DE937900C - Electrical resistance - Google Patents

Description

Electrical Resistance The invention relates to electrical Resistors and resistance elements therefor. In particular, the invention relates to a improved resistance element and resistors incorporating such elements are for electronic use.

For many purposes, resistances in the range of o, i to io M S2 required. However, resistors are used for special applications of several hundred M, P are required. Under the designation "high resistance values" or "high values" should in the following resistance values in the range of o, i M S2 up to a few hundred M Q can be understood. For broadcast and similar purposes different types of resistors are currently on the market. Adhere to all of them however, certain disadvantages make their successful use in modern electronic Restrict devices. In the electrical industry there is a constant need for Resistors that have a high and constant resistance value, really noise free are, a small, preferably positive temperature coefficient of resistance and at the same time of compact design and easy to handle. So far known, no resistor is currently available to meet all of these requirements fully takes into account. The main object of the invention is in the creation of an improved resistance element, with the help of which Let build resistors that have an improved mode of operation and the requirements correspond more perfectly to the electrical industry than the currently known resistors.

Another object of the invention is to provide a resistance element to create, with the help of which resistors of high value, high constancy and let build real freedom from noise.

The invention seeks to provide a metal film resistor that can be used by compact design and at the same time high constancy in connection with a low Has temperature coefficient of resistance.

The invention also wants to create a resistance element with which Help one can get a resistor of great value without going to the aid to have to resort to grinding in a helix.

In the course of extensive research to solve all of these needs Tests were carried out with resistance elements that consisted of metal coatings, which were applied to insulating substrates. It turned out that with very thin metal coatings it was possible to achieve high resistance values that However, resistance values were not constant, while relatively thick metal coatings exhibited the required constancy, but not the achievement of high resistance values made possible, unless such resistance elements had a length which was less suitable for electronic purposes.

The problem to be solved by the invention was therefore to create a resistance element whose current conduction path was sufficiently thick, to ensure the constancy of the resistance value, but at the same time also in sufficient length could be made to fit the finished resistor to give high value without making the resistance itself too extensive as a result or became long.

In the course of the investigations carried out, it was found that one A useful resistance element is obtained by using a thread, strand or fiber made of non-conductive material with a relatively thick coating of a certain metal or metals. The material from which the Thread, strand or fiber is selected here so that the metal coating can be burned in. The material of the thread, strand or fiber should be also have sufficient flexibility and strength so that it can be placed on cores or bodies of small diameter, for example about 6 mm, can be wound, how such a body is usually used for small resistors. In this way you get a resistance of compact design and handy size, the one has constant and high resistance value. An electrical according to the invention Resistance element is therefore characterized in that it consists of a thread, Wire, strand or a fiber made of a non-conductive, heat-resistant, inorganic Material is made, which preferably has sufficient flexibility and strength possesses so that it can be wound onto a core body, and on its Outer surface a firmly adhering, relatively thick coating or a similar one Layer is burned in, which or which exclusively or predominantly consists of a metal or a metal alloy from the element group consisting of gold, platinum as well Gold-platinum alloys includes.

"Heat-resistant material" is understood to mean a material that can withstand firing temperatures of at least q00 ° C; under a »relatively thick coating "or a" coating layer "becomes a film-like coating or a Coating layer understood with a resistance value of ro to rooo ohms per square.

It is useful as a material for the thread, strand or fiber Glass or a glass-like material is used, preferably glass is used.

If the coating layer consists of a gold-platinum alloy, the result is such an alloy with a gold content of 80 per cent gives excellent results. A resistor made from such an alloy has a high specific resistance and a low temperature coefficient of resistance.

The gold or platinum or both metals can also be used if desired further metals are added within the conductive coating: the invention further comprises a method for producing an electrical resistance element, that consists in that one is on the surface of a thread, strand or a Fiber made from a non-conductive, heat-resistant, inorganic material, e.g. B. Glass, a coating from a solution in which a gold or platinum compound is applied or a mixture of gold and platinum compounds is dissolved and then the thus coated thread, strand or fiber is heated, thereby forming the metal connection or compounds to decompose 'and the resulting metal or alloy coating to fix firmly on it.

The solution used according to the invention can, for example from a mixture of a gold and / or platinum compound and a cellulose derivative exist, which are dissolved in a suitable solvent or solvent mixture are to which an adhesive or flux can conveniently be added. Satisfactory For example, a solution of platinum chloride, bismuth chloride and nitrocellulose has results in a solvent mixture of acetone and alcohol that result during the firing process results in a platinum coating.

