DE3340094A1 - Electrical measuring instrument - Google Patents

Abstract

An electrical soft-iron instrument having a body which is arranged in a stationary manner in a field coil and consists of ferromagnetic material. The two parts are constructed as stamped-bending parts which are produced from a strip material which is at least partially bimetallic, consisting of ferromagnetic and non-ferromagnetic material. The holders for the rotating bearing can be integrally formed on the body which is arranged in a stationary manner, said holders consisting of surface-hardened moulded glass. The measurement mechanism pointer and an attachment arm for the spiral spring can be integrally formed on the body which is arranged in a moving manner. The parts are initially partially stamped-free from a strip which is partially constructed as a bimetallic element, are thereafter subjected to further bending and welding processes and are finally completely stamped out. In this way, the parts can be manufactured completely automatically.

Description

Electric meter

The invention relates to an electrical measuring instrument, t ment with a field coil, a fixedly arranged body within the coil ferromagnetic material and one movably arranged within the coil, body made of ferromagnetic material connected to a pointer.

In these known measuring instruments, the field of the coil magnetized the two ferromagnetic bodies so that they are one on top of the other exert a repulsive or attractive force. This makes the moving ferromagnetic Body deflected in relation to the fixed ferromagnetic body. The deflection is made by a pointer connected to the flexible ferromagnetic body displayed, the pointer deflection being a measure of the amount flowing through the field coil Electricity is. The restoring force for the moving body made of ferromagnetic material is generated by a spring. Such instruments are commonly called soft iron instruments because the two ferromagnetic bodies are usually made of soft iron exist.

The remaining parts of the measuring mechanism of such a measuring instrument exist usually made of non-ferromagnetic material in order to interfere with the moving Avoid body made of ferromagnetic material acting field.

So far, the measuring mechanisms for such measuring instruments were made up of several Individual parts made from different materials and assembled. Of the Structure and arrangement of the individual parts of these well-known soft iron instruments however, it is not suitable for mass production.

The object of the invention is to provide such a measuring instrument from a few and easily manufacturable parts to be designed so that it is suitable for mass production suitable. Another object of the present invention is to provide a method for mass production to indicate such measuring instruments.

The task is given by those mentioned in the characterizing part of claim 1 Measures resolved. One method of making such an instrument is in Claim 11 stated.

Appropriate further developments of the measuring instrument or the method can be found in the subclaims.

According to the invention, a simple and suitable for mass production Suitable construction of an electrical measuring instrument of the type mentioned at the beginning achieved in that both the fixed and the movable part as stamped and bent parts are formed, which consist of a bimetal strip, which is partially made of ferromagnetic and partly made of non-ferromagnetic material.

The parts are made from a band, which is partly a bimetallic band is trained. Such a tape consists of two layers, namely one Layer of non-ferromagnetic material and a layer of ferromagnetic Material, for example, by rolling two strips of the corresponding Material were made in the manner of the known bimetal. This has the advantage that only a single strip of material is required for production is preferred the band is only partially designed as a bimetallic band, d. that is, preferably the ferromagnetic material over the entire length of the belt, but not over the the entire width of the belt. This ensures that the ferromagnetic Material is only available where it is needed.

By using a partially designed as a bimetallic band Band is further achieved that the ferromagnetic material with a base is made of non-ferromagnetic material, whereby the ferromagnetic material A greater mechanical stability is obtained and the whole band can be worked equally well is. It is known that ferromagnetic material, such as. B. soft iron, essential inferior mechanical properties than non-ferromagnetic material, e.g. B. Brass.

The tape from which the two parts are made is for example made of brass and on part of its width additionally made of soft iron or one Iron-nickel alloy. The two metals are preferably combined with one another in such a way that that the tape both where it comes from non- ferromagnetic material consists, as well as where it consists of two layers of ferromagnetic and non-ferromagnetic Material is the same thickness. Depending on your needs, the layer can be made of ferromagnetic Material occupy one half of the band or the middle of the band.

From such a tape, simple processing operations can be used to such as B. punching and bending, produce parts that are made of both bimetal and consist of non-ferromagnetic material. Therefore parts / the so far from separate items were made to be molded onto the two bodies. For example, the brackets for the pivot bearings can be fixed to the Body be integrally formed while, for example, the measuring tool on the movable Body is molded. A fastening arm can also be attached to the movably arranged body be molded for a spiral spring and a rotating shaft can be attached in a simple manner be welded to the movably arranged body, since this is only partially consists of ferromagnetic material.

A torsion band can also be welded to the movable body that takes over the function of the rotating shaft as well as the return spring.

