RU2345455C2 - Connecting device and connection network for insulated electrical conductors - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: connection device consists of a housing where a multiple set of solid contact elements are available. Each element includes at least one contact with insulation shift or cut-in contact to ensure the first conductor contact. The element also includes at least one second contact with insulation shift or cut-in contact to ensure the second conductor contact. The first and second contacts of each contacting elements are electrically connected with each other. The contact elements are situated in pairs and asymmetrically so that transitional parts of both contact elements in the pair are located closer to each other than to the transitional parts of the adjacent contact elements in different pairs. The first and the second contact with insulation shift or cut-in contacts are arranged so that the first and second conductors are located at the different sides of housing.

EFFECT: high speed of data transfer at small amounts and satisfactory reliability of data transfer meeting the standards, easy connection and low price for connection device production.

20 cl, 11 dwg

Description

The present invention relates to a connection device and a connection network for a plurality of insulated electrical conductors. For connecting telephone lines or data lines in telephone exchanges or distribution devices, often connecting devices are provided, for example terminal blocks. Typically, they include many guides for the first lines ("incoming lines"), many guides for the second lines ("outgoing lines"), as well as contact elements for connecting each first line to the second. Preferred are connection devices that provide a solderless connection for insulated conductors that are based on Insulation Displacement Contact (IDC) technology. Then it is preferable that each of the contact elements has at least two contacts with insulation bias or - at least - two mortise contacts or one contact with insulation bias and one mortise contact.

Many devices of this kind are known, and many of them are available on the market. As documents that describe devices of this type, one can cite, for example, EP-A-0321151, DE-A-2301398, and DE-A-19652422.

A terminal box is known from EP 0994528, which is made on the basis of contact technology with insulation bias, and is characterized in that the casing is integral. Contact elements, in addition to contacts with insulation bias, have a cutting edge on one side (from the incoming line side). This allows you to do without this complex tool when connecting the conductor, which must be cut to the required length. Another junction box is also known from US Pat. No. 4,964,812.

In the case of connecting devices of the mentioned type, there are at least several problem areas.

1. Cross connection between adjacent pairs of contact elements. It matters, especially in the case of data transfer. The higher the data transfer rate, the more problems there are. To ensure reliable data transmission, the contact elements of the connecting devices for increased transmission frequencies should be located as far as possible from each other, or all contact groups must have compensating capabilities. This, however, is undesirable or in many cases impossible due to the lack of the necessary space and because of the high cost.

2. Convenience of connection. Naturally, there is a need to make the connection procedure as easy and convenient as possible. This eliminates the need for sophisticated tools.

3. The cost of manufacturing. There is tremendous pressure on the market for telecommunication equipment prices.

US Pat. No. 5,556,296 and US Pat. No. 5,160,273 disclose a connection device with a detachable contact. A detachable contact of this kind consists of two separate contact elements, each of which includes a contact with insulation bias and a spring-loaded end contact, while the spring-loaded end contacts of both contact elements are pressed against each other by a spring force. Between the two end contacts there may be a separate element. Such an element may be electrically isolated, as a result of which the electrical circuit may open. It is also possible that a separate element of this type is made, for example, in the form of a printed circuit and performs some function, for example, protection against overloads or receiving signals. In accordance with these two mentioned documents, these two end contacts are formed asymmetrically so that the distance between the end contacts within the pair of detachable contacts is less than the distance between the adjacent end contacts of the pair of detachable contacts, which leads to a decrease in cross-connections. Similar connecting devices can be found in US Pat. No. 5,967,826, which also shows an embodiment in which two contact elements located opposite each other are connected through a bridge and therefore form an integral, U-shaped contact connecting element.

Considering the universal possibilities of connecting devices of this type with detachable contacts, they are suitable for special applications, however, they are difficult to manufacture, consist of many individual elements, and due to the complex geometry of their body consists of several parts. In addition, due to the complex geometry, the incoming and outgoing lines are laid on one side of the housing and in the same direction, which requires precise cutting of the lines with a separate cutter and which can lead to uncontrolled contacts between the conductors.

In accordance with the documents mentioned above, the common feature of all devices is that they are not suitable for high transmission speeds, for example, 100 Mbit / s or more, as a result of cross-connections, in addition, they have large sizes. In addition, they, in particular, are very difficult (that is, roads) in manufacturing and also installation.