A lower temperature coefficient than what you get with a coating Obtained from platinum alone can be obtained by finding a solution used, those of any sulforesinate of gold and platinum (in the proportion of 4 parts Gold to i part platinum) and any bismuth resinate in a solvent mixture consists of essential oils.

The thread, strand or fiber is expediently covered, by drawing the thread through a bath made of the desired coating solution or by letting the thread run over a pad filled with the coating solution is saturated.

The following are some examples of coating solutions that can be used to produce resistor elements according to the invention by using them to coat a glass fiber and then heating it so that the organic components burn off and a firmly adhering coating film made of gold, platinum or a gold-platinum Alloy remains on the fiber. Of course, these examples are not intended to limit the invention. Example I Platinum Chloride. . . . . . . . . . . . . . . . . . 8 0/0 alcohol. . . . . . . . . . . . . . . . . . . . . . . 8% nitrocellulose. . . . . . . . . . . . . . . . . 8% acetone. . . . . . . . . . . . . . . . . . . . . . . 76% During the firing process, this solution results in a coating of platinum. Example II Gold (as a sulforesinate) ..... 7.00 / 0 rhodium (as a sulforesinate). , o, i 0/0 bismuth (as a resinate) ...... o, 2% oil of turpentine. . . . . . . . . . . . . . . . . . 43.00 / 'lavender oil. . . . . . . . . . . . . . . . . . 18.0% nitrobenzene. . . . . . . . . . . . . . . . . . i0.0110 rosin. . . . . . . . . . . . . . . . . . 21.70 / 0 This solution results in a coating of gold during the firing process. Example III Gold (as a sulforesinate) ..... 5.6% platinum (as a sulforesinate) .... 440/0 rhodium (as a sulforesinate). . o, i 0/0 bismuth (as a resinate) ...... o, 2 0/0 oil of turpentine. . . . . . . . . . . . . . . . . . 43, o O / 0 lavender oil. . . . . . . . . . . . . . . . . . 18.0% nitrobenzene. . . . . . . . . . . . . . . . . . io, o% rosin. . . . . . . . . . . . . . . . . . 21.70 / 0 During the firing process, this solution results in a coating made of a gold-platinum alloy.

If desired, the application of the coating solution can depending on the desired final thickness and resistance of the metal coating or repeated several times.

In making high value resistors using of a resistance element according to the invention, this is on an insulating body of preferably circular cross-section applied or wound, although Of course, other cross-sections can also be used.

In this way, as a result of the extraordinary reduction in cross section of the conduction path get a resistance of high value in a manageable size.

The method can expediently take the form of an ongoing process be carried out by running an endless thread or fiber through the plating solution of gold, platinum, or gold and platinum, pulls through the thread so coated running an oven in which the organic constituents of the coating layer burned away and a firmly adhering coating of the metal or metal alloy remains on the thread, and the thread metallized in this way finally on one Winds bobbin or drum.

To produce a resistor using the inventive Resistance element is the metallized thread or the metallized fiber in the required length. pulled off the drum and placed on an insulating body, which consists, for example, of a suitable ceramic material, wound, wound, whereupon the external connections are made in the usual way.

For a better understanding of the invention and how it is carried out should be referred to in the following, for example, to the schematic drawing will. In this figure i denote a partially completed resistor of high value according to the invention, FIG. 2 the completed resistor and FIG. 3 a method of making the metallized thread or fiber that makes up the resistance element forms.

According to FIG. I, the resistor consists of a body i made of ceramic Material on which a resistance element in the form of a glass thread 2 is wound which is previously metallized according to the invention. On both ends of the body i sit caps 3 on which the free ends 4 of the metallized glass thread 2, for example by soldering, as indicated at 5. The usual lead wires 6 are soldered to the outer ends of the caps 3 at 7 to turn the resistor into a to be able to install electronic circuit.

The finished resistor is covered with a layer of lacquer 8 made of silicone resin (Fig. 2) or another suitable heat and moisture-resistant paint covered by good insulation properties.