A further simplification and cheaper results from the fact that Bearing blocks are used as pivot bearings, which are made of surface-hardened pressed glass exist.

In manufacture, the parts for the measuring instrument are preferred initially only partially from the tape punched free, and then in completely punched out in a further punching process. This two-step punching process has the great advantage that further processing operations between the two punching operations can be made in which the partially punched parts are still with are connected to the tape, so that these process steps can be mechanized very well permit. For example, bending processes can be carried out between the two punching processes or parts can be injected or welded on These processes can easily be carried out with automatic machines, since the parts are still connected to the tape. Only at the end are the parts completely punched out. So there are no longer any machining operations required on the isolated parts.

The invention is to be explained in more detail with reference to the figures.

Figures 1 and 2 show different embodiments of the invention.

Figures 3 to 7 show different process stages for production of the parts for the electrical measuring instrument, as well as the tapes used in section.

The embodiment of the measuring instrument shown in FIG. 1 according to the invention consists essentially of two stamped and bent parts from a strip, partly as a bimetal made of non-ferromagnetic and ferromagnetic material is trained. To the fixed body 1 are the two Shaped bearing arms 10 and 11, which carry the two bearings 4 and 5. These camps 4 and 5 are preferably made of surface-hardened pressed glass. On the moving ones The instrument pointer 3 is molded onto body 2 and the shaft 6 is welded on. on The coil spring 7 is attached to the shaft 6 and provides the restoring force for the measuring mechanism generated. The fixed body 1 has an integrally formed tongue 1a. This tongue exists on the inside made of ferromagnetic material and on the outside made of non-ferromagnetic material Material. The two bearings 4 and 5 are resilient by springs in openings in the arms 10 and 11 held, wherein the lower bearing 4 can be designed as a ball bearing to dampen the movement of the moving body.

In the embodiment of FIG. 2 is on the movable body 2, a support arm 8 for the spiral spring 7 is integrally formed. It is also indicated that the Pointer 3 is not formed in one piece with the movable body 2, but that only a short pointer stub 3a is formed, to which the pointer 3, for example made of plastic. This can e.g. B. be advantageous to the movable To decrease crowds. The injection of the pointer 3 can also be easily automated perform as long as the body 2 is still with the original tape from which it was punched is connected.

The manufacture of the fixed body should be based on the figures 3a and 3b are explained in more detail. The parts are made from a tape 9, which, as FIG. 3b shows, partly made of non-ferromagnetic material and partially consists of ferromagnetic material. As can be seen from the cross section of the band in Fig. 3b can be seen, the ferromagnetic material 9a takes up only part of the width of the band 9 and is in the band 9, which consists for example of brass, rolled in so that the strip 9 has the same thickness everywhere. As on the left in Fig.

3b can be seen, the fixed body is first partially punched out of the band 9, namely the two bearing arms 10 and 11 and the tongue 1a. As can be seen from the cross section of FIG. 3b, the tongue 1a is made of bimetal with a layer of ferromagnetic material, while the two bearing arms 10 and 11 consist exclusively of non-ferromagnetic material. In the two The holes for the jewels are punched in the support arms at the same time. In the On the right side of Fig. 3a, a further method step is shown in: the the two support arms 10 and 11 are bent perpendicular to the plane of the tape, while the Tongue 1a was bent in a cylindrical shape. In this process step is the body 1 still connected to the band 9 by webs.

After all machining operations have been carried out on the body 1, the connecting webs between the body 1 and the band 9 by another The punching process is severed so that the finished parts 1 fall out.

In Fig. 4a it is shown how the movable body 2 from a Band 15 is produced, Fig. 4b showing the cross section of the band 15 How As can be seen from this figure, the band 15 consists of about half of it Width of non-ferromagnetic material alone, such as B. brass, while on the other half it consists of two layers, with the second layer 15a a ferromagnetic material, such as. B. soft iron or an iron-nickel alloy, represents. In this case, too, the tape is the same across its entire width Thickness.

The parts 2 are partially punched out of the band 15 again, the pointer 3 being punched onto the movable body 2. In another Process step in which the body 2 is still connected to the band 15 the rotating shaft 6 is welded to the movable body 2 and optionally in one In a further process step, the spiral spring 7 is connected to the shaft 6.

Instead of the molded pointers, as shown in Fig. 4a, but only pointer stubs can be provided to which in a process step, in which the body 2 is still connected to the band 15, the pointer 3 made of plastic be injected onto the pointer stub 3a.

In FIGS. 5a and 5b, individual process steps for production are shown of bodies 2 shown in which, instead of a shaft, a torsion band for storage of the movable body is used. Fig. 6 shows the manufacture of the torsion band.

