EA021379B1 - Device of electrical connection (variants) - Google Patents

Abstract

The claimed invention relates to electrical engineering, in particular, to devices of electrical connection and can be used as a socket with an adaptor/plug for connecting, i.a. simultaneous, different electrical appliances/instruments to general electrical network. Proposed is an electrical connection device, comprising a socket, the body of which has a rectangular base and Llength wherein a contact group is arranged, phase, neutral and earth contacts of which isolated from each other are electrically connected to the corresponding network conductors, and a plug-type adaptor (a plug in the second variant) comprising contact pins. Each socket contact is made in the form of current element of Llength, where L≤L, uninsulated through all its length and disposed in the socket body parallel to the socket body base. Pin jacks in the body are made as one common contact opening arranged through all Llength of the body. The adaptor further comprises an earth contact and adapted to be connected to the socket with fixation from fall out in the contact opening forming an electrical contact between its contact pins and the earth contact and corresponding socket contacts at any point through all Llength of the socket body, allowing to move the adaptor through all Llength of the socket body.

Description

The claimed invention relates to electrical engineering, in particular to variants of an electrical connection device, and can be used as an outlet with an adapter / plug for connecting, including simultaneous, various electrical devices / devices to a common electrical network.

The most common, especially in relation to general-purpose electrical networks, for the plug-in connection of electrical appliances to such electrical networks are the so-called plug connectors. In general, the plug connection consists of two parts: a socket and a plug. In this case, the outlet, as a rule, is connected to a general-purpose electrical network, i.e. electric energy is supplied to it from the source, and the consumer’s electrical devices are supplied with plugs with electrical contacts in the form of pins for connection to an outlet [1]. Due to the simplicity and reliability (including from the point of view of safety) of their design, such electrical connection devices are very widespread. However, the design of socket-plug connectors, like most other types of electrical connection devices, has a significant drawback: for each electrical device connected to the electric network through a plug, it needs its own separate socket or at least separate sockets for the contact pins of the plug. Thus, the number of electrical devices that can simultaneously be connected to the electrical network through a single outlet is limited not only by the permissible loads of the network itself, but also constructively. Another problem is the difficulty in changing the location of the outlet. This problem is most often faced by consumers at home, when due to a change in the layout of rooms and / or the arrangement of furniture or overall household devices / appliances, it is difficult or even impossible to have permanent access to stationary outlets. In these cases, as a rule, various types of transition devices such as extension cords are used, which is not always convenient and safe.

The problem of increasing the number of simultaneously connected electrical devices is mainly solved either by increasing the number of sockets in one housing (one socket) [2], or by using the so-called tees [3]. This problem is similarly solved in the designs of other types of electrical connection devices [4]. However, such designs still have a fixed number and places of possible connections. At the same time, the area (dimensions) of such a socket increases in proportion to the number of possible simultaneous connections.

Another solution to the problem of increasing the number of electrical devices connected at the same time using a single outlet is provided by a plug for the power cord of the appliance, which contains a housing in which the output contacts are connected, connected to the wires of the power cord of the appliance, and is additionally equipped with receiving contacts and holes that are aligned with the output contacts and made with the possibility of interaction with the outgoing contacts of the next plug [5]. Thus, the described plug is simultaneously used both as a plug of a specific electrical device and as a socket for a plug of the next electrical device. The described construction also has a number of drawbacks, among which are the bulkiness of the structure (each subsequent plug will protrude farther from the surface of the outlet), which can lead to its accidental violation and damage, for example, elements of the housing of the plugs (protruding plugs can be touched, and with a sufficiently large effort, breaking the contacts between the contact groups of the plugs and sockets and even mechanically destroy them). Thus, the possible number of simultaneously connected electrical devices is also limited not only by the capabilities of the electrical network and the socket, but also by the design (dimensions) of the plugs.

If the above-mentioned technical solutions for electrical connection devices such as a socket outlet offer at least some options for increasing the number of simultaneously connected electrical devices, then they cannot solve the problem of changing the connection point, because For the contact pins of each plug, certain separate sockets must be provided, while the socket itself, as a rule, is stationary mounted in the area of the electrical wiring leads either directly on the wall or in a specially designed recess in the wall.

