DE461216C - Device for the remote transmission of data from automatic compensation measuring devices - Google Patents

Description

Device for remote transmission of information from automatic compensation measuring devices. In the known devices for automatic compensation of a measured variable usually a reversing motor is used, which increases the compensating size when running clockwise and reduced in counterclockwise rotation or vice versa. It becomes necessary for everyone Compensation process to accelerate the relatively large mass of the motor armature and delay. In the present invention, the drive motor runs with practically constant speed constantly in one direction while controlling the compensation direction is carried out by a friction gear. The essence of the invention should be explained on the basis of the schematic representation (Fig. i).

i is a measuring device whose information is displayed at a considerable distance should be, z. B. a power meter. A Ferrari drum is on the axis of rotation 2, while the current and voltage paths as a coil 3 next to the Ferrari drum are indicated. With the measuring unit i is a second measuring unit with drum d. and coils 5 coupled. The torque of the measuring mechanism q. is opposite to that of the measuring mechanism i directed and is kept at the same size by an automatic device. The current or the voltage on the coil 5 then give a measure of the application at the measuring unit i, and this current or this voltage is used to operate a remote indicator 6 used. On the common axis 2 of the measuring units i and -. is a pointer 7 attached, which carries a small thickening at its end, z. B. a ball that with a movement of the pointer between a bracket io and a rocker 20 swings freely. The movably mounted bracket i o is mediated by a resilient connecting rod .ii, a crank 12, a worm wheel 1 3 and a worm 1 ¢ from a shaft 15 periodically moved up and down. The shaft 15 runs at a constant speed always in the same direction; it is driven by an electric motor or the like.

The double-sided rocker 2o is rotatably mounted about an axis 2i. A downwardly resilient arm 22 engages a tab 23, which at its right end with a ring 2-. is articulated. The ring 2.4 is rotatably mounted on an extension of a double-sided friction disk 25, but in such a way that it cannot move on the extension in the axial direction. The double-sided disk 25 is mounted with tongue and groove 26 on a shaft 27 so as to be displaceable in the axial direction. A friction roller 16 attached to the shaft 15 runs between the two friction disks 25. A worm 28, which engages in a worm wheel 29, is also placed on the shaft 27. The latter is mounted on the axis of a rotary transformer 30 , the primary winding 31 of which is fed by an alternating current network. The secondary winding is on an armature 32; their ends are connected to terminals 33 via slip rings. By turning the armature 32, the voltage at the terminals 33 can be changed between zero and a maximum value. The voltage at the terminals 33 is used to feed the winding 5 of the compensation device 4 and at the same time to feed the remote indicator 6.

If the arrangement is in operation, the following game occurs: a) The torques on the two devices i and 4 are just the same. The ball 8 is then held on the pointer 7 ' by the spiral spring 9 precisely over the center of the rocker 2o, ie over its axis of rotation 21. If the bracket io now goes down, it will press the ball 8 down onto the rocker 2o, but the latter will not experience any change in position. After a short time, the bracket io releases the ball 8 again, and the pointer 7 can play freely. Then the bow goes down again and so on.

b) The torque on the device i outweighs that on the device 4. Then the pointer 7 strikes when the bracket io releases its ball 8, for example to the right. If the bracket io now goes down again, it presses down the right arm of the rocker 2o through the mediation of 8. Thus, through the intermediary of v011: 22, 23 and 24, the right of the two friction disks 25 comes into contact with the revolving roller 16 and is itself replaced in rotation. The armature 32 of the rotary transformer 30 is thus adjusted via the organs 26, 27, 28, 29 in such a way that the voltage at its terminals 33 increases. The current in the coils 5 and 6 and the torque on the compensation device 4 now also grow the rocker 2o is. Then the torques between i and .4 are fully compensated again, and the remote indicator 6 shows a new value which = corresponds to the new torque on the measuring device i.

c) The torque on device i is smaller than that on device 4. The -Pointer swings to the left, the left half of the rocker 2o will be at the following Descent of the bracket io depressed, and the left of the two friction discs 25 comes into friction with roller 16. As a result, the shaft 27 is reversed Meaning rotated as under b, the voltage at 33 drops, and it becomes in a similar way (read equilibrium between the torques at i and 4. established as below b described. Then the remote indicator 6 also shows your new torque again corresponding value on measuring device i.

In the present invention, the motor-driven one runs Wave 15 at a constant speed in the same direction, and only the friction disk 25 with its shaft 27 must be at a low speed when engaging be accelerated.

In the schematic Fig. I, the compensation measuring device 5 is with the Remote indicator 6 connected in series to terminals 33 of the rotary transformer. It it may be useful to have the two devices parallel to the type of voltmeter switch. For very long distances it is particularly advantageous as a remote instrument 6 to use an electrostatic voltmeter because of its low power consumption the resistance of the long-distance lines is practically insignificant.

Direct current can also be used to operate the instruments 5 and 6 use: then another suitable regulating device must be used instead of the rotary transformer 3o step.

The device according to the present invention cannot be Use only on the transmitter side of a telemetry line, but also on the receiver side. This is to be explained with reference to Fig. 2. For the essential part, the friction gear and its controls, here is one from @hh. i chose different form to agree = To be able to emphasize perfections of the inventive idea.

In Fig. I the remote instrument was labeled 6, in Fig. 2 the coil of this instrument is labeled 5o. The distance between donors and the desire to receive is very great; so that-to .the coil 5o of the receiving device only weak forces are available that are not sufficient to z. B. the pointer 57 of a writing instrument to operate. The coil 5o is on an axis of rotation 51 with attached to a pointer 52 which has a fork-shaped formation 53 at its end. A gripper 54, which is the outer end of a spiral spring, is also attached to the axle 51 55 summarizes, the inner end of which is attached to a shaft 56, which still has the registration pointer 57 and a bevel gear 58 carries. The task is now set, the rotating noinent to compensate at the coil 5o by a torque of the spiral spring 55 so that the pointer 57 indicates the measured value sought.

