DE1590881A1 - Changeable electrical resistances - Google Patents

Description

Variable electrical resistors The invention relates to variable resistors and relates in particular to those resistors which have an immutable resistance element and an optionally displaceable contact element, with the aid of which at any points spaced from one another along the effective length of the resistance element an electrical contact can be established , as a result of which the electrical resistance between the terminals can be varied .

It is an object of the invention to provide a variable resistance element in which the electrical resistance can be changed with virtually unlimited fineness by moving the fixed resistance element and the electrical contact element relative to one another. This relative movement is to take place in that either the contact element remains in a certain position and the resistance element is displaced with respect to the contact element, or, conversely, that the resistance element remains in a fixed position while the contact element is moved with respect to the resistance element. In both cases, such relative movement should take place either through a linear displacement or helical rotation, so that changes in the fixed resistor can be made by further processing producer if he tunes the circuit or by the manufacturer of the resistors by this fixed value resistors from Adds resistance code components that have fixed resistance elements that differ greatly in their production sizes.

The wide, the invention relates to a significant reduction in Petigungskosten of precision resistors by economically viable variable resistors will create overall, for the comparable Fixwertwiderstandselemente turns can be very vary greatly in their resistance values. For example, resistors are currently being manufactured in large numbers and by means other than the use of costly manufacturing, classification, and selection techniques, with nominal tolerances of about 0.01, which resistors must be manufactured to such accurate nominal values.

The resistors according to the invention can be produced in large quantities without having to meet any particular accuracy requirements. They have nominal values that vary by a whole number, for example from 10 to 100 ohms, from 1 megohm to 10 megohm and so on, and at which the effective resistance can ultimately be set in between to a desired nominal value, with the accuracy about 0.001 % of such a nominal value. The novel variable resistor should be temperature- independent, ie its temperature coefficient should be approximately zero. On the other hand, the variable resistance should be designed in such a way that its effective temperature coefficient can optionally be changed, while the effective resistance remains constant.

According to the invention, a variable resistance is achieved. fen which has a non-conductive housing which forms an elongate chamber which is essentially symmetrical about a longitudinal axis and is open at its opposite ends. An electrical resistor is fastened in this housing and is arranged over its entire length in the chamber parallel to the longitudinal axis. This resistor has at least two opposite ends which are adjacent to the corresponding housing ends, several electrical Anachlutklemmen are attached to these housing ends, each of which is in electrical contact with at least one end of the electrical resistor and having a cap which at least partially closes the associated housing end . At least one such cap is provided with a central through-hole which is aligned with the longitudinal axis of the housing and also has a finger-like movable contact device with an elongated rod which is located partially within the chamber, along the longitudinal axis of the chamber, and outwards through at least one of these central through-holes protrudes. The above-mentioned rod carries an electrically conductive contact element transversely to its axis of symmetry, the circumferential surface of which is at least partially in displaceable contact with the resistor, whereby by optional manual longitudinal displacement of the contact element with respect to the housing, corresponding changes in the characteristic of the electrical resistance occur located between the electrical connection terminals .

Individual features of the various embodiments of the subject matter of the invention relate to the size, shape and selected characteristics of the resistance elements that make up the electrical resistance, as well as changes to the design and the internal cross-section of the housing that forms the chamber, changes to the shape and attachment of the electrical contact element, other types of mechanical and electrical functions and changes to the electrical connection terminals and finally various options for electrical contact and the shape and mechanical mounting of the elongated rod.

Further details and advantages of the subject matter of the invention can be found in the drawing and the description, in which exemplary embodiments of the invention are shown schematically. 1 is a partially broken away side view 2 of a further embodiment in Fig i to another embodiment of the variable resistor, Figure 3 is a view similar to Fig of a partial longitudinal section of a variable resistor according to the invention, shows a view, similar to the:.. In the drawing,.. variable resistor, FIG. 4 is a partial plan view of a partial cross section taken along the line 4-4 in Fig. 3, Fig. 5 is a partial plan view geschnitterenSeitenansicht another embodiment of the variable resistor, FIG. 6, 7 and 8 are cross-sectional views of a cylindrical shaped one in the longitudinal direction Housing with different forms of the resistance element, FIG. 9 a schematic diagram of a circuit that can be produced with the subject matter of the invention, and FIG. 10 a schematic diagram of a further circuit that can be produced with the subject matter of the invention.