According to the results of the analysis of various designs of electrical devices of the socket-plug type, the plug-in device [3], including a socket in the housing of which a contact group is placed, the contacts of which are electrically connected to the corresponding wires of the network, can be selected as the closest to both versions of the claimed device and a plug type adapter comprising contact pins configured to contact the contacts of the contact group of the socket through the socket made in the housing and contact sockets, and at least one contact group, configured to contact with it the contact pins of the plug through made at least one surface of the housing of the adapter contact sockets. As in all cases described above, this design provides the ability to connect one / limited number of electrical devices / devices only at certain points of connection.

Thus, the object of the invention is to develop a design for an electrical connection device containing mating elements that function as a socket and plug, which would make it possible to significantly increase the number of possible connections of electrical devices / devices to the electrical network, as well as the possibility of simple and convenient change connection points of an electrical device / appliance.

Specialists in this field are well aware that any possible design options for sockets and plugs should be developed taking into account the basic requirements for them:

ensuring reliable contact with an acceptable current value, reliable isolation of live parts from each other, protection against contact with live parts by foreign objects, especially with your fingers, both when the plug is disconnected and when the connection is incorrect, protection against incorrect connection, manufacturing of housings and others structural elements of non-combustible materials.

Taking into account these requirements, as well as offering an unexpected form of contacting the contact group of the outlet, the author was able to find an original solution to the above problems of increasing the number of possible connections and simple and convenient change of connection points using a single outlet.

Thus, the task is solved by the claimed electrical connection device in the first embodiment, including a socket in the housing of which there is a contact group, the contacts of which are electrically connected to the corresponding wires of the network, and a plug-type adapter containing contact pins made with the possibility of contact with the contacts of the contact outlet groups through contact slots made in the socket housing, and at least one contact group configured to contact push pin plugs through contact sockets made on at least one surface of the adapter housing. The problem is solved due to the fact that the housing of the outlet is made with a rectangular base and has a length of L _To . The contact group socket comprises isolated from each other phase contact, a neutral contact and a grounding contact, each of which is formed as a conductive element L _e length, where L _e <L _K, bare along its entire length and arranged in the housing outlet parallel to the base socket housing , the socket contact in the housing are formed as one common situated over the entire length L. _The contact slot housing and the adapter further comprises a ground contact and being connectable latching socket from falling out of the contact slot to form an electrical contact between its contact pins and ground contact pins and corresponding sockets at any point throughout the length L _K socket housing and movable adapter over the entire length L _K socket housing.

In the structure of the socket proposed in the framework of the electrical connection device, the contacts (phase, neutral and grounding) are essentially made in the form of not point, but long (length b _e ), conductive elements uninsulated along their entire length located in a plane parallel to the base plane housing, and perpendicular to the plane in which the contact pins of the adapter are located (in the position attached to the outlet). Thus, on each long, non-insulated along the entire length of the conductive element (phase, neutral and grounding contacts) at any point, contact with the contact pins of the adapter can be formed. In addition, the contact slots in the housing, which determine the connection point in sockets of standard designs, in the proposed design are replaced by one common contact slot located along the entire length of the housing.

Thanks to this original solution, the socket does not provide a connection point or several connection points, but an entire region of length b _e , at each point of which an adapter can be connected. In this case, the number of adapters simultaneously connected to such an outlet is limited only by the length b _e (which is chosen, at least taking into account the permissible load on the network) and the dimensions of the adapters themselves. The socket and / or adapters are generally provided with any suitable means known to those skilled in the art for securing the adapter against falling out of the contact slot. In this case, the adapter can move (slide) along the contact slot throughout the entire length b _{To the} socket body.

Selecting the length L _K of the rectangular base socket housing can be made by those skilled in the art depending on the particular conditions of use outlet (permissible load, the required number of simultaneous connections, etc.).

In a preferred embodiment, the contact slot can be made along the bottom wall of the socket housing, and in the cavity of the housing on its upper wall along the entire length b _{To the} parallel to the base of the housing, an insulating partition is made, the height of which corresponds to the height of the front wall of the housing to the contact slot. In this case, the conductive element of the grounding contact can be located along the lower boundary of the base of the housing, the conductive element of the neutral contact can be located on the base of the housing along the upper boundary of the base, and the conductive element of the phase contact can be located on the front wall of the housing, at least along its upper borders.

This embodiment makes it possible to ensure reliable insulation of the contacts with respect to each other, even taking into account the fact that the contacts themselves are made in the form of conductive elements that are not insulated along their entire length.

