is the earth connection, the left hand pin is neutral and the right hand pin is line when looking at a socket or at the rear of a plug. 2 ampere This plug was used to connect low power appliances (and to adaptors from the larger socket types). It is sometimes still used to connect lamps to a lighting circuit. 5 ampere 5 A switched socket-outlet to BS 546 This plug corresponds to Type D in the IEC table.
 In the UK it was used for moderate sized appliances, either on its own 5 A circuit or on a multi socket 15 A circuit, and also on many adaptors (both multi socket 5 A adaptors and adaptors that also had 15 A pins). This 5 A plug, along with its 2 A cousin, is sometimes used in the UK for centrally switched domestic lighting circuits, in order to distinguish them from normal power circuits, this is quite common in hotel rooms.
This plug was also once used in theatrical installations for the same reasons as the 15 A model below. 15 ampere 15 A switched socket-outlet to BS 546 This plug corresponds to Type M in the IEC table. It is the largest in domestic use and is commonly used in the UK for indoor dimmable theatre and architectural lighting installations. 30 ampere The 30 A plug is the largest of the family.
This was used for high power industrial equipment up to 7.2 kW, such as industrial kitchen appliances, or dimmer racks for stage lighting. Plugs and sockets were usually of an industrial waterproof design with a screw locking ring on the plug to hold it in the socket against waterproof seals, and sockets often had a screw cap chained to them to be used when no plug was inserted to keep them waterproof.
Use of the BS 546 30 A plugs and sockets diminished through the 1970s as they were replaced with BS 4343 (which later became IEC 60309) industrial combo plugs and sockets. Characteristics of BS 546 three-pin plugs BS 546:1950 (current version confirmed October 2012) specifies pin dimensions only in decimal fractions of an inch, as shown below. The metric values are conversions provided here for convenience.
Note, the original lengths of the line and neutral pins on the 15 and 5 amp versions were slightly longer at 0.812 inches (20.6 mm) and 0.625 inches (15.9 mm) respectively. Current rating 30 A 15 A 5 A 2 A Diameter, line and neutral pins 0.312 inches (7.9 mm) 0.278 inches (7.1 mm) 0.200 inches (5.1 mm) 0.140 inches (3.6 mm) Length, line and neutral pins 1.125 inches (28.6 mm) 0.733 inches (18.
6 mm) 0.585 inches (14.9 mm) 0.500 inches (12.7 mm) Diameter, earth pin 0.375 inches (9.5 mm) 0.343 inches (8.7 mm) 0.278 inches (7.1 mm) 0.200 inches (5.1 mm) Length, earth pin 1.437 inches (36.5 mm) 1.125 inches (28.6 mm) 0.812 inches (20.6 mm) 0.625 inches (15.9 mm) Distance, L and N pin centres 1.437 inches (36.5 mm) 1.000 inch (25.4 mm) 0.750 inches (19.1 mm) 0.570 inches (14.5 mm) Distance, perpendicular, E pin centre and axis of L and N pin centres 1.
562 inches (39.7 mm) 1.125 inches (28.6 mm) 0.875 inches (22.2 mm) 0.570 inches (14.5 mm) BS 1363 three-pin (rectangular) plugs and sockets Left: a typical moulded BS 1363 plug, showing the fuse access from the underside of the plug. Right: a typical rewireable plug; the large central screw releases the cover, allowing access to the terminals and also the fuse BS 1363 is a British Standard which specifies the common single-phase AC power plugs and sockets that are used in the United Kingdom.
Distinctive characteristics of the system are shutters on the line and neutral socket holes, and a fuse in the plug. It has been adopted in many former British overseas territories. BS 1363 was introduced in 1947 as one of the new standards for electrical wiring in the United Kingdom used for post-war reconstruction. This plug corresponds to Type G in the IEC table. BS 1363 replaced the BS 546 plug and socket (which are still found in old installations or in special applications such as remotely switched lighting).
Other exceptions to the use of BS 1363 plugs and sockets include equipment requiring more than 13 A, low-power portable equipment (such as shavers and toothbrushes) and mains-operated clocks. History BS 1363:1947 "Fused-Plugs and Shuttered Socket-Outlets" which resulted from the report "Post-War Building Studies No. 11, Electrical Installations" In 1941 Lord Reith, then the minister of Works and Planning, established committees to investigate problems likely to affect the post-war rebuilding of Britain.
One of these, the Electrical Installations Committee, was charged with the study of all aspects of electrical installations in buildings. Amongst its members was Dame Caroline Haslett, President of the Women's Engineering Society and an expert on safety in the home. Convened in 1942, the committee reported in 1944, producing one of a set of Post War Building Studies that guided reconstruction.
 The plug and socket-outlet system defined in BS 1363 is a result of one of the report's recommendations. Britain had previously used a combination of 2 A, 5 A and 15 A round pin sockets. In an appendix to the main report (July 1944), the committee proposed that a completely new socket-outlet and fused plug should be adopted as the "all-purpose" domestic standard. The main report listed 8 points to consider in deciding the design of the new standard.
The first of these was stated as “To ensure the safety of young children it is of considerable importance that the contacts of the socket-outlet should be protected by shutters or other like means, or by the inherent design of the socket-outlet.” Others included flush fitting, no need for a switch, requirements for terminals, bottom entry for the cable, and contact design. The appendix added 5 further "points of technical detail" including requirements that plugs could not be inserted incorrectly, should be easy to withdraw, and should include a fuse.
 This requirement for a new system of plugs and sockets led to the publishing in 1947 of "British Standard 1363:1947 Fused-Plugs and Shuttered Socket-Outlets". One of the other recommendations in the report was the introduction of the ring circuit system (often informally called a "ring main"). In this arrangement a cable connected to a fuse, or circuit breaker, in the distribution board was wired in sequence to a number of sockets before being terminated back at the distribution board, thus forming a ring final circuit.