Therefore, an object of the present invention is to provide a connection device that provides high data rates at small sizes and a satisfactory reliability of data transmission in accordance with standards. It is also necessary to ensure ease of connection and low manufacturing cost.

The device of the present invention is made in a one-piece housing comprising a plurality of integral contact elements, each of which respectively includes at least one first and at least one second contact with insulation bias or mortise contact. Between the first and second contacts of each contact element there is a transition section. Contact elements are arranged in pairs. In accordance with the present invention, the contact elements are asymmetrical, and the transition sections of both contact elements in a pair are closer to each other than the transition sections of adjacent contact elements of other pairs.

As a result of the fact that the distances between the transition sections are different, the characteristics of the cross-connections of adjacent pairs decrease at fixed distances between the contacts. The difference in the distances between the transition sections is due to the asymmetric design of the contact elements. This leads to a number of advantages. The first advantage is that the contacts with bias insulation, or mortise contacts, if necessary, can be equidistant. The asymmetric shape provides optimization of currents in the areas of contact elements most susceptible to cross-connection, that is, contacts in pairs are located as far away from each other as possible. This allows you to satisfy the requirements of a higher data transfer rate without any resizing compared to existing connecting devices. For example, with the dimensions of an existing category 3 device, based on the present invention, it is possible to make a connecting device corresponding to ISO / IEC 11801 (2002) category 5. Therefore, plugs, sockets, etc. of the present device can be used for a higher category 5. When using the present invention, category 6 connecting devices can also be used in a limited space, for which it is preferable to use shielding plates between the contact pairs. When using the method of the present invention, the housing can be made integral. The manufacturing technology of an all-in-one body, for example, by injection molding, has significant advantages: production costs are lower than in the case of detachable bodies. The design of the present invention makes it easy to insert contact elements into an integral housing. Therefore, to assemble the connecting device in an integral housing, it is necessary to provide only cameras for contact elements.

In addition, as another advantage, the contact elements can be made flat and can be made to lie in a common plane. This is especially important in the manufacture: all contact elements or at least groups of contact elements can be jointly stamped from one metal sheet. After possible deformations, in particular during extrusion and / or cutting, they can be inserted into the housing together, fixing together with a transport tape (jumper). If the contact elements include at least one flat section, then they are arranged, for example, asymmetrically with respect to the plane that connects the two contacts to the insulation offset or two mortise contacts and which extends vertically to the flat section.

It is possible that the number of contact elements includes elements that extend beyond the plane of the contact elements and extend beyond the configuration of the plane formed, for example, by extrusion. Such elements can be made in the form of latches, which prevent the longitudinal displacement of the contact elements inserted into the housing. Since the elements of the contact plane extend beyond the plane of the contact elements, reinforcements can be made that increase the mechanical stability at critical points and which therefore allow the use of very thin metal sheets. Reinforcements of this type may, in particular, allow the insertion of two contact plugs with an offset insulation.

As you know, the first and second conductors can run parallel to each other and vertically to the contact elements. In addition, they generally pass from opposite sides ("front" and "back") of the case, until they come into contact. Although such a construction is preferred, the present invention can also be used for connecting devices in which the first and second conductors are not parallel (angular connecting device). It can be carried out, for example, using curved contact elements.

Often, the contact elements of each pair corresponding to each other (that is, all “left” or all “right” contact elements of each pair) are made the same. Then each pair contains, respectively, the first and second contact element, while the first and second contact elements differ in their shape and orientation. Therefore, within a pair of contact elements, contact elements of a particular orientation in accordance with the present invention are not the same. However, in accordance with many preferred embodiments of the present invention, the first and second contact elements of each pair of contact elements are mirror images of each other.

Therefore, it is possible that, so to speak, two types of contact elements are available: “right” and “left” or the first and second. The first and second contact elements can be of the same shape and differ solely in their orientation. That is, the second contact elements are the first contact elements, which, for example, are rotated 180 ° relative to the longitudinal axis. They are used, in particular, in cases where the contact elements do not contain any elements protruding beyond the plane (latches, amplifications, etc.).