In Fig. 2 b represents a plan view of part a. The fork 53 of the pointer 52 freely embraces the center piece of a T-shaped lever 6o which is rotatably mounted at 61. The lever is based on the right end (io via a rotary ring 62 of a double-sided friction disk 63. On the left end of the lever 6o two helical springs 65, 6: I act. They serve to keep the lever 6o in the correct rest position. The shaft 70 is kept at a certain number of revolutions by a motor drive (not shown) .A friction roller 71 and a worm 72 are attached to this shaft 70. The latter engages in a worm wheel 73 which is rotatably mounted about an axis 74. On this axis 7.I there is also a cam disk 75 which rotates continuously with the worm wheel 73. To the right and left of the cam disk 75 are two levers 76, 77 which are rotatably mounted about the axes 78 and 79. Furthermore, in the levers 76, 77 two rollers So, 81 rotatably mounted, which are pressed by a helical spring 82 on the cam disc 75. The levers 76, 77 carry at their upper end cheeks 84, 85 which, when the lever moves on di e pointer fork 53 to move. .

The game of the Al) machine in operation is similar to that described on the basis of Fig. i. Are the two torques of So and 55 (Fig. 2) the same size, the pointer fork 53 is in the middle between the two cheeks 84 and 85 (: see Fig. 2b). These do not become the fork 53 during their movements touch. However, if the fork 53 arrives due to the inequality of the two torques So and 55 from the middle position, the fork is through the cheek 84 or 85 on the Middle part of the lever 6o pressed, whereby further the double-sided series transmission 63, 71 is engaged and clockwise or counterclockwise via the bevel gears 67, 58 the torque of the spring 55 changes. This game is repeated with the periodic ones Movements of the levers; 6 and; , until between the torques on the Coil So and on the spring 55 how (equilibrium prevails.

Fig. 2 illustrates another important measure that can be applied to the sending and receiving apparatus with equal advantage. The cheeks 84 and 85 have the shape of a wedge, as a result of which the mechanical contact between the pointer fork 53 and the lever 60 lasts longer, the further the fork 153 has moved away from the central position. The greater the deflection of the pointer 52, the longer the friction gear will remain engaged during the next game and the compensating torque of the spring 55 is changed by the greater the amount. The duration of the mechanical contact between the cheeks 84 and 85 and the lever 6o can also be influenced by the shape of the cam disk 755 (FIG. 2). These two precautions make it possible to completely compensate for a change in the torque at the coil So the next time the friction gear 6, 3, 71 is engaged, which significantly increases the speed at which the receiving instrument follows the transmitter instrument.

Fig. 3 shows a further embodiment of the inventive concept, which is particularly suitable for the remote display of the information of such instruments that have no mechanical torque in normal execution, z. B. phase meter, frequency meter, olimmeter and the like. The whole measuring device ioo is mounted in Fig.3 on an axis of rotation to rotate. The red pointer again has a fork 103 at its end. The mechanical control device and the double-sided friction gear, which would roughly correspond to the illustration in FIG. 2, have been omitted in FIG. 3 for the sake of simplicity. Only the end of the driven shaft 1o6 is shown. This shaft tob rotates the entire measuring device i oo via bevel gears 1 07 and i o8. When phasing z. For example, the directionless pointer 102 also assumes a very specific position relative to the instrument body for a very specific phase shift. If the instrument body is rotated in such a way that the pointer fork 103 comes to the same place in space with each phase shift, the position of the body ioo gives a measure of the phase shift Instrument ioo in such a way that the pointer fork 103 is at a very specific point in space, i.e. in the middle between the cheeks SI and 85 of Fig Fig. I is shown at 30, 31, 32, 33, its voltage, which can be conducted into the distance, gives a measure of the phase shift to be measured.

In the above description, the task of remote measurement is in put in the foreground. Of course, the idea of the invention can also to solve other metrological questions, e.g. B. to registration very much weak currents, as already explained in the explanation of Fig. 2. Furthermore, l; öiintc- instead of the double-sided described Friction gear 25, i6 and 63, 71 a corresponding toothed gear or the like.

Claims (3)

PATENT CLAIMS: i. Device for remote transmission of data from automatic compensation measuring devices, characterized in that a shaft (i5) driven with the same speed and direction of rotation acts on a double-sided friction gear (25, 16) in this way. that its right or left disc (25) is coupled by periodically depressing the pointer (7) of the measuring device (i to q.) with the assistance of a rocker (io, 2o) moved with the drive shaft (i5) and thereby its associated shaft (27) is rotated with a rotary transformer (30) in one direction or the other, which in turn acts on a remote indicator (6) and the compensation measuring device (i to 5) of the encoder, so that electrical contacts and greater wear are avoided and no greater inertia need to be accelerated. 2. Device according to claim i, characterized in that d.aß especially with the so-called directionless measuring devices by the double-sided Friction gear (at io6) rotates the whole measuring device (ioo) around its axis (ioi) will, 3. Device according to claim i and 2, characterized in that particular in the case of large distances between the sending and receiving instruments, the latter is an electrostatic one Voltmeter is used. 4 .. device according to claim i to 3, characterized in that that also at the receiving point of the Fernmeßleitungg a double-sided friction gear (63, 71) according to claim i is installed, especially when the incoming electrical Energy is too low to operate the desired measuring instrument.