In the case of the above-described execution of the contact slot, it is preferable when the adapter housing is in the form of a substantially rectangular parallelepiped, the contact pins of the adapter are located on the upper wall of the housing and at different distances from the front wall of the housing, the grounding contact of the adapter is located on the lower wall of the housing along the rear wall housing, and contact slots are located on the front wall of the housing.

As already mentioned above, the means of fixing the adapter from falling out in the contact slot can have a different form of execution. In preferred embodiments, at least one adapter fixing member may be provided in the socket housing, selected from the group comprising a longitudinal vertical locking protrusion on the insulating partition and a longitudinal horizontal locking protrusion on the front wall of the housing. In this case, the adapter is equipped with corresponding locking response elements.

To increase the contact area in preferred embodiments, the conductive elements can be made in the form of plates.

Typically, plug-to-plug electrical connection devices comprise a plug and one plug or plug adapter. However, in preferred embodiments of the inventive device, it comprises at least one additional adapter.

Since usually not the entire connection area is covered by the adapter (s), a protective cover may be provided in the area (s) of the open (s) part (s) of the contact slot, consisting of at least one protective element.

The design features of the claimed electrical connection device as a whole and the sockets in its composition described above, in particular, make it easy to change the position of the connection point by moving the adapter along the conductive contact elements. In this case, if the outlet is installed horizontally, you can change the position of the connection point horizontally, and if vertically - vertically.

The problem is also solved by the claimed electrical connection device in the second embodiment, including a socket, in the housing of which there is a contact group, the contacts of which are electrically connected to the corresponding wires of the network, and a plug with contact pins made with the possibility of contact with the contacts of the contact group through those made in the housing sockets contact sockets. The problem is solved due to the fact that the socket housing is made with a rectangular base and has a length of _K , the contact group of the socket contains a phase contact isolated from each other, a neutral contact and a grounding contact, each of which is made in the form of a conductive element of length B _e , where L _E <L _K, bare along its entire length and arranged in the housing parallel to the base socket outlet housing, the contact socket in the housing are formed as one common situated over the entire length L to _K shell ntaktnoy slot, and the plug further comprises a ground contact and is configured to be connected to an outlet with detent from falling out of the contact slot to form an electrical contact between its contact pins and the ground contact and the corresponding contacts of sockets anywhere along the length L _K socket housing and the ability to move the adapter along the entire length b _{To the} socket housing.

For this embodiment, all that is said above with respect to the first embodiment for the electrical connection device of the plug-in adapter-type plug remains true.

As in the first embodiment, it is preferable when the contact slot is made along the bottom wall of the socket housing, in the cavity of the case on its upper wall along the entire length b _{To the} parallel to the base of the case, an insulating partition is made, the height of which corresponds to the height of the front wall of the case to the contact slot, while the conductive element of the grounding contact is located along the lower boundary of the base of the housing, the conductive element of the neutral contact is located on the base of the housing along the upper the boundary of the base, and the conductive element of the phase contact is located on the front wall of the housing, at least along its upper boundary.

With the indicated location of the contact slot and the conductive elements, the plug housing is preferably in the form of a substantially rectangular parallelepiped, the plug contact pins are located on the upper wall of the housing and at different distances from the front wall of the housing, and the grounding contact of the plug is located on the lower wall of the housing along the rear wall of the housing .

As a means of fixing the plug in the contact slot from falling out in the socket housing, at least one plug fixing element selected from the group including a longitudinal vertical locking protrusion on the insulating partition and a longitudinal horizontal locking protrusion on the front wall of the housing may be provided, while the plug is provided corresponding response fixing elements.

As in the case of the first embodiment of the inventive electrical connection device, the conductive elements can be made in the form of plates, the device itself can contain

- 3 021379 at least one additional plug, and in the area of the contact slot may be provided with a protective cover consisting of at least one protective element.

