DE1293893B - Electrical component with impedance distributed over an arc - Google Patents

Description

The present invention is based on electrical resistor arrangements with a grinder whose point of contact with an extended resistance element, z. B. a coil, a grinding wire, a carbon or graphite resistance layer, is changeable. With such arrangements there are difficulties with regard to the wear of the sliding contact. Attempts have been made to eliminate this by the sliding contact is either specially designed and made of particularly high quality Material or the sliding contact when moving over the Resistance element not only in the longitudinal direction, but also in the transverse direction at the same time has moved, so that when you paint over, the resistance element different parts of the wiper come into contact with the resistance element and thereby wear is distributed over a larger part of the grinder surface. With a straight outstretched one Resistance element has z. B. the slider on a swivel arm with a very large Radius attached so that the grinder is not a straight one, but a curved one Movement performs on the resistive layer. With resistance elements curved in the shape of a circular arc the axis of rotation of the grinder is slightly opposite the center of the circular arc offset. In both embodiments, however, difficulties arise when one has a certain relationship between the deflection of the wiper and the change in resistance wants to achieve depending on this deflection. It is an arrangement though to change the value of an ohmic or inductive resistance as required by means of a uniform rectilinear or circular movement Known tax body. There, however, the task is without any special shaping of the resistance carrier in the case of non-linear measured variables, scales with whole or partially proportional progression. This task is solved there by a special guide of the grinder. Especially with linear resistances, in which the resistance increase or decrease in the angular adjustment of the grinder should be linearly proportional, difficulties arise. Object of the invention is to eliminate these difficulties by simple means.

The invention relates to an electrical component with over one Circular arc of distributed impedance, in particular a variable resistor arrangement with a grinder whose axis of rotation is perpendicular to the plane of the circular arc lies outside the center of the circular arc. To achieve one of the angle changes proportional change in impedance penetrates the axis of rotation according to the invention Perimeter of the circle whose radius of curvature and center match that of the in Dependency of the arc length linearly distributed impedance bearing or forming component matches, at a point which is opposite the circular arc-shaped component. The pivot point of the grinder arm is therefore on the same circle, which is at least partially forms the center line of the circular arc-shaped component.

According to a preferred embodiment of the invention, the axis of rotation lies opposite the center of the circular-arc-shaped component. Depending on whether the impedance curve is linear as a function of the arc length covered on the circular arc-shaped component or follows another law, the increase or decrease in impedance, based on the angular deflection of the grinding arm, will also be linear in the arrangement according to the invention Follow the law of impedance change per arc unit of the distributed impedance linearly. The length of the contact element of the wiper is to be selected so that reliable contact is made with the component carrying the impedance, e.g. B. a resistance track is guaranteed.

The invention is not applicable to ohmic resistors limited, but can also be done with the same advantages with coils, their Inductance can be increased or decreased by adding or disconnecting turns target. Also other components with an arc of a circle according to a certain law distributed electrical impedance, e.g. B. a circular arc-shaped Lecher line, could be constructed according to the principle of the invention. The point where the axis of rotation of the grinder penetrates the circumference, lies on the part of the circumference, which is not covered by the resistance element. One becomes the penetration point expediently arrange opposite the center of the resistance element.

Arrangements according to the invention can be used in a number of ways in electrical or use electromechanical devices: e.g. B. as a changeable element in the bridge circuit of a compensation, display or writing device in which either another element changes depending on an input variable or connection options for the infeed of a depending on a any size changing signal are provided. This input variable can, for. B. be a temperature or a pressure. usually contains such a compensation device also an amplifier and a motor that respond to the error signal of the bridge circuit respond, wherein the motor adjusts the grinder arm so that the desired Adjustment is established. In these arrangements, the position of the grinder arm is at any time a clear measure for the amount of the input variable, so that the engine can also serve to drive a display or writing device.

The invention is particularly suitable for the formation of a balancing or feedback potentiometer serving resistor arrangement in a self-balancing Bridge circuit in which one in the presence of a difference between the actual Value of an input variable and that represented by the position of the grinder electrical variable occurring error signal a motor adjusting the grinder controls so that the error signal is reduced and the bridge circuit in the adjusted state is transferred.

