DE1253342B - Follower for remote transmission of a movement - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

G05f

German class: 21c -46/51

Number: 1253

File number: K 51347 VIII b / 21 c

Filing date: November 13, 1963

Open date: November 2, 1967

Follower for remote transmission of a movement

Applicant:

Kistler Instrumente A. G., Winterthur (Switzerland) Representative:

Dipl.-Phys. R. Kohler, patent attorney, Stuttgart, Hohentwielstr.

Named as inventor:

Dipl.-Phys. Walter Paul Kistler, Clarence, N.Y.

(V. St. A.)

Claimed priority:

Switzerland of November 26, 1962 (13 827)

The invention relates to a follower controller for remote transmission of a movement with a transmitter for generating a control signal and an adjustable one as a function of this control signal Tracking element, the position of which determines the size of a compensation signal, and with an amplifier containing device for adjusting the tracking member until the control signal is canceled by the compensation signal.

Such a device is known which has an inductive transmitter and an inductive one Feedback works. This device requires an absolutely symmetrical structure and can easily are disturbed by influences that impair the symmetry of the structure. Furthermore, at the known device for the transmission of the measured values uses voltages, which at a larger Transmission path can be influenced to a considerable extent by external influences. Everyone unforeseen resistance in a line ao

leads to voltage drops that are not taken into account

and therefore the accuracy of the post- *

impair leadership. There can also be tension

influenced by extraneous errors to a considerable extent shows that depending on the position of the be. Another disadvantage of the known forward rod a direct current of a certain size and direction is that it is generated at least four direction, furthermore that the encoder is also designed to generate a direct current dependent on its position and the encoder direct current is an im Area of the follower 30 element arranged circuit is supplied, in which the voltage dependent on the difference in the direct currents is generated and fed to an amplifier, the output signal of which is used to feed the electromagnetic adjustment device of the follower machine, in which the stylus is a capacitive 35 element.
The use of a direct current for transferring control voltages that match the values generated by the encoder has the advantage that this current is proportional at every point of the voltages . However, this dimensional device is the same and therefore inadequate accounting does not eliminate the disadvantages of the above-mentioned device with unexpectedly large or even changed device. Seldom contact resistances do not play a role

The invention is based on the object of an adaptation, and also no adaptation, to the line length of the upstream follower controller to create that needs to be taken from those discussed above. Since only the Disadvantages of the known follower controller is no longer transmitted direct current value, two cables suffice. This object is according to the invention 45 lines for connecting the tracking devices, solved by the fact that the follower element is one in one. It is also possible to use the one that transmits the current value Housing has a displaceable rod that moves with the line through several follower devices Part of an electromagnetic adjustment to be carried out and in the area of each follow-up pre-device and also with the moving direction the comparison with that in the follower leading element a variable capacitor is provided to make the compensation current generated 50 direction, in the circuit of an alternating voltage source so that it is possible from a transmitter is arranged to control such a diode arrangement on several tracking elements.

709 680S12

necessary for the transmission and feedback of the values. Finally, it is with the known device also not possible to connect more than one follower link to the encoder.

It is known that instead of inductive transducers, capacitive transducers are also used in such follower controllers can be used. It has also already been suggested that scanning devices for copy milling

3 4

The structure according to the invention of the trailing link trailing element, which has a variable capacitor, des in the form of a high-frequency generator and a diode array that can be displaced in a housing Rod that includes with an electromagnetic order.

table adjustment device and at the same time with the in F i g. 1 shown follower exists

the movable member is so connected one to the control of the compensating circuit 5 from the transmitter unit A, and one or any number of sationsstromes serving variable capacitor receiver units B, C the transmitter unit A, resulting in a very simple and contains a variable capacitance, the robust by a Zylinsehr Structure of the device. A special capacitor with the fixed part 12 and the particular advantage here is that part 13 is formed in spite of the simple movable part. Instead of building the electromagnetic field of the adjustment device, a plate capacitor could also be used instead of the purely electrical field of the variable condenser. Furthermore, a high-frequency generator 14 is not influenced by the pre-capacitor and therefore no coupling hands, the output of which is connected to the primary winding between these two organs and that of a transformer 15. The circles belonging to it are to be feared. The outer winding is on the one hand connected to the device according to the invention and on the other hand is connected via a diode 16 to the capacitor part 13, which is very responsive and movable. A low inertia, which ensures that another diode 17 is located in the line 19 at point 18, so that even very fast movements with high precision are connected. At point 20, the sion is transmitted. Line 21 connected.