To separate the elements between the transition sections of the contact elements of adjacent pairs, elongated, intermediate gaps can be set. This makes sense, in particular, in the case of connecting devices designed for high data transfer rates: this leads to a more compact design while observing standards (for example, category 6).

As is known, the housing may include grooves for inserting conductors. By inserting insulated conductors into the grooves and subsequently introducing them into the contact, the conductors come into contact, because the cut ends or the cut-in ends of the contacts enter these grooves. It is possible that conductors are inserted inside using a wiring tool.

It is also possible that the housing includes latches for installation in the mounting channel. The latches can be asymmetric with the possibility of fixing in the mounting channel in two positions. In the first position, the first side (for mounting the first, in this case, "incoming" lines) and in another position, the second side (for mounting the second, in this case, "outgoing" lines) is located in front, which provides convenient access. 3 latches of this type are known, for example, from the proposed patent EP-A-0994528, which in this case is referred to in the description, in particular, of figure 1. In accordance with a preferred embodiment of the present invention, each contact element is provided with at least one , usually two, with incisors. Through this cutter or cutters during installation work, excess lengths of conductors are cut. As a result of the fact that the cutter is made integral with the connecting device, the design of the wiring tool can be significantly simplified. Moreover, for the installation and trimming of excess lengths, only one process step is required. In contrast to this solution, in which a cutter is provided in the wiring tool, are more complex.

The cutter can be performed separately from the contact elements. At the same time, the technological process receives advantages: the cutter (or its cutting edge) should naturally meet the requirement that it is located in a different plane than the contact with the insulation offset, or the cut-in contact. From the prior art it is known that the cutter is integral with the contact element. The mentioned requirement can be fulfilled only if the contact element (with a cutting edge) is made volumetric, i.e. not in one plane. After it is cut out of a metal sheet, in accordance with the prior art it is necessary to change its shape, which is expensive. Another advantage, consisting in the fact that the cutter is made separately, is that the choice of materials of the contact elements and the cutter can be optimized. Thus, for example, the material of the cutter may be harder than the material of the contact elements.

Particularly preferred is the design, in the case of which the contacting conductors no longer touch the cutter after electrical work. In this case, the cutter does not contribute to the cross-connections, and the capacity of the device becomes smaller, which also minimizes losses. In addition, the electric potential of the cutter is not significant, and, in principle, it is possible that between the cutters of adjacent contact elements there is an electrical contact. The connecting device may even be configured such that the cutting element forms several cutters and possibly includes a single, common cutting edge extending at right angles to the direction of the conductor, which cuts off the excess of several adjacent conductors.

It is possible that in addition to the housing, contact elements and cutters, the connecting device also includes other components.

For example, on one of the sides (usually from the side of the second "outgoing" conductors), an electrical cover can be installed on which you can write or print something. When using this part, the grooves may be closed, and inscriptions can be made on the pairs of conductors in accordance with their function.

It is also possible that from the side of the first "incoming" conductors, the connecting device is provided with a second cover, which may include an element that relieves the mechanical stress of the multicore cable.

In addition, gel or weather grease may be present in one of the mounting covers or directly in the grooves for inserting the conductors to protect against corrosion.

The following is a description of embodiments of the present invention based on the following drawings.

The figure 1 shows the connecting device of the present invention with two covers.

Figure 2 shows the connecting device of the present invention with contact elements and cutters open in some areas.

Figure 3 shows a cross section of a connecting device.

The figure 4 shows two pairs of contact elements of the connecting device of the present invention.

The figure 5 shows the relative location of the contact element, cable and cutter after electrical work.

Figure 6 shows the blanks made by punching and extrusion, with many contact elements and cutters for the connecting device of the present invention, together with the housing.

The figure 7 shows two connecting devices in the mounting channel.

The figure 8 shows the housing and the shielding element according to one variant of the connecting device of the present invention with screens between pairs of contact elements.

Figure 9 shows a pair of contact elements for a variant of the connecting device of the present invention, in which the incoming and outgoing conductors are located at an angle to each other.

Figure 10 shows a plug of a connection cable for connection to a connection device of the present invention.