In the drawing in which the same elements in the different Embodiments are provided with the same reference numerals, correspond to Dimensions and proportions for reasons of drawing clarity and des better understanding not the actual circumstances.

In Fig. 1, a variable resistor is shown, which has a non-conductive housing 10, the preferential example of ceramic material produced is an elongated chamber and encloses, on its inner surface 14, a resistive element 12 superimposed. The shape of the chamber 10, its inner surface 14 and the resistance element 12 can be changed, as shown in the following with the aid of other embodiments. The illustrated in Fig. 1 overall housing 10, its inner surface 14 as well as the resistance element 12 are thus tubular or cylindrical overall shapes and have a cross-section as is shown overall in Fig. 6. An elongated rod has two axial end pieces 16 and 18 which are partially arranged within the chamber and extend in the axial direction, for example along the elongated central part, out of the housing 10 and at their respective inner ends 20 and 22 through a Mechanical coupling 24 made of an electrically non-conductive material, for example ceramic, and provided with a binding agent 28, for example an epoxy cement. The end piece 16 has an electrically conductive contact element, which is designated quite generally with 30 and has an O-ring 32 which is surrounded by a conductive jacket 34. The O-ring 32 is preferably elastic and can consist of rubber or a similar material, while the coating A is preferably composed of silver and / or gold and is obtained by plating the O -ring 32 with a silver film and then plating with a - Gold film is deposited on the ring, the thickness of each layer being approximately 0.5 to 1 micrometer (20 to 50 millionth of an inch). The diameter of the contact element 30 is dimensioned such that constant contact with the surface of the resistance element 12 is ensured. The contact element 30 is firmly connected to the conductor end 16. This connection can be made in any way, for example , as shown, by means of two heads 36 and 38, which include the contact element 30 and are produced by cold deformation at the conductor end 16 itself , with part of the conductor end 20 protruding from the cold deformation point and towards the Attachment of the aforementioned coupling 24 is used.

The electrical conductor ends can be equipped with two identical, electrically conductive, circular end caps 40 and 42, which are fastened in the opposite ends of the housing 10 by, for example, a press fit. Each end cap has a hub 44 which forms an axial or central bracket 46 which serves as a sliding fit for the conductor ends 16 and 18 and thus both supports them and is in electrical communication with them. In the embodiment shown in FIG. 1, each inner end of the housing 10 is provided with an annular, rounded surface 48. Resistive element 12 may be formed in any known manner, such as vacuum deposition, carbon deposition, and the like, with resistive element 12 overlapping inner surface 14 to end face 48 so that a mechanically and electrically suitable connection with a layer 50 of the conductive material arises, which overlaps at least that part of the resistance element 12 which overlaps the rounded surface 48. The conductive layer 50 is applied in any known manner by deposition, plating or the like and serves to reduce the contact resistance to the resistor element 12 and to provide a low contact resistance for the end caps 40 and 42. The end caps 40 and 42 are provided with an outer lip portion 52 which abuts the outer end of the housing 10 and has a cup-shaped central portion 54 which connects the lip portion 52 and the hub 44 so as to provide an interference fit and electrical contact with layer 50 to create. This measure is used to secure the end caps in place, as well as to form a soldered contact zone, shown generally at 56, which receives solder, in a manner and for a purpose which will be described below with reference to the description of the operation of the novel device should be shown.

