CH666580A5 - Ripple control receiver. - Google Patents

Description

DESCRIPTION

The invention relates to a ripple control receiver with a power supply unit, with a filter connected to a transmission line and with an evaluation part connected downstream of the filter for decoding the ripple control commands of a received pulse program and for comparing the decoded ripple control commands with a pulse image contained in a memory, depending on the The result of the comparison is actuated at least one relay which is designed to be bistable, does not consume any power in its end positions and receives the operating voltage from a mains rectifier via a resistor and a capacitor arranged in parallel with the relay, and the voltage on the capacitor required for relay actuation only after operational readiness of the evaluation part and, in the event of an interruption in the mains voltage, the voltage necessary for the operational readiness of the evaluation part to be fallen below.

Such a ripple control receiver is already known (DE-PS 2 409 883). In this known ripple control receiver, a diode is connected in parallel with the resistor arranged between the capacitor and the line rectifier and is reverse-polarized with respect to the polarity of the outputs of the line rectifier. If the output voltage of the mains rectifier drops below the charging voltage of the capacitor, then both the relay and the evaluation part and the filter are supplied with voltage by the capacitor via the diode. Since the response threshold of the relay is higher than the operating voltage required for the operation of the evaluation unit and the filter, it is ensured that the relay can only be operated if the evaluation unit is still working properly. However, the relay remains in the position it was in when the response voltage fell below.

Also known is a ripple control receiver with a non-volatile program memory for customer-oriented programs that are based on raster control systems commonly used in the pulse grid.

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relate to steme. At the place of use of the ripple control receiver, a desired pulse pattern can be selected by appropriate programming of a microcomputer (DE-OS 2 831 771).

The invention has for its object to further develop a ripple control receiver of the type described in such a way that with a simple structure and the lowest possible self-consumption when switched on for the first time and in the event of power failures that exceed a predetermined time, incorrect response of the relays is prevented and a defined relay position is reached.

According to the invention, the object is achieved by the measures described in claim 1.

After the power failure, the microcomputer will continue to work properly for a while with this arrangement until the input voltage at the voltage regulator has dropped below a predetermined threshold. Power failures that are shorter than the time it takes the input voltage to drop to the threshold do not interrupt the operation of the ripple control receiver. If the power failures exceed this minimum time, the bistable relays are set to a defined position, which they still assume after the voltage recovery. This position can be assumed when sending new ripple control commands. In the start-up phase after the voltage recovery, uncontrolled relay actuations are avoided with the arrangement described in claim 1. Relay operation is only possible when the microcomputer is fully operational. During the rise in the operating voltage, the signal state at the relay-controlling outputs of the microcomputer is not clear as long as the microcomputer is not ready for operation. Despite these ambiguous signal states, the arrangement explained in claim 1 suppresses undesired relay actuations. A voltage reserve can be achieved with the capacitors, with which there is sufficient operating voltage for a certain time even after the mains voltage failure. Short-term voltage drops or mains voltage failures can therefore be bridged more easily.

With the preferred embodiment explained in claim 2, considerable power savings can be achieved both in operation and in the start-up phase of the ripple control receiver. This current saving means that the voltage regulator delivers its nominal voltage earlier in the start-up phase. The ripple control receiver is therefore ready for operation faster after switching on or after voltage recovery. In the event of a mains voltage failure, the operating voltage slows down slowly due to the low power requirement. There is therefore more time available for the microcomputer to carry out operations which are expedient in the event of a power failure. The capacity of the storage capacitors can also be reduced due to the lower power consumption. Since the ripple control receiver returns to its initial position after a power failure that exceeds a predefinable minimum time, it can be prevented

that e.g. Consumers that are switched on for the network utilization of a network that is not disturbed, are switched on immediately and uncontrolled when voltage returns after a fault.

In the preferred embodiment described in claim 3, the memory is prevented from being switched on by simple means until the operating voltage has reached a certain minimum level, e.g. can correspond to the nominal operating voltage. The power consumption of the ripple control receiver is therefore reduced, especially in the start-up phase after the first connection to the network or after the end of a network interruption. Inexpensive memories can therefore be used, the power consumption of which is somewhat higher. E.g. can be built in bipolar technology

Use memories that require more power than memory built using CMOS technology, but are less expensive than CMOS memories.

A preferred arrangement in connection with a voltage discriminator is explained in claim 4.

In the arrangement described in claim 5, only mains voltage failures that exceed a predeterminable minimum time lead to the relay being reset to the defined rest position. Shorter power failures, e.g. in the event of short-circuit advancements do not affect the ripple control receiver's continued work.

In an expedient embodiment it is provided that the circuit for resetting the microcomputer has a zener diode connected to the output of the mains rectifier, which is connected in series with a resistor, that the tap between the resistor and the zener diode is connected to the reset input of the microcomputer via a further resistor and that the reset input is connected to the output of the voltage regulator via a clamping diode. With this arrangement, an operationally reliable reset of the microcomputer is achieved with very little circuit complexity.