In the embodiment of the invention, when the movable capacitor moves, the ao may variable capacitor of the trailing element part 13, which is due to the displacement along the dimension maintaining Circuit which can be recognized by a rod 22, if necessary, the capacitance changes Transformer coupled high frequency genes of the capacitor 11 proportional to the executed rator and two mutually parallel and mutually rectilinear path. The capacitor 11 is below have mutually connected diodes. In series as the alternating voltage generated by the generator 14 to one of these diodes is then the output of and via the transformer 15 to the condenser transmitter circuit switched while the repeater is being transmitted. The one in the secondary circuit of the ker flowing across the capacitor in parallel to the transformer formed by the two diodes Series connection is coupled. But it is also reactive current is exactly proportional to the respective possible, instead of two parallel and opposing 30 capacitance of the capacitor 11 or to the one on your Diodes connected to one another have a Diodenanord- scale 22 readable measurement path, if the frequency tion to choose a Greatz circuit with four and the amplitudes of the oscillator 14 constant biei diodes forms. In this way one gets through ben and the diode arrangement practically in Kuiz full wave rectification a larger reference current. can work at the end. So the giver is a current

A generator with a high internal resistance,
variable double capacitor serve, one of which The receiver unit B is similar to the

Partial capacitance due to the movement of the transmitter unit to be measured from a variable capacitor 25 mechanical transducer part and its with fixed electrode 26 and movable electrode other partial capacitance increased by this movement 27, a high-frequency generator 28, a trans is, the double capacitor with 40 formator 29 and the rectifier diodes 30 and 31. a high frequency generator and four diodes according to the respective position of the movable capacitor type a ring modulator is interconnected; part can be read on the scale 32. In Here it can also be advisable to use exactly the same way as the one described above Branch of the ring modulator circuit in series with the transmitter unit generate the receiver diodes mentioned Arrange resistors. 45 divide a direct current, but it is reversed

The tracking element of the controller according to the invention is because the diodes 30 and 31 work in the opposite direction can further expediently be switched from direct current from a - compared to the transmitter unit. Current source controlled with high internal resistance The negative pole of the rectifier circuit - namely

This power source according to the borrowed the point 33 - is connected via the line 19 with the circuit arrangement of the follower element also 50 positive pole of the rectifier arrangement of the transmitter unit a circuit with high frequency generator, varia- also have the same with the one emblem capacitor and diode arrangement have an output terminal one Amplifier 34. The positive pole of the can; Every change in the rectifier arrangement of the receiver unit belonging to the transmitter - capacitance then causes a corresponding movement, ie the point 35 - is via the line 36 and a movement of the mechanical follower element. 55 further receiver units C connected in series

The invention is explained in more detail below with reference to the exemplary embodiments shown in and via the line 21 with the negative pole of the drawing, transmitter unit A (point 20), and also explained. But it also shows with the other input terminal of the

F i g. 1 shows a schematic representation of a booster 34. The receiver unit C is formed in the same way as the receiver unit B; the same parts current control signal generating encoder and one are provided with the same reference numerals,
Follow-up controlled by the DC signal. The output of amplifier 34 goes to a

member, magnetic coil 37, in whose field the bar magnet

FIG. 2 shows another 38 in a schematic representation. The latter is fixed to the movable one Embodiment of a transmitter for generating the 65 capacitor electrode 27 connected. The workSr DC control signal and the arrangement described is as follows:

F i g. 3 to 7 different embodiments for If the equalization generated in the encoder unit A

the circuit of a current designed according to the invention and the one in the receiver unit B or C