The above-described and other features, advantages and advantages of the inventive device of electrical connection will be discussed in more detail below on one of the possible preferred, but not limiting examples of the implementation of the inventive device in the first embodiment. Moreover, all of the following will apply to all possible forms of the claimed device in the second embodiment. For clarity, the description will refer to the position of the drawings, which are schematically represented in FIG. 1 is a side view in section of a socket; in FIG. 2 is a front view of the outlet of FIG. one; in FIG. 3 is a left view of a fork type adapter; in FIG. 4 is a front view of the adapter of FIG. 3; in FIG. 5 is a rear view of the adapter of FIG. 3; in FIG. 6 is a right side view of the adapter of FIG. 3;

in FIG. 7 is a side view in section of a device for electrical connection assembly (the adapter is installed in the socket);

in FIG. 8 is a front view of the device of FIG. 7.

In FIG. 1 is a schematic cross-sectional side view, and FIG. 2 is a front view of a socket 1 from the composition of the claimed device for electrical connection. The housing of the outlet is made with a rectangular base and has a length of L _To . Along the bottom wall 2 of the housing 1 is formed outlet slit 3. The contact body cavity in its upper wall 4 along the entire length L _K parallel to the base 5 of the housing is formed an insulating partition 6, whose height corresponds to the height of the front wall 7 of the casing to contact the slit 3. The conductive member 8 grounding contact is located along the lower boundary of the base 5 of the housing. The conductive element 9 of the neutral contact is located on the base 5 of the housing along the upper boundary of the base. The conductive phase contact element 10 is located on the front wall 7 of the housing from its inner side, at least along its upper boundary. Thus, all the contacts of the outlet are made in the form of corresponding conductive elements of length L _E , where L _E <L _K , uninsulated along their entire length and located in the housing of the socket 1 parallel to the base 5 of the housing of the socket 1. In this case, the conductive elements are phase, neutral and ground contacts are reliably isolated from each other.

In the embodiment of FIG. 1 and 2, in the housing of the socket 1, adapter fixing elements are provided in the form of a longitudinal vertical locking protrusion 11 on the insulating partition 6 and a longitudinal horizontal locking protrusion 12 on the front wall 7 of the housing from its inner side.

In FIG. 3-6 in various forms, a plug adapter 13 of the inventive electrical connection device is schematically shown.

The housing of the adapter 13 is in the form of a substantially rectangular parallelepiped. The contact pins 14 of the adapter 13 are located on the upper wall 15 of the housing and at different distances relative to the front wall 16 of the housing. The grounding contact 17 of the adapter 13 is located on the bottom wall 18 of the housing along the rear wall 19 of the housing. Contact slots 20 are located on the front wall 16 of the housing.

In FIG. 7 is a schematic cross-sectional side view, and FIG. 8 is a front view of the electrical connection device assembly (adapter 13 is installed in outlet 1). The contact zones formed after installing the adapter 13 in the contact slot 3 of the socket 1 between the contact pins 14 of the adapter 13 and the conductive elements 9 and 10 of the socket, as well as between the grounding pin 17 of the adapter 13 and the conductive element 8 of the socket 1, are indicated in FIG. 7 positions 21, 22 and 23, respectively.

The bold arrows in FIG. 1 and 7 schematically indicate the connection of the contact elements 8, 9, 10 of socket 1 to the corresponding wires of the electrical network.

The inventive electrical connection device operates as follows.

In accordance with the plan (project), the conductive elements 8, 9, 10 of socket 1 are connected to the corresponding wires of the electrical network and the base 5 of socket 1 is fixed to the wall (horizontally or vertically). One adapter 13 or several adapters 13 are installed in the socket 1 through the contact slot 3 in the place (the connection point), which is the most convenient from the point of view of the user. When installing the adapter 13 due to the fact that its contact pins 14 are located on the upper wall 15 of the housing and at different distances relative to the front wall 16 of the housing, one of them (contact pins 14) is placed between the base 5 of the housing of the socket 1 and the insulating partition 6 made in the cavity of the housing on its upper wall 4 along the entire length b _To parallel to the base 5 of the housing, and the second between the insulating partition 6 and the front wall 7 of the housing of the socket 1. After installation of the adapter 13 in the contact slot 3 of the socket 1 The following contacts are mirrored:

between the conductive element 8 of the grounding contact of the socket 1, located along

- 4 021379 the lower boundary of the base 5 of the housing of the socket 1, and the grounding contact 17 of the adapter 13 located on the lower wall 18 of the housing of the adapter 13 along the rear wall 19 of the housing (position 23 in Fig. 7);

between the conductive element 9 of the neutral contact of the socket 1, located on the base 5 of the housing of the socket 1 along the upper boundary of the base 5, and the corresponding contact pin 14 of the adapter 13 located on the upper wall 15 of the housing of the adapter 13 (position 21 in Fig. 7);

between the conductive element 10 of the phase contact of the socket 1, located on the front wall 7 of the housing of the socket 1 from its inner side, at least along its upper boundary, and the corresponding contact pin 14 of the adapter 13, located on the upper wall 15 of the housing of the adapter 13 (position 22 in Fig. 7).