During operation of the device shown in FIG. 1, the resistance element 12 is displaced with respect to the electrical contact element 30 in each of the two directions indicated by the arrow 58 by an axial movement of the housing 10 or the finger-shaped displaceable contact device with the conductor ends 16 and 18. The original nominal value or also the originally fixed magnitude of the resistance as it occurs between the end caps 40 and 42 is that of the complete resistance element 12 which is located between these end caps. The effective electrical resistance, however, is provided by the portion of the resistive element 12 which lies between the movable contact element 30 and the end cap 42 as a result of the short-circuiting of the remainder of the resistive element 12 through the effective zero resistance path from the contact device with its contact element 30 and its elongated conductor end 16 is formed. In this way, the effective resistance of the device is optionally changed by a relative axial displacement of the movable contact element against the electrical resistance element 12. One type of preferred attachment of the resistor is shown in FIG. The conductor pieces 16 and 18 are immovably attached in the vicinity of their ends by being bent so that they protrude through the corresponding openings 60 and 62 of a switchboard 64 and thus hold the housing 10 on the surface 66 of the switchboard 64. Thus, the user of the resistor only needs to fasten it in the position shown, make the correct circuit connections with the conductor ends 16 and 18 on the switchboard and then determine the size of the effective resistor required for the desired operation by simply moving the housing 10 in an axial direction Direction 58, corresponding to the appropriate values found by an ordinary, associated test device and / or supplied by the power of the circuit itself . If necessary, and usually recommended, once the required effective resistance is present, the user can drip some solder in one or both of the end caps 40 and 42 onto the location 56, thereby removing the conductor ends for mechanical and. electrical safety to their respective end caps. Adjustments can of course also be made later, you only need to loosen these soldered joints by heating them accordingly.

Another field of application of the subject matter of the invention relates to the field of the fixed resistor, the manufacturer supplying a fixed resistor which has a nominal resistance value and certain accuracy tolerances of the nominal value, which are usually given in positive and / or negative percentages of the nominal value. Of course, smaller tolerances are for a very accurate resistance required which can only be achieved through greater accuracy in the production and / or in the selection of resistance values, demands therefore that involve a cost increase with it. The subject matter of the invention, on the other hand, enables the resistors to be manufactured in a relatively imprecise manner, insofar as the resistance values vary widely. However, the manufacturer can set the effective value of the resistance within extremely low tolerance limits, ie with very high accuracy, by making the above-mentioned adjustment that has already been described and either one or both conductor ends 16 and 18 with their corresponding end caps 40 and / or + soldered and thus creates a fixed value resistor. The adjustment of the resistor can be in the preparation of, for example, by the use of an electrical bridge circuit to perform automatically. In addition, the subject matter of the invention enables the economic attainment of tolerances that are at least one order of magnitude smaller, if one takes into account that currently the achievable manufacturing tolerances of fixed- value resistors are 0.01% of the nominal value.

The resistor shown in FIG. 2 has various modifications with respect to that shown in FIG. The cylindrical inner surface 14 of the housing 10 is provided with a resistance element 70 in which a spiral groove 72 is located over a substantial part, but not over its entire length. The inner surface 14 of the housing 10 is cylindrical the entire length of the housing and the identical end caps 74 and 76 are seal- like with their hubs 44 facing outward. To produce mechanical and electrical contact , the annular peripheral surfaces 78 and 80 are soldered to the annular conductor layers 48. The conductor end 16 is threaded at least over part of its length, as is the surface 82 of the axial bore in the end cap 74, so that a rotational movement of the housing 10 and the conductor ends 16 and 18 against each other causes a relative movement of the contact element 30 with respect to the resistance element 70 Consequence. Due to such helical rotation, the amount of axial displacement with any applied rotational force is considerably less than when such a force is applied directly in an axial direction. In this way the sensitivity to the axial displacement by hand is increased, whereby finer changes in the setting of the effective resistance value of the resistor are possible. In addition, the setting of the effective resistance value is preferably carried out on the section of the resistance element 70 which is not grooved in a spiral shape, so that even finer changes in resistance can be achieved.

