DE2006996A1 - Transducers for linear movements or angular movements - Google Patents

Description

Transducer for linear movements or angular movements The invention refers to differential transformer transducers for linear movements or Angular movements, in particular for setting recording galvanometers, with a primary winding fed with frequency current and a signal voltage supplying secondary winding are provided, furthermore one of the windings of two there is oppositely connected coils and one with the movable organ, whose Movement is to be recorded or to be captured, connected movable magnetic Shunt is provided.

Galvanometer for recording periodic processes with the frequency between 0 and 200 Rz, generally consist of a movable coil, which moves in a magnetic field and takes a pen with it.

This pen makes a visible trace on the rolling paper for example by means of color or heating. The end of the pen can describe a straight or curved path. In the former case, the rectilinear recording with the help of a mechanism built into the pen or by means of an edge can be achieved over which the paper is pulled and on which the pen rubs.

Usually the moving frame is closed by means of a return spring in Held at rest. In order to overcome the torque of this spring one does not have to negligible energy can be applied. To avoid this disadvantage, the spring can be omitted and the axis of the galvanometer with a transducer for Angular position are provided. This transducer generates an electromotive Force, which an electrical titersersion of the angular position of the spring or the Represents the pen. This voltage is compared with the voltage to be recorded. The difference between these two voltages, i.e. H. the so-called "error signal" is amplified and converted into electricity to feed the moving frame.

In the case of a galvanometer with a transducer for angular positions the frame therefore only traversed by the fault current, that of the difference between the actual position and the desired position of the frame depends.

This current must be sufficient to cope with the friction and inertia of the moving System to overcome. Since the frictional forces are small, a small amount of energy is sufficient to move the spring or pen at low speed. Against it if the inertial forces are greater, the more the moving system is accelerated will. Therefore, the higher the currents, the higher the currents must be fed to the frame frequencies to be recorded. To get the best results, the moving System equipped with minimal inertia and the amplifier chain with correction circles Mistake.

the latter are said to be the "error signal" of the speed and the Add proportional signal to the acceleration of the moving system. The angular velocity signal can optionally be obtained via a separate transducer, which consists of a small moving frame in a magnetic field.

There are known transducers for angular positions which use a potentiometer with low torque, with a circular or rectilinear path given is. In the latter case, the web can be immediately below the end of the Be arranged pin.

There are also known transducers for angular positions, which are equipped with a differential transformer. -This transformer has three coils, which are arranged on three cores, each at one end are connected to each other. The two outer cores are each on their other End connected by a magnetic circuit1 which is connected by a bust gap of is separated by a pole piece connected to the central core. The middle coil a current is supplied with a high frequency related to the frequency of the processes to be measured, so that there is a magnetic field which turns into two fields, which cause electromotive forces in the two outer coils that are opposite are connected. The potential difference between these two coils is therefore zero. If, however, a magnetic shunt is arranged in the air gap, then it is the potential difference is no longer zero, but rather all the greater; the farther the shunt is removed from the axis of the pole piece connected to the central core is. In another embodiment, the magnetic shunt is through a circuit breaker which surrounds the magnetic circuit and moves in the i14ftspa% t. the Winding creates a field which is opposite to the field which crosses it and causes a weakening of the field in the nearest coil emerged.

The object of the invention is to provide a differential transformer pick-up to convey the type described at the beginning, which compared to the known transducers - improved is. The differential transformer pick-up according to the invention is characterized by such a closed magnetic circuit that the The field generated by the primary winding completely flows through the secondary winding.

In an advantageous development of the invention, the magnetic Circle essentially rectangular, with the two coils of the two-coil winding are placed on two opposite arms of the circle, while the second Winding on one of the other two arms of the old man is arranged in parallel to which the shunt is movable. Further advantageous embodiments of the invention can be found in the attached subclaims three to twelve.

Below are embodiments of the invention. based on the attached Drawings described for example.

In these show: FIGS. 1 to 5 each show a view of a different form of embodiment of the transducer according to the invention Fig. 6 is a view of a transducer with double Differential transformer, which is equivalent to the transducers according to FIGS. 4 and 5 Fig. 7 is a view of another form of bus routing of the pickup according to the invention; 8 shows the perspective illustration of a galvanometer with a movable frame, which is equipped with a transducer according to the invention.