The formed contacts in zones 21, 22, 23 are constant and highly reliable due to their large area, as well as due to the reliable fixation of the adapter 13 in the contact slot 3 of socket 1 by means of a longitudinal vertical locking protrusion 11 on the insulating partition 6 of socket 1 and a longitudinal horizontal the locking protrusion 12 on the front wall 7 of the housing of the socket 1 on its inner side, which operate on the principle of a lock together with the response elements of the adapter 13 (which are not indicated in the drawings). Thus, any electrical device with a standard plug can be connected to the electrical network by installing the contact pins of the plug in the contact sockets 20 located on the front surface 16 of the housing of the adapter 13.

If it is necessary to change the connection point of the electric device / device to the electric network, the adapter 13 can be moved to the desired point along the length b _{To the} socket housing 1 (the plug of the external electric device / device must first be removed from the contact sockets 20 of the adapter 13).

If it is necessary to connect several electrical devices / devices to the electrical network, the corresponding number of adapters 13 are installed in the contact slot 3 of the socket 1 in the manner described above, placing them at the specified connection points.

In the general case, the set of electrical connection device may include one socket 1 and one adapter 13 or a socket 1 and a number of adapters 13, the maximum number of which is determined taking into account the length L _K socket housing 1 and dimensions (width) of the adapter 13. The optimum can be considered a set consisting of one outlet 1 and several adapters 13, the number of which is less than the maximum for this outlet 1. In this case, the adapters 13 can be freely moved along the length b _{To the} housing of the outlet 1, choosing the optimal their position.

The claimed electrical connection device works in a similar way in the second embodiment, except that the external electrical devices / consumer devices must be equipped with a plug of the construction described above, which is directly (without an adapter) installed in the contact slot 3 of socket 1.

Claims (8)