Figure 11 shows three types of plug contact for the plug of Figure 10. The connecting device 1 shown in Figure 1 corresponds to category 5. It includes a housing 2, which, as you know, includes many chambers for contact elements. The cameras are located between the grooves 2.1, which serve as guides for the contacting insulated electrical conductors (not shown). Contact elements are arranged in pairs. In the above embodiment, the pairs of contact elements 11 are numbered 2.2. The grooves 2.1 in the above embodiment of the present invention are equidistant, that is, the distance between the two grooves 2.1 of each pair is equal to the distance from one groove to the nearest groove of the adjacent pair. On the side of the contact elements, the housing contains latches 2.3, which are used for mounting in the mounting channel. In addition to the housing and contact elements, the connecting device includes cutters 4, 5. Their function will be explained below. In addition, a marking cover 6 for second lines (outgoing lines) is shown, as well as a cable cover 7 for first lines (incoming lines). The cable cover 7 includes an unloading collar (for load shedding) 7.1, which serves as a guide for the incoming cable, including several conductors, and / or providing its mechanical fastening.

Figure 2 shows only a part of the housing 2. Therefore, it is possible to see contact elements 3 arranged in pairs next to each other, as well as first cutters 4 and second cutters 5. Each contact element has a first cutter 4 and a second cutter 5. The contact elements are essentially flat and form the plane of the contact elements. Mostly, the cutters are parallel to this plane of the contact elements and are electrically isolated from the contact elements. The design and arrangement of the contact elements by the pairs of contact elements 11 are particularly clearly visible in Figures 3 and 4. Each contact element forms a first contact with an offset of insulation 3.1, a second contact with an offset of insulation 3.2 and a transition section 3.3 between them. It is possible that the contacts with a bias of insulation 3.1, 3.2 are made in a known manner and are provided for multiple contacting of insulated conductors of a certain diameter or diameter range. In the above embodiment of the present invention, the insulation biased contacts are made with reinforcements 3.4, which were extruded and which provide mechanical stability and sufficient closing forces in the case of using very thin sheet metal. Visible beetles (here as rectangular elements) at the most stressed contact point with insulation offset are used to adjust the width of the contact groove independent of the punching tool. In the area of the transition section 3.3, the contact elements include a latch 3.5, formed by a slice, which, after inserting the contact elements into the chambers of the housing 2, are latched by the protrusion 2.4 of the housing and prevent the contact elements from moving in the direction of their longitudinal axis. During the "cutting", unlike cutting, the material is not completely removed; at the same time, the latch bends. For each contact element there are two latches 3.5. If the chambers are asymmetrical and formed in such a way that during insertion they form an emphasis for the locking elements, then only one latch on the locking element is sufficient.

The contact elements are made asymmetrically and, in particular, in such a way that, in the case of equidistant placement of the contacts with an insulation bias, the transition sections 3.3 of the two contact elements of the pair of contact elements become closer to each other than to the transition section of the contact element of the adjacent pair. And this is in contrast to the prior art, according to which the contact elements are respectively symmetrical (in this case, the plane of symmetry is a plane extending in the longitudinal direction vertically to the plane of the contact elements).

Based on the extruded elements (latches 3.5, gain 3.4), the first and second contact element 3 of each pair of contact elements not only differ in their orientation, but also in geometry. In the above example, the first and second contact elements are contact reflection of each other. During electrical work, the conductors are inserted into the grooves 2.1 of the housing from the outside, as a result of which the insulation is cut off and displaced by the contact cutters with an insulation displacement of 3.1, 3.2 so that the contacts with the insulation displacement contact the core of the conductors. At the same time, during installation, cutters 4, 5 cut off the excess length of the conductor. The cutters are made and arranged so that after electrical work the conductors do not come into contact with them. This is shown, in particular, in figure 5, which shows the conductor 12, the portion of the contact element 3 and the cutter 4. The cutter in the embodiment of the present invention includes a recess 4.1, which provides a safe distance between the conductor and the cutter, which prevents the conductor and the cutter from contacting.

