DE1792999U - ELECTRICAL RESISTANCE WITH PROTECTIVE COVER MADE FROM PRESSED INORGANIC INSULATING MATERIAL. - Google Patents

Description

Electrical resistance with protective cover made of pressed inorganic insulating material. -------------------------------------------------- ----- The so-called enamelled electrical resistors normally consist of tubular or plate-shaped ceramic supports around which a resistance wire made of a metal alloy such as chromium-nickel or constantan is wound in a helical manner, the winding being protected by a fired inorganic enamel layer. The enamel is applied cold to the resistor using well-known dipping, spraying or brushing methods, whereby it is used as a fine suspension in various liquids such as water, turpentine or alcohol * After the liquid has evaporated, the resistor remains with a layer of powder Enamel, which is then fired in suitable ovens at a temperature between 600 and 1 oooo, C, depending on the properties of the enamel used.

To ensure that the enamel grains are sufficiently cemented and stick to one another and to achieve with the support surface, the resistance at high temperature, which is not much lower than the melting temperature of the enamel used will. This causes the wires embedded in the email to become a strengthen Subject to oxidation and chemical corrosion, and wire breaks can often occur occur that result in rejects that cannot be reused.

The application of the enamel on the resistors and the following Burning usually has to be repeated several times because one is too thick Layer of powdered enamel easily peeled off from the support during firing and this creates waste. You have to apply several thin layers one after the other and burning The protective cover according to the innovation is characterized in that the enamel, glass or the inorganic insulating materials that surround the resistor and protect, exposed to mechanical pressure during heating d. H. in plastic state are pressed so that they are sintered and pressed.

The mechanical compression and consequently the plastic four-fold formation of the Protective cover made of enamel or glass can be made using dies or similar suitable tools can be achieved. The mechanical pressure on the insulating protective cover can also be used can be achieved by atmospheric pressure. The protective cover according to the innovation turns out cheaper than the known. The well-known protective covers are by Re-application of the enamel layer received and fired at higher temperatures.

One of the simplest possible ways to implement the innovation is there in that you put a sufficiently thick layer of powder on the resistor body Emails applies the prepared resistance into one, consisting of two halves introduces metallic die and then introduces this into a furnace in which is heated to a suitable temperature.

Once the enamel softens, the weight pushes the top half of the Die, possibly increased by external mechanical pressure, the enamel body together so that they are cemented together and to the carrier.

There is a plastic deformation of the enamel, whereby the Emä. the shape of the die is given. After cooling down, the resistor can be removed from the die. be taken.

According to another embodiment, disks, tubes Od. The like. Or easily manufactured containers made of enamel or glass. These Discs, tubes or containers are then attached to the resistors and heated and pressed together.

In the drawings are various embodiments of the innovation shown.

Fig. 1 shows a not yet sheathed resistor, Figs. 2 and 3 show the same resistance between two Ema & l or Gals disks in plan view and in perspective, Fig. 4 shows the resistor with the disks of Fig. 3 in a die for placing in a furnace, FIGS. 5 and 6 show resistors without inner support, Fig. 7 shows a sheet resistor in the form of a helix is wound around a ceramic rod.

Fig. 8 shows the same resistor as Fig. 7, but with one Protective cover made of insulating material, Fig. 9 illustrates the same resistance according to firing and simultaneous pressing9 Fig. lo and loa illustrate an in a protective tube introduced resistance in longitudinal and cross-section? Fig. 11 shows the resistor with protective tube of Fig. lo, ready, little by little to be introduced into an oven while on the tube by means of a vacuum pump a negative pressure is applied and FIGS. 12, 13, 14, 15 show the manufacture of the resistor according to Fig. 11.

According to the exemplary embodiment according to FIGS. 1 to 4, a resistor is used Ry consists of a flat ceramic carrier C, which is connected to a resistance wire F is wrapped between two enamel or glass panes LI and L2 of suitable thickness and dimensions arranged. Then the whole thing is in the lower part S of a metallic The upper part P of the die is placed on the three pieces L1, R, L2 created by its own weight, possibly by external mechanical Pressing can be increased, which presses three pieces together.