In the ring circuit, each socket-outlet was supplied with current by conductors on both sides of the 'loop.' This contrasts with the radial system (which is also used in the UK, often in the same installation) wherein a single cable runs out radially, like a spoke, from the distribution board to serve a number of sockets. Since the fuse or circuit breaker for a ring circuit has to be rated for the maximum current the ring could carry (30 A or 32 A for a breaker), additional protection is required at each socket-plug connection.
Theoretically, such protection could have been designated either within the socket or within the plug. However, to ensure that this protection has a rating matched to the appliance flexible cord fitted to the plug, a fuse rated between 1 A and 13 A is incorporated into each plug. Wired connections may also be connected to the ring, and these are also required to include a suitably rated fuse. The ring circuit in the UK requires the use of BS 1363 plugs and sockets, but the BS 1363 system is not limited to use with ring circuits.
 Chronology An early MK plug to original version of standard. Note the unsleeved Line & Neutral pins, and the inspection hole for the purpose of making the connection of an earth conductor visible with the cover in place (as required by BS 1363:1947 clause 15.) BS 1363 is periodically revised, and with supplements and amendments issued between major revisions. BS 1363:1984 and earlier versions dealt only with 13 A plugs and sockets.
From 1989 onwards the standard was rearranged into five parts as follows: Part 1: Rewirable and non-rewirable 13 A fused plugs Part 2: 13 A Switched and unswitched socket-outlets Part 3: Adaptors Part 4: 13 A fused connection units: switched and unswitched Part 5: 13 A fused conversion plugs The following chronology shows revisions, supplements and significant amendments. June 1947: BS 1363:1947 "Fused-Plugs and Shuttered Socket-Outlets" published.
May 1950: BS 1363:1947 Amendment 3, title changed to "Specification for two-pole and earthing-pin fused-plugs and shuttered socket-outlets for A.C. circuits up to 250 Volts (not intended for use on D.C. circuits)". January 1957: BS 1363:1947 Amendment 5, added clause permitting operation of shutters by simultaneous insertion of two or more pins (in addition to original method using only earth pin).
January 1957: BS 1363:1947 Supplement No. 1 added specification for surface mounted socket-outlets. 1957: Complementary standard published, BS 2814:1957 "Two-pole and earthing-pin flush-mounted 13-Amp switch socket-outlets for A.C. circuits up to 250 Volts". A separate standard specifying a switched version of the BS 1363 socket-outlet for use with BS 1363 plugs. December 1960: BS 1363:1947 Supplement No.
2, added specification for Resilient Plugs. December 1961: BS 2814:1957 Amendment 2, title simplified to "13 Ampere Switch Socket-Outlets". 1962: BS 2814:1957 Supplement No. 1 added specification for surface mounted switch outlets. September 1967: BS 1363:1967 "Specification for 13A plugs, switched and unswitched socket-outlets and boxes" published. This standard superseded both BS 1363:1947 and BS 2814:1957.
Only 3 A and 13 A fuses are specified. Resilient Plugs are included. August 1984: BS 1363:1984 "Specification for 13 A fused plugs switched and unswitched socket-outlets" published. This standard superseded BS 1363:1967. Changes include introduction of sleeved pins on Line and Neutral, metric dimensions replacing inches, specifications added for non-rewirable plugs and portable socket-outlets.
The standard was aligned, where possible, with the proposed IEC standard for domestic plugs and socket-outlets. February 1989: BS 1363-3:1989 "13 A plugs socket-outlets and adaptors - Part 3: Specification for adaptors" published. This new standard covers adaptors for use with BS 1363 socket-outlets and includes conversion adaptors (those which accept plugs of a different type), multiway adaptors (those which accept more than one plug, which may or may not be of a different type) and shaver adaptors.
All adaptors (except for those accepting not more than two BS 1363 plugs) require to be fused. All sockets, including those to other standards, must be shuttered. 1994: A Product Approval Specification, PAS 003:1994, "Non-Rewirable 13 A Plugs with Plastic Socket Shutter Opening Pins" published. PAS 003 allowed for the design and approval of plugs without earthing intended for class II applications only.
This was superseded by BS 1363-1:1995 but the PAS was not withdrawn until 23 July 2013. February 1995: BS 1363-1:1995 "13 A plugs socket-outlets adaptors and connection units - Part 1: Specification for rewirable and non-rewirable 13 A fused plugs" published. This standard, together with BS 1363-2:1995, supersedes BS 1363:1984. The provisions of PAS 003 are incorporated, but the plastic pin is redesignated as an "ISOD" September 1995: BS 1363-2:1995 "13 A plugs socket-outlets adaptors and connection units - Part 2: Specification for 13 A switched and unswitched socket-outlets" published.
September 1995: BS 1363-3:1995 "13 A plugs socket-outlets adaptors and connection units - Part 3: Specification for adaptors" published. Supersedes BS 1363-3:1989 November 1995: BS 1363-4:1995 "13 A plugs socket-outlets adaptors and connection units - Part 4: Specification for 13 A fused connection units switched and unswitched" published. A new standard. August 2008: BS 1363-5:2008 "13 A plugs socket-outlets adaptors and connection units - Part 5: Specification for 13 A fused conversion plugs" published.
A new standard. May 2012: BS 1363-1:1995 +A4:2012 (Title unchanged) published. This amended standard allows switches to be incorporated into plugs, and introduced new overload tests amongst others. BS 1363-1:1995 remained current until 31 May 2015. May 2012: BS 1363-2:1995 +A4:2012 (Title unchanged) published. This amended standard adds a requirement that it shall not be possible to operate a shutter by the insertion of a two-pin Europlug, and introduced new temperature rise tests amongst others.
