RU2490764C2 - Electric contact element - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: contact element for electric current transfer consists of a connecting terminal (10) and contact area (51) located opposite each other and in the centre of the base (50). Within the contact area (51) there are two functionally independent contact points (52, 53); each of them is equipped with a diverted form the base (50) pair (58, 59, 60, 61) of spring levers forming a socket (62, 65) for installation of a contact stud (32, 33, 54).

EFFECT: forming a contact element that ensures reliable and easy to mount contact for elements.

19 cl, 8 dwg

Description

The invention relates to a contact element according to the generic concept of claim 1.

Sockets with socket contact elements for installing the contact pins of the instrument plugs are known in the field of household wiring equipment and are used for initial equipment, as well as for subsequent retrofitting. It is often important to be able to functionally equip this kind of wiring device. For this reason, it turned out to be preferable to create appropriate nodes, which, if necessary, can be mounted additionally on an existing installation device.

In the prior art, for example from EP 0 281 969 B1, a wiring device is known in which the device plug is inserted from the front side by plug-in connection into the corresponding contact elements, while an optional assembly can be located on the rear side. The disadvantage in this case is that the electrical contacting of the rear module is carried out by one-piece connection with the contact elements in the installation device. Such systems and methods involve increased installation costs and are not particularly practical.

Therefore, the objective of the present invention is to eliminate the above disadvantages and create a contact element that will provide reliable and easy to install contacting of at least two elements.

This problem is solved using the characteristics indicated in paragraph 1 of the claims. Preferred embodiments follow from the dependent points.

The invention according to claim 1 has the advantage that detachable contacting is provided for a device plug and another node, while mechanically and functionally independent contact points are made in one integral contact area of the contact element. The contact element consists of a connecting area for connecting the supply wires and, on the contrary, from a solid contact area for at least two elements.

The mechanical processes during the insertion of the corresponding contact pins are not transferred from one contact point to another contact point, so that the clamping forces are not subjected to variable influences, and continuous and at the same time reliable contact is ensured. The forces and movements acting on the sockets during insertion are perceived independently by spring levers, so that when inserting different nodes into the same contact element, the connection properties, such as clamping forces or contact forces, which are important in cases of detachable contacting, are not affected. . This kind of preferred effect is ensured by pairs of spring levers made separately from the common base on the contact element, each pair of spring levers forming a receptacle for the contact pin. In this case, a pair of spring levers depart from the base parallel to each other and are separated from each other by a slot.

Due to the different design of the pairs of spring levers and the different positioning of the respective sockets, insertion positions for two parallelly inserted elements, for example, an instrument plug and a module, are provided. Thus, conventional and practical insertion from the front and / or from the back is still possible.

The spring shelves located opposite each other depart from the base, which are divided into two pairs of spring levers. The upper spring levers are bent back inward and form a socket for a contact pin. The height of the spring levers increases on both sides to the bend and again decreases in the direction of the socket on one side. Due to this, the nest acquires its own strength, and mechanical loads are perceived mainly by a thickened bend, and are not transmitted to the base. The lower spring levers protrude in front of the upper spring levers and, in longitudinal length, have a shape that gradually bends inward and closes with each other directly in front of the socket ending on the front side. The height of the spring arms does not change.

The different versions of the pairs of spring levers allows different clamping forces in the respective sockets. Since decreasing clamping forces can be realized by increasing the length of the pairs of spring levers, contact pins of a larger circumferential dimension are inserted into the shorter spring levers, while thin contact pins, with a lower clamping force, are inserted into the longer spring levers .

Conical versions of the sockets facilitate insertion. In addition, the upper region of the socket of the upper pair of spring levers is not attached to the spring levers, so that the insertion of the contact pin is even more facilitated. The contact pin expands the socket first only at the top and then slides along the formed inclined surface, continuing to expand it into the socket. When the contact pin is removed, a twisting effect is also triggered, so that at the end the contact pin or plug is “ejected”. In addition, when a pulling force is applied, even before the limit of sliding friction is reached, the socket undergoes some elastic deformation. Due to this, the balance of forces inside the socket changes, and the plug is easily disconnected.