The transducer shown in Fig. 1 consists of a closed one magnetic circuit 1 on which a Primary coil 2 and two identical Secondary coils 3 and 4 are arranged. The circle 1 is rectangular. The coil 2 is long and has one or more layers of adjacent wires on. The coil 2 is arranged on an Itängsarm 1a of the circle 1, while the Coils 3 and 4 which are opposite. are divided on the cross arms Ib and flc of the circle 1 are provided. The coil 2 is fed with a current whose Frequency is high with respect to that of the transducer. When the pickup on frequencies of 200 Hz should respond, then the frequency of the coil 2 is given up Current for example 20 EHz.

The magnetic field generated by the coil 2 traverses one after the other the coils 3 and 4 and causes the same electromotive forces in these. the The total potential difference is therefore usually zero.

A magnetic shunt 5 whose position matches that of the organ is coupled whose displacement is to be determined is between the two Arranged longitudinal arms la and 1d of the magnetic circuit 1, in the direction the arms 1a and Id are movable.

The turns of the coil 2, which are to the left of the shunt 5, call thus a field emerges, the largest part of which passes through the coil 3 and above the shunt 5 closed iSt.

Likewise produce the turns of the coil 2, which is to the right of Shunt 5 lie, a field, the largest part of which passes through the coil 4. Between Coils 3 and 4 therefore have a potential pifferene which is greater - the further the shunt 5 is removed from the transverse axis of the circle 1. This potential difference is. zero if the shunt 5 lies in this axis, and returns when it traverses this axis Reverse the phase.

In the embodiment shown in Fig. 2, the magnetic Shunt 5 is replaced by a short-circuit winding 6 which is displaceable on coil 2 is. This turn, which is cut out of a conductive, lightweight metal, for example is, such as liuminiui, creates a magnetic barrier in the area in which it is located. Their effect can be compared to that of an air gap High magnetic resistance are compared, which moves with the winding 6. The magnetic field thus runs according to arrow H3, around itself through the coil 3 to close, and according to arrow H2 to close through the coil 4 through. The coils 3 and 4 also have a potential difference here, which is different from the Position of the turn 6 depends and is zero when this turn 6 in the middle Transverse axis of the coil 2 lies.

The same result is achieved when the turn 6 on the longitudinal arm ld of the magnetic circuit 1 is arranged as shown in Fig. 3, or when one turn is arranged on the coil 2 and one turn on the longitudinal arm ld becomes, as in the embodiment according to FIG. 4 the case. In the latter embodiment the two windings are designed as a plate 7, which consists of a metal, which is very conductive, but not magnetic.

If there is one turn on the spool 2 and another on the long arm 1d Turn is arranged, then the current flows in the first turn in one Direction, but opposite in the second turn. The two turns can therefore connected in series and designed as an 8-shaped curved conductor loop 8 as shown in FIGS. 5, 7 and 8.

With low coupling losses, the two turns are exhibiting Devices according to FIGS. 4 and 5 are equivalent to a double magnetic circuit, as shown in FIG. There are two magnetic circles 1 and 1; ' intended, which respectively the coil 3 and 'a coil 2 or the coil 4 and a coil 2' have, the two turns having a fictitious air gap in circle 1 and circle 1 '. The series connection of the two windings according to, for example, Fig. 5 is equivalent to coupling the two magnetic circuits through their arms 1c and 1tb.

The primary coil can be partly on an arm 1a and partly on it another arm 1d of the magnetic circuit can be arranged, as can be seen from FIG. The coils 9 and 9 'are arranged in series, so that one in magnetic circuit 1 Field is generated in the same direction.

All the arrangements described can be used in reverse, d. H. the high-frequency current can be applied to coils 3 and 4 while the voltage on the terminals signaling the displacement of the movable organ the bobbin 2 or the bobbins 9 and 91 is removed.

