DE411087C - Switching device for automatic remote registration or remote display of physical processes, such as changes in pressures, flow speeds, level heights, voltages and the like. Like., By means of synchronously moving drives on the transmitting and receiving station - Google Patents

Description

Switching device for automatic remote registration or remote display of physical processes, such as changes in pressures, flow velocities, Levels, voltages, etc., by means of synchronously moved drives on the transmitter and recipient location. According to the Union Treaty of z. June ig i i the priority based on registration in the Czechoslovak Republic from io. March igzz claimed. The subject of the invention is a switching device for automatic remote registration or remote display of physical processes, such as changes in pressures, flow velocities, level heights, tensions and the like, by means of synchronously moving drives on the sending and receiving stations. Electric remote indicators are already ordering, with a l'endelsclieibe of the transmitter with a contact of a pressure detector and a pendulum disc of the Receiving apparatus by means of a writing device attached to it with the Registration drum cooperates. When brought about by a spring from time to time Swinging out of the pendulum disc occurs when the contact of the pressure detector is touched a record corresponding to his position is made on the recording drum. The invention consists in another solution to the problem in such a way that on the pointer caused by the print or other change in the sending station or lever deflection an auxiliary value that is inevitably changed periodically, such as B. a inevitably rotating auxiliary arm, the force of a periodically tensioned spring, etc. Like., acts in such a way that a when establishing the state of equilibrium between the expression of force to be measured and the auxiliary worker or when the Auxiliary arm with the pointer caused current short on a part, which is by a synchronously with the motor of the transmitting station, which periodically changes the auxiliary value there running motor of the receiving station is inevitably moved in the same periods, acts in such a way that a recording is made on a moving recording tape takes place, which corresponds to the equilibrium state bnv. (A meeting point between the two arms in the encoder station. The device according to the invention is suitable for remote measurement of both physical and chemical processes, which have a physical Process, e.g. B. cause a change in volume. By the device according to the Invention is compared to the known @ "devices greater accuracy and Reliability of the transmission, achieved and the field of application expanded.

In the drawings are two embodiments of the device shown according to the invention. Fig. I shows scllemati> cli vain device for Remote registration of full pointer positions of a measuring device. Fig. 2 also tends schematically a device for remote registration of a changing pressure. Fig. 3 is a detail of Fig. I.

In the device according to Fig. B. a pressure, a flow velocity, level height, an electrical voltage or the like, in the position of a pointer 4 .. A synchronous motor with magnetic poles 54 and winding 56 and armature 5o with winding 52 (Fig. 3) drives a wave 48 with the mediation of a translation 46, -.d. a shaft 42 which is connected to a shaft 41 by a differential gear 2.4, 26, 28, 30. The shaft 41 drives, through a transmission 22, an insulated contact disk which is conaxial with the axis of rotation of the pointer 4 and on which a contact arm io is seated. This arm io carries a contact 12 which interacts with the contact tip 6 of the pointer 4 -rusaminen. The pointer d., 6 is connected to one pole of a battery 6o by a sliding contact 8, while the contact disk 2o is grounded at 66 by a sliding contact i8.

The synchronous motor 5o to 56 is connected to an alternating current network 58, the other pole of the battery 6o via a choke coil is also connected to one of the conductors 62 is connected. In addition, the contact 18 with the choke coil 62 is below Interconnection of a capacitor 64 connected.

At the receiving point E there is a synchronous motor 70 with an armature 72 carrying windings 74, which drives an arm 88 which is rotatable about an axis 86 through the intermediary of transmissions 76, 78 and 84 and with the interposition of a differential gear 8o, 82. This arm 88 moves over a recording belt 92, which is also continuously moved by the motor 70 , and carries at its free end 9o a recording element, e.g. B. a pen or the like writing over a ribbon. The free end of the arm 88 engages with its free end a one-armed lever 96 which is mounted in a bearing 98 and carries the armature ioo of an electromagnet io2. The electromagnet io2 is via a choke coil io8 and a conductor of the alternating current network 58 connected to the Stromduelle 6o of the transmission point S and io-. grounded; Furthermore, the electromagnet io2 is bridged by a capacitor io6.

The width of the registration tape of the receiving station E corresponds to your maximum deflection of the pointer 4. of the transmitting station S, which does not exceed i $ o °.

The device described works as follows: The pointer .I of the apparatus 2 takes one of the respective value of the physical or chemical variable to be measured, e.g. B. the level, corresponding position. The synchronous motors 50 to 56 and 70, 72 rotate uninterruptedly on the one hand the arm io on the transmitting station S and on the other hand on the receiving station E the arm 88 in a uniform synchronous gear. At the moment when the arm io shows the position of the pointer q on the transmitting station S. reached, contact 6, 12 and the following circuit are closed: 6o, 8, .1., 6, 12, io, 20, 18, 66, 104, i o2, i o8, 58, 62, 6o. The reactors 62 and io8 pass the direct current of the battery 6o while holding back the alternating current of the mains 58. The current of the battery 6o in this circuit lasts only a moment because the contact 6, i2 is immediately interrupted again when the arm io continues to move. The current pulse of the battery 6o excites the electromagnet io2 of the receiving station E, which attracts its armature i oo and presses it with your lever 96 on the arm 88, so that the end 9o of the latter enters a point on your paper 92. The location. this point in the width direction of the recording tape 92 corresponds to the current position of the pointer .4 on the transmitting station S and therefore also to the current value of the variable to be measured. The individual points entered form a diagram line 9.4 on the paper.