Additional stiffening and protection against excessive expansion of the socket and spring levers is carried out by positioning the contact element with a geometric circuit in the respective chambers of the base of the device.

The contact element proposed by the invention makes it possible to obtain an installation device of universal application, which, if necessary, can be equipped with an appropriate modular assembly, while still allowing easy assembly and disassembly. Preferably, when the assembly is mechanically mounted, it is simultaneously electrically contacted. Certain connection work, such as, for example, soldering, is not performed. The contact element is suitable for contact pins that can be inserted from both the front and / or the back.

Modules can perform a variety of functions and are functionally closed nodes, so that on the basis of the device does not require any changes. In particular, there are modules that are used depending on the purpose, for example, surge protection modules, indication and lighting modules or mechanical function modules. In addition, the input mains voltage in the modules can be converted to any lower voltage or other type of energy. Along with conventional installation techniques, bus technology is also possible here. Along with wired, wireless components are also possible here, for example, for transmitting data via radio or infrared signals. Modules include, in particular, optical, mechanical and / or electrical components.

A particularly preferred arrangement of structural elements makes it possible to create a receiving space for an optional unit within the existing base structure of the device. In a preferred embodiment, the receiving space is geometrically closed in the form of a modular housing and therefore is compact. No extra space is required in front of or behind the base of the device to position the module. The module can be mounted on the front side and integrated flush into the base of the device. It is significant at the same time that to equip the installation device it is only necessary to remove the special functional frontal element so that the module can be inserted or, accordingly, replaced. Dismantling the base of the device or the supporting frame from the stationary installation case is not required, so that a significant advantage during installation is provided. Usually, the existing base structure of devices, in particular, their dimensions and their mounting and contact points, remain unchanged. Thus, it is possible, for example, to continue to use special functional frontal elements within one series of products when replacing an existing installation device.

One possible embodiment of a wiring device is a power outlet with an optional surge protection module.

Other details, features and advantages of the invention follow from the following description of one of the preferred embodiments using the drawings.

Shown:

Figure 1 is a perspective view of the contact element.

Figure 2 is a top view of the contact element.

Figure 3 is a perspective view of an installation device with a frontal element and a coating.

Figure 4 is a perspective view of the module.

5 is a perspective view of the installation device and the module before installation.

Fig.6 is a perspective view of the installation device shown in Fig.5, without a disconnecting element.

Fig.7 is an enlarged view of Fig.6.

Fig. 8 is an enlarged view of Fig. 7 with inserted contact pins.

The same or performing the same function structural elements are provided in the following description with the same reference position.

The design of the contact element of the invention is described in more detail using FIGS. 1 and 2.

The contact element 8 consists, for example, of a multiple-machined, preferably bending, copper sheet, and has a box-like basic structure. From the centrally located base 50, a connecting terminal 10 for connecting the power wires and an integral contact area 51 with separated contact places 52 and 53 for the various contact pins 32, 33 and 54 of the preferably not shown instrument plug and module 2 extend in opposite directions. In the contact area 51 depart from the base 50 located opposite each other slightly inclined inside the shelves 55 and 56 of the spring, which as a whole go into separated by the slot 57 of the upper pair of spring levers 58, 59 and the lower pair of spring levers 60, 61. The choice of sizes of the upper spring levers 58 and 59 and the lower spring levers 60 and 61 is made with the expectation of mechanical loads of the contact pins 32, 33 and 54 of different thicknesses.

The upper spring levers 58 and 59 extend respectively at first, continuing the shelves 55 and 56 of the spring, then slightly inclined, and then bent almost 180 degrees inward, and form a socket 62. At the upper end, the socket 62 has an outwardly bent flange 63 to facilitate insertion of the contact the pin 54. The height H1 of the spring arms 58 and 59 increases, starting from the shelves 55 and 56 of the springs, up evenly in the direction of the fold location 64 to the maximum, and again decreases in the direction of the seat 62 to the original height. Due to this, the contact point 52 acquires its own strength, and mechanical stresses are perceived mainly by the thickened bending place 64, and are not transferred to the base 50. The contact place 52 is preferably designed to be fitted with a clamp pin contact pins 54 from 4 to 5 mm in size, for example, an instrument plug .