As can be readily seen, the resistance of the finished resistor depends on a number of factors such as the total length of the winding, the pitch of the winding, and the thickness of the metal or alloy coating. For example, a resistor with metallized glass thread according to the invention and a value of i M S2 can have the following composition: Glass thread. . . . . . . . . . . . 0.025 mm resistance of the metal coating. . . . . . . . . . . . 100 ohms / square resistance of i cm length of the metallized thread 12,5oo S. required length for the resistance of i M, Q. 80o mm core body. . . . . . . . . . q. mm o number of turns. ........ 63 Pitch of the winding ... 0.1 mm Length of a turn .... 12.7 mm Another resistor according to the invention with a resistance value of 10 M d2 can be constructed as follows: Glass thread . . . . . . . . o, o25 mm C @ resistance of the metal coating. . . . . . . . . 300 Ohm / square resistance of 1 cm length of the metallized thread 37 500 S2 required thread length for a resistance of ioMSZ ........ ...... 266o mm core body. . . . . . . . . . . . . 6.35 mm number of turns. ....... 133 pitch of the winding. , GI mm length of one turn. . . . 2o mm In Figure 3, for example, the production method of a resistor element according to the invention is shown in schematic form. According to this figure, a glass thread io of a certain length is wound onto a bobbin or drum 9. The thread io is withdrawn from the drum 9 and runs through a pair of superimposed felt cushions ii and 12, which in one of the respective metallizing solution 1q. containing container 13 are housed, the cushion ii is partially immersed in this solution. When the glass thread io emerges from the container 13, it is covered with a thin coating of the plating solution. He then runs into a muffle furnace 15 with an electrical resistance heater 16; Here the coated thread is first heated to a temperature of 50 to 55o ° C, this temperature depending in detail on the particular composition of the glass that forms the thread. The purpose of the heating is to burn away the organic components of the coating solution and to form a firmly adhering metal coating from the metal contained in the solution, which is then annealed, whereupon the thus metallized and fired thread emerges from the furnace and onto a drum 17 is wound up.

It goes without saying that the scope of the invention is electrical Including resistors which contain a resistance element according to the invention.

Claims (9)

PATENT CLAIMS: i. Electrical resistance element, characterized in that. that it consists of a thread, wire, strand or a fiber made of a non-conductive, Heat-resistant and inorganic material consists on the outer surface of a Firmly adhering, relatively thick coating or a similar layer burnt in is that or which exclusively or predominantly consists of a metal or a metal alloy consists of the element group, the gold, platinum and gold-platinum alloys includes. 2. Electrical resistance element according to claim i, characterized in that that the thread, strand or fiber used is made of non-conductive, heat-resistant, inorganic material has such flexibility and strength that he can be wound onto a core body. 3. Electrical resistance element according to claim 2, characterized in that the metallized thread, strand or Fiber is wound on an insulation body. q .. Electrical resistance element according to claim i, 2 or 3, characterized in that the thread, the strand or the fiber is made of glass. - 5. Electrical resistance element according to one of the preceding Claims, characterized in that the metallic coating layer consists of a Gold-platinum alloy with 8o 1 / o gold consists. 6. Electrical resistance element according to one of the preceding claims, characterized in that the metallic Coating layer initially in the form of a solution containing a gold or platinum compound or contains a mixture of gold and platinum compounds, on the thread den Strand or fiber is applied. 7. Electrical resistance element after Claim 6, characterized in that the coating solution from the solution of a Gold or platinum compound or a mixture of gold and platinum compounds and a cellulose derivative in a suitable solvent or solvent mixture, preferably with the addition of an adhesive or flux. B. Electrical Resistance element according to claim 7, characterized in that the solution from the Solution of platinum chloride, bismuth chloride and nitrocellulose in a mixed solvent from acetone and alcohol or from the solution of any sulforesinate of gold or platinum or a mixture of any gold and platinum sulforesinates in consists of a solvent mixture of essential oils. 9. Electrical resistance element according to claim 8, characterized in that the composition of the solution the Examples I, 1I or III corresponds. ok Method of manufacture an electrical resistance element, characterized by the following process steps: Coating the surface of a thread, strand or fiber made of non-conductive, heat-resistant, inorganic material such as glass with a solution that contains a gold or contains a platinum compound or a mixture of gold and platinum compounds, and then heating the coated thread, strand or fiber to decompose the metal compound or metal compounds and solidification of the resultant Metal or metal alloy coating thereon. i i. Method according to claim ro, characterized by the use of solutions from the composition of the examples I, II or III. 1a. Method according to claim io or ii, characterized in that that the thread, strand or fiber through the solution or over pillows that are moistened with the solution.