Claims (4)

if direct currents produced equal to each other, then the input of the amplifier 34 is voltage-free and so is its output. As a result, nothing happens. If there are differences in these currents, a relatively high voltage arises at the input of the amplifier 34, and the amplifier sends a current in one direction or the other to the coil 37, whereby the movable electrode 27 of the capacitor 25 is shifted to the left or to the right will. This shift changes the capacitance and thus the current flowing in the electrical circuit of the receiver unit. If the point is reached where the current in the receiver unit is the same as that in the transmitter unit A, there is again no voltage at the input of the amplifier 34, and the electrode 27 remains at the point reached. Any shift out of this rest position is counteracted by a current through the coil. If the corresponding circuits of the transmitter and receiver units are dimensioned the same, then the same currents also correspond to the same capacitances of the variable capacitors U and 25, and the same positions result for the movable capacitor parts. As mentioned, several receiver units can be connected in series. All units then inevitably have to adjust themselves in such a way that the amplifiers at the input and output remain de-energized. This condition then corresponds to the same positions of the variable capacitors. In this way, the receiver units B, C etc. each form a tracking unit which can be controlled very precisely with the aid of a direct current signal generated by a transmitter. Instead of the described transmitter unit A according to FIG. 1 could also be the one shown in FIG. 2 shown sensor unit A1 can be used, which is characterized by a very simple structure. It contains a battery 41, a potentiometer 42 and a resistor 43. If a battery with a high voltage and a large resistance is selected, as in the case of the transmitter unit A, a power source with a high internal resistance is obtained. There are various circuits for rectifying the reactive current of the capacitor used for capacitive displacement measurement. The F i g. 3 and 4 show two circuits for so-called pumping circuits. Both circuits use half-wave rectification. F i g. Figure 5 shows an example of full wave rectification in a ring modulator circuit. The measuring system according to FIG. 6 is somewhat modified in that it has a double capacitor, one of whose partial capacitances is reduced by the movement of the follower or trailing element, while the other is increased. In the middle position of the double capacitor, both capacitances are equal, and a direct current flows in the ring modulator. There is no voltage difference at the output of the circuit because the current is self-contained and one capacitor "pumps" the same amount of current in one direction as the other in the opposite direction. If the equilibrium is disturbed, more current is pumped in one direction and the difference between the currents must be balanced out by the external measuring circuit with the amplifier via 6g. The special feature of this system is that direct currents can be generated in both directions of flow. Since the internal resistance of the amplifier is in most cases significantly greater than the internal resistance of the ring modulator, it is useful in many cases to increase the resistance of the ring modulator so that the differential current is forced to flow through the outer circuit, and not simply flows through the diodes. Such a circuit with additional resistors R1, R2, Rs and Rt is shown in FIG. 7 shown. The invention is not restricted to the exemplary embodiments discussed. For example, the electrical-mechanical converter could also have a hydraulically controlled intermediate member or end member. Patent claims: 1. Follower controller for remote transmission of a movement with a transmitter for generating a control signal and an adjustable follower element depending on this control signal, the position of which determines the size of a compensation signal, and with a device containing an amplifier for adjusting the follower element until the control signal is canceled the compensation signal, characterized in that the follower element has a rod which is arranged displaceably in a housing and which is provided with the movable part (38) of an electromagnetic adjusting device (37) and also with the movable element (27) of a variable capacitor (25), which is arranged in the circuit of an alternating voltage source (28) which has such a diode arrangement (30, 31) that a direct current of a certain magnitude and direction is generated depending on the position of the rod, and that the transmitter (A) also generates one of his position dependent direct current is formed and the encoder direct current is fed to a circuit arranged in the area of the follower element, in which a voltage dependent on the difference between the direct currents is generated and fed to an amplifier (34) whose output signal is used to feed the electromagnetic adjustment device of the follower element. 2. Regulator according to claim 1, characterized in that the variable capacitor of the Circuit containing the follower element, possibly via a transformer (29) coupled high-frequency generator (28) and two mutually parallel and opposite to each other switched diodes (30 and 31) and that in series with one of these diodes (31) of the Output of the encoder circuit is connected, while the amplifier (34) in parallel with that of is coupled to the two diodes formed in series. 3. Regulator according to claim 1, characterized in that the diode arrangement consists of a Graetz circuit with four diodes (Fig. 6). 4. Regulator according to claim 1, characterized in that a capacitive displacement measurement variable double capacitor is used, one of which is a partial capacitance due to the movement to be measured of the mechanical converter part is reduced and its other partial capacity is reduced by this movement