DE1119974B - Changeable resistor with cylindrical sleeve - Google Patents

Description

Variable Resistor With Cylindrical Sleeve The invention relates to a variable resistor with a cylindrical, longitudinally slotted, electrically insulating sleeve that serves as a carrier for a roofing over its slot cylindrical resistance winding is used, and with a concentric to the carrier sleeve Threaded spindle, which is used for longitudinal displacement of a contact finger, this being through the slot of the carrier sleeve with the inner surface of the resistance winding is in contact.

One known resistor of this type is the resistance winding embedded in an insulating body. In the ends of the insulating body is a metal cap provided with a central bore is attached to each. The threaded spindle carries a countersunk screw head at one end and is at the other end expanded outside of a cap to form a rivet head-like structure.

This arrangement has the main disadvantage that the threaded spindle Depending on the design of the rivet head, it either turns too difficult or has a dead gear and then no longer offers secure contact. The contact finger moves then namely together with the spindle in the longitudinal direction. In addition, the necessary Contact between one end of the spindle and the associated cap is unsafe. Further the inside of the resistor is neither from the head of the screw nor from their riveted end sufficiently sealed. For various purposes however, a perfect seal is required. For example, some write Large consumers in their acceptance conditions that the resistors longer immersion Must withstand hot and cold salt water baths without water penetrating them and without any noticeable signs of corrosion inside.

These disadvantages are eliminated by the invention in such a way that the carrier sleeve is housed tightly in a housing, in one end with With the help of a plug, a thrust bearing is arranged for one end of the threaded spindle is that at the other end of the threaded spindle an electrically insulating spindle head is attached, of which a circular cylindrical piece in a matching opening of the Housing is rotatably mounted and rotatable from the outside, and that the circular cylindrical Piece of a compression spring - in particular a helical spring - is surrounded, which between an inner shoulder of the housing and an outer shoulder of the spindle head under prestress is inserted.

The interaction of the thrust bearing with the compression spring results in three things Achieved: Firstly, perfect contact between the thrust bearing and the spindle is achieved created, which cleans itself each time the spindle is adjusted. Secondly dead run of the spindle is avoided, because the spindle is always held by the spring pressed against the thrust bearing. Third, the spindle is against one end Overturning secured. That is, if the contact finger moves against as far as it will go the thrust bearing and if you then turn the spindle further, the spindle simply lifts from the thrust bearing, but remains undamaged. This over-rotation protection is special for the one end of the resistance at which the resistance value changes from zero to finite Values change, matter.

Another advantage of the invention is that the interior of the Resistance on the one hand by the plug, on the other hand by the circular cylindrical Piece of the spindle head is well sealed against the outside space.

Further details and advantages of the invention emerge from the following description of a potentiometer serving as an exemplary embodiment with reference to the drawing. 1 shows a central longitudinal section of the potentiometer, FIG. 2 shows an end view along line 2-2 in FIG. 1, FIG. 3 shows a cross section along line 3-3 in FIG. 1 and FIG. 4 shows area 4 in an enlarged illustration -4 of the cross-section according to FIG. 3. The potentiometer has a tubular housing 10. This has a part 11A of relatively large diameter and an end part 11B of smaller diameter. The end part is provided with an external thread for fastening purposes. An obliquely extending annular shoulder 11 C separates the housing parts 11A and 11B in the interior. A tubular core 12 made of insulating material such as Bakelite has end pieces 12A and 12B which have a diameter substantially equal to the inside diameter of the housing so that the end pieces fit snugly. The core also has a central portion 12C of smaller diameter. The end pieces 12A and 12B have a larger inner diameter than the middle piece 12C.

The wall of the center piece 12C of the core has a longitudinal direction extending slot 14. A small diameter resistance wire is called continuous helix 15 wrapped around the center piece of the core and envelops the slot 14 for the most part. The wire is covered with enamel. The insulating email will subsequently removed from the part of the wire coil that passes through the slot 14 shows inside. Instead of this, a winding made of bare wire with spacing can also be used are made between the turns.

A threaded spindle 16 is molded into a cylindrical spindle head 17 made of insulating material or fastened in it in some other way. Most of the spindle head has a diameter that matches the inside diameter of the housing part 11 B and is rotatably mounted in this way. The inner end of the spindle head 17 has a portion 17A of larger diameter which matches the inner diameter of the end piece 12B of the core. A helical spring 18 is applied to the spindle head 17 between the enlarged part 17A and the shoulder 11C of the housing. If the device is to be hermetically sealed, the shoulder 11C is preferably inclined, as shown, and a sealing ring 20 of circular cross-section is applied to the spindle head 17 and squeezed by the spring 18 into the annular notch on the inside of the shoulder 11 C and the wall of the spindle head 17 is formed. The outer end of the spindle head is provided with a slot 21 for a screwdriver. As a result, the spindle 16 can be rotated. If desired, the spindle can also be extended out of the housing so that it can be rotated by other means. The opposite end of the spindle abuts a thrust bearing 22 which is received in the inner end of a plug 23. The spring 18 presses the spindle against this bearing.

The plug 23 is retained in the end of the housing 10 by curling the end edge of the housing inwardly (24) to pinch the plug abutting the end of the core. Instead, the plug can also be driven in by known methods or held in place by pins. The bearing 22 consists of a conductive disc, preferably made of silver, and is embedded in the inner end of a bore 25 in the plug with the aid of a potting compound. A central bore in the bearing disk receives a jumper wire 27. The insulation 28 of this jumper wire is preferably passed through the hole in the disk, and the bare wire end 29 is soldered to the disk surface. With this design, the jumper wire is clamped very securely, a good bearing is formed and a good current transfer is achieved.