Figure 6 shows how the use of substantially flat contact elements simplifies the manufacture of the device of the present invention. The housing 1 is preferably molded in one piece. For the manufacture of contact elements 3, the first cutters 4 and second cutters 5 by punching, followed by extrusion, respectively, from a metal sheet, for example from sheet steel, a workpiece is obtained. The blank includes a plurality of contact elements / cutters that are connected by jumpers 13, 14 or 15. If necessary, the blanks are cut to a length corresponding to the length of the connecting device, and subsequently, as shown in figure 6, are pressed into the housing chambers provided for this purpose. Then the jumpers are cut off. The cutters are fixed in the housing by welding the cutters into plastic housings (behind the barbs). These contact elements, for example, in contrast to the contact elements according to the patent EP 0994528, do not include sections bent more than 90 ° relative to the plane of the contact elements. This is the only circumstance that allows us to produce contact elements (as well as cutters) exclusively by cutting and extruding.

The figure 7 shows two connecting devices, the covers 6, 7 of which are fastened, in the mounting channel 21. The latches 2.3 catch the hole 21.1 provided for this purpose on the side walls of the cable channel through which the connecting devices are mounted.

In accordance with another embodiment of the connecting device of the present invention, FIG. 8 shows a housing 31. This connecting device is different from that described above in that a shield element is provided between pairs of contact elements (not shown). It is formed by shielding walls 32.1, which are present on the shielding element 32. For shielding walls in the housing 31, special grooves 31.1 are provided between the pairs of contact elements. As a result, a shielding element can be inserted into the housing from the outside. The shielding walls 32.1 shield the contact elements of adjacent pairs, in particular, in the area where the contacts with insulation bias are closer to each other than in the area of the transition sections. All shielding walls 32.1 are electrically connected to each other. In addition, the shielding element 32 is generally grounded through plugs 32.2, which, when the device is installed, are in contact with the side walls of the mounting channel 21. For example, the embodiment of the present invention shown in FIG. 8 corresponds to category 6. The contact elements may be identical to the contact elements shown in figure 4, where the distance between the pairs of contact elements may be greater than in the case of the embodiment described above. Of course, various types of asymmetrical contact elements can also be used. Unlike the category 5 device described above with 10 pairs of contact elements, in the device of the same overall width shown in Figure 8, only 8 pairs are provided.

Figure 9 shows a pair of contact elements of an embodiment of the present invention, in which the incoming and outgoing conductors are arranged at an angle to each other. Even if for the manufacture of these contact elements 42 arranged at an angle to each other, it is necessary one more technological operation than in the case of the above embodiments of the present invention, and the housing may not be inseparable, the idea of the present invention is still feasible in this an embodiment of the present invention. The transition sections 41.3 of the two contact elements of the pair, also made using an asymmetric circuit (relative to the plane that connects the contacts with the insulation bias together and goes vertically to the parts of the plane), are closer to each other than to the adjacent contact element of the other pair.

Figures 10 and 11 show a plug of a connecting system, which, instead of directly contacting the current-carrying conductors of the cable (corresponding to the conductors), passes through the contacts with insulation bias, used to ensure contact between the two-core cable and a pair of contact elements. The plug is provided with a plug housing 51 with at least two plug contacts 52. The plug, for example, can be inserted into the connecting device from the side of the output conductors, while the housing, for example, is equipped with locking tabs 51.1, which are inserted into the connecting device and guide there and fix the plug. During insertion into the connecting device, contact is made between the plug contacts 52 and the contact elements. This is clearly seen in FIG. 11, where, in addition to the plug contact 52, a portion of the contact members 2 is also shown. FIG. 11 shows a side view of the contact member with the plug contact in FIG. Figure B shows a top view of the device at an angle, while Figure C shows a top view of a section of the device along line CC (in Figure A).

At the end, the plug contact contains a wire section 52.1, which is installed between the contact plugs with a bias of insulation 3.2 to ensure electrical contact. The cross section of the wire section, for example, round or rectangular. It has, for example, a diameter that corresponds to the diameter of the conductor without insulation. It passes between two parallel legs 52.3, which form a plane. Here, this plane extends vertically to the plane of the contact elements. On the other hand, the plug contact includes a contact portion with a cable 52.4, which may include at least one contact with an insulation offset of 52.5.

There may also be plugs having longer than two plug contacts, for example with four plug contacts.

