CS256465B1 - Bar and contacts - Google Patents

Abstract

The solution concerns the area of contact strips with mechanically and electrically independent pairs of contact springs, serving^ for independent transmission of two electrical signals from individual output pins of electrical components. The said design solution of the strip with contacts is suitable for use in electronic devices intended for measuring the transmission resistances of internal contact connections of electrotechnical components, which are equipped with suitable output pins outside their contours. The essence of the solution is the placement of pairs of flexible, flat contact springs in the support strip so that the directions of springing of their flexible arms are always mutually perpendicular in the said pair. The contact surfaces, located at the ends of the flexible arms of the contact springs lie above each other, while the contact surface of the upper spring is turned by a certain angle to the side surface of its flexible arm, which is necessary for the sliding of the output pin. However, the contact surface of the lower spring lies in the plane of the upper surface of its flexible arm.

Description

CAT JAROSLAV, PARDUBICE

Toolbar and contacts

The present invention relates to the field of contact strips with mechanically and electrically independent pairs of contact springs for the independent conversion of dual electrical signals from individual terminals of electrical components. Said construction of the contact bar is suitable for use in electronic devices intended for measuring the transmission resistance of the internal contact joints of electrical components, which are equipped with suitable outlet pins outside their contours. The essence of the solution is to place pairs of flexible, flat contact springs in the support rail so that the directions of spring of their flexible arms are always perpendicular to each other in said pair. The contact surfaces located at the ends of the flexible legs of the contact springs lie one above the other, the contact surface of the upper tongue being turned at an angle to the lateral surface of its flexible arm which is necessary to slide the outlet pin. However, the contact surface of the lower tongue lies in the plane of the upper surface of its flexible arm.

256 465 (11) (B1) (51) Int. Cfí ^J

H Ol R 13/26

256 465

The invention relates to a contact rail design with built-in mechanically and electrically independent pairs of contact springs for independent double conversion of electrical signals from individual terminal pins of electrical assemblies.

Different types of contact strips carrying contact springs serve to measure the internal contact resistances of the contact fields with the corresponding contacts in the different types of electrical components which are led outside the contour of the outlet pins. Measured components, mainly switching devices, usually have outlet pins designed to be oriented in one or more directions and are mechanically rigid. When measuring the internal transition resistances of the contact fields with the corresponding contacts housed within said components, electrical signals must be transferred from the corresponding outlet pins to the measuring devices.

For coarser or orientation measurements, it is sufficient to carry out the transmission with one or more but interconnected contacts on one output pin.

For accurate measurements of small transient resistance values, at least two but independent, non-conductive contacts must be assigned to one pin.

In known embodiments of contact strips for this purpose, the outlet pins are clamped between two independent contact springs with recesses for insertion. However, they have a sufficiently long construction length in the insertion direction and are connected in a conductive state in a quiescent state. A similar solution where in the quiescent state the transfer contacts intended for one outlet pin are not connected is one where the contacts are placed one after the other. At rest, however

2S6 465 both rest on an insulating pad between which the outlet pin is inserted between the contacts. The solution is characterized by an even longer construction length and worse operational reliability due to possible contamination on the contacts. A disadvantage is the precise positioning of the outlet pins for reliable insertion between the collecting contacts.

Another solution used is an infeed bar with collecting contacts, located in pairs, always to the respective outlet pin. The contacts are generally in the form of a wire and are pushed together with the bar to the outlet pins, which must, however, be very rigid for this purpose in order to prevent their deformation. The infeed mechanism itself is very complex and demanding on the precise execution of the individual parts from which it is assembled.

Similar disadvantages, but to an even greater extent, are seen with the contact bar with the contacts that are pushed to the outlet pin from two opposing directions. Here, the possible deformations of the outlet pins are reduced to a minimum, but the device for feeding the contact strips is even more complicated, which is disadvantageous.

The above-mentioned disadvantages are overcome by the solution according to the invention, characterized in that at least one pair of resilient flat contact tongues is arranged in the support body such that the contact surface of the lower tongue is identical or parallel to the upper surface of its flexible surface. and at the same time perpendicular to the lateral surface of the flexible tongue of the upper tongue, provided with a shear surface located above the contact surface of the lower tongue inclined with respect to the lateral surface of the upper tongue arm by an angle of rotation of 20 ° to 60 °; the contact edge lies above the contact surface located at the end of the flexible arm of the lower tongue, similar to the shear surface at the end of the flexible arm of the upper tongue.

A great advantage of the solution according to the invention is its relative simplicity. The installation height is minimal, which is important from the point of view of the operation of the contact strip according to the invention in the case of electrical components equipped with only relatively short outlets.