The lower pair of spring levers 60, 61 protrudes in longitudinal length in front of the upper pair of spring levers 58, 59. The spring levers 60 and 61 respectively have a shape that gradually bends inward and closes with each other directly in front of the socket 65 ending on the front side. The height H2 of the spring levers 60 and 61 does not change and does not exceed the height H1 of the upper spring arms 58 and 59. The socket 65 is preferably designed to be fitted with a clamp of the contact pins 32, 33 of a size of 1 mm, due to the slight expansion of the socket 65, and Also, the length and height H2 of the spring arms 60, 61 form a self-supporting contact point 53, which does not transmit forces to the base 50.

Below, as an example, an electrical installation device 1 is shown in the form of a socket, which is equipped with the contact elements 8, 9 of the invention. The installation device 1 is equipped on one side with an optional module 2 for surge protection, and on the other hand with a device plug.

The installation device 1 includes a base 3 of the device, which is usually round and block and is made of insulating materials. The base 3 of the device externally encloses an annular support frame 4, which is preferably fixed in place. The carrier frame 4 is made of either metallic or non-metallic materials, preferably a polymeric material. In the radial direction, on the contrary, on the base 3 of the device or on the supporting frame 4, claw-shaped fastening means not shown in detail are provided, which enable mounting device 1 to be mounted in a stationary installation case not shown. Preferably, the base 3 of the device and the supporting frame 4 form a mounting unit. On the front side, a special functional frontal element 5 is fixed, which, depending on the purpose, may consist of one or more parts (figure 3)

At the base 3 of the device, under the so-called disconnecting elements 6 and 7, there are metal contact elements 8 and 9 into which the plug pins of the device plug not shown are inserted from the front side and which are connected to the supply wires through the connecting terminals 10 and 11 from the rear side. In addition, in the base 3 of the device there is a repeatedly bent grounding bracket 12, which serves for frontal contacting the grounding contact of the instrument plug and for the rear connection of the grounding wire to the connecting terminal 13.

Both contact elements 8 and 9 are fixed in the center of the base 3 of the device in correspondingly shaped chambers 14 and 15. The connecting terminals 10, 11 are arranged in a standard manner in the connecting region 16 of the base 3 of the device. On the radially opposite side, inside the solid base 3 of the device, a radial outer wall 17 and a straight inner wall 18 are formed with a cylindrical receiving space 19, which has a base surface 20 in the form of a circular segment formed by the rear bottom panel 21 (FIGS. 5 and 6)

According to figure 3, in an unfinished state, the removable cover 22 covers this receiving space 19, while the coating 22 is flush with the disconnecting elements 6 and 7. On the bottom panel 21 inside the receiving space 19 are locking protrusions 23, which serve to fix the module 2. In the receiving space 19 along the bottom are chambers 14 and 15 of the contact elements 8 and 9. The grounding bracket 12 is located between two contact elements 8 and 9 and passes first along the bottom, and then bent perpendicularly along the outer wall 17 to the receiving space 19. In this receiving space 19 can be inserted with a geometric circuit module 2.

According to figure 4, the module 2 is made of insulating material and has a cylindrical spatial shape starting from the surface 24 of the base in the form of a circular segment, from which the straight wall 25 and the bent wall 26, which are closed by a cover 27, depart. On the walls 25 and 26, various recesses , slots and protrusions. In module 2, various structural elements are located, for example, varistors 28, gas outlets, a printed circuit board, resistances, photocells and contact elements. Due to this, it is possible, for example, to obtain a surge protection assembly.