In Fig. 8, a galvanometer is shown, which with an inventive Transducer is provided. The galvanometer has a frame 10 in the air gap of a magnet11 is movable. The axis 12 of the frame 10 is with a lever 13 provided, to which the magnetic shunt is attached, the 8-shaped bent Conductor loop 8 is formed. The frame 10 is fed with a current, which the difference between the signal received in the transducer and the appropriately demodulated signal and is proportional to the signal to be measured. The error signal is amplified and processed according to the rules of the assigned system.

The axle 12 is also provided with a pin or a spring 15, which results in a straight line recording on an edge 16. The tangent of the The deflection angle c must be proportional to the signal to be recorded. The transducer enables this correction to be carried out because the magnetic circuit 1 is rectilinear is. It is sufficient to give the conductor loop 8 enough play so that they have a can describe a curved path without touching any part of the circle. That from The signal generated by the transducer is then tg o (proportional, but not CX, and man maintains a very good linearity of the.

Recording. If the angle iX is to be recorded, it is sufficient to give the magnetic circuit 1 arcuate shape, the center of curvature lies on the axis of the galvanometer.

The transducer according to the invention provides numerous advantages. He is simple in construction because the magnetic circle is a simple rectangle and has no intricate shape.

There is no need to produce an air gap with great precision obtain a high linearity. Easy processing with homogeneous materials gives excellent results. The output signal is increased. The correction in tg CK +.

for certain types of galvanometers is easy to obtain. Same principle is for transducers of linear movements and for transducers of angular movements suitable. Legs approximation is infinite, furthermore the dimensions can be very small be.

Claims (12)

Expectations (% yI. Differential Transformer Pickup for Linear Movement or angular movements, especially for setting recording galvanometers, wherein a primary winding fed with high frequency current and a signal voltage supplying secondary winding are provided, furthermore one of the windings of two there is oppositely connected coils and one with the movable organ, its Movement is to be recorded or to be captured, connected movable magnetic Shunt is provided, characterized by such a closed magnetic Circle (1) that the field generated by the primary winding (2; 9,9 ') is the secondary winding (3,4) flows through completely. 2. Sensor according to claim 1, characterized in that the magnetic Circle (1) is essentially rectangular, the two coils (3, 4) being the two-coil Winding on two opposite arms (Ib, Ic) of the circle (1) are arranged, while the second winding (2) on one of the two-other arms (la, 1d) of the circle (1) is arranged, parallel to which the shunt (5; 6; 7; 8) is movable. 3. Sensor according to claim 2, characterized in that the second Winding consists of two series-connected coils (9, 9 '), each on one the other two arms ('pa, Id) of the circle (1) are arranged (Fig. 7) 4. Transducer according to one of the preceding claims, characterized in that it is at the winding around the secondary winding consisting of two oppositely connected coils (3, 4) acts. .5. Sensor according to one of Claims 1 to 3, characterized in that that it is the winding consisting of two oppositely connected coils is the primary winding. 6. Sensor according to one of claims 2 to 5, characterized in that that the shunt consists of a Eurzschlusswindung (6) on one of the other Arms (la, Id) of the circle (1) is arranged (Fig. 2,3). 7. Sensor according to claim 6, characterized in that the turn (6) is arranged on the second winding (2) (Fig. 2). 8. Sensor according to claim 6, characterized in that the turn (6) on the arm (la) opposite the second winding (2) Arm (1d) of the circle (1) is arranged (Fig. 3). 9. Sensor according to one of claims 2 to 5, characterized in that that the shunt consists of two turns (7; 8), which on the second winding (2) or on the opposite arm (led) of the circle (1) (Figs. 4, 5, 7, 8). 10. A transducer according to claim 9, characterized in that the second Winding of two coils (9; 9 ') on opposite arms (la; ld) of the circle (1) and the turns (7; 8) each encompass one of the coils (9; 9 ') (Fig. 7). 11. Sensor according to claim 9 or 10, characterized in that the turns as a plate (7) made of highly conductive, non-magnetic Metal are formed - (Fig. 4). 12. Sensor according to claim 9 or 10, characterized in that the turns are designed as an 8-shaped curved conductor loop (8) (Fig. 5, 7, 8). L e r s e i t e