The die with the resistor is now placed in the furnace or warmed in another way. As soon as the softening temperature of the glass or enamel, from which the disks L1, L2 consist is reached, they are reached by the pressure of the upper part are plastically deformed and fill the entire shape, whereby they are attached to the Join the edge.

The plastic deformation can be achieved by mechanical pressure and achieve the merging of the discs at a temperature that is noticeable is lower than when the mechanical pressure is not used. After cooling down one can see the resistor, which is practically completed in a single work step remove it and then, if necessary, clean and deburr.

Of course you have to know the temperature, the heating time, the mechanical Pressing and other details of the shape of resistance and experimentally adapt to the properties of the enamel or the glass.

The first LI sheet can also be produced by cold or hot pressing Make powdery or granular enamel or glass in the die yourself. To this Disc is then placed the resistor and on top of it a layer of powdery or granular enamel or glass applied, which then by the stamp P before and Pressing while heating.

If, instead of the two discs, a previously made enamel or Glass tube with round or flat cross-section is used, the resistance in the The tube is pushed in and the whole thing is placed in the die, through the punch P is closed. Plastic deformation of the pipe is achieved through heating using mechanical pressure when the weight of the stamp is not sufficient.

The chemical, mechanical and electrical properties of the materials, that are used to protect the resistances must be adapted to the respective purpose will.

The thermal expansion coefficient of the enamel or the Glass and the support on which the resistance wire is winds or the conductive layer is applied should be the same or only slightly different from each other.

The carrier around which the resistance wire is wound can be made of Mica, asbestos cardboard or asbestos fabric, or made of glass thread fabric, or you can also use the same material for the panes, roof. Enamel or glass, alone or mixed with suitable inorganic filler material, use.

The enamel or glass of the insulating sleeve can be used alone or with others p inorganic powdery or granular fillers how Pebbles, magnesium oxide and possibly with metallic powders for improvement the thermal conductivity of the enamel and the glass can be used.

According to the innovation, you can of course also use any resistance Manufacture of other shapes and dimensions using dies that are suitable for this purpose On the inner surface of the die you can also put labels or signs, which are then printed on the resistor.

The flexible resistors, consisting of spiraling on an asbestos or Glass core with single or double braided resistance wires or fabric, in which the warp or the weft is made from a resistance wire or from a Resistance spirals are ideal for insulation with enamels or layers of glass.

Enamel or glass resistors can also be used without a carrier for wrapping of the resistance wire are used, the resistance wire being zigzag is placed between two enamel * "or glass panes, as indicated in FIG.

In Fig. 6 a similar embodiment as in Fig. "5 is shown, wherein the resistance wire before bending in a zigzag shape spirally on a core which is removed after winding.

One can also use two or more resistors that are electrically separated or can be connected to one another, embedded in the same enamel or glass layer According to The innovation can also include resistors without resistance wire, ie graphite, metal or Oxide film resistors, as well as ground resistors, consisting of a mixture of powdery inorganic insulating materials such as kaolin, clay, glass and others Silicates, with powdery conductive materials such as metal, graphite, oxide, etc., which have been pre-fired and sintered, with an enamel or glass protective cover be coated.

If the materials that form the actual resistance i.e. metals, alloys, metallic oxides, graphite, coal, etc. exposed to oxidation at the softening temperature of the enamel or glass are then the heating and pressing of the resistors in a closed evacuated air or with vessels filled with neutral gas such as nitrogen.

If you have direct contact with the enamel or the glass the resistance wire or with the conductive layer that is the actual resistance forms, wants to avoid, then according to the invention the support of a 0.5 to 2 mm thick layer of inorganic insulating materials, such as pebbles, magnesium oxide, kaolin, Asbestos etc. These materials are finely ground and then made of it a suspension in water, turpentine susw. with a small addition of binding materials such as gum arabic, natural and artificial resins, etc.

This suspension is applied to the resistor using known methods, as applied by dipping, spraying and brushing.