In Fig. 5, a further embodiment of the resistor according to the invention is shown. This embodiment is generally known as a potentiometer and is mounted on a switchboard 62 in the drawing. The resistor has connecting terminals with two conductor ends 84 and 86 which are in contact with the resistor element 12 at its opposite ends via conductive rings 88 and 90 and extend through corresponding openings 92 and 94 in the switchboard 62 . The movable contact device consists of an electrical xiataktelenent 961 which is fastened by means of two disks 100 and 102 soldered on at 104 and 106 on the conductor rod 98 which is movable back and forth in the axial direction. The conductor bar 98 extends axially in both directions through the ends of the housing 10 and two electrically conductive bearing elements. 108 and 110, which are electrically insulated from the two conductive rings 88 and 90 by annular head pieces 112 and 114 made of glass. The bearing element 108 is provided with a connection line 116 which runs through the opening 118 in the switchboard 62 in the same way as the other connection lines or conductor ends 84 and 86.

The conductive rings 88 and 90 can be of any shape, so that the connecting lines 84 and 86 can be mechanically fastened to them and thereby come into electrical connection with the resistance element 12. In the illustrated embodiment, the axial bearing element 110 need not be electrically conductive, is aller- recently executed for simplicity of construction so, WO in the shape of the ends in general that of the corresponding FScl hats, which was described in the other embodiments. The contact element 96 can be similar to the contact element 30 described above, but can also have a structure which is commonly referred to as a fibrous button and consists of gold-plated steel wool of fine texture which is very strongly compressed so that it is essentially uniform , cylindrically shaped body forms.

In operation, the electrical contact element 96 is by longitudinally displacing the rod 98 with respect to the Ge. Housing 10, as described above , moved against the electrical resistance element 12 in the axial direction. The rod 98 functions as an electrical conductor due to its electrical connection with the connecting line 116, so that the voltage appearing on the connecting line 116 with respect to the voltage appearing on each of the other electrical connections 84 and 86 represents that voltage which is caused by the optional displacement of the contact element 96 is obtained on the resistance element 12 .

In Fig. 6 there is shown a cross-section of one possible shape of the housing 10 , the housing defining a cylindrical chamber provided with a resistive element 12 in the form of a layer of substantially uniform thickness which extends over the entire circumference of the inner surface 14 of the housing 10 adheres. The layer 12 corresponds to the resistance element 12 described in FIGS. 1 and 5 and the resistance element 70 of FIG. 2 before the creation of the spiral groove 72. The present invention does not deal with the composition of the resistance element, except in connection with it with its use according to the invention. The resistive element can be made in any suitable known manner, for example by techniques known as sputtering, vacuum deposition, dipping, etc. / or obtain these properties during the deposition and / or treatment according to the known process techniques. To simplify the illustration , the embodiments discussed above are provided with a resistance element 12 or 70, the general shape of which is shown in FIG. It is expressly understood, however, that viele.andere types, shapes and configurations of the resistive element or resistor elements in any or all of these Ausführungsfor- men with appropriate action in accordance with the uses, advertising used according to the invention of the ultimate use and desired operating parameters the can. Some additional training courses and combinations are described below.

In Fig. 7, a cylindrical housing 10 is shown, in the inner surface 14 of which there is an elongated groove 120 , P into which a resistance element 122 is inserted, which consists of a non-conductive base material 124 with a resistance layer 126 of any known type , has been applied in a suitable manner to the base material, with many of these techniques the planar shaping is common. The planar resistance element 122 can be used in place of the cylindrical element 12 in any of the embodiments shown in FIGS. 1 and 5 without the need to change the other parts, except for the fact that the hermetic sealing effect of the end caps can be changed appropriately the end cap shape must be achieved. In this way, the subject invention enables the use of the resistor element 122, which can be manufactured separately from the main body and then inserted, whereby molding techniques can be used which are not easily directly usable within the housing 10.

Referring to FIG. 8, another embodiment is that shown in FIG Combination shown, the housing 10 with two flat resistance elements 122 and 128, which are located in corresponding elongated grooves 120 and 130 are located in the cylindrical wall surface 14. As shown, the gutters are i20 and 130 for reasons of secure electrical and mechanical contact with the resistance elements arranged diametrically opposite, but they can also any have another suitable distance from one another on the circumference. Of course you can also an additional number of resistance elements in a corresponding number arrange of gutters. It should be noted that the gutters 120 and 130 are a particularly suitable option for fastening and storing the resistance elements 122 pnd 128 bid.