BS 1363-2:1995 remained current until 31 May 2015. May 2012: BS 1363-4:1995 +A4:2012 (Title unchanged) published. Minor changes to BS 1363-4:1995 which remained current until 31 May 2015. November 2012: BS 1363-3:1995 +A4:2012 (Title unchanged) published. This amended standard adds a requirement that it shall not be possible to operate a shutter by the insertion of a two-pin Europlug, and added specifications for switched adaptors amongst others.
BS 1363-3:1995 will remain current until 31 December 2015. August 2016: BS 1363-1:2016 (Title unchanged) published. Added requirements for incorporated electronic components and for electric vehicle charging. BS 1363-1:1995 +A4:2012 will remain current until 31 August 2019. August 2016: BS 1363-2:2016 (Title unchanged) published. Added requirements for incorporated electronic components and for electric vehicle charging.
BS 1363-2:1995 +A4:2012 will remain current until 31 August 2019. August 2016: BS 1363-3:2016 (Title unchanged) published. Added requirements for incorporated electronic components. BS 1363-3:1995 +A4:2012 will remain current until 31 August 2019. August 2016: BS 1363-4:2016 (Title unchanged) published. Minor changes only. BS 1363-4:1995 +A4:2012 will remain current until 31 August 2019. August 2016: BS 1363-5:2016 (Title unchanged) published.
Minor changes only. BS 1363-5:2008 will remain current until 31 August 2019. BS 1363-1 Rewirable and non-rewirable 13 A fused plugs BS 1363 plug, with a plastic pin insulated shutter opening device (ISOD) and sleeved pins. A BS 1363 plug has two horizontal, rectangular pins for line and neutral, and above these pins, a larger, vertical pin for an earth connection. Note, both line and neutral carry current and are defined as live parts.
 The earth pin also serves to operate the basic shutter mechanism used in many sockets. Correct polarity is established by the position of the earth pin relative to the other two pins, ensuring that the line pin is connected to the correct terminal in the socket-outlet. Moulded plugs for unearthed, double-insulated appliances may instead have a non-conductive plastic pin (an Insulated Shutter Opening Device or ISOD) the same size and shape as an earth pin, to open the shutters.
When looking at the plug pins with the earth uppermost the lower left pin is line, and the lower right is neutral. UK Consumer Protection legislation requires that most domestic electrical goods sold must be provided with fitted plugs to BS 1363-1. These are usually, but not necessarily, non-rewirable. Rewirable plugs for hand-wiring with a screwdriver are commonly available and must be provided with instructions.
 Nominal dimensions BS 1363-1 specifies the dimensions of plug pins and their disposition with respect to each other in precise, absolute terms. The line and neutral pins have a rectangular cross section 6.4 mm by 4.0 mm, 17.7 mm long and with centres 22.2 mm apart. The protective-earth pin is a rectangular cross section 8.0 mm by 4.0 mm, 22.3 mm long and with a centre line 22.2 mm from the line/neutral pin centre line.
The dimensions were originally specified in decimal inches with asymmetric tolerances and redefined as minimum and maximum metric dimensions in BS 1363:1984. Dimensions are chosen to provide safe clearance to live parts. The distance from any part of the line and neutral pins to the periphery of the plug base must be not less than 9.5 mm. This ensures that nothing can be inserted alongside a pin when the plug is in use, and helps keep fingers away from the pins.
The longer earth pin ensures that the earth path is connected before the live pins, and remains connected after the live pins are removed. The earth pin is too large to be inserted into the line or neutral sockets by mistake. Pin insulation Initially, BS 1363 did not require the line and neutral pins to have insulating sleeves. Plugs made to the recent revisions of the standard have insulated sleeves to prevent finger contact with pins, and also to stop metal objects (for example, fallen window blind slats) from becoming live if lodged between the wall and a partly pulled out plug.
The length of the sleeves prevents any live contacts from being exposed while the plug is being inserted or removed. An early method of sleeving the pins involving spring-loaded sleeves is described in the 1967 British Patent GB1067870. The method actually adopted is described in the 1972 British Patent GB1292991. Plugs with such pins were available in the 1970s, a Southern Electricity/RoSPA safety pamphlet from 1978 encourages their use.
 Sleeved pins became required by the standard in 1984. Fuses BS 1362 fuses (for BS 1363 plugs) There are two common misconceptions about the purpose of the fuse in a BS 1363 plug, one is that it protects the appliance connected to the plug, and the other is that it protects against overloading. In fact the fuse is there to protect the flexible cord between the plug and the appliance under fault conditions (typical British ring circuits can deliver more current than appliance flexible power cords can handle).
BS 1363 plugs are required to carry a cartridge fuse, which must conform to BS 1362. Post-War Building Studies No. 11, Electrical Installations included the recommendation that Provision should be made in the plug for the accommodation of a cartridge type of fuse for 13 amps., and alternatively, for 3 amps. Fuses of these ratings should be interchangeable and be readily identified. The original BS 1363:1947 specified fuse ratings of 3 A, 7 A and 13 A.
 The current version of the fuse standard, BS 1362:1973, allows any fuse rating up to 13 A, with 3 A (coloured red) and 13 A (coloured brown) as the preferred (but not mandated) values when used in a plug. All other ratings are to be coloured black. Plugs, when supplied separately from any appliance, should be available with either a 3 A or 13 A fuse fitted. The fuses are mechanically interchangeable; it is up to the end user or appliance manufacturer to install the appropriate rating.
BS 1362 specifies sand-filled ceramic-bodied cylindrical fuses, 1" (25.4 mm) in length, with two metallic end caps of 1/4" (6.3 mm) diameter and roughly 1/5" long. The standard specifies breaking time versus current characteristics only for 3 A or 13 A fuses. For 3 A fuses: 0.02–80 s at 9 A, < 0.1 s at 20 A and < 0.03 s at 30 A. For 13 A fuses: 1–400 s at 30 A, 0.1–20 s at 50 A and 0.