On the surface 24 of the base of the module 2 there are free spaces 30 and 31 in which the protected contact pins 32 and 33 of the module 2 are held, which have the ability to electrical contact with the contact elements 8 and 9 of the base 3 of the device. Between the free spaces 30 and 31, a groove 34 is made, into which a contact pin 35 is inserted, which contacts the grounding bracket 12 passing through the base 3 of the device. In addition, there is a through hole 36 in the module 2, so that it is also possible to implement a socket outlet with a grounding pin, while the location and contacting of the pin pin 35 remains the same. Inside the groove 34 there are recesses 37 for engaging in a fixed engagement with the locking tabs 23 of the bottom panel 21.

On the upper side of the module 2, preferably on the cover 27, extensions 38 are made that facilitate the insertion and, if necessary, removal of the module 2. In addition, a pin-shaped protrusion 39 is located on the edges of the module 2 for purposefully directing the optical signals from the module 2 to the indication elements located in the frontal element 5. For this, at least the protrusion 39 is made of light-conducting material, such as for example PX or PMMA. The photocell in the form of an LED 40 is located in the recess 41.

The following briefly describes the installation or operation of the installation device 1.

The basic version of the installation device 1 consists of a device 3 equipped with contact elements 8 and 9 and a grounding bracket 12 and a carrier frame 4 mounted thereon. The receiving space 19 is covered by a coating 22, and there is no module 2 in it. This kind of assembly in a socket for concealed wiring is usually connected by means of connecting terminals 10, 11, 13 and is fixed with claw-shaped fastening means. In conclusion, the frontal element 5 is attached.

If necessary, the wiring device 1 is retrofitted, for example, to integrate surge protection. For this, the front element 5 and then the coating 22 of the base 3 of the device is removed. Due to the geometrical closure, the module 2 can linearly skew linearly against the stop into the receiving space 19, which has the shape of a circular segment. Automatically, it undergoes both mechanical fixation and electrical contact, without the need to dismantle the installation device 1 or additional connection work. On the front side, module 2 after installation is flush with the disconnecting elements 6 and 7. Only extensions 38 extend forward, but end with the supporting frame 4.

During installation, the locking protrusions 23 protruding from the bottom panel 21 of the receiving space 19 are fixed in the recesses 37 of the module 2. The contact pins 32 and 33 slide through the geometric locking of the chambers 14 and 15 and the free spaces 30 and 31 into the contact elements 8 and 9. Contact the pin 35 slides into the socket 45 in the grounding bracket 12, while the grounding bracket 12 is enclosed in a groove 34.

Figures 7 and 8 show the contacting of each of the contact pins 32, 54 of module 2 and the not shown instrument plug on an enlarged scale. Both module 2 and the instrument plug are inserted from the front side and parallel to each other. The contact pin 32 of the module 2 is inserted at the contact point 53 of the contact element 8 into the socket 65 of the lower pair of spring levers 60, 61, while the geometric closure between the module 2 and the receiving space 19 provides sufficient centering, so that the contact pin 32 can be inserted without centering. In this case, the contact pin 32 expands the socket 65 and slides in until it is in its final position. In the final position, the spring arms 60 and 61 are slightly widened and enclose, pinching, the contact pin 32. In this case, the spring arms 60 and 61 touch the chamber 14 and increase the contact pressure.

The contact pin 54 of the instrument plug is inserted at the point 52 of the contact of the contact element 8 into the socket 62 of the upper pair of spring levers 58, 59, first centering in the flange 63 of the socket 62. Then the contact pin 54 expands the socket 62 at the top and then slides along the formed inclined surface spring levers 58, 59, continuing to expand it into the socket 62, until it is in its final position. In the final position, the spring levers 58 and 59 are slightly expanded and enclose, pinching, the contact pin 54, while the sufficiently high contact pressure due to the short spring levers 58 and 59 ensures reliable contact of the contact pin 54. The contact of the pin 32 of module 2 in the contact element 8 occurs when contacting the pin pin 54 of the instrument plug in the same contact element 8 due to the separation of the places 52 and 53 of the contact without mechanical variable loads.

When the instrument plug is removed, the described twisting effect is also triggered, so that at the end the instrument plug is “thrown out”. In addition, when a pulling force is applied even before reaching the sliding friction limit, the socket 62 undergoes some elastic deformation. Due to this, the balance of forces inside the socket 62 is changed, and the instrument plug is easily disconnected.