After the liquid has evaporated, the organic substances are removed by heating, the inorganic grains remain on A. e Adhere to the surface of the resistor.

A graphite-metal or oxide film resistor is shown in FIG. 7 as an example shown, consisting of a ceramic carrier on which a spiral ground with the length of the spiral-shaped conductive layer O being increased significantly will. The metallic caps are marked with T and the corresponding wires with F, which represent the end connections. In Fig. 8 the same resistor is in cross section, covered with a layer of powdered, inorganic insulating material, shown. Finally, FIG. 9 shows the same resistor with an enamel or glass protective cover shown after the innovation.

Even if you use a glass or enamel tube, inside which some kind of resistance. d. H. a wire or sheet resistor introduced it is possible to create a protected resistor without using dies and stamping according to the following procedure.

As shown in Figo lo and in the following figures, the Resistor R, finished with metal caps F, is inserted into the tube T. The two ends of the glass tube T, which must be longer than the resistor R, are replaced by two flexible Hoses are connected to a vacuum pump P, which increases the pressure inside the glass tube lower than the external atmospheric pressure holds «The tube T with the resistance R is warmed up to the change temperature by progressively pushing the pipe in introduces the annular furnace N. With progressive warming and softening of the pipe, the external atmospheric pressure causes a plastic deformation of the Pipe wall until it adheres to the resistance surface.

By regulating the temperature of the oven N and the At the speed of insertion of the tube, it is possible to fully insert the resistance encapsulate in an enamel or glass envelope. If the connecting wires F consist of a are made of solderable metal, it is possible to make an airtight seal, and in this case the resistance is completely protected against external influences. To get the finished resistor, you have to attach the two undeformed tubes cut off the points Ll, L2.

The various stages of work are shown in FIGS. 11, 12 and following shown.

For the protective cover according to the innovation, graphite layers are resistors or an easily oxidizable material, because it is particularly suitable for working In addition, the application of the Intermediate layer of neutral materials, an immediate one according to the invention Touching the actual resistance with the enamel or glass of the protective cover avoided, The resistors @ according to the innovation differ from the known ones Resistances (in which there is direct contact between the protective cover and the live Resistance is avoided) by having the insulating protective cover made of glass. E-mail or sintered ceramic materials in direct contact with the actual Resistance, so that the value of the heat transfer coefficient is very high.

Even if the resistor with an intermediate layer of neutral materials is provided, the heat transfer coefficient remains very high because of the extensive Contact surface of the current-carrying resistor with the insulating protection and shell / because of the heat dissipation to the outside by means of solid materials.

Claims (1)

Protection claims Protection claims 16 Fixed or adjustable electrical resistance, d. hú wire-wound, or sheet or ground resistor, which is protected with inorganic enamel, glass or ceramic materials in pure form or mixed with powdered inorganic insulating materials, characterized in that the resistor on which the outer protective layer is applied is sintered and pressed . 26 resistor according to claim 1, characterized in that disks, Tubes or cans of suitable shape made of inorganic enamel or glass on the actual Resistance applied with simultaneous application of heat and mechanical pressure are. 3. Electrical resistance according to claims 1 and 29, characterized in that that its protective cover is made of powdered or granular inorganic insulating materials mixed enamel or glass. 4 <Electrical resistance according to claims 1 and 3, characterized marked that the enamel or glass used with powdery or granular pure metals or metal alloys is mixed. 5. Electrical resistance according to claims 1, 3 and 49, characterized in that the enamel used or glass Insulated with powder or granular inorganic substances and with powdery or granular pure metals or metal alloys is mixed. 6. Electrical resistor according to claims 1 to 5, characterized in that between the actual resistor and the enamel or glass envelope an intermediate layer from 0.5 to 0.5 mm thick made of fine powders or grains organic electrically insulating substances is applied. 7. Electrical resistance according to claims 1 to 69 characterized in that on the whole glass or enamel outer surface or on a part thereof, writings, numbers Drawings etc. are deepened or raised. 8. Electrical resistor according to claims 1 to 7, characterized in that that the enamel or glass used is colorless or only slightly colored and transparent is.