CH134768A - Electric capacitor. - Google Patents

Description

  

  Electric capacitor. Electrical capacitors, which consist of electrical layers and interposed metal foils, must be kept under mechanical pressure to keep the capacitance constant and the losses low, so that intimate contact between the dielectric and metal coating remains.



  In the known versions of these capacitors, such as those in particular for telephone systems who are often used, the capacitor core produced by winding paper with interposed metal strips is occupied in a pressed state in a tin can and caulked in this by wedges of insulating materials.



  The relatively thin walls as well as the inserts made of insulating material, for example pressboard, are subjected to bending stress by the pressed capacitor core and are therefore often bulged out, or a strong pressure on the capacitor core must be dispensed with, which is to comply with the above-mentioned requirements requirements is disadvantageous.



  The invention consists in the fact that the required pressure is permanently retained by the force of one or more tensioned springs and the reaction forces absorbed by the spring or springs are transmitted through the same to the can walls so that the latter is essentially only mechanically through tensile forces be claimed.



  In Fig. 1 and <B> 2 </B> an embodiment of the capacitor according to the invention is provided in longitudinal section and in cross section.



  It means: 7c made of paper strips with capacitor cores wound between placed metal strips, d1, d'1, dz and d'2 the side walls of the thin-walled metal can, e deci tightly closing cover with connection lugs <I> 1, i </I> insulation inserts. The pressure on the capacitor cores is transmitted by two pre-bent leaf springs f, which face the concave side against the can walls d2 and d'2.



  The two springs f transmit the pressure to the four corners of the tin can, the side walls d2 and d'2 of which absorb the force in the form of tensile stress.



  In Fig. 3 an embodiment is shown in which the capacitor core is pressed from all four sides and four leaf springs f are used to transfer the pressure to the can walls :.



  In Fig. 4 and 5, the type of power transmission to the can walls is explained. In Fig. 4, the spring f lies freely in the immediate vicinity of the edge o on the wall dl with a small distance from the walls on d2 and d'2. In this case, the spring f is only subjected to bending stress and the reaction
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   is transmitted with practically sufficient accuracy to the edge o and in the form of a tensile force <B> A </B> on the walls d2 and d'2.



  In Fig. 5, the pretensioned spring f is pressed into the box so that it is at the edge o on both dl and d2, respectively. d'2 rests. In this case, the force component b 'transmitted from the spring f to the corners o is recorded by a tensile force c extending in the sheet metal wall d1. This counteracts any change in the deflection of the spring f.



  The design of the capacitor is not limited to the use of leaf springs alone, but any other spring types can be used; In addition, the pressing forces can be transmitted to the can edges using rigid intermediate links.

 

Claims (1)

PATENT CLAIM: An electrical capacitor with at least one core of dielectric and conductive layers under mechanical pressure, which is inserted into a thin-walled box, characterized in that the pressure on the core is continuously maintained by the tension force of at least one tensioned spring remains and that the reaction forces absorbed by the spring are transmitted by the same to the can walls that the latter are mechanically essentially only subjected to tensile stresses. <B> SUBClaims </B> 1. Electrical capacitor according to patent claim, characterized in that the springs for transmitting the pressing force are designed as leaf springs which are inserted into the can with pre-bending so that the edges of the springs resting on the can walls exert the pressure on the edges of the Transfer cans. 22 Electrical capacitor according to claim and dependent claim 1, characterized in that the leaf springs, which transmit the pressure, are pressed into the can in such a way that the tensile forces in the can walls make it difficult to change the deflection of the springs.