01–0.2 s at 100 A. Other safety features Internal wiring. Cable grip Neutral terminal Earth terminal Line terminal Fuse The plug sides are shaped to improve grip and make it easier to remove the plug from a socket-outlet. The plug is polarised, so that the fuse is in the line side of the supply. The flexible cord always enters the plug from the bottom, discouraging removal by tugging on the cable, which can damage the cable.
 Rewireable plugs must be designed so that they can be wired in a manner which prevents strain to the earth connection before the line and neutral connection in the event of failure of the cord anchorage. Ratings BS 1363 plugs and sockets are rated for use at a maximum of 250 V ac and 13 A, with the exception of non-rewirable plugs which have a current rating according to the type of cable connected to them and the fuse fitted.
The rating must be marked on the plug, and in the case of non-rewirable plugs the marking must be the value of the fuse fitted by the plug manufacturer in accordance with table 2 of the standard. Typical ratings for non-rewirable plugs are 3 A, 5 A, 10 A and 13 A. Counterfeits and non-standard plugs Plugs which do not meet BS 1363 often find their way into the UK. Some of these are legal in the country they are manufactured in, but do not meet BS 1363 - these can be brought into the UK by unsuspecting travellers, or people purchasing electrical goods online.
They can also be purchased through many UK electrical component distributors. There are also counterfeit plugs which appear to meet the standards (and are marked as such) but do not in fact comply. Legislation was introduced, with the last revision in 1994, to require plugs sold to meet the technical standard. Counterfeit products are regularly seized when found, to enforce the safety standards and to protect the approval marks and trademarks of imitated manufacturers.
 The pressure group PlugSafe reported in March 2014 that since August 2011 "thousands" of listings of products including illegal plugs had been removed from the UK websites ebay.co.uk and amazon.co.uk. The UK Electrical Safety Council expressed shock at the magnitude of the problem and published a video showing a plug exploding due to a counterfeit BS 1362 fuse. The Institution of Engineering and Technology also published information on the extent of the problem with on-line retailers, many advertising replacement cord sets, mobile device chargers, and travel adaptors fraudulently marked BS 1363, and mentioning the same sites.
 BS 1363-2 13 A switched and unswitched socket-outlets BS 1363 type electrical socket-outlet. The closed shutters block entry of foreign objects BS 1363 sockets are commonly supplied with integral switches as a convenience, but switches are optional and did not form part of BS 1363 until 1967. Sockets are required to mate correctly with BS 1363 plugs (as opposed to the dimensions of the socket contacts being specified).
This is checked by means of the use of various gauges which are specified in the standard; these gauges ensure that the socket contacts are correctly positioned and make effective and secure contact with the plug pins. There is no provision for establishing the interchangeability with any other device having plug pins incorporated, but which is not covered by BS 1363 (for example a charger or socket cover) unless that device conforms precisely to the plug pin dimensions specified.
The insertion of non-compliant plugs may damage sockets. The important socket dimensions which the standard does specify are: A minimum insertion of 9.6 mm from the face of the socket-outlet to the first point of contact with a live part, a minimum distance of 9.5 mm from the line and neutral apertures to the periphery of the socket face, and not to exceed dimensions for the apertures of 7.
2 mm x 4.8 mm (line and neutral) and 8.8 mm x 4.8 mm (earth). When looking at the front of the socket with the earth aperture uppermost (as normally mounted) the lower left aperture is for the neutral contact, and the lower right is for the line contact. Shutters BS 1363 sockets must have shutters on the line and neutral contacts to prevent the insertion of a foreign object into the socket.
 Many sockets use the original method of shutters opened by the earth pin (or plastic ISOD), longer than the other pins and hence opening the shutters before the other pins engage, alone. Alternatively, shutters may be opened by simultaneous insertion of line and neutral pins. Some later designs require all three pins to be inserted simultaneously. The use of automatic shutters for protection dates back to at least 1927.
 Other countries, for example the USA, are gradually requiring their sockets to be protected by shutters also. There is a specific requirement in the standard to ensure that Europlugs and other two-pin plugs may not be used with BS 1363 sockets It shall not be possible to operate a shutter by inserting a 2-pin plug into a 3-pin socket-outlet. However, many extension sockets will allow a plug to be inserted upside down, i.
e. only the earth pin, defeating the shutter mechanism. This method is sometimes used to allow a Europlug (with two small round pins and no earth pin) to be forced into the open line and neutral ports. The UK Electrical Safety Council has drawn attention to the fire risk associated with forcing Europlugs into BS 1363 sockets. Socket covers In countries using other socket-outlet types, socket covers are sold to protect children from electrocution by inserting objects into otherwise unprotected sockets.
Such covers are also sold in the UK, but the shutters of the BS 1363 socket-outlet make these unnecessary. The Institution of Engineering and Technology published an article on socket covers by Mark Coles, its Technical Regulations Manager, in its journal "Wiring Matters". The article concludes that: "Socket-outlets to BS 1363 are the safest in the world and have been since they were first designed in the 1940s.
Socket protectors are not regulated for safety, therefore, using a non-standard system to protect a long established safe system is not sensible." The UK government does not collect statistics of injury or accidents related to use of socket covers. A UK-based group called "FatallyFlawed" notes that none of the available socket covers are made to BS 1363 dimensions and so can introduce hazards, either by damaging socket contacts or by allowing foreign objects to be inserted into the live openings.
 The FatallyFlawed website displays a statement from the socket-outlet manufacturer MK Electric, "MK goes to great lengths to ensure that all its BS 1363 plugs and sockets are safe. Inserting incorrectly dimensioned products into a socket-outlet can both damage the socket and reduce its safety". As of 30 June 2016 the use of socket covers has been banned in all premises controlled by the National Health Service (NHS) in the United Kingdom.
