WO2009145665A1 - Multipurpose electric distribution system - Google Patents

Abstract

The inventive multipurpose electric distribution system is in the form of a body of an arbitrary geometrical shape, which body comprises at least one groove or a cavity in which at least one conductor, substantially a current-conducting bus, is arranged on an insulating substrate, and a current collector which is directly connected to the bus. In one of the variants, the bus, irrespective where it is open, is covered with at least one protective element. In the other variant, the body comprises at least one sealing element. In one more variant of the invention, at least one of the elements of a contact pair, which consists of at least one contact stem of the current collector and at least one conductor, is provided with an elbow made thereon, a projection being made on the other element of the contact pair. Furthermore, at least one of the elements is insulated from the current-carrying parts in such a way that a gap for preventing from an electric arc striking by a load connection, is formed between the elements of the contact pair by the insertion of the current collector. The invention makes it possible to extend the flexibility of the system (the possibility of using it as a skirting board, a border, a duct and incorporated into a wall) and to increase the safety thereof.

Description

 ELECTRIC DISTRIBUTION SYSTEM

MULTIFUNCTIONAL

FIELD OF TECHNOLOGY

The invention relates to electrical engineering, namely, to electrical distribution systems.

BACKGROUND OF THE INVENTION

Everywhere, especially recently, the number of electrical appliances, as well as their total power is constantly growing. Existing networks can not withstand increasing loads, and their reconstruction requires large investments. The equipment constantly “moves” from place to place, and almost any major overhaul or design project begins with determining the location of the access points to the power grid, which must be taken into account when designing, and also, due to the different power of electrical appliances, often use wires of different sections. There is a shortage of access points to power grids, which, within the framework of existing networks, is mainly solved by installing additional electrical outlets, using extension cords and tees. When laying internal wiring, as well as for installing various wiring products gating of walls and other building structures is required, which is extremely undesirable, especially after finishing work. As a result, there are large economic costs, energy and human resources are spent, time, the environment is suffering, and the user characteristics of such systems are limited. In addition, different standards for plug connections are used in different countries, which is why there is a compatibility problem. The existing solutions today are not able to solve such problems comprehensively, as well as, in most cases, in particular. The solution proposed by the authors is able to positively affect the existing situation and in most cases solve the problems considered.

Known electrical conduit (1), in which the wires forming the power lines are embedded in two grooves in a rubber casing. As a result of this, the contact area between the teeth of the power take-off device and the conductors is very small, practically it is a point contact, as a result of which the connection opens. In addition, the housing configuration does not allow lateral bending of the conduit relative to the grooves. For this, one or more recesses are needed to allow the conduit to be bent. Similar systems in which the indicated conduits are used do not provide reliable connection with the conductors in the conduit, but are based on the direct insertion of the teeth of the power take-off device into the grooves in which the contacts are located, i.e. generally based on the elasticity of the body material and its ability to hold contact.

Known electrical distribution bus (2), including an extended flexible conductor and an extended flexible knife contact, in electrical contact with the specified conductor. Moreover, the specified long knife contact is essentially U-shaped in cross section and is equipped with a pair of opposite inwardly curved substantially arcuate strips, and the closed part of the specified knife element encloses the specified conductor. The described flexible tire enclosed in a housing can be used on the floor and on the ceiling, and also in skirting boards, in lighting wiring for lighting systems or for transmitting audio signals in sound systems. The ability of the flexible housing claimed in the proposed invention to bend at an angle, usually right or at other angles, up to 180 °, when used, avoids the use of transitional devices in the corners of rooms. However, the number of power-consuming devices connected to such a bus is limited by the number of access points to the conductor.

