DE1098083B - Remote control receiver for audio-frequency network overlay remote control systems - Google Patents

Description

Remote control receiver for audio-frequency network overlay remote control systems Network overlay remote control systems, also called ripple control systems, are known to be used to do this, switching commands from a command post via the electrical power distribution network to be able to send to all consumer points of the network, be it for tariff changeover of counters, be it for switching consumers on and off, e.g. B. boilers, stoves, Street lights, etc., or to control switches.

In a known manner, this is done by a transmitter at the command post audio-frequency impulses are given to the network, and the locations to be controlled have receivers, which respond to predetermined commands and the intended switching function carry out. Among the various known overlay remote control systems the most common ones are based on the time interval method. With this one will be A sequence of command pulses is assigned to the start pulse on the time axis. These will generally by means of an audio frequency generator with a synchronous selector as a transmitter generated, which in a known manner on the power distribution network to be controlled is working. The receivers are generally synchronous with the network frequency Voters whose voting contacts match those of the synchronizer.

Receiving devices of the type described often have right sensitive receiving relays, which are accordingly affected by the interference voltages present in the network can be made to respond. You protect yourself against continuous interference voltages by choosing a response voltage that is above the possible continuous interference voltage level lies. To protect against short-term but relatively intense interference pulses various measures have been proposed and in some cases implemented. So was z. B. already proposed, a delay device in the remote control receivers to be provided for the transmission of command pulses, which acts in such a way that interference pulses, which are shorter in comparison to the command pulses, the receiving device is not to address. bring, or that to prevent the automatic start of the synchronous selector it is provided with a reset device due to short-term interference pulses, which. the voter always returns to the zero position, if the impulses are not one Have pulse duration of a certain size. It is then useful to give the start impulse to be selected longer than the command pulses and the aforementioned reset variable greater than the length of a command pulse. It is thereby achieved that the device against unintentional self-start not only due to brief glitches, but; is also protected by command pulses.

The present invention is concerned with a concrete implementation the reset device, which is a backup of the operated with a synchronous motor Receiver against self-start and especially a precise definition of the starting position of the voter permitted. It concerns a remote control receiver for audio-frequency network overlay remote control systems, which works according to the synchronous selector principle, using a synchronous selector a start pulse temporally assigned command pulses are processed in which a shaft driven by a synchronous motor on the one hand one in the circuit of the synchronous motor driving this shaft, assigned to the start pulse Contact device and on the other hand at least one assigned to the command pulses Contact device actuated, and wherein the synchronous selector with a reset device is provided in such a way that the synchronous selector through deflections from the zero position Impulses which do not exceed a certain length, smaller than the start impulse, is returned to the I \ Tullage. The invention is essentially thereby characterized in that the reset device consists of one acting on the synchronizer shaft Resetting member consists on which on a reset lever member via a coupling member a return spring acts, and a locking member acting on the synchronizer shaft, on which a locking spring acts via a locking lever member.

The drawing schematically illustrates an example embodiment a device according to the invention.

Fig. 1 shows the device before the arrival of a start pulse; Fig. 2 shows the device in the state after a start pulse.

In Fib. 1, the synchronous motor M is connected to the network P, O via the contact r of a receiving relay E and the contact pair K2, K 3 of a contact package K 1, K 2, K 3. The synchronous motor 141 is connected to an auxiliary shaft HW via gears Z 1, Z2 and this is connected to the synchronous shaft W via gears Z3, Z4m, it. The synchronizing shaft W and the auxiliary shaft HW are expediently arranged parallel to one another. A circular disk-shaped resetting member R is attached to the auxiliary shaft HW and has a groove N on its circumference. Furthermore, a reset lever member RH is pivotably mounted on the auxiliary shaft HW. The arm of the restoring lever element RH is pressed against a likewise stationary stop P by means of a restoring spring RF attached to a stationary part V. The reset lever member RH carries a pin Z on which a coupling member K is pivotably mounted. The same has a vertically bent arm S which engages in the groove N of the restoring member R. A bolt B firmly connected to the coupling member K actuates the center contact K2 of the control contacts K1, K2, K3. The coupling member K also has a finger F with an edge O which at least approximately forms part of a roller surface coaxial with the shaft HW. The coupling member K is pressed with the surface O against the locking bracket H by the force of a spring, preferably directly by the spring of the center contact K2.

The locking bracket is formed as part of an H zweiarmigere Arretilerhebelgliedes AH, which is pivotable about a stationary pin T and .the ArretierfederAF in contact with the slideway G, F 1 a on the wave W is fixed to the locking lever A. The position of the pin T is chosen so that when the locking lever member AH is pivoted, the locking bracket H moves on a path directed radially to the auxiliary shaft HW.

If the receiving relay E in Fig. 1 is energized, its contact r closes the circuit of the synchronous motor M, and this moves the shafts HW and W via the gears Z 1, Z2, Z3, Z4 in the sense of the arrows drawn: With the auxiliary shaft HW is the restoring element R moves, which with its groove N entrains the arm S of the coupling element K and thereby the coupling element K and the restoring lever element RH. The reset lever member RH is removed from the stop P by this movement, and the return spring RF is tensioned. The surface 0 of the finger F moves along the locking bracket H. The position of the control contacts K1, K2, K3 is selected so that the bolt B keeps the two contacts K2, K3 closed against the pressure of the spring of the contact K2.