3 and 4 is a further embodiment of the invention Resistance shown in which the housing 132 is rectangular consists of an upper housing half 134 and a lower half 15%, which for example connected to each other by epoxy cement Lib or by another suitable material and form a uniform housing. The housing halves or shells 134 and 136 have similar corresponding planar elongated surfaces 140 and 142 facing each other and on which opposed resistance elements 144 and 146 are arranged. As shown, the elongated surfaces 11E0 and 142 form base areas on which the resistance elements 140 and 146 directly and arranged separately or in another titmouse with the help of familiar ones Process techniques are formed or also like the resistance elements 122 and 128 of Fig. 8 can be placed on these surfaces. At the end of the body are two rectangular ones End caps 74 and 76 arranged and by melting or soldering with the corresponding conductive layers 48 for mechanical connection to the housing 132 and the Establish electrical contact with the corresponding ends of both resistance elements 144 and 146, as shown, connected so that the resistance elements between the End caps 74 and 76 are electrically connected in parallel. The end cap 76 is with a connecting lead 148 which extends through a switchboard 150, and the end cap 74 has a hub 44 that is terminated by another panel 152 runs through that parallel. arranged to the opposite switchboard 150 is. In the end cap 74 there is a central or axial bore 46 through which the ladder bar 1 () can be pushed back and forth. The ladder bar 16 ends inside the housing 132 and has a C-shaped at its inner end 154 Contact element 156. The contact element 156 is preferably light resiliently designed to ensure safe mechanical and electrical contact with two resistive elements 144 and 146 when it is sliding with these Touch stands.

The resistance element shown in FIG. 3 can be used for operation either by the manufacturer or by the user by simply moving the electrical contact element 156 in the longitudinal direction with respect to the resistance elements Set 144 and 146 to the desired effective resistance value. This shift can optionally either by moving the ladder rod 16 of the movable Contact device or the housing 132 perform against each other before the whole Device between the circuit boards 150 and 152 is used, und.die soldering of the ladder bar 16 with the hub 44 takes place as soon as the desired "cri:" is available is, however, it is also possible to shift the ladder rod 16 in the longitudinal direction to be carried out only after the resistor has been inserted between the mentioned switchboards. Of course, there is a suitable electrical connection of the conductor to the end cap 74, for example on the hub 44, is present, which is a not shown, printed Circuit connection can be.

9 shows a schematic representation of a resistor according to the invention, the external shape of which can correspond to the exemplary embodiments already described. A connection end cap 160 and its connection lead 162 are in electrical contact with one end of each of the two resistance elements 164 and 266, which can be located within the housing in the manner shown in FIGS . The other terminal end cap 168 and its lead 170 are in electrical contact with the opposite ends of the resistor elements 164 and 166 so that these elements are electrically connected in parallel between the leads 162 and 170. The movable contact element 172 and its connecting rod 174 are in electrical contact with the end cap 168, as well as with the entire length of the resistance elements 164 and 166 on which the contact element 172 slides. Thus, the effective resistance, represented by the distance between the connecting lines 162 and 170, can be set as desired by the connecting rod 174 of the contact element 172 being shifted by hand in one of the two longitudinal directions indicated by the arrow 58.

According to an advantageous further development of the subject matter of the invention, the resistance elements 164 and 166 can be selected so that, although they have the same nominal resistance values, they are equally large and opposite resistance values based on the temperature coefficient, hereinafter referred to as temperature-dependent resistance. As a result, changes in temperature as a result of fluctuations in the ambient temperature and / or the current heat have the effect that the resistance elements 164 and 166 have the same but oppositely directed resistance values. yielding a Auesehaltung such effects niLhert and obtains a resistance device having a selectively variable effective resistance and a constant temperature-dependent resistance, so an extremely t% riinsehenswerte and advantageous combination of parameters. In general, a resistor with the lowest possible temperature dependence is required for most applications. Much effort has been made in the past, and much effort is now being made, to improve the manufacturing processes so that the seamless, predictable and economical production of resistor elements with a negligibly small temperature dependence is possible. One of the difficulties encountered is that the normal range of temperature dependence of resistance in a given group of fabricated elements varies considerably and unpredictably, with only a relatively small proportion of these elements having what is known as negligible temperature dependence.