Known low-voltage electrical distribution circuit (3), providing a disconnectable and non-disconnectable power supply, which contains a molded case containing a cavity, three conductors connected to a disconnectable, non-disconnectable and a neutral power source, while these conductors are equipped with receiving means into which insert the pins of the plug connected to the load, the plug socket, which has a mechanical detachable connection to the housing, while the socket has sockets, Call several holes extending through the socket and aligned with corresponding receiving means of conductors. Thus, the circuit is, in fact, a long multi-socket outlet, designed to connect plugs of a certain type, while the electric device or the load is constantly connected or connected to the disconnected power supply. In this scheme, as well as in the aforementioned electric distribution bus (2), the number of connected power-consuming devices is limited by the number of access points to the conductor. In addition, the receiving means indicated in this diagram do not allow the simultaneous use of various types of current collectors, and also, for example, if the current collector (plug) is unintentionally “broken out”, such receiving means can cause mechanical damage to circuit elements. The lack of a sufficient uniform contact pressure adversely affects the contact density, which is especially important for prolonged use, because after some time, the receiving means may deform and, therefore, will not be able to provide the necessary contact density. In addition, all the analogues and prototypes presented, as well as other similar solutions, including the currently most common standard power supply system, to one degree or another, have basically the following disadvantages: - lack of freedom to connect current collectors and limiting their number

- Inadequate safety of the use of systems and load connections

- the presence of open current collector contacts (plug)

- insufficient protection against water, dust, as well as against unauthorized access

- a small contact spot, as a result of which the contacts burn out, as well as the inability to provide the necessary contact surface area depending on the load, which is especially important when connecting large power appliances - the inability to simultaneously use various types of current collectors.

SUMMARY OF THE INVENTION

The objective of the invention is a comprehensive solution to the identified problems, shortcomings and limitations within one system, including providing the ability to connect the load to the electric bus in any place without physically limiting the number of access points along the entire length and with complete connection security, as well as simplicity and ease of use , during installation and design. Organization of a simple modular design, taking into account the expected increase in consumer capacity. Ensuring, in the majority, continuity of the conductor, incl. with its bends. A reliable electrical connection that reduces the likelihood of an electric arc when connecting a load with additional fixation of the current collector, as well as the possibility of changing the contact surface area. In addition, the tasks solved by the proposed system include protection against the ingress of water, dust and other foreign objects, unauthorized access (including from children), as well as combining various electrical communications, including low-current noise-resistant signal lines, such as, for example, analog (telephone, antenna, audio / video), digital (computer) and other similar lines that have all the main advantages of this system. Adaptation of the system for the simultaneous use of plugs of various types.

The problem is solved by a multifunctional electric distribution system (EDSM) designed for distribution and delivery of electric energy and other signals to consumers and is a combination of various engineering networks and other components that ensure reliability, safety and protection of the system, up to complete sealing, which in some incarnations allows you to use it also in the aquatic environment. The system involves a modular configuration and is predominantly the end device, preferably in residential networks.

EDSM, made in the form of a housing of arbitrary geometric shape, containing at least one groove or cavity, in which at least one conductor is installed, preferably a conductive busbar, on an insulating substrate, while the current collector (plug) is connected directly to the bus and is simultaneously an adapter for being connected devices, the height of the current collector surface in contact with the tire is equal to the height of the tire, and the insulating substrate has compensation holes along its entire length that facilitate its bending, etc. This tire has a trapezoidal cross-sectional shape and is installed in a groove, of similar shape, arranged in the insulating substrate, and comprising sealing elements, mainly flows, energizing bus that shifts the tires along the slot when bending the busbar and seals the contact. In addition, the walls of the housing, mainly made of elastic material, are tightly adjacent to the current-carrying conductors and / or to the insulating substrate, with the possibility of spontaneous expansion when the current collector is inserted, or are carried out at a certain distance, and one of the conductors performs the function of a grounding conductor.

In this case, at least one of the elements of the contact pair, consisting of at least one contact leg of the current collector (plug) and at least one conductor installed on the insulating substrate, at least one step is made, and on the other element at least at least one protrusion, while at least one of them is isolated from current-carrying parts, which forms a gap between the elements of the contact pair when the current collector is inserted, preventing the occurrence of an electric arc when the load is connected.

In another embodiment, the housing is shielded and has cuts in the transverse direction, forming “ribbons”, with the ability to spontaneously slide apart when the plug is connected and form a shielded connection.

In another embodiment, the current collector (plug) is made rotatable with at least one L-shaped or T-shaped contact, the working surface of which is facing the bus, while at least one groove is made in the housing, made in cross section in the form of the letter “G” ”Or“ T ”, with at least one transverse slot in which at least one tire is located.

In another embodiment, at least one cavity is made in the longitudinal housing, in which at least one bus is installed, and the load, supply voltage and contactors are connected from the ends of the conductor using connectors mainly with knife contacts, while the conductor is a socket or plug, and connector, respectively, with a plug or socket.