If during the further rotation of the auxiliary shaft HW the surface 0 of the coupling member K leaves the locking bracket H, the coupling member K is pivoted under the influence of the spring of the contact K2, and the arm S of the coupling member K leaves the groove N, whereby a further connection of the restoring member R. is interrupted with the restoring levergli: ed RH and the coupling member K (see Fig. 2). The finger F comes under the locking bracket H and prevents the return lever member from pivoting backwards through the return spring RF. At the same time, by pivoting the coupling member K with the bolt B , the two contacts, K2, K3 are brought out of contact and the circuit is closed via the contacts K1, K2. As a result, the synchronous motor M is connected directly to the network P, 0 and continues to move independently of the receiving relay E, which now transmits the command pulses.

Due to the shape of the path G of the locking member A, the locking lever @ member AH is slowly pivoted so that the locking bracket H moves to the right in the picture, releasing the finger F, so that .das Rüekstellhebelglied RH by the action of the return spring RF to the stop GP jumps back. After further rotation of the synchronizer shaft W, the locking member AH slides over the flank Fl of the locking member A when it reaches a full rotation. The locking bracket H moves to the left in the picture, pushes the coupling member K into the position shown in FIG. 1 and pushes. its arm S back into the groove N of the resetting member R. As a result, the circuit via the contacts KI, K2 is interrupted by means of the bolt B, and the contacts K2, K3 are brought into contact with one another again. Since after a completed pulse transmission the relay L is no longer energized, its contact r is open. The motor M stops and the entire device is ready for a new cycle.

The function described takes place if the start pulse has the required length. For short power surges, e.g. B. disturbances, the edge O of the coupling member K does not leave the locking bracket H, and: the return spring RF rotates with the help of parts RH, K, R, Z2, Z 1 the motor M back to the starting position after the current surge has ceased.

The device according to the present invention not only has that Advantage that they give the receiver the start-up against brief glitches or Command impulses that are shorter than the start impulse make it more difficult. She allowed about it in addition, by specifying: the zero position of the synchronous selector a more precise time Assignment of the pulse diagrams for: the often in; large numbers in the networks used recipient. As for the correct functioning of large numbers of recipients certain tolerance requirements for the accuracy of the pulse train in terms of prescribed synchronous position of the receiver relative to the transmitted pulse train must be, the device according to the present invention also brings significant Facilitation of the serial fibrillation of the receiving devices.

The embodiment of the inventive concept described has the Advantage that it is easily combined into a separate structural element can be, which can be found in receiving equipment without any further construction measures worth mentioning. which are not equipped with a reset device, can be inserted.

Claims (5)

PATENT CLAIMS: 1. Remote control receiver for audio-frequency network overlay remote control systems, which works according to the synchronous selector principle, whereby by means of a synchronous selector a start pulse temporally assigned command pulses are processed in which a shaft driven by a synchronous motor on the one hand one in the circuit of the synchronous motor driving this shaft, assigned to the start pulse Contact device and on the other hand at least one assigned to the command pulses Contact device actuated, and wherein the synchronous selector with a reset device is provided in such a way that the synchronous selector with deflections the zero setting by pulses that are a certain length, smaller than the start pulse, not exceeded, is returned to the zero position, characterized in that that the reset device consists of one acting on the synchronizer shaft (W) Reset member (R), on which a reset lever member (RH) via a coupling member (K) a return spring (RF) acts, and one acting on the synchronizer shaft (W) Locking lever member (A), on which a locking spring via a locking lever member (AH) (AF) works. 2. Remote control receiver according to claim 1, characterized in that the locking lever member (AH) at the end opposite the locking member (A) is designed as a locking bracket (H) for the coupling member (K), such. that after a certain angular expansion of the resetting member (R) a finger (F) of the coupling member (K) slides under the locking bracket (H), the coupling member (K) being lifted out of the groove (N) and thus the resetting member (R) releases. 3, remote control receiver according to claims 1 and 2, characterized in that after lifting the coupling member (K) from the groove (N) of the restoring member (R) the locking lever member (AH) by means of a slide (G) of the locking member (A) against the locking spring (AF) is rotated so that after a certain rotation of the synchronizer shaft (TI ') the finger (F) of the coupling member (K) is released again from the locking bracket (H), so that after one full revolution of the synchronizer shaft (W ) when the locking lever member (AH ) falls over a flank (FL) of the locking member (A), the coupling member latches directly back into the groove (N) of the restoring member (R). 4. Remote control receiver after the Claims 1, 2 and 3, characterized in that the coupling member (K) with a Polzen (B) is provided, the control contacts (K1, K2, K3) of the via a gear transmission, a synchronous shaft (W) and an auxiliary shaft (HW) driving synchronous motor (H) actuated. 5. Remote control receiver according to claims 1 to 4, characterized in that the resetting device (R, K, RH, AH, A) is designed as a closed structural unit. Considered publications: Austrian patent specification No. 132 318.