 In October 2016 the UK Department for Education confirmed in a written answer to a parliamentary question that they have brought the Department of Health’s recent alert on the dangers associated with the use of electrical socket covers to the attention of early years providers in England. ‘Action for Children’ has published a notice, via the Foundation Years website, about the use of electrical socket covers in early years provision in England.
This is available at: www.foundationyears.org.uk/2016/10/dfe-note-on-the-use-of-electrical-plug-socket-coversinserts-in-early-years-provision-in-England BEAMA (British Electrotechnical and Allied Manufacturers Association) published the following statement in June 2017: “BEAMA strongly advises against the use of socket-outlet ‘protective’ covers.” BS 1363-3 Adaptors Tripler (left) and doubler (right).
The tripler has a red fuse carrier visible. Plug adaptors permit two or more plugs to share one socket-outlet, or allow the use of a plug of different type. There are several common types, including double- and triple-socket blocks, shaver adaptors, and multi-socket strips. Adaptors which allow the use of non-BS 1363 plugs, or more than two BS 1363 plugs, must be fused. Appliances are designed not to draw more power than their plug is rated for; the use of such adaptors, and also multi-socketed extension leads, makes it possible for several appliances to be connected through a single outlet, with the potential to cause dangerous overloads.
 Shaver adaptors Shaver adaptor The purpose of these adaptors is to accept the 2 pin plugs of shavers, they are required to be marked as such. Shaver adaptors must have a 1 A BS 646 fuse. They must accept UK shaver plugs complying with BS 4573 and also Europlugs and American two-pin plugs. BS 1363-4 13 A fused connection units switched and unswitched Switched and unswitched fused connection units, without sockets, use BS 1362 fuses for connection of permanently wired appliances to a socket-outlet circuit.
They are also used in other situations where a fuse or switch (or both) is required, such as when feeding lighting off a socket-outlet circuit, to protect spurs off a ring circuit with more than one socket-outlet, and sometimes to switch feeds to otherwise concealed sockets for kitchen appliances. BS 1363-5 13 A fused conversion plugs Conversion plug suitable for europlug, empty, europlug inserted and closed A conversion plug is a special type of plug suitable for the connection of non-BS 1363 type plugs (to a recognized standard) to BS 1363 sockets.
An example would be Class 2 appliances from mainland Europe which are fitted with moulded europlugs. Similar converters are available for a variety of other plug types. Unlike a temporary travel adaptor, conversion plugs, when closed, resemble normal plugs, although larger and squarer. The non-BS 1363 plug is inserted into the contacts, and the hinged body of the conversion plug is closed and fixed shut to grip the plug.
There must be an accessible fuse. Conversion plugs may be non-reusable (permanently closed) or reusable, in which case it must be impossible to open the conversion plug without using a tool. The Plugs and Sockets, etc. (Safety) Regulations 1994 permit domestic appliances fitted with non-BS 1363 plugs to be supplied in the UK with conversion plugs fitted, but not with conversion plugs supplied for fitting by the consumer.
BS 1363 variations Folding plugs Due to the size of the BS 1363 plug, attempts have been made to develop a compatible folding plug. As of July 2014 two folding plugs have been certified under specially developed ASTA Standards. SlimPlug which complies with ASTA AS153 and ThinPlug which complies with ASTA AS158. SlimPlug is available only as part of a complete power lead terminating in an IEC 60320 C7 unpolarized (figure-of-eight) connector.
 In 2009 the ThinPlug received a "Red Dot" award for product design, the first product, also a power lead terminating in an IEC 60320 C7 unpolarized (figure-of-eight) connector became available in 2011. Folding plugs The SlimPlug folding plug SlimPlug with pins retracted The ThinPlug folding plug ThinPlug with ISOD folded Variant pin configurations Several manufacturers have made deliberately incompatible variants for use where connection with standard plugs is not acceptable.
Common uses include filtered supplies for computer equipment and cleaners' supplies in public buildings and areas (to prevent visitors plugging in unauthorised equipment). Examples are one design made by MK which has a T-shaped earth pin, and the Walsall Gauge 13 A plug, which has each pin rotated 90°, the latter being in use on parts of the London Underground for 110 V AC supply. and also in some British Rail offices for filtered computer supplies.
Variant plugs MK 13 A Plug with a T-shaped earth pin Walsall Gauge 13 A plug (bottom) compared with regular BS 1363 plug Walsall Gauge 13 A plug BS 8546 Travel adaptors compatible with UK plug and socket system BS 8546 applies to travel adaptors having at least one plug or socket-outlet portion compatible with BS 1363 plugs and socket-outlets. It was first published in April 2016 to provide a standard for travel adaptors suitable for the connection of a non-BS 1363 plug, or to a non-BS 1363 socket-outlet.
It provides for an overall rating of 250 V ac, minimum current rating of 5 A, and a maximum of 13 A. Adaptors with BS 1363 plug pins must incorporate a BS 1362 fuse. BS 8546 travel adaptors may also include USB charging ports. UK electric clock connector British electric clock connector, 3-pin, made by MK. Showing the rear of the plug with its 2 A fuse. Fused plugs and sockets of various proprietary and non-interchangeable types are found in older public buildings in the UK, where they are used to feed AC electric wall clocks.
They are smaller than conventional sockets, commonly being made to fit BESA junction boxes, and are often of very low profile. Early types were available fused in both poles, later types fused in the line only and provided an earth pin. Most are equipped with a retaining screw or clip to prevent accidental disconnection. The prevalence of battery powered quartz controlled wall clocks has meant that this connector is rarely seen in new installations for clock use.