256 465 pins. The contact springs are arranged as larger flat elements springing in two mutually perpendicular directions. This allows good contact even when the outlet pins do not have a precisely defined position, which is advantageous. Another advantage is that the tongues are not conductively connected in the rest position. The contact of the outlet pin with the contact lips is perfect. The contact springs only minimally stress the output pins, which can therefore be less rigid mechanically. The solution also enables the measurement of such components which have the control elements formed in the direction of the output pins. By making the contact pen of the pair flat as the front contact on the pin, it helps to eject the part from the fixture after the measurement has been completed and the measured component is released in the fixture. This appears to be a considerable handling advantage.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be explained in detail with reference to the accompanying drawings, in which: FIG. 1 is an axonometric representation of a contact strip in a rest position; FIG. 2 also shows in axonometric representation the functional elements of a contact strip in a working position; 4 is a side view and FIG. 5 is a plan view of the contact bar in the rest position, FIG. 6 is a front view, FIG. 7 is a side view, and FIG.

The contact strip of FIG. 1 consists of at least one pair of resilient, mutually insulated, flat contact springs which are firmly engaged in a support body in the form of a single or more articulated prism. In the lower part of the body, the lower tongue 2 is anchored so that the upper surface 22 of its flexible arm 21 is most often parallel to the mounting surface 11 of the body J. In the upper part of the body is fixed the upper tongue 2, whose flexible arm 31 carries the sliding surface 33. The lateral surface 32 of the flexible arm 31 is perpendicular to the upper surface 22 of the flexible arm 21 of the lower tongue 2. the angle of rotation θ well seen in Fig. 3.

The shear surface 33 is limited on the underside of the contact surface

256, 465, and lies above the contact surface 23 as shown in FIG.

and 5. It can be clearly seen from the drawings that the shear surface 33 of the upper tongue J is located at the end of the flexible arm 31 as well as the contact surface 23 of the lower tongue 2 at the end of the flexible arm 21.

At the opposite ends of the contact springs, a soldering tip 35 of the upper tongue 2 ^{and a} soldering tip 25 of the lower tongue 2 are formed.

The contact surface 23 of the lower tongue 2 serves for the conversion of electrical signals as well as the contact edge 34 of the upper tongue J. The electrical signals from the face 41 of the outlet pin 4 of the measured component are transferred by the contact surface 23 to the soldering tip 2 $ of the lower tongue 2. the electrical signals from the flank 42 of the workpiece lead 4 are transferred by the contact edge over the flexible arm 31 to the soldering tip 35 of the upper tongue 11. This is particularly evident from Figures 7 and 8.

From these figures, as well as the axonometric view of FIG. 2, the bending of the flexible arm 31 of the upper tongue 2 as well as the elastic deformation of the flexible arm 21 of the lower tongue 2 after insertion of the lead pin 4 of the measured component are visible. In this case, the flexible arm 31 of the upper tongue 3 performs a movement whose direction is perpendicular to the direction of movement of the flexible arm 21 of the lower tongue 2. FIG. 6 and 7 show a front view of the bar with the deflected flexible arm 31 of the upper tongue 2 and the deflected flexible arm 21 of the lower tongue 2 by sliding the outlet pin 4, respectively.

The advancing pin 4 of the measuring component slides over its sliding surface 33 by its face 41. As it is firmly fixed in the measuring component and is guided firmly, it deflects its flexible arm 31 by progressively sliding along the sliding surface 33 of the upper tongue. The contact pin 34 is supported by its face 41 against the contact surface 23 of the lower tongue 2, deflecting its flexible arm 21. The elasticity of the flexible arm 21 of the lower tongue 2 and the flexible leg 31 of the upper tongue J maintains a constant contact of the contact surface 23 of the lower tongue 2 with the face 41

256 465 of the outlet pin 4 similar to the contact edge 34 of the upper tongue 3 with the side 42 of the outlet pin 4.

The contact strip according to the invention is suitable for use in electronic devices intended for measuring the transient resistance of internal contacts of various kinds of electrical components provided with outlet pins, but is particularly suitable for accurately measuring very small transient internal contact resistances of miniature rotary switches provided with short and thin outlet terminals. pins oriented in the direction of the shaft control or in the opposite direction.

Claims (1)

SUBJECT OF THE INVENTION The contact strip is characterized in that at least one pair of resilient * flat contact springs (2, 3) is disposed in the support body (1), the contact surface (23) of the lower spring (2) being identical or parallel with the upper surface (22) of its flexible arm (21) and at the same time perpendicular to the side surface (32) of the flexible arm (31) of the upper tongue (3), provided with a shear surface (33) disposed above the contact surface (23) of the lower tongue inclined with respect to the side surface (32) of the flexible arm (31) of the upper tongue (3) by an angle of rotation (from) in the range of 20 ° to 60 °, the shear surface (33) terminating at the bottom with the contact edge (34) above the contact surface (23), the lip at the end of the flexible arm (21) of the lower tongue (2), similar to the shear surface (33) at the end of the flexible arm (31) of the upper tongue (3).