The drawings show exemplary embodiments of the invention, namely F i g. 1 is a perspective view of the moving parts of a resistor assembly according to the invention, FIG. 2 is a diagram for explaining the operation of FIG new resistor arrangement, F i g. 3 is a block diagram of a control device with the new resistor arrangement.

The various parts of the arrangement according to FIG. 1 are usually carried by a metal chassis, not shown, which is fitted into a housing, also not shown. The scale 10 with the pointers 9 and 11 can be observed through a window in the front of the housing. The scale 10 is partially broken away so that the remaining parts of the device are visible. The pointer 9 is carried by an arm 25 which is attached to the axis 4 of the motor 5 and rotates with this motor axis. The arm 25 is attached to the axle with the aid of a socket 25 a and grub screws, not shown. On the side of the axis 4 opposite the pointer 9 , the arm 25 carries the wiper arm 3 of the variable resistor arrangement according to the invention. The grinder arm 3 is attached to the arm 25 in an electrically insulated manner. He carries a contact member 26 in the form of a small silver rod. The electrical lead 27 for tapping is soldered to the grinder arm 3.

The resistor arrangement 2 has an arc-shaped resistor element, consisting of a copper bracket 28, which is isolated by a coating or the like and carries the winding in the form of a uniformly wound resistor coil 29. The two ends of the resistance coil 29 are connected to electrical lines 30 and 31 . The coil 29 can for example consist of Manganin wire and have a total resistance of 1250 ohms. The contact member 26 rests on the upper edge of the coil and the bracket. If the arrangement is only viewed from above, both the center 32 of the arcuate bracket 28 and the center of this arc lie on a line which connects the center of the scale with the axis 4 . The center point 32 is to be found on the side of the axis 4 facing away from the scale 10 at a distance from this axis which is equal to the radius of the circular arc 28 on which the resistance element is arranged. The center of the circle is in FIG. 1 denoted by 32. In this way, the grinder arm 3 rotates about an axis which penetrates through a point on the circumference of the circle which is partially formed by the arcuate bracket 28 . The axis is perpendicular to the circular plane.

F i g. 2 shows this arrangement schematically, with the grinder arm pivoted out of the central position. From this illustration it can be seen that in every position of the grinder 3, the angle CBA is always half as large as the angle COA. Therefore the arc length CA is always proportional to the angle CBA. From this it follows for each movement of the grinder arm 3 that the change in resistance is in each case directly proportional to the change in angle of the grinder arm 3. The change in resistance should be understood to mean the resistance between the end points of the respective wiper movement. If the coil 29 is wound onto the carrier 28 in such a way that the change in resistance per unit of arc follows a non-linear law, the change in resistance per unit of angle follows the same law, apart from a factor of two.

The arm 24 with the setpoint pointer 11 is attached to the output axis 45 of a drive 46 , which can easily consist of a crown gear and a pinion. The axis 45 is coaxially located below the motor axis 4. The input axis of the drive 46 is connected to the axis 48 with the help of a customary flexible drive, the slotted end of which is adjustable through the front panel of the device. The flexible shaft 47 is fastened to the device chassis with a clamp 49. The connection with the setting axis 48 is made by a thread 50. With this setting device, the setpoint pointer 11 can be set to any point on the scale 10 by turning the axis 48 by hand using a screwdriver or the like.

As shown in the block diagram of FIG. 3, the control device serving to measure, display and control the amount of an input variable contains a balancing circuit 1 with the variable electrical resistance arrangement 2 according to the invention. The grinder arm 3 is, as FIG. 3 shows schematically adjusted by an axle 4 driven by the motor 5. The adjustment circuit 1 also has an adapter for connection to the input 6. The type of adapter depends on the type and size of the input variables, but in each case has the task and effect that any element in the adjustment circuit depending on the amount of Input variable changes or that an electrical signal, e.g. B. a voltage or a current, which changes as a function of the input variable, is fed to the balancing circuit.