However, it has found use where a low profile fused connector is required and is still available. A relatively common example of such a use is to supply power to an illuminated mirror that has limited clearance from the wall. Obsolete non-BS types Wylex 13 A Plug. Note offset line pin (top of photograph). Wylex Plug George H. Scholes Ltd. of Manchester first introduced plugs with a hollow round earth pin between rectangular current-carrying pins in 1926 under the Wylex brand name, this was prior to the first British Standard for earthed plugs.
The Wylex plugs were initially made in three ratings, 5 A, 10 A and 15 A and were unpolarized (the current carrying pins were on the same centre line as the earth pin). In 1933 an asymmetric polarized version was introduced, with line pin slightly offset from the centre line. In 1934 the dual plug system was introduced with the socket rated at 15 A and three sizes of plug, fused 2 A and 5 A plugs and a 15 A plug.
The 15 A "dual plug" incorporated a socket with narrower apertures than a standard Wylex 15 A socket, that accepted only the narrow rectangular pins of the lower-rated plugs. The introduction of a 13 A fused plug, rated as 3 kW., enabled Scholes to propose their system as a possible solution for the new standard competing with the Dorman & Smith round pin solution, but it was not selected and the completely new BS 1363 design prevailed.
 Wylex sockets were used in council housing and public sector buildings and, for a short time in private housing. They were particularly popular in the Manchester area although they were installed throughout England, mainly in schools, university accommodation, and government laboratories. In some London schools built in the 1960s they were used as low-voltage AC sockets, typically 12 V, 5 A from a transformer serving one or more laboratories, for microscope lamps etc.
Wylex plugs and sockets continued to be manufactured for several years after BS 1363 sockets became standard, and were commonly used by banks and in computer rooms during the 1960s and 1970s for uninterruptible power supplies or "clean" filtered mains supplies. Dorman & Smith (D&S) 3 D&S Sockets mounted on a panel Made by Dorman & Smith Ltd. (using patents applied for in 1943) the plugs and sockets were rated at 13 A and were one of the competing types for use on ring final circuits.
 They were never popular in private houses but were widely deployed in prefabricated houses and council housing. The BBC also used them. Some local authorities continued to use them in new installations until the late 1950s. Many D&S sockets were still in use until the early 1980s, although the difficulty in obtaining plugs for them after around 1970 often forced their users to replace them with BS 1363 sockets.
The D&S plug suffered from a serious design fault: the line pin was a fuse which screwed into the plug body and tended to come unscrewed on its own in use. A fuse that worked loose could end up protruding from the socket, electrically live and posing a shock hazard, when the plug was removed. International usage of BS types Standards derived from BS 546 Indian IS 1293 Indian standard IS 1293:2005 Plugs and Socket-Outlets of Rated Voltage up to and including 250 Volts and Rated Current up to and including 16 Amperes includes versions of the 5 A and 15 A BS 546 connectors, but they are rated at 6 A and 16 A respectively.
Some 6 A 3 pin sockets also have two extra holes above the line and neutral holes to allow a 5 A 2-pin plug to be connected. Malaysian Standard MS 1577 MS 1577:2003 15 A plugs and socket-outlets for domestic and similar purposes Russian GOST 7396 The 2 A, 5 A, and 15 A, connectors of BS 546 are duplicated by Group B1 of the GOST 7396 standard. Singapore Standard SS 472 SS 472:1999 15 A plugs and switched socket-outlets for domestic and similar purposes South African SANS 164 Main article: SANS 164 The South African standard SANS 164 Plug and socket-outlet systems for household and similar purposes for use in South Africa defines a number of derivatives of BS 546.
 A household plug and socket is defined in SANS 164-1, and is essentially a modernised version of the BS 546 15 A (the essential differences are that pins can be hollowed to reduce the amount of metal used, the dimensions are metricated, and it is rated 16 A). SANS 164-3 defines a 6 A plug and socket based on the BS 546 5 A. The South African Wiring Code now defines the plug and socket system defined in SANS 164-2 (IEC 60906-1) as the preferred standard, and it is expected that SANS 164-1 and SANS 164-3 devices will be phased out by around 2035.
 SANS 164-4 defines three variants of the 16 A plug and socket intended for specialist (known as "dedicated") applications. The variants use a flattened earth pin, each at a different specified rotational position. This arrangement ensures that the dedicated plugs can all plug into an ordinary ("non-dedicated") socket, but that the various dedicated plug and socket combinations are not interchangeable (nor can a non-dedicated plug be inserted into a dedicated socket).
 The dedicated versions have specific colours assigned to them, depending on the rotational position of the flattened portion. These are black (-53°), red (0°), and blue (+53°). The red (0°) version is by far the most common, and is widely used on computer and telecommunication equipment (although this is not required in the standard). In this application the "dedicated" socket refers to one that is not connected to a residual current circuit breaker, which is otherwise mandated for all normal power sockets.
 International usage of Type D The IEC World Plugs lists Type D as being used in the following locations: Bangladesh, Bhutan, Botswana, Chad, Congo (Democratic Rep. of), Dominica, French Guiana, Ghana, Guadeloupe, Guyana, Hong Kong, India, Iraq, Jordan, Lebanon, Libya, Macau, Madagascar, Maldives, Martinique, Monaco, Myanmar, Namibia, Nepal, Niger, Nigeria, Pakistan, Qatar, Saint Kitts and Nevis, Senegal, Sierra Leone, South Africa, Sri Lanka, Sudan, Tanzania, United Arab Emirates, Yemen, Zambia, Zimbabwe.
International usage of Type M This plug is often used for air conditioners and washing machines. The IEC World Plugs lists Type M as being used in the following locations: Bhutan, Botswana, India, Israel, Lesotho, Macau, Malaysia, Mozambique, Namibia, Nepal, Pakistan, Singapore, South Africa, Sri Lanka, Swaziland. Standards derived from BS 1363 Irish I.S. 401 Irish Standard 401:1997 Safety requirements for rewirable and non-rewirable 13 A fused plugs for normal and rough use having insulating sleeves on live and neutral pins is the equivalent of BS 1363 in Ireland.
