DE3443069A1 - Electrical capacitor - Google Patents

Abstract

In the case of an end-contact electrical capacitor having at least two capacitor windings (6), the windings (6) are connected to one another without using solder, via the end-contact layers (8), by electrically conductive contact springs (1). The contact springs (1) are braced in the core hole (7) of the capacitor winding (6) by means of a mounting portion (2) and have a contact portion and spring portion (5). <IMAGE>

Description

Electric capacitor

The invention relates to an electrical capacitor, which consists of at least two electrically conductively interconnected end-contact capacitors ickeln, which are built into a housing.

Such capacitor structures, which result from the series connection of two or more capacitor coils exist, especially in the case of power capacitors used.

The electrical connection of the individual capacitor coils takes place in that the end contact layers are provided by electrical lines soldered on both sides or connecting plates are interconnected. The exposed first and last end contact layers are then connected to the connection elements.

To establish the electrical connection, an additional Work step required, whereby it must be ensured that "cold" solder joints be avoided. Such defective soldering points are namely under certain circumstances not discovered during the final test, but can only after many hours of operation appear, causing the capacitor to fail.

In addition, there are such electrical connecting lines only at one point of the end contact layers, so that the individual capacitor windings under certain circumstances "tilt" against each other, which makes installation in the housing more difficult and can affect the isolation.

The object of the invention is to provide a capacitor of the type mentioned at the beginning Specify the type in which the individual winding is electrically conductive with one another in a safe manner are connected, this connection being made in a simple manner and the risk of "tilting" is reduced.

This object is achieved according to the invention in that the individual Coils are connected to one another without soldering by electrically conductive contact springs.

The contact springs can preferably be arranged in the core hole.

According to a further development, the contact springs are designed in one piece, including, for example, the contact springs have frayed tabs that consist of a Fastening part arranged in the core hole and one bent over by approx. 90 ° Contact and spring components exist, with the contact and spring components of the tabs can be sharp-edged.

The advantages of the subject invention will be apparent from the following Embodiments explained in more detail.

The accompanying drawings show: FIG. 1 the basic structure a contact spring before installation, Fig. 2 a contact spring in the installed state, FIG. 3 shows an embodiment of the contact surface, FIG. 4 shows another embodiment a contact spring before installation and FIG. 5 shows the contact spring according to FIG State.

1 shows the basic structure of a contact spring 1 shown after installation. A strip of a suitable material is used for production, such as.

Spring steel used, with one part 2 as a fastening part and the other part 3 serves as a contact and spring portion. The fastening portion 2 is bent by approx. 900 compared to the contact and spring part 3.

The contact and spring portion 3 has individual, for example stamped Sections 4, whereby contact springs 5 are formed.

2 shows the installation of the contact spring 1 in a capacitor winding 6 shown schematically. The contact spring 1 is bent so that it is in the Core hole 7 of the winding 6 with the fastening portion 2 can be introduced. That The material of the contact spring 1 ensures that the installation is in a tensioned state takes place, whereby the contact spring 1 is sufficiently in the core hole 7 of the capacitor coil 6 is fastened until the capacitor structure is made up of several partial windings 6 will.

The contact and spring component 5 lies on the end contact surface 8 of the capacitor winding 6 and causes the electrical connection to the end contact surface of the next capacitor winding.

The dimensions of the contact spring 1 are preferably chosen so that that not only tolerances of the core hole 7 can be compensated, but that also capacitor windings of different diameters with different core hole diameters can be connected with contact springs of the same type.

The contact and spring portion 5 of the contact spring 1 preferably has a sharp-edged shape, so that by a "clawing" between the End contact surfaces a good electrical contact is made.

Another advantage is that due to the resilient part a tolerance compensation occurring due to shrinkage in the axial direction is taken over will. This is achieved in that the individual capacitor winding under one Tension pressure of e.g. approx.

300 N can be built into the housing, creating a sufficient tolerance is present, which is sufficient even with shrinkage in the axial direction electrical contact (and shake-proof installation) guaranteed. With the conventional Connection of the capacitor winding by soldered electrical lines or connecting plates it was necessary to arrange a tolerance compensation spring at the bottom of the housing, so that the capacitor is shake-proof even after shrinkage in the axial direction Housing was arranged.

In the fig; 3 is an example of the shape of the contact surfaces 5 shown in side view. The individual contact surfaces 5 are semicircular curved and in their center from below with one or more pierced holes provided, whereby sharp prongs 9 formed on the surface of the contact springs 5 will.

The sharp edges of the semicircular bends make the a good contact to the lower forehead contact layer is established in the tensioned state, while the sharp prongs 9 make electrical contact to the upper forehead contact layer cause.

In Fig. 4, the embodiment of a contact spring is shown, in which the fastening portion 10 is formed from bent contact portion tabs will.

The resilient contact portion 11 is "S" -shaped bent in the area, creating sharp edges that make good contact with the lower and upper Effect forehead contact layers.

In FIG. 5, the contact spring according to FIG. 4 is in the installed state shown in the core hole 13 of a capacitor winding 12.

5 claims 5 figures - blank page -

Claims (5)

Claims Electrical capacitor, which consists of at least two electrically conductively interconnected end-contact capacitor windings exists, which are built into a housing, d u r c h e k e n n -z e i c h n e t that the individual winding (6, 12) by electrically conductive contact springs (1) are connected to one another without soldering. 2. Electrical capacitor according to claim 1, d a -d u r c h g e k It is noted that the contact springs (1) are arranged in the core hole (7, 13) are. 3. Electrical capacitor according to claim 1 or 2, d a d u r c h it is noted that the contact springs (1) are integrally formed. 4. Electrical capacitor according to claim 4, d a -d u r c h g e k It is noted that the contact springs have punched-out tabs that a fastening part (10) arranged in the core hole (13) and one against it about 900 bent contact and spring parts (11) exist. 5. Electrical capacitor according to claim 4, d a -d u r c h g e k It is noted that the contact and spring portion of the tabs (5, 11) are sharp-edged is trained.