In addition, with a certain configuration of the system, as well as subject to compliance with the dimensions established by the international standards for plug connections (4), the EDSM is adapted for the simultaneous use of plugs, mainly in household electrical networks, of virtually any existing type. At the same time, the tire opened somewhere is blocked by at least one protective element, for example, a static or movable plug, in addition, the groove is blocked on both sides by two tapes of flexible insulating material, fastened with its one side to the tops of the groove throughout the length or one tape on one side of the groove with the possibility of spontaneous extension when connecting the current collector.

Also, in an additional niche arranged in the housing, at least one curtain is installed, mainly reinforced and / or magnetized, with a chamfer made on it, which ensures smooth insertion of the current collector and is movably fixed in the niche, which allows the curtain to be displaced when the current collector is inserted, which, in at rest, it tightly overlaps the groove along its entire length, while in the system mainly metal stoppers are installed, which are, in fact, “locked”, preventing the curtain from moving in when there is an attempt to insert an object into the system, except for a current collector specially designed for such a configuration, equipped with a protective mainly corrugated cap and a protective mainly movable and / or magnetized visor that tightly closes the place where the current collector is turned on and acts on the stoppers that release the shutter, insertion of the current collector, which is, in fact, the "key".

In addition, the housing contains at least one sealing element, for example, when the housing is made with ebbs sealing the contact, in addition, preferably opposite the conductive bus, at least one spring tab plate is installed, also sealing the contact and electrically connected to the conductive bus.

The possible development of the EDSM, based on the materials presented in this application, is obvious to a specialist of average skill in this field and, therefore, the description and drawings should not be construed as the only implementation and are indicative. BRIEF DESCRIPTION OF THE DRAWINGS

A specific implementation of the system is presented in figures 1-4, where:

FIG. 1 - general view of the base system in axonometric projection

FIG. 2 is a perspective view of a variant of a system with protection, a busbar device and an electrical connection of a current collector with a conductor (bus), as well as one of the options for using additional electrical communications.

FIG. 3 is a section A-A, showing in more detail the system shown in figure 2

FIG. 4 - an embodiment of the invention, preferably designed for lighting networks

List of positions with the names of the designated elements:

1-insulating substrate, 2-copyc, 3-current collector (for Fig. 1), 4-flexible tape-insulators, 5-groove, 6-conductor, 7-compartment holes, 8-bus, 9-way foot, 10- coefficient block, 11-groove in the insulating substrate, 12-seam elements (ebbs), 13-pin, 14-pin, 15-pin current collector leg, 16-pin drive, 17-screen housing, 18-pin, 19-pin, 20-niche, 21-shutter, 22-visor, 23-corrugated cap, 24-current collector (for Figs. 2 and 3), 25-pin current collector ground contact, 26-way visor, 27-stop, 28-29 seat fittings (tides), 30-inlet holes, 31-G unit main contact, 32-current lock (for Fig. 4), 33-slot

MODES FOR CARRYING OUT THE INVENTION

The main element of the EDSM is the busbar shown in FIG. 1, 2 and 3 (section AA), consisting of an insulating substrate 1, and buses 8 installed on it and a conductor 6, which in this embodiment performs the function of grounding. In FIG. 3 (section AA) in detail shows one of the options for installing tires on an insulating substrate, where the tire 8, having a trapezoidal cross section the form is installed in a groove 11 of a similar shape arranged in the insulating substrate 1 and containing sealing elements (ebbs) 12, spring-loaded on the busbar, which compensates for possible angular deviations of the positions of the contact legs of the current collector, ensuring almost always tight contact over the entire connection area, as well as promotes the displacement of the tire along the insulating substrate during bending of the busbar, because the tire has some freedom relative to the insulating substrate. In addition, in FIG. 1 shows through compensation holes 7 arranged in the insulating substrate 1, allowing it to be easily deformed during bending, which contributes to the bending of the entire busbar trunking and allows its use practically over the entire perimeter of the room without breaks, and also saves the substrate material. Conductors can be installed in other known ways, for example, by gluing, fusing.