In order to be able to control the synchronous operation of the transmitting and receiving stations S and E, is on the transmitting station S at a certain point, z. B. at the zero position of the pointer 4, a connected to the battery 6o contact 16 is provided, which correspond to two isolated contacts 14 on the arm io. As soon as the arm io passes the zero position, the contacts 16, 14 are closed in quick succession, and two pulses arrive in the circuit 6o, 16, 1q., Io, 2o, 18, 66, io4, io2, io8, 58, 62, 6o of the battery 6o in quick succession in the electromagnet 102 of the receiving point E, so that two points 93 are entered on the recording tape 92 at its zero line. These colons form a double line 93 at the zero line, the straight course of which indicates the synchronous gear. The exact match of the zero positions .der the arms io and 88 on the transmitting and receiving stations S and E can be achieved by the differential gear 2q. to 30 and 8o, 82 can be adjusted. For this purpose, a gear wheel 32 engages in the ring gear 3o of the differential gear 24 to 3o, on the axis 34 of which a disk 36 and a button 38 are fixed. The disc 36 is clamped on its periphery by a nut .Io. After it has been released, the gear wheel 32 can now be rotated with the aid of the knob 38, whereby the differential gear 24 to 30 and thus also the arm 10 are created. After the precise adjustment of the arm io, the middle part 28, 3o of this differential gear is fixed again by tightening the nut. In a similar way, the adjustment can be carried out on the receiving stationE.

In this version, the regularly changing position of the Armes io an auxiliary variable which corresponds to the original size, i.e. i. the location of the Pointer 4th, interacts. When reaching a predetermined level this Cooperative, in the present example the correspondence of the positions of the arm io and the pointer .l, a pulse of the auxiliary electrical energy 6o arises, which on the receiving station E the current position of the synchronously driven there Armes 88 registered. The synchronous motors are used to transmit the pulses 56 and 7o driving current applied.

Figure 2 shows the facility of a transmitter for remote registration of the pressure of any medium acting on a Bourdon tube 120 through a 1:24 line. The Bourdon tube 12 adjoins a pressure chamber 122. The free end of the tube i2o is connected by a tie rod 126 to one arm of a lever 1 28 pivotable on blades 130 , the other arm of which lies between two .Anschllagen 132 and 134 and carries an extension 136 serving as a contact. The contact 136 is connected to one pole of a local power source 162. Opposite the contact 136 is an insulated leaf spring 130, which is supported against an adjusting and contact screw 142, which is grounded with its nut part at 144. The arm of the lever 128 carrying the contact 136 is loaded by a tension spring 146, the other end of which terminates in a flexible member which is wound on a roll 148. This roller r48 is rotated by means of a transmission i 50 by a shaft 152, which is again driven by a transmission 154 from a reversing motor 156 fed by the power source 162. The middle terminal of the motor 156 is connected to one pole of the battery 162, the other pole with a z. B. is connected by a clockwork 17a actuated switching arm 178. The arm 178 operates between two contacts 174, 176 which are connected to fixed contacts i8o of a circuit breaker. The resilient mating contacts 182 of the same are connected to the outer terminals of the motor 156. The roller 148 carries a stop pin 18: I, which always interrupts one of the contacts i 8o, 182 in the two end positions and brings the motor 156 to a standstill by opening the circuit 162, 156, 182, i8o, 174, 178, 162. The clockwork 172 then switches over the contact arm 178 and lets the motor 156 run in the opposite direction until the stop 184 in the other end position again interrupts the other of the contacts 18o, 182. The clockwork 172, which is independent of the motor 156, operates so that it always switches the contact arm 178 after the circuit has been interrupted by the stop pin 184.

A three-phase rotor 158, the stator winding of which 16o is fed from the current source 162. The rotor 158 has rings 164 and brushes 166, which through a trunk line 168 with the brushes of rings igo of a three-phase motor 192 of the receiving station E are connected. The excitation winding 194 of this motor is fed by a local battery 196 of the receiving station E.

The three phase motor 192 drives an arm through a transmission 198 Zoo, who with his registrar 2o6 over a registration tape 202 regularly swings back and forth. About the arm 200 engages a stored in a bearing 2io, the armature 214 of an electromagnet 2i2 carrying lever 2o8. The electromagnet 212 is grounded on the one hand at 216 and on the other hand through a long-distance line i 7o with connected to one pole of the battery 162 of the transmitting station S, the other pole via contacts 136, 130, 142, i4o is grounded at 144.