1. The device is an electrical connection, including a socket in the housing of which there is a contact group, the contacts of which are electrically connected to the corresponding wires of the network, and a plug-type adapter containing contact pins made with the possibility of contact with the contacts of the contact group of the socket through contact sockets made in the socket body , and at least one contact group configured to contact with it the contact pins of the plug through the housing made on at least one surface Adapter plug sockets, the socket housing is formed with a rectangular base and has a length L _R, a contact group of sockets comprises isolated from each other phase contact, a neutral contact and a grounding contact, each of which is formed as a conductive element length L _E, where D _E <B _To . uninsulated along its entire length and located in the socket housing parallel to the base of the socket housing, while the contact sockets in the housing are made in the form of one common contact slot located along the entire length b of the housing _K , and the adapter additionally contains a grounding contact and is configured to connect to the socket with fixing from falling out in the contact slot with the formation of an electrical contact between its contact pins and the grounding contact and the corresponding contacts of the outlet at any point on throughout the entire length b _K of the socket housing and with the possibility of moving the adapter along the entire length b _K of the socket housing, characterized in that the contact slot (3) is made along the bottom wall (2) of the socket housing (1), has a generally rectangular transverse shape cross-section, and its width is selected according to the height of the front wall (16) of the adapter housing (13), and the depth is selected according to the width of the lower wall (18) of the adapter housing (13), in the cavity of the socket housing (1) on its upper wall (4) the entire length b _to parallel to the base (5) of the housing an insulating partition (6) is made, the height of which corresponds to the height of the front wall (7) of the housing to the contact slot (13), while the conductive element (8) of the grounding contact is located along the lower boundary of the base (5) of the housing, the conductive element (9) of the neutral contact located on the base (5) of the housing along the upper boundary - 5 021379 of the base (5), and the conductive element (10) of the phase contact is located on the front wall (7) of the housing, at least along its upper boundary, and all conductive elements of the grounding contact (8), neutral contact (9) and the phase contact (10) is made in the form of flat plates, the adapter case (13) has the shape of a basically rectangular parallelepiped, the contact pins (14) of the adapter (13) are located on the upper wall (15) of the adapter case (13) and at different distances relative to the front wall (16) of the adapter housing (1 3) with the possibility of placing one of the contact pins (14) between the base (5) of the socket housing (1) and the insulating partition (6), and the second between the insulating partition (6) and the front wall (7) of the socket (1) with the formation of electrical contact between the pins (14) and the conductive element (9) of the neutral contact and the conductive element (10) of the phase contact and with the placement of the front wall (16) of the adapter housing (13) in the plane of the front wall (7) of the socket housing (1), while the grounding contact (17) of the adapter (13) is located on neither the bottom wall (18) of the adapter case (13) along the rear wall (19) of the adapter case (13), and the contact slots (10) are located on the front wall (16) of the adapter case (13). 2. The device according to claim 1, characterized in that at least one adapter fixing element (13) is provided in the socket housing (1), selected from the group including a longitudinal vertical locking protrusion (11) on the insulating partition (6) and longitudinal horizontal locking protrusion (12) on the front wall (7) of the housing, while the adapter (13) is provided with corresponding locking response elements. 3. The device according to claim 2, characterized in that it contains at least one additional adapter. 4. Device according to any one of claims 1 to 3, characterized in that a protective cover is provided in the area of the contact slot (3), consisting of at least one protective element. 5. An electrical connection device, including a socket, in the housing of which a contact group is placed, the contacts of which are electrically connected to the corresponding wires of the network, and a plug with contact pins configured to contact the contacts of the contact group through contact sockets made in the socket housing, wherein the housing the socket is made with a rectangular base and has a length of L _K , the contact group of the socket contains a phase contact isolated from each other, a neutral contact and a ground contact, each of which is made in the form of a conductive element of length b _e , where b _e <b _K , non-insulated along its entire length and located in the socket housing parallel to the base of the socket housing, while the contact sockets in the housing are made in the form of one common b located along the entire length of b _{To the} body of the contact slot, and the plug additionally contains a grounding contact and is configured to connect to the outlet with fixation from falling out in the contact slot with the formation of an electrical contact between its contact pins and the gap a grounding contact and corresponding socket contacts at any point along the length b _K of the socket body and with the possibility of moving the adapter along the entire length b _K of the socket body, characterized in that the contact slot (3) is made along the bottom wall (2) of the socket body (1) , has a mainly rectangular cross-sectional shape and its width is selected corresponding to the height of the front wall (16) of the adapter housing (13), and the depth is selected corresponding to the width of the lower wall (18) of the adapter housing (13) in the cavity of the socket housing (1) on in rhney its wall (4) along the entire length L _K parallel to the base (5) of the housing is formed an insulating partition (6), whose height corresponds to the height of the front wall (7) of the housing to the contact slots (13), wherein the conductive element (8) ground contact located along the lower boundary of the base (5) of the housing, the conductive element (9) of the neutral contact is located on the base (5) of the housing along the upper boundary of the base (5), and the conductive element (10) of the phase contact is located on the front wall (7) of the housing, least along her faith henna of the border, and all the conductive elements of the grounding contact (8), neutral contact (9) and phase contact (10) are made in the form of flat plates, the plug body has the shape of a mainly rectangular parallelepiped, the contact pins of the plug are located on the upper wall of the plug body and at different distances relative to the front wall of the plug housing with the possibility of placing one of the contact pins between the base (5) of the socket housing (1) and the insulating partition (6), and the second between the insulating partition (6) and the front wall (7) of the socket housing (1) with the formation of electrical contact between the plugs of the plug and the conductive element (9) of the neutral contact and the conductive element (10) of the phase contact and with the placement of the front wall of the plug housing in the plane of the front wall (7) of the socket (1 ), while the grounding contact of the plug is located on the bottom wall of the plug housing along the rear wall of the plug housing. 6. The device according to claim 5, characterized in that at least one plug fixing element is selected in the socket housing, selected from the group including a longitudinal vertical locking protrusion on the insulating partition and a longitudinal horizontal locking protrusion on the front wall of the housing, wherein the plug is provided corresponding response fixing elements. 7. Device according to any one of paragraphs.5 or 6, characterized in that it contains at least one - 6 021379 additional plug. 8. Device according to any one of paragraphs.5-7, characterized in that in the area of the contact slot is provided a protective cover consisting of at least one protective element.