In FIG. 1 shows a general view of the basic version of the system. The busbar is installed in the base of the groove 5 of the housing 2 by means of the landing leg 9. The current collector 3 is connected directly to the tires 8 and the conductor 6 by inserting it into the groove 5, covering the busbar on both sides. At the same time, the current collector 3 is supplied with a spring-loaded ground contact (not shown) located, like other contacts of the current collector, between its legs, which provides the connection of the grounding contact of the current collector 3 and conductor 6, primarily, in the direction of travel, before connecting the other contacts. The busbar can be single, made of flexible material or divided into segments. When using a busbar system consisting of segments, the latter are connected, for example, by connecting blocks 10 made in the form of a U-shaped profile of insulating material or by other known methods, for example, by soldering. Protective flexible tape insulators 4 (which are one of the embodiments of the security elements described in more detail below) are fixed with their one side on the tops of the groove 5, overlapping it along the entire length, with the possibility of spontaneous extension when connecting the current collector at the point of inclusion. In FIG. 3 (section AA), a reliable electrical connection device is shown that reduces the likelihood of an electric arc being formed when the load is connected, with an additional fixation of the current collector, as follows. A step 13 is made on the busbar, and on the contact leg 15 of the current collector 24, a protrusion 14 of insulating material. When inserting the current collector, the contact legs slightly extend, as the distance between the protrusions is less than the width of the busbar, forming a gap between the contact of the current collector and the tire, and when the current collector is inserted in the lowest position (to the stop), the protrusion 14 falls into the ledge 13 of the busbar, as a result of which the contact legs 15 return to their base position, due to of which almost instantaneous contact occurs, which prevents the occurrence of an electric arc when the load is connected, and the current collector is fixed.

For the device of noise-protected signal lines with the possibility of free connection of plugs (not shown) along the entire length, the busbar 16, similar to the above, is installed in a shielded closed housing 17, which protects the conductors from extraneous interference, preferably made of a metal spring strip, where at the point of contact Faya stripes are bent in opposite directions, forming a wedge-shaped entrance. In this case, the housing is partially cut in the transverse direction, thus forming the petals 18, as a result of which, when the plug is inserted into the housing, the petals 18 are unbent at this point, letting the plug into the internal cavity, thus forming a shielded connection.

In FIG. 4 shows an embodiment of the invention, preferably for lighting networks. The current collector 32 is rotary with at least one L-shaped or T-shaped contact 31, the working surface of which is facing the bus 8, while in the case 2, which is also an insulating substrate, at least one groove 5 is made, made in cross section in the form the letters "G" or "T", with at least one transverse slot 33, in which at least one bus is located 8. When connected, the current collector 32 is inserted into the groove 5 and rotates around its axis, as a result of which the contact 31 is mechanically fixed in the slot 33 and electrically connected to the bus 8. The advantages of this option are, firstly, that with sufficient simplicity of design, unauthorized access to current-carrying tires is difficult by itself, which virtually eliminates the need in additional protection, secondly, the rotary current collector performs the functions of mechanical holding (fastening) of consumers, so that such a system can be used, for example, as a lighting system we have a free position in space and, thirdly, in providing fixed positions it is possible to turn the current collector device "vyklyuchatelya". T. e., When turning at X-degrees, the current collector is mechanically fixed in the housing, in the next position, when turning in the same direction, for example, 2X-gradients, the current collector contacts are connected to at least one bus, then when turning, for example, at 3X-degrees, the current collector contacts are connected to the next bus, etc. In addition, it is possible to install through-circuit breakers in such a system with the possibility of easy reinstallation in any convenient place. The current collector contacts can be movable.

To supply voltage to other branches of the system, without using internal wiring, a conductor is used, which is one of the components of the EDSM (can also be used separately) and arranged as follows. In a predominantly closed longitudinal housing, preferably of rectangular cross-section (similar to that shown in Fig. 4), at least one longitudinal cavity is made into which at least one bus bar is embedded, while in the cavity there is some free space for connecting the load, supply voltage and contactors from the ends of the conductor with the help of connectors of various configurations, mainly with knife contacts, while the conductor is a socket or plug, and the connector, respectively, is a plug or socket. The housing is made with fasteners that allow you to mechanically fasten these housing together, which allows you to dial the required number of conductors. Also, from the ends or in the gap between two segments of the conductor, it is possible to install various devices for this branch, such as, for example, timers, circuit breakers, RCDs, circuit breakers, which (as for other system components) can be installed directly on the branch or in the electrical panel, which makes the EDSM more flexible in installation and maintenance. In general, the advantages of using the described conductor are the possibility of toolless assembly of the system, the ability to integrate it into various products, for example, door trim, sills, and it is also possible to install an electrically balanced system consisting of many branches.