The subject of the invention now makes it possible that in the manufacture or buying large series of resistor elements do not take special care or special costs must be incurred, since the problem mentioned is only one It is a matter of choosing those elements, the same but opposite temperature-dependent ones Have drag coefficients and. thus together in a resistor according to the invention can be installed. For example, the normal sorting procedures enable the selection of a resistance element 164 with a temperature coefficient of, for example, +600 millionths and a resistance element 140 with a Partial temperature coefficients of -600 millionths, which, if they are in the form shown in Fig. 3 and 4 or 8 can be used together in an effective way variable resistor with an effective temperature-dependent resistance value of -0.36 millionths, i.e. a negligible value.

FIG. 10 shows a schematic diagram of another embodiment of the inventive resistor, the two resistor elements 164 and 166 again being selected so that they have the same nominal value but opposite values for the temperature dependency, as described above with reference to FIG. 9 was described. In this embodiment, one connection line 176 is connected only to one end of one of the resistance elements 166 and another connection line 178 is connected to the opposite end of the other resistance element 164. A movable contact element 180 is slidably supported by the rod 182 so that it is in mechanical and electrical contact with the two resistance elements 164 and 166. The contact element 180 closes a current path connected in series between the connection lines 176 and 178 via the parts of the resistance elements 164 and 166 which are located between the contact points of the contact element 180 and the corresponding connection lines 178 and 176. Thus, by longitudinally displacing the contact element 180 with the aid of its manually operated rod 182 in one of the directions indicated by the arrow 58, the magnitude of the resistance which is switched on or removed from the circuit by the resistance element 164 is equal to the resistance which , conversely, is removed from or switched into the circuit by the resistance element 166. As a result, the effective resistance between leads 178 and 176 has a constant nominal value. If, however, the values of plus and minus 600 millionths selected above for the temperature coefficients of elements 164 and 166 as examples are used, then the selected longitudinal displacement of contact element 180 results in oppositely proportional effective resistance values of the temperature coefficients of resistance elements 164 and 166 being added and added be subtracted. The effective temperature-dependent resistance value of the constant resistance value, which is present between the connecting lines 178 and 176, can, however, vary continuously and between the extreme values of plus and minus 600 millionths by moving the contact element 180 in the longitudinal direction from the far left to the far right with respect to FIG to adjust. As a result, such a resistor can be used extremely advantageously as a compensation element in a circuit in which the operating parameters are such that the other circuit elements require a resistance that compensates for the temperature dependence in order to produce the correct and / or desired function. Of course, the conductor rod 182 must be electrically insulated from the connection lines 176 and 178, for example by an end cap coated with a glass head, as shown in FIG.

i It goes without saying that the characteristics of the various The embodiments shown of the subject matter of the invention are not limited to those specifically shown Combinations are limited. The described in connection with an embodiment Features can therefore also be used in other embodiments, i.e. those according to the invention Features are interchangeable. Here are the embodiments described to be understood only as examples to which the person skilled in the art can still make various changes can make that fall under the scope of protection claimed.

Claims (1)