An electrical conductor 28 is soldered to the bearing button 22 or attached to this in another way and, as shown, passed through the plug.

A contact spring 30 is attached to a sleeve 31 which is screwed onto the spindle 16 and has a shoulder 32 to which the contact spring 30 is attached. An advantage of this contact is that a single metal strip simultaneously forms a contact and a spring and that the hinge point is remote from the mechanical fastening. This pivot point is located at 33 in the drawing, while the mechanical fastening is located at the attachment 32. As a result of this remote location fastening, any softening of the metal at the hinge point by welding is prevented, and the hinge point is only a point of contact rather than a point of attachment.

By jumping in the projection 32 in the slot 14 is the Sleeve prevented from rotating, so that each rotation of the spindle 16 to a linear Displacement of the sleeve along the spindle leads to a displacement of the Contact spring along the winding.

A backing strip 36 is cemented onto the spool outside of the slot 14. The strip serves to reinforce the coil along the contact line and also serves as an internal power supply to one end of the winding. This end of the winding is connected by means of a connecting piece 37 to a conductive part of the contact strip, which is connected at its opposite end to a line 38 running through the plug 23. The inner coil end is electrically connected in the same way to a line 39 passing through the plug. The back strip can either consist of insulating material and be provided with a printed or otherwise applied conductor along its free surface, or the back strip itself can consist of conductive material and be insulated from the winding. Either the wrapping enamel or the adhesive with which the backing strip is applied can be used for insulation.

Preferably the inner surface of the backing strip becomes slightly convex formed, which can be seen particularly clearly in the enlarged section in FIG. Due to this design, the winding is pressed in and thereby the contact surface with the contact spring 30 is reduced to essentially one point of contact. This results in a cleaner contact that is less prone to failure. Simultaneously becomes one by the indentation of the winding in a desired manner after winding Tension generated, which balances the individual turns and the unwanted looseness eliminated from turns. The back strip can be glued to the winding under pressure or cemented, so that the deformation of the winding even after removal the pressure remains.

The current path leads from the contact spring through the sleeve, the screw spindle and the bearing button to the outside of the device. This increases the space requirement for the usual separate power supply rail superfluous. Will If a linearly displaceable rod is used, the electrical current path between the contact and a connection in the plug by means of an interposed helical spring manufactured.

When the housing 10 is made of metal, as is often required, it is desirable that an insulating skin be placed between the coil and the housing. In the case of the potentiometer shown, a film 42 made of polytetrafluoroethylene is pushed into the housing and rests tightly on its inner wall as a skin. This isolates the winding from the housing, thereby avoiding electrical losses or leakage currents that can otherwise occur under certain circumstances.

The operation of the illustrated wirewound resistor device as a potentiometer will be apparent hereinafter. Electrical lines 38 and 39 are connected to opposite ends of the resistance winding 15 and the line 28 is connected to the spindle 16 . Contact 30 is adjustably connected so that it taps off a certain portion of each voltage applied to the resistor. The device can be used in any way in which conventional rectilinear potentiometers are used, but, as mentioned above, is particularly suitable as a small component, since it is designed to save space. Although the use of the resistance device as a potentiometer has been described and illustrated, the device can also be used as a variable resistor and as a rheostat.

A device of the type shown and described can, for example have the following dimensions and parameters: 6.3 mm outer diameter, 32 mm outer diameter Length, resistance wire from 0.13 to 0.15 mm in diameter, winding resistance of 3 ohms to 80 kOhms, 15.9 mm contact displacement length, 16.5 mm effective winding length.

As mentioned, this is only an example of the information about the reduction or should not limit enlargement.

Claims (5)

PATENT CLAIMS: 1. Variable resistor with a cylindrical, longitudinally slotted, electrically insulating sleeve, which serves as a carrier for a cylindrical resistance winding covering its slot, and with a threaded spindle concentric to the carrier sleeve, which is used for longitudinal displacement of a contact finger, this through the slot the carrier sleeve through is in contact with the inner surface of the resistance winding, characterized in that the carrier sleeve (12) is housed tightly in a housing (10) , in one end of which a thrust bearing (22) for the one with the aid of a plug (23) End of the threaded spindle (16) is arranged that at the other end of the threaded spindle an electrically insulating spindle head (17) is attached, of which a circular cylindrical piece is rotatably mounted in a suitable opening of the housing and rotatable from the outside, and that the circular cylindrical piece of a compression spring (18) - in particular a helical spring - Is surrounded, which is inserted between an inner shoulder (11C) of the housing and an outer shoulder (17A) of the spindle head under prestress. 2. Resistor according to claim 1, characterized in that a circular cylindrical piece of the spindle head (17) surrounding the sealing ring (20) is arranged between the inner shoulder (11 C) of the housing and the compression spring (18). 3. Resistor according to claim 1 or 2, characterized in that the carrier sleeve on both sides of its middle piece (12 C) carrying the resistance winding (15) has two expanded hollow cylindrical end pieces (12A, 12B), the outer diameter of which is essentially the same as the inner diameter of the main housing part, and that the plug (23 ) engages in the interior of one end piece (12A) and the spindle head (17 ) engages in the interior of the other end piece (12B). 4. Resistance according to one of the preceding claims, characterized in that outside the the slot (14) of the support sleeve (12) roofing part of the resistance winding a back strip (36) pressing this part inward is provided, of which Inner surface is curved in the circumferential direction against the sleeve axis. 5. Resistance according to claim 4, characterized in that the back strip is an electrical one Connection from one end of the resistor winding to one at the other end represents the connection arranged on the support sleeve and one opposite the resistance winding has or represents isolated Leitei. Considered publications: German Auslegeschrift No. 1026 401; British Patent No. 645,898; U.S. Patent No. 2,454,986.