The current collector is at the same time an adapter for an energy-consuming device, and the height of the current collector surface contacting the bus is equal to the height of the bus, while the contact legs of the current collector can be standard or non-standard, for example, when the area of their contact surface with the bus is significantly increased for connecting high-power equipment. In addition, a certain system configuration, provided that the dimensions comply with the established standards (4), are applicable for the simultaneous use of plugs, practically of any existing types, in networks with a voltage of 100 - 277 v and a frequency of 50/60 Hz, provided that voltage and frequency converters or other similar known devices.

Similar to that described above and shown in FIG. 1, 2 and 3 of the system, two busbars are installed in the base of the groove of the housing, parallel to each other and to the walls of the groove, each of which contains two busbars mounted on opposite sides of the insulating substrate. In this case, busbars are installed at a distance from each other, corresponding to the largest diameter (or size, provided that the cross section is different from the circle) of the ground contact from a number of existing types of plugs and at an equal distance from the side walls of the groove, also corresponding to the largest size of other contacts from same row. On the side walls of the groove, longitudinally connected spring-loaded spring plates are installed, made similar to those described above shielding housing 17 (Fig. 3, section AA), each of which is electrically connected to one conductive bus, and having petals, pressing contact pins of the current collector (plug) at the point of inclusion, which also increase the area of the connection. At the same time, the two buses closest to the center of the groove, between which the flap spring plate described above are also installed, are the grounding conductor, one of the external buses is connected to the phase, and the other to zero, while the groove is covered by protective elements.

Protection elements designed to ensure the necessary safety of the use of EDSM, as well as protection against penetration of water, dust and other foreign objects into the system, can have many implementations used together or separately. The most preferred of them, according to the authors, are described below.

An open tire somewhere is blocked by a static or movable plug, for example, when the latter is made longitudinal and divided into separate parts (sections) that perform the function of doors.

In FIG. 2 and 3 (section AA) another option is shown where the protection is organized as follows (optional). The shutter 21, made of an elastic material, mainly rubber, is movably fixed in an additional niche 20 located in the housing 2 and, in the absence of a current collector 24 (this state is not shown), is pressed by the shank 19 of the shutter 20 to the stop, which is mainly used as an insulating substrate 1 busbar trunking. In this case, the shutter 21 and part of the insulating substrate, which serves as a stop, are reinforced and / or metallized and magnetized, for example, by installing a metal magnetized conductor 6, which provides a more close contact between them, hermetically overlapping the internal space of the groove 5 of the housing 2 In addition, reinforcing strengthens the shutter 21 and contributes to the fulfillment of the design strain conditions, also increasing the durability of the shutter, on which a chamfer is performed, which contributes to the shift of the shutter the current collector 24, on the tops of the contact legs 15 of which a chamfer (bevel) is performed, as can be seen in FIG. 2 and 3, which allows, in combination with the chamfer of the shutter 21, to insert the current collector almost unhindered. A movable visor 22 is mounted on the current collector 24, the lower surface of which faces the shutters 21 and is provided with a sealant (not shown). The peak 22 is held at the tops of the contact legs 15 of the current collector 24, which is outside the system, with a corrugated cap 23, as a result of which, when the current collector 24 is inserted, its entry point is always hermetically closed. The corrugated cap 23 seals the gap between the movable visor 22 and the collector body 24, on which it is firmly fixed, which prevents water, dust and other foreign objects from entering the interior of the collector 24, the system itself when the collector is inserted, as well as during insertion him. In addition, the visor 22 or the seal installed on it is magnetized, which contributes to a closer connection of the visor 22 to the shutters 21. When assembling the system or, at least the case, from separate segments, the joint is sealed, and the extreme segments are closed by end caps, also equipped with a sealant. Thus, the entire system is sealed in a static state, with the current collector inserted, as well as during the insertion of the current collector.