Claims (20)

1. A connecting device for insulated electrical conductors with a housing (2, 31) and with a number of non-separable contact elements (3) fixed in the housing, each of which includes at least a first contact with an insulation bias or a mortise contact (3.1) for providing contact of the first conductor, at least a second contact with an insulation bias or a cut-in contact (3.2) to ensure contact of the second conductor, and with a transition section (3.3) going between the first and second contacts with an insulation bias or the first and the second mortise contacts, while the contact elements form a pair of contact elements (11), the contact elements are formed asymmetrically in such a way that the transition sections (3.3) of two contact elements, at least one pair of contact elements (11), at least some zones are closer to each other than the transition section (3.3) of one of the two contact elements to the transition section (3.3) of the next contact element of an adjacent pair of contact elements (11), characterized in that the first and second contacts are mixed insulating contacts or mortise contacts (3.1, 3.2) are placed in such a way that the first and second conductors are located on different sides of the housing (2, 31). 2. The connecting device according to claim 1, characterized in that the contact elements include at least one flat section and are located asymmetrically relative to the plane that connects the first and second contacts with an offset insulation and / or mortise contacts (3.1, 3.2) with the plane that runs vertically to a flat area. 3. The connecting device according to claim 1 or 2, characterized in that the housing (2) forms a series of first grooves (2.1) and a series of second grooves (2.1), and that the contact elements (3) are arranged so that the first insulated conductor can contact the first contact with an insulation bias or a mortise contact that is inserted into the first groove, and the second insulated conductor can contact the second contact with an insulation bias or mortise contact that is inserted into the second groove. 4. The connecting device according to claim 1 or 2, characterized in that each contact element has at least one cutter (4, 5) for trimming the excess length of the conductor. 5. A connecting device according to claim 4, characterized in that each contact element has a first cutter (4) for trimming the excess length of the first conductor, and a second cutter (5) for trimming the excess length of the second conductor. 6. The connecting device according to claim 5, characterized in that the cutter for the contact element (4, 5) or at least one of the cutters (4, 5) for the contact element is made as a separate element. 7. The connecting device according to claim 6, characterized in that at least one cutter (4, 5), made in the form of a separate element, is flat and is parallel to the plane of the first contact element. 8. The connecting device according to claim 7, characterized in that the housing (2) and the cutter (4, 5), made in the form of a separate element, are formed and mutually arranged so that the conductor with which they come into contact does not contact cutter after trimming excess lengths. 9. The connecting device according to claim 1 or 2, characterized in that it contains covers (6, 7) for contacts that are installed after electrical installation. 10. The connecting device according to claim 9, characterized in that at least one cover includes a locking element (7.1) for fixing the cable in the form of a discharge device. 11. The connecting device according to claim 1 or 2, characterized in that the contact elements (3) includes latches (3.5) to prevent longitudinal movements of the contact elements (3) located in the housing (2). 12. The connecting device according to claim 1 or 2, characterized in that the first and second contacts with a bias of insulation, or mortise contacts (3.1, 3.2) are located so that the first and second conductors are guided on the sides of the housing, located opposite each other. 13. The connecting device according to item 12, characterized in that the contact elements are made flat and are located in a common plane. 14. The connecting device according to item 12, wherein the contact elements (3) are flat except for the possible elements made by extrusion and / or cutting from metal sheets. 15. The connecting device according to claim 1 or 2, characterized by the presence of electrically conductive shielding walls (32.1) located between the pairs of contact elements. 16. A connecting device according to claim 15, characterized in that the housing (31) includes grooves (31.1) into which shielding walls (31.1) can be inserted from the outside. 17. A connecting device according to claim 15 or 16, characterized in that the shielding walls (32.1) are formed on a single shielding element (32) and it is preferable that the shielding element (32) includes contacts (32.2) for grounding the shielding walls (32.1). 18. The connecting device according to claim 1 or 2, characterized in that the housing (2, 31) is made one-piece. 19. A connecting system, including a connecting device according to any one of the preceding paragraphs, wherein at least the second contact (3.2) of each contact element (3) is a contact with a bias of insulation, as well as a plug for connecting a cable containing at least , two conductors, characterized in that the plug includes plug contacts (52), which can directly contact with the second contacts (3.2). 20. The connecting system according to claim 19, characterized in that the plug contacts include a portion resembling a wire shape (52.1) in order to insert it between the cutters of the second contact (3.2).

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