The device described works as follows: The Bourdon tube 12o loads one end of the lever 128 with a force that is dependent on the pressure to be measured. The spring 146 acts on the other end of the lever and is periodically tensioned to a maximum by the rotation of the roller 148 in one direction and the other and then relaxed again to a minimum. At the minimum of the force of the spring, the force of the Bourdon tube 120 always predominates, so that the lever 128 is supported against the upper stop 132. When the spring 14.6 is tensioned, the movement 172 closes the contact 178, 174 and thereby the circuit 162, 156, 182, 18o, 174, 178, 162, and the roller 148 rotates in the direction indicated by the arrow. When the spring 146 is tensioned, sooner or later, depending on the magnitude of the pressure acting in the tube 120, the moment occurs when the force of the tube 12 acting on the lever 128 and the force of the spring 146 keep one another in equilibrium. At this moment the lever arm 128 loaded by the spring 146 begins to move away from the stop 132 towards the stop 134, and its extension 136 touches the resilient contact 130. This closes the following circuit: 162, 136, 130, 142 , 140, 144, 216, 212, 170, 162. Immediately thereafter, the lever 128 pulled further downward by the spring 146 brings the contact spring 1 30 away from the contact screw 142 and interrupts this circuit, so that the electric magnet 212 only has a short Current surge of source 162 is energized. As a result of this current surge, the current position of the arm Zoo is entered as a point on the recording paper 2o2 at the receiving point E. The points form a diagram line 204.

In addition to the roller 148, the three-phase rotor 158 is driven by the motor 156 at the same time; the electric current induced in this rotor drives the three-phase motor 192 of the receiving point E exactly synchronously, so that the arm Zoo executes a movement which is exactly proportional to the rotation of the roller 148 and therefore also to the tension of the spring 146. Since the electric current pulse is produced in a moment when the force of the spring holds 146 of the force of the Bourdonschen tube 12o the balance, the position corresponding of the point in the diagram 204 in the width direction of the recording tape 2o2 also the size of the JE in Bourdonschen tube because of the acting pressure.

After the current pulse, the roller 148 continues to rotate and tension the Spring 146 even more up to a maximum, at which the stop 184 the right brings lying spring 182 away from contact i8o and the circuit 162, 156, 182, 18o, 17q., 178, 162 interrupts. The motor 156 stops. If then by the clockwork 172 the contact 17q., 178 is interrupted and the contact 176, 178 is closed, so the motor 156 in the circuit 162, 178, 176, left contact iSo, left contact spring 182, 156, 162 driven in the opposite direction. He thereby rotates the roller 148 and the rotor 158 opposite to the direction of the arrow and relaxes the spring 146. There is another moment when the force of the spring 146 equals the force of the Bourdon tube i2o keeps the equilibrium. At that moment touched again the spring contact 13o the screw 142 and sends in the electromagnet 212 of the Receiving station E a current pulse, which is immediately restored by lifting the extension 136 is interrupted by contact 130. The impulse again has the entry of one Point in diagram 204. When the roller is rotated back i.1.8 rotates also the rotor 158 and consequently also the motor 192 in the opposite sense.

When the spring 146 is relaxed, the stop 184 abuts against the roller 148 the left spring contact 182 and brings it away from contact i8o, causing the motor 156 stops again until the movement 172 interrupts the contact 176, 178 and the contact 174, 178 turns on again, after which the game repeats.

In this embodiment, the force of the spring 146 forms an within certain limits periodically regularly changing auxiliary variable. As soon as a certain Relationship between this auxiliary variable and the physical or chemical to be measured Size, here the pressure in the Bourdon tube i2o, is reached, e.g. B. an equal weight at a certain leverage, the impulse of the auxiliary energy arises, here the power surge from the source 162. The electric motor 156 driving the transmitter at the same time drives a Synchrondvnamo 158, which a synchronous motor i g: 2 for Drive of the receiving apparatus feeds. In this way there is an exact synchronism achieved without the use of synchronizers, and to drive the two A single common motor 156 is sufficient for stations.

Claims (2)

PATENT CLAIMS: i. Switching device for automatic remote registration or remote display of physical processes, such as changes in pressures, flow rates, Levels, voltages, etc., by means of synchronously moved drives on the transmitter and on the receiving station, characterized in that on the in the sending station (S) pointer or lever deflection caused by the pressure or other change (from q. or 128) a periodically inevitably changed auxiliary value (rotating auxiliary arm io, tensioned spring 146 0 of the two forces (12o, 46) or when the auxiliary arm (io) meets with the Pointer (4) caused a current short (136, 130, 1.I2 or 6, 12) to a part (2oo or 88), the by one with the motor (156 or 56) of the transmitter (S), the There auxiliary value (146, i o) changes periodically, synchronously running motor (192, 70) the receiving point (E) is inevitably moved in the same periods, in such a way acts that on a moving recording tape (2o2, 92) a record (2o4, 94) takes place, the equilibrium state (between 146, i2o) or the coincidence corresponds to the two arms (4, io) in the encoder point (S). 2. Switching device according to claim i, characterized in that between the drive member (1lotor 56, 70) and the driven part (io, 88) on the transmitter and receiver points (S and E) a differential gear (24 to 3o and 8o to 82) switched on in this way is that by adjusting the middle part of the same the mutual position of the synchronously running parts (io, 88) of the sending and receiving points (S and E) exactly can be adjusted.