The use of this standard is enforced by Consumer Protection legislation which requires that most domestic electrical goods sold in Ireland be fitted with an I.S. 401 plug. Malaysian Standard MS 589 MS 589 parts 1,2,3 and 4 correspond to BS 1363-1, BS 1363-2, BS 1363-3 and BS 1363-4 Russian GOST 7396 Group B2 of the GOST 7396 standard describes BS 1363 plugs and sockets. Saudi Arabian Standard SASO 2203:2003 SASO 2203:2003 Plugs and socket-outlets for household and similar general use 220 V Singapore Standard SS 145 SS 145-1:2010 Specification for 13 A plugs and socket-outlets - Part 1 : Rewirable and non-rewirable 13 A fused plugs SS 145-2:2010 Specification for 13 A plugs and socket-outlets - Part 2 : 13 A switched and unswitched socket-outlets International usage of Type G The IEC World Plugs lists Type G as being used in the following locations: Bahrain, Bangladesh, Belize, Bhutan, Botswana, Brunei Darussalam, Cambodia, Cyprus, Dominica, Falkland Islands, Gambia, Ghana, Gibraltar, Grenada, Guyana, Hong Kong, India, Iraq, Ireland, Isle of Man, Jordan, Kenya, Kuwait, Lebanon, Macau, Malawi, Malaysia, Maldives, Malta, Mauritius, Myanmar, Nigeria, Oman, Pakistan, Qatar, Saint Kitts and Nevis, Saint Lucia, Saint Vincent and the Grenadines, Saudi Arabia, Seychelles, Sierra Leone, Singapore, Solomon Islands, Sri Lanka, Tanzania, Uganda, United Arab Emirates, United Kingdom, Vanuatu, Vietnam, Yemen, Zambia, Zimbabwe.
References ^ BS 546: "Specification. Two-pole and earthing-pin plugs, socket-outlets and socket-outlet adaptors" (1950) ^ , Assembly Automation and Product Design, Second Edition, Geoffrey Boothroyd, CRC Press, 2005, p.315 (retrieved 20 December 2013 from Google Books) ^ , Physics for AQA, Patrick Fullick, Heinemann, 2001, p.16 (retrieved 1 March 2013 from Google Books) ^ , Trevor Linsley, Routledge, 2008, p.
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^ "Guidelines on the application of Directive 2006/95/EC". p. 7. Retrieved 24 February 2015. ^ "Fraudulant use of CE Marking". Retrieved 24 February 2015. ^ "The History of Electric Wiring" (1957), London: Macdonald. ^ , Second Chance: Two Centuries of German-speaking Jews in the United Kingdom, edited by Werner Eugen Mosse, Julius Carlebach, Mohr Siebeck, 1991, p.362 (retrieved 20 December 2013 from Google Books) ^ , A Company of Many Parts, A.
Heerding and Derek. S Jordan, Cambridge University Press, 1989, p.51 (retrieved 20 December 2013 from Google Books) ^ a b "SMALL SWITCHES, etc., and their CIRCUITS" (1911), MAYCOCK, W. Perren, London: S. Rentall & Co. ^ , Electric cooking, heating, cleaning, etc: being a manual of electricity in the service of the home, Maud Lucas Lancaster, Constable & Company, Ltd., 1914, p.312 (retrieved 13 March 2013 from Google Books) ^ a b c d e f "The History of Electric Wiring" John Mellanby, Ch 10, (1957), London: Macdonald.
^ a b c "History of the 13 amp plug and the ring circuit" DWM Latimer FIEE, (2007), London: IET. http://www.theiet.org/resources/wiring-regulations/ringcir.cfm?type=zip ^ BS 4573 (1970), British Standard Specification for two-pin reversible plugs and shaver socket-outlets, British Standards Institution. ^ IEC/TR 60083, Plugs and socket-outlets for domestic and similar general use standardized in member countries of IEC – Sheet GB6, CH: International Electrotechnical Commission, 2009 ^ BS EN 61558-2-5 includes the following definitions: (3.
1.101) Shaver transformer: isolating transformer for fixed installation and with a limited output, designed to supply electric shavers, toothbrushes, and similar appliances rated 50 VA or less used in a bathroom. It supplies only one shaver, or the like, at a time and (3.1.102) Shaver supply unit: accessory embodying a shaver transformer or a power supply unit incorporating a shaver transformer, and one or more socket outlets allowing the use of only one plug at a time.
^ "World Plugs, Plug Type D". CH: IEC. ^ a b "World Plugs, Plug Type M". CH: IEC. ^ "Blue Room - 15A Connector". Retrieved 2012-07-04. ^ Robert S. Simpson Lighting control-technology and applications, Focal Press, 2003 ISBN 0-240-51566-8, page 512 ^ a b "World Plugs, Plug Type G". CH: IEC. ^ Messenger, Rosalind (1967), The Doors of Opportunity, A Biography of Dame Caroline Haslett DBE Companion IEE, London: Femina Books, pp.
76–77 ^ "Post-War Building Studies No. 11 Electrical Installations", HMSO, London 1944 ^ Post War Building Studies No. 11, Electrical Installations, Paragraph 84 ^ Post War Building Studies No. 11, Electrical Installations, Appendix ^ Mullins, Malcolm (Spring 2006). "The Origin of the BS 1363 Plug and Socket-Outlet System". IEE Wiring Matters. Institute of Electrical Engineers. Retrieved 2009-06-20.