To ensure protection against unauthorized access, a lock is arranged, organized as follows (optional). In the cover 28, a plurality of stoppers 27 are installed along its entire length, the width and quantity of which is determined mainly by the size of the current collector. The stoppers 27, at rest (with no current collector), sag under their own weight, when they are placed in space above the shutters 21 or spring by any known method, for example, using ebbs made in the cover 28 and abut against the shutter 21, overlapping the groove, blocking the possibility of its displacement, and, accordingly, access to current-carrying tires. The decorative cover 28 mounted on the housing 2 has inlet openings 30 for inserting the current collector 24 and performs the function of stabilizing the groove width, which is desirable to ensure a constant gap between the stoppers 27 and the shutter 21, which prevents jamming of the stoppers. When the current collector 24 is inserted, the visor 22 is applied to the open surface of the shutters 21 at the intended switching point, as a result of which the stoppers 27 located directly under the magnetized visor 22 are lifted by the magnet, releasing the shutter 21, which shifts when pressed against the current collector 24 and is recessed into a niche 20, passing the current collector 24 into the internal space of the groove 5. In this case, the stoppers 27 located outside the overall dimensions of the visor 22 remain in place, continuing to block the rest of the w torques 21, and the visor 22, held by the cover 28, moves along the guides 26 made on the contact legs 15 of the current collector 24 to their base, as the current collector is inserted, the corrugated cap 23 is compressed, and the contacts of the current collector 24 are adjacent to the current-carrying tires 8, forming an electrical connection. When pulling the current collector 24, the above steps occur in the reverse order.

The housing 2 is made with sealing elements (ebbs) 29 located in the internal cavity of the groove 5, providing a variable width of the groove, as well as the necessary clamping of the contacts of the current collectors of various standards to the current-carrying tires due to the deformation of the ebbs 29. The current collector 24 is provided with an earth contact 25.

There are many configuration options for the described protection system, for example, when the peak 22 is part of the current collector body 24, which eliminates the specified gap between the current collector body 24 and the visor 22, and accordingly there is no need to use a corrugated cap 23. In this embodiment, the system is protected from water, dust, except when the current collector 24 is turned on, but is not protected from unauthorized access.

The supply voltage to the system is provided, for example, by means of connecting blocks 10, which are closed externally as shown in FIG. 1, or modules similar in principle to the current collector 3 or current collector 24 (Fig. 2 and 3), as well as in any other known manner. The connection modules are predominantly fixed.

The system can be made in the form of a plinth, curb, duct, and can also be installed in the thickness of the wall. In addition, the system is performed by the national team, for example, by replacing the covers 28 (shown in Figs. 2 and 3), which have a different configuration, or by any other known method, as a result of which universality is achieved, which ultimately allows the use of certain components in the system , lines, depending on candy tasks.

INDUSTRIAL APPLICABILITY The use of the described EDSM, while retaining all the advantages of analogs and without compromising the quality of existing networks with which it can be used, allows you to combine most of the various electrical communications and other construction products within a single system, which, in essence, completely changes the approach to installation work , simplifies and cheapens them, and also significantly saves time, labor and energy costs, without requiring the work associated with violations of the integrity of buildings and structures Eden. In addition, the user is given the opportunity to choose a connection location, with virtually no limit to the number of connection points.

The security systems and the versatility of the EDSM, as well as its execution as a decoration element, allow expanding the scope of application, in particular, such a system can be used in conditions of high humidity, in child care facilities, in industry and in many other areas.

References:

1. US patent Ne2062752, 1936

2. RF patent N ^Q 2107372, 1998

3. RF patent Ns 2316090, 2008

4. GOST 7396.1-89 (IEC 83-75), dated 1992, 2003 edition

Claims

FORMULA

1. Multifunctional Electric Distribution System (EDSM), made in the form of an arbitrary geometric shape housing containing at least one conductor, characterized in that said conductor, preferably a conductive busbar, is installed on an insulating substrate, while the current collector (plug) is connected directly to the bus .

2. Multifunctional Electric Distribution System (EDSM), made in the form of an arbitrary geometric shape housing containing at least one conductor, characterized in that said conductor, preferably a conductive busbar, is installed on an insulating substrate, while the current collector (plug) is connected directly to the bus and an open tire somewhere is blocked by at least one protective element.