As can be seen from FIG. 5a, a band 15 becomes the body 2 partially punched free. In a further method step, which is shown in FIG. 5a the right-hand side is shown, is still connected to the band 15 Bodies 2, the torsion band 13 attached. After that, the body 2 completely punched out of the band 15 so that it is the one shown in FIG. 5b Have shape. The measuring tool pointer can, for example, be attached to the arm 16 by gluing will. The torsion strip 13 has transverse webs 14 at the free ends, with the aid of which it is welded to the arms 10 and 11 of the fixed body 1. The torsion band has the function of the shaft for the movable body 2 and the coil spring as Restoring force.

According to Fig. 6, the torsion band is made from a flat wire 13, be welded to the round wire pieces 14 at certain intervals. After that, will the flat wire 13 is cut between the transverse webs 14. As can be seen, can also the torsion strips 13 with their transverse webs so easily in a mechanized Process are produced.

Fig. 7a shows individual process steps in the production of the Body 2 made of a band 15. In Fig. 7b, the band 15 is shown in section. The tape is made of non-ferromagnetic material, such as. B. Brass, and the Part 15a made of ferromagnetic material, such as. B. soft iron or an iron-nickel alloy. As the process step a shows, the parts 2 are initially partially from the Volume 15 punched free. In process step b, the parts are subjected to an embossing process subjected, and in process step c, the bearing tips of the shaft 6 are welded. In process step d, the spiral springs 7 are pressed onto the shaft and finally the body 2 is completely punched out of the band 15.

From the above description, it can be seen that the measuring instrument is made up of only a few and easily manufactured parts and that the Manufacture of the parts can be mechanized very easily.

Claims (16)

Patent claims g electrical measuring instrument with a field coil, a ferromagnetic body which is fixedly arranged within the coil Material and one movably arranged within the coil, with a pointer connected body made of ferromagnetic material, d a d u r c h e -k e n n z e i c h n e t that both the fixedly arranged body within the coil (1) as well as the body (2), which is movably arranged within the coil, each made of one The stamped and bent part consists of strip material (9, 15) which is at least partially a bimetallic strip is made of ferromagnetic and non-ferromagnetic material. 2. Measuring instrument according to claim 1, characterized in that the ferromagnetic parts (9a, 15a) of the two bodies (1, 2) face one another. 3. Measuring instrument according to claim 1 or 2, characterized in that the bimetallic strip (9, 15) on the one hand made of brass and on the other hand made of soft iron or an iron-nickel alloy. 4. Measuring instrument according to one of claims 1 to 3, characterized in that that on the fixed Body (1) the brackets (10, 11) for the rotary bearings (4, 5) are formed. 5. Measuring instrument according to one of claims 1 to 4, characterized in that that the measuring tool (3) is formed on the movably arranged body (2). 6. Measuring instrument according to one of claims 1 to 5, characterized in that that on the movably arranged body (2) a fastening arm (8) for a spiral spring (7) is molded. 7. Measuring instrument according to one of claims 1 to 6, characterized in that that on the movably arranged body (2) a rotating shaft (6) by welding is attached. 8. Measuring instrument according to one of claims 1 to 6, characterized in that that a torsion band (13) is attached to the movably arranged body (2). 9. Measuring instrument according to claim 8, characterized in that the Torsion band (13) consists of a flat wire with cross webs near the ends (14) are welded from round wire, with which the torsion band (13) is fixed to the arranged body (1) is attached. 10. Measuring instrument according to one of claims 1 to 7, characterized in that that the bearings (4, 5) are made of hardened pressed glass. 11. A method for producing measuring instruments according to any one of the claims 1 to 10, characterized in that the two bodies (1, 2) consist of a band (9, 15), which consists at least partially of bimetal, first partially punched free and then completely punched out. 12. The method according to claim 11, characterized in that according to the partial free punching on the movably arranged body (2) a rotating shaft (6) is welded on. 13. The method according to claim 11, characterized in that according to the partial free punching on the movably arranged body (2) a torsion band (13) is welded on. 14. The method according to claim 11, characterized in that according to the partial free punching on the movably arranged body (2) a pointer (3) and / or a balancing arrangement made of plastic can be molded on. 15. The method according to any one of claims 11 to 14, characterized in that that a tape (9, 15) is used over the entire length, but only on parts its width, made of bimetal. 16. The method according to claim 15, characterized in that the tape (9, 15) consists of a brass band in which strips running in the longitudinal direction are rolled in from ferromagnetic material (9a, 15a).