^ , Guide to the Wiring Regulations: 17th Edition IEE Wiring Regulations (BS 7671:2008), Darrell Locke, John Wiley & Sons, 2008, pp.86-88 (retrieved 18 January 2015 from Google Books) ^ BS 1363-1:1995+A4:2012, cl. 7.4 ^ BS 1363-1:1995+A4:2012, fig. 4a ^ British Patent GB1067870 (Spring loaded pin sleeves) ^ British Patent GB1292991 (Fixed pin sleeves) ^ "Safety in the home", Southern Electricity & RoSPA | 00-980-05 |, October 1978 ^ , A Practical Guide to the Wiring Regulations, Geoffrey Stokes, John Wiley & Sons, 2008, p.
65 (retrieved 24 February 2014 from Google Books) ^  Cl 6.8, Cook, Paul "Commentary on IEE Wiring Regulations 16th Edition (BS 7671:2001)" IET 2002 ISBN 0852962371 ^ Mullins, Malcolm (Spring 2006). "The Origin of the BS 1363 Plug and Socket-Outlet System". IEE Wiring Matters. Institute of Electrical Engineers. Retrieved 2009-06-20. ^ "Post-War Building Studies No. 11 Electrical Installations", Appendix "Supplementary report on a recommended new standard socket-outlet and plug", page 88, para x.
, HMSO, London 1944 ^ "Journal of the Institution of Electrical Engineers, Volume: 94, Issue: 81, page 390, September, 1947 ^ BS 1363-1:1995+A4:2012, cl. 12.13 ^ BS 1363-1:1995+A4:2012, cl. 12.4 ^ BS 1363-1:1995+A4:2012, cl. 19.1 ^ BS 1363-1:1995+A4:2012, cl. 11.8 ^ BS 1363-1:1995+A4:2012, cl. 7.1 f) ^ , Volex company website, (retrieved 7 March 2013) ^ Wiring Accessories & Counterfeiting ^ PlugSafe website ^  ^ "Buyer Beware, Many plugs and chargers – often obtained online – pose a serious risk to users", Wiring Matters, Summer 2013, p14 ".
.. the main problem is with online stores such as eBay and amazon marketplace" ^ BS 1363-2:1995+A4:2012, figs. 11 to 16 ^ Peacock, David (Winter 2013). "The Remarkable Evolution of BS 1363". IET Wiring Matters. Institution of Engineering and Technology. Retrieved 2013-11-07. ^ BS 1363-2:1995+A4:2012, cl. 13.3 ^ BS 1363-2:1995+A4:2012, cl. 13.10 ^ BS 1363-2:1995+A4:2012, cl. 13.9 ^ a b BS 1363-2:1995+A4:2012, cl.
13.7 ^ GB Patent 294,689: "Improvements in or in connection with Plug and Socket Connectors for Electric Circuits." (MK Electric Ltd.) ^  ^  "Conversion Plugs for Foreign Appliances", Switched On, Issue 9, Summer 2008, p17 ^ UK Government safety advice ^ Coles, Mark (Autumn 2012). "Socket Protectors". IET Wiring Matters. Institution of Engineering and Technology. Retrieved 2012-09-28. ^ FatallyFlawed website ^ "Estates and Facilities Alert - Ref: EFA/2016/002 - 13A electrical socket inserts (socket covers or protectors)".
Department of Health (United Kingdom). 2016-06-30. Retrieved 2016-07-16. ^ "Schools: Electrical Safety:Written question - 49797". UK Parliament. 2016-10-31. Retrieved 2017-05-30. ^ "BEAMA Position Paper on Socket Outlet Covers". BEAMA. 2017-06-05. Retrieved 2017-09-05. ^ BS 1363-3:1989, cl. 12.5 ^ Electrical Safety First: Overloading sockets ^ BS 1363-3:1989, cl. 7.1 ^ BS 1363-3:1989, cl. 18 ^ BS 1363-5:2008 ^  ^ a b ThinPlug ^ Alan Winstanley.
"Slimplug Compact UK Power Lead". EPEmag.net. Retrieved 2014-07-23. ^  ^ Walsall Gauge in use at London Underground ^ "BS 8546:2016 Travel adaptors compatible with UK plug and socket system – Specification". BSI. April 2016. Retrieved 2017-09-05. ^ "Clock Connectors". Retrieved 2013-02-18. ^ Installation instructions for the Italian made Inda (stage arch model) illuminated mirror: States that a low profile plug and socket are required (It has to fit in a space of just 15 mm).
In the UK, this clock connector seems to be the only option but only if the socket is sunk into the wall. ^ Oud, Oof. "Wylex plugs and sockets". Digital Museum of Plugs and Sockets. NL. Retrieved 17 December 2011. ^ a b "History of the 13 amp plug and the ring circuit" DWM Latimer FIEE, (2007), London: IET. http://www.theiet.org/resources/wiring-regulations/ringcir.cfm?type=zip ^ "Museum of Plugs and Sockets: Dorman & Smith plugs and sockets".
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SANS 164 (1 ed.). Standards South Africa. p. 5. ISBN 0-626-17847-9. Retrieved 2012-07-29. ^ Brian Bilton. "Earth leakage protection unravelled". Retrieved 2012-07-29. ^ "World Plugs, Plug Type D". CH: IEC. ^ I.S. 401, "Safety requirements for rewirable and non-rewirable 13A fused plugs for normal and rough use having insulating sleeves on live and neutral pins", NSAI (National Standards Authority of Ireland), (1997), Dublin ^ "S.
I. No. 526/1997 — National Standards Authority Of Ireland (Section 28) (Electrical Plugs, Plug Similar Devices and Sockets For Domestic Use) Regulations, 1997". irishstatutebook.ie. Retrieved 2011-05-28. Retrieved from "https://en.wikipedia.org/w/index.php?title=AC_power_plugs_and_sockets:_British_and_related_types&oldid=811731158#BS_1363_three-pin_(rectangular)_plugs_and_sockets"