The balancing circuit generates an error signal in the form of a direct voltage which, according to polarity and size, reflects the difference between the actual value of the input variable and the comparison variable given by the slider position. This error voltage is applied to the input of a transistor inverter 7 , which derives an alternating current signal from the direct current error signal, which alternating current signal can be amplified in the transistor alternating current amplifier 8. The amplifier output feeds the control winding 5a of the motor 5 in such a way that the motor adjusts the axis 4 and thus the grinder 3 in such a direction that the error signal is reduced to zero. The position of the grinder 3 is always indicative of the amount of the input variable, so that a pointer 9 driven by the motor axis 4 can be provided, which moves over a scale 10 and shows the respective amount of the input variable.

To regulate the input variable, a setpoint pointer 11 is also provided, which can be set to any point on the scale 10 with the aid of a manual setting device 12 and a shaft 13. The shaft 13 also adjusts part of the control tap 14, the other part of which is adjusted by a drive from the motor shaft 4. The control tap 14 is electrically connected to a control circuit 15 , the control tap 14 and the control circuit 15 together generating electrical or other signals to enable the controller 16 to change the magnitude of the input variable such that the pointer 9 corresponds comes with the setpoint indicator 11. The control tap 14 can also be connected to a pneumatic or hydraulic controller.

The dashed connection between the controller 16 and the input 6 is intended to indicate this influence of the controller or the manipulated variable supplied by it on the actuator. If, for example, the input variable is a temperature, the controller can be a simple two-point controller for the burner, and the 1: 4 control tap with control circuit 15 switches the controller to "On" if the displayed temperature falls below the value specified by the setpoint pointer 11. Similarly, a. simple proportional controller or a controller with any control behavior can be used.

In the resistor arrangement according to FIG. 1, the control tap has a flag 20 fastened to the pointer 9 and a lamp 21 with a photodiode 22 carried by the setpoint pointer 11. The flag 20 is arranged in such a way that it interrupts the luminous flux from the lamp 21 to the photodiode 22 just when the pointer 9, coming from the left, enters the position of the setpoint pointer 11, that is, when the displayed measured variable increases and approaches the setpoint from lower values approaching. The flag 20 is so long that the interruption of the light beams continues until the pointer 9 reaches a temperature value which is approximately 4 ° C. above the setpoint temperature specified by the setpoint pointer 11. A further deflection of the pointer 9 is then prevented by limiting means, not shown, arranged on the arms 24 and 25.

Instead of a display device, a writing device can also be provided, the axis 4 only driving the arm 3 directly and being coupled to the writing mechanism drive via a mechanical connection. In such a case, the setpoint pointer 11 and the control tap 14 are connected to the recorder and the control circuit 15 is combined with the controller 16 to form an electrical controller or replaced by a pneumatic or hydraulic controller.

It should be emphasized that the control device described above only one embodiment for the application of the resistor arrangement according to the invention represents: Instead of the resistor arrangement with a wound wire resistor other resistance elements, such as sliding wire or carbon film resistors, can also be used. be used. The invention is equally suitable for linear resistors, as for resistors whose change in resistance follows a different law. Claims: 1. Electrical component with distributed over an arc Impedance, in particular variable resistor arrangement with a wiper, whose axis of rotation, perpendicular to the plane of the circular arc, outside the center of the Circular arc lies, d u r c h e -k e n n n z e i c h n e t that to achieve a change in impedance proportional to the change in angle, the axis of rotation the circumference of the circle whose radius of curvature and center are dependent on that of the the linearly distributed impedance of the supporting or forming component corresponds to the arc length, penetrates at a point which is opposite the circular arc-shaped component.

2. Electrical component according to claim 1, characterized in that that the axis of rotation is opposite the center of the circular arc-shaped component.

3. Electrical component according to claim 1 or 2, characterized in that that the impedance change as a function of the arc length in modification of the arrangement according to claim 1 is non-linear, namely in that the impedance is across the arc of a circle is distributed in a manner known per se according to a certain law.