Patent claims before 1. Variable electrical resistance, characterized by a non-conductive housing (10) with an elongated, substantially symmetrical about a longitudinal axis lying chamber, which is open at its opposite ends; by an electrical resistance element (12, 120) fastened to the housing (10), which element is arranged within the chamber over substantially the entire length of the chamber and parallel to said longitudinal axis and has at least two opposite ends which lie at the corresponding housing ends; by a plurality of electrical conductors (16, 18, 84, 86, 118) attached to the gelicius ends, each of which is in electrical contact with at least one opposite end of the opposite ends of the resistance element (12, 120) and a cap body (40, 42, 74 , 76), at least partially the associated Gehiuseende closes, with at least one of these cap l (iirper is provided with a central through hole (46) which aligned with said longitudinal axis; and through a finger-like movable contact element (30, 96, 156) with a liinglichen ladder rod (16, 18, 98), which extends along the named longitudinal axis is partially located within the chamber det. and through at least one such central hole the I: ailiirier protrudes, whereby on the ladder pole (16, 18, 98) an electrically conductive one, perpendicular to the ladder pole syiili'.lei: il.SClier 'Loiit "ilctlcöriier is attached to the least with a `feil his Uinfangs.r1i@clie with. your; liderstandseleiiient (i2, 120) is in sliding contact, with either, manual longitudinal displacement of the movable contact element against the housing (9_0, 132) corresponding changes to the effective electrical resistance can be caused, the between said electrical connection lines (16, 18, 162, 170, 1 76, 178). 2. Variable electrical resistance according to claim 1, characterized in that the electrical resistance element (12, 120) is attached to the inner surface of the chamber, that each cap element (40, 42, 74, 76) with a central Through hole (46) is provided so that the finger-shaped movable Liche contact element two electrically conductive, elongated Ladder rods (16, 18, 98), which partially within of the chamber are arranged along said longitudinal axis and through a corresponding central bore from the chamber protrude and at the same time with the corresponding cap elements are mechanically in sliding as well as electrical contact, that one end of each conductor bar is within the chamber, that a non-conductive 31 coupling device (24) mechanically connects the inner ends of the conductor bars together, that the electrical contact element (30, 96, 156 ) is mounted concentrically on one of the conductor bars (16, 98), near the end of the bar, and has a circular periphery which is in sliding contact with the resistance element (12, 120,) and that the conductor bars are also suitable as electrical circuit connections. 3. Variable electrical resistance according to claim 2, characterized in that the resistance element (12, 120) has a substantially uniform thickness and is provided at one end with a spiral groove (72) to give this end a greater resistivity than the rest of the resistance element, whereby when the electrical contact element (30) is longitudinally displaced along the other, unslotted section of the resistance element, the changes in the effective electrical resistance can be selected more finely. 4. Variable electrical resistance according to claim 2, characterized in that one of said through bores (46) is provided with an internal thread (44) and that one of the conductor bars (16) is threadedly engaged with this threaded cap element (74) stands, whereby with optional rotation of the movable contact device with respect to the housing by hand, a longitudinal displacement takes place between the two. 5. Variable electrical resistance according to claim 2, characterized in that the electrical resistance device (22) consists of two planar resistance elements (i20, 130) , both of which are fixed essentially over the entire length of the inner housing surface, parallel to said longitudinal axis, that each resistance element has two opposite ends which are located near the ends of the housing, and that the contact element (30) is arranged on the conductor bar, being perpendicular to the conductor bar and symmetrically and having two opposite peripheral parts, both with the corresponding resistance element ( i20, 130) are in sliding contact, which causes corresponding changes in the effective electrical resistance that exists between the two electrical connection lines when the movable contact device and the housing are manually longitudinally displaced relative to one another. 6. Variable electrical resistance according to claim 5, characterized in that both resistance elements have the same nominal resistance value and the same but with respect to the sign opposite temperature-dependent resistance coefficient, and that the resistance elements are electrically connected in parallel, whereby the effective temperature-dependent resistance component of the effective tyider stand, occurring between the electrical conductor ends is essentially equal to the algebraic sum of the two opposite temperature coefficients. 7. Variable electrical resistance according to .lnspruch 5, characterized in that both resistance elements have the same nominal resistance value and the same but signed opposite temperature coefficient, and that corresponding sections of the resistance elements aiif opposite sides of the contact element are electrically connected in series by the Kontrl.liteleinent optional misalignment of the movable l @ Oiitiilit # elenientes beviiglieli of the housing selective changes in the effective temperature-dependent resistance between the conductor ends can be brought about. B. Variable electrical resistance according to claim 5, characterized in that the contact element has a Cf () i'illigell, resilient body (156i) in the transverse direction, and that the rod (16) consists of an electrically conductive. the geometrical center of the contact element (156) is attached and is in sliding contact with its associated happenelemeiit (7t1) for mechanical mounting and for making swift contact.