3. Multifunctional Electric Distribution System (EDSM), made in the form of an arbitrary geometric shape housing containing at least one conductor, characterized in that said conductor, preferably a conductive busbar, is mounted on an insulating substrate, while the current collector (plug) is connected directly to the bus and the housing contains at least one sealing element.

4. The Multi-Functional Electric Distribution System (EPCM), made in the form of an arbitrary geometric shape housing containing at least one conductor, characterized in that at least one of the elements of the contact pair, consisting of at least one contact leg of the current collector (plug) and at least one conductor, at least one ledge is made, and at least one protrusion on the other element, at least one of them is isolated from current-carrying parts, which forms a gap between the element tami contact pair when inserting a current collector (plug), which prevents the occurrence of an electric arc when connecting a load.

5. EDSM, according to any one of claims 1 to 4, characterized in that the housing contains at least one groove or cavity and / or is an insulating substrate on which at least one conductor is installed, preferably a conductive busbar.

6. EDSM, according to any one of claims 1 to 5, characterized in that the current collector is at the same time an adapter for the connected device, and the height of the current collector contacting the bus is equal to the height of the bus.

7. EDSM according to any one of claims 1 to 5, characterized in that the insulating substrate has compensation holes along its entire length.

8. EDSM according to any one of claims 1 to 5, characterized in that one of the conductors performs the function of a grounding conductor.

9. EDSM according to any one of claims 1 to 5, characterized in that the walls of the housing, mainly made of elastic material, are tightly adjacent to current-carrying conductors and / or to an insulating substrate, with the possibility of spontaneous extension when a current collector is inserted, or are performed at a certain distance .

10. EDSM according to any one of claims 1 to 5, characterized in that the conductive busbar has a trapezoidal cross section and is installed in a groove of a similar shape arranged in the insulating substrate and containing sealing elements, mainly castings, spring-loaded the busbar.

11. EDSM according to any one of claims 1 to 5, characterized in that the housing is shielded and has cuts in the transverse direction, forming “ribbons”, with the possibility of spontaneous extension when the plug is connected.

12. EDSM according to any one of claims 1 to 5, characterized in that the current collector (plug) is made rotatable with at least one L-shaped or T-shaped contact, the working surface of which is facing the tire, at the same time, at least one groove is made in the casing, made in cross section in the form of the letter “G” or “T”, with at least one transverse slot in which at least one tire is located.

13. EDSM, according to any one of claims 1 to 5, characterized in that the housing has at least one cavity in which at least one bus is installed, and the load, supply voltage and contactors are connected from the ends of the conductor, while the conductor is a socket or a plug, and the connector, respectively, with a plug or socket.

14. EDSM, according to any one of claims 1 to 5, characterized in that, with a certain configuration of the system, as well as subject to compliance with the dimensions established by the standards for plug connections, the EDSM is adapted for the simultaneous use of plugs, mainly in household electrical networks, practically any existing types.

15. The EDSM according to claim 2, characterized in that the tire open somewhere is blocked by a plug.

16. ERSM according to claim 2, characterized in that the housing contains at least one groove overlapping on both sides with two tapes of flexible insulating material, attached to the tops of the groove along its entire length or with one tape on one side of the groove with the possibility of spontaneous extension when connecting the current collector.

17. EDSM according to claims 2 and 3, characterized in that in the additional niche arranged in the housing, at least one curtain is predominantly reinforced and / or magnetized, with a chamfer made on it, which ensures smooth insertion of the current collector, which is movably fixed in the niche, providing the possibility of shifting the curtain when inserting the current collector, which, at rest, tightly overlaps the groove along its entire length.

18. EDSM according to claim 17, characterized in that stoppers are installed in the system, which are, in fact, “locked”, preventing shutter displacement, at rest, when trying to insert any object other than that specifically designed for such a configuration current collector, which is, in fact, the "key".

19. EDSM according to claim 18, characterized in that the current collector is equipped with a protective visor that tightly closes the place where the current collector is turned on and acts on the stoppers that release the shutter when the current collector is inserted.

20. EDSM according to claims 2 and 19, characterized in that the current collector is equipped with a protective cap.

21. EDSM according to claim 3, characterized in that the housing is made with ebbs that seal the contact.

22. The EDSM according to claim 3, characterized in that at least one spring leaf plate is installed in the housing, sealing the contact, electrically connected to the conductive bus.