The above description of an exemplary embodiment is for illustrative purposes only and not to limit the invention. Within the scope of the invention, various changes and modifications are possible without departing from the scope of the invention, as well as its equivalents.

List of Reference Items

1 Installation device

2 Module

3 Device base

4 Support frame

5 Front element

6 Release element

7 Breakaway element

8 contact element

9 Contact element

10 Connection terminal

11 Connection terminal

12 Earthing bracket

13 Connection terminal

14 Camera

15 Camera

16 Connecting area

17 Outer wall

18 Inner wall

19 Reception space

20 Base surface 19

21 Bottom panel

22 Coating

23 locking tab

24 Module base surface

25 Walls

26 Walls

27 Cover

28 Varistor

30 free space

31 free space

32 pin pin

33 pin

34 groove

35 pin

36 through hole

37 notch

38 Continued

39 Projection

40 LED

41 Depth

45 socket

50 Base

51 Contact area

52 point of contact

53 Place of contact

54 pin

55 Spring shelf

56 Spring Shelf

57 Schlitz

58 spring lever

59 spring lever

60 spring lever

61 spring lever

62 socket

63 flange

64 Bend

65 socket

H1 Height

H2 Height

Claims (19)

1. A contact element for transmitting electric current, consisting of a connecting terminal (10) and a contact region (51) located opposite each other on a centrally located base (50), and in the contact region (51) there are two functionally independent places ( 52, 53) of the contact, each of which is equipped with a pair of spring levers (58, 59, 60, 61) extending from the base (50), which forms a socket (62, 65) for installing the contact pin (32, 33, 54). 2. The contact element according to claim 1, characterized in that the contact region (51) is made integral. 3. The contact element according to claim 1, characterized in that the pairs (58, 59, 60, 61) of spring levers are directed parallel to each other and are separated by a slot (57). 4. The contact element according to claim 1, characterized in that the sockets (62, 65) are oriented parallel to each other. 5. The contact element according to claim 1, characterized in that mutually different contact pressure is created in the sockets (62, 65). 6. The contact element according to claim 1, characterized in that the nests (62, 65) are at different distances from the base (50). 7. The contact element according to claim 1, characterized in that the diameter of the nests (62, 65) is different. 8. The contact element according to claim 1, characterized in that at least one socket (62) is provided with an expanded flange (63). 9. The contact element according to claim 1, characterized in that the spring levers (58, 59) of the pair of spring levers are bent back and forth. 10. The contact element according to claim 1, characterized in that the height (H1) of the pair of spring levers (58, 59) increases from the base (50) and decreases in the direction of the socket (62). 11. The contact element according to claim 1, characterized in that the spring levers (58, 59) are made conically expandable. 12. The contact element according to claim 1, characterized in that the spring levers (60, 61) of the pair of spring levers have a shape gradually bending inward. 13. The contact element according to claim 1, characterized in that the height (H2) of the pair of spring levers (60, 61) does not change. 14. Wiring device (1), consisting of the base (3) of the device, from the supporting frame (4) fixed to the base (3) of the device, from the device of the special functional front element (5), fixed on the front side of the base (3), and from the fixed on the basis of (3) the device of the module (2), while in the base (3) of the device are contact elements (8, 9) according to one of claims 1 to 13. 15. The wiring device according to claim 14, characterized in that the base (3) of the device has a receiving space (19) for the module (2) inserted with a geometric circuit. 16. The wiring device according to claim 14, characterized in that the module (2) is flush in the base (3) of the device from the front side. 17. Wiring device according to 14, characterized in that the receiving space (19) and the module (2) have a cylindrical shape and, accordingly, the base surface in the form of a circular segment. 18. Wiring device according to claim 14, characterized in that during the mechanical positioning of the module (2) in the receiving space (19), automatic electrical contacting occurs. 19. The wiring device according to claim 14, characterized in that the wiring device (1) is made in the form of an electrical outlet, equipped with an overvoltage protection module.

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