In a favorable embodiment it is provided that the microcomputer is connected to the transmission line via a programmable scanning filter. The ripple control receiver can thus be universally adapted in a short time to various ripple control frequencies which are specified by the respective ripple control transmitter. With the sampling filter, high selectivity can be achieved in a simple manner with high accuracy and great constancy with a corresponding settling time, so that short interference pulses in the network are rendered ineffective.

Plug-in bases are preferably provided for at least three bistable relays, into which bistable relays can be inserted if necessary. With this arrangement, the ripple control receiver can be easily set to generate 1 to 3 command outputs. It is easy to change the number of output relays on site without removing or converting the ripple control receiver.

At least the digital scanning filter, the evaluation part, the power pack and the bistable relays are expediently arranged under a cover which is secured with a seal. If the ripple control receiver is fitted with a seal after installation, it can be seen from the seal whether the lid has not been opened without authorization.

In a preferred embodiment, contacts are arranged under the cover for actuating the bistable relays via the microcomputer independently of a pulse telegram. These contacts enable the functioning of the microcomputer and the relays to be checked. Such a check is often useful in order to be able to control the functioning of the units to be switched on and off by the ripple control receiver. The sealed cover of the contacts makes it possible to check whether unauthorized persons have removed the cover.

Further advantageous embodiments are described in claims 11 and 12.

The invention is explained in more detail below with reference to an embodiment shown in a drawing, from which further features and advantages result.

Show it

FIG. 1 shows a block diagram of a ripple control receiver,

FIG. 2 shows more details of the arrangement shown in FIG. 1,

FIG. 3 shows a front view of a ripple control receiver,

4 shows a switching arrangement for switching the memory of the ripple control receiver shown in FIG. 1 on and off.

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An audio frequency ripple control receiver 1, which is shown in the drawing in a block diagram, contains a connection 2 for the power line, which is not shown in detail. The connection 2 is followed by a sampling filter 3, which is designed as an integrated circuit and is connected via external elements, e.g. Resistor 4 and 5, can be set to the desired bandpass characteristic. A clock generator, which can be a quartz oscillator, is also required to store the sampling filter 3. A microprocessor 6, like a programmable read-only memory 7, is part of a microcomputer 8. The microcomputer 8 is connected to the scanning filter 3 via a discriminator (not shown). A power supply unit 9, which contains a rectifier 10 and a capacitor 11 as an energy store, is also connected to the connection 2.

The power supply 9 feeds the microcomputer 8, the discriminator, the sampling filter 3, the read-only memory 7 and the amplifier 12; the amplifier inputs are connected to corresponding outputs of the microcomputer 8. The microprocessor 6 and the read-only memory 7 can be commercially available units. The amplifier 12, e.g. consists of four separate amplifier units, controls three bistable relays 13, 14, 15 via three outputs. The bistable relays 13, 14, 15 are arranged in plug-in bases 16 ', 17', 18 '. The relays 13, 14, 15 can therefore be easily inserted into or removed from the plug base 16 ', 17', 18 'of the ripple control receiver 1 if required. The microcomputer 8, in conjunction with a decoder and the amplifier, forms the evaluation part of the ripple control receiver 1. In the evaluation part, the ripple control commands of a received pulse telegram are decoded and compared with a pulse image that is contained in the read-only memory 7. Depending on the comparison result, the microcomputer 8 generates command signals at its outputs with which the amplifier 12 is actuated, which acts on the bistable relays 13, 14 and 15 in accordance with the command signals. For the respective ripple control system, the pulse image in the read-only memory 7 contains the pulses and pulse pauses for the start, address and execution pulse steps, taking into account the duration and the intervals of the pulses and pulse pauses.

The audio-frequency control signal tapped at connection 2 is separated from the 50 Hz mains voltage and from the mains harmonics via the programmable sampling filter 3. The scanning filter 3 has a high selectivity which, in conjunction with a corresponding settling time, also makes short interference pulses from the network ineffective. By appropriately dimensioning the resistors 4 and 5, a bandpass characteristic for different nominal control frequencies can be set with the scanning filter 3. The center frequency of the bandpass can be set via the clock frequency and the resistors 4, 5.

The bistable, preferably polarized relays 13, 14, 15 need only one pulse to be switched from one position to the other. In one or the other rest position, the bistable relays 13, 14, 15 do not consume any energy. The energy consumption of the ripple control receiver 1 is therefore very low, taking into account that the other components also consume little energy. The ripple control receiver can therefore be of compact construction and, owing to its small dimensions, can be more easily installed in distribution cabinets or in or on consumers.

A voltage regulator 16 is connected to the rectifier 10 and generates a regulated operating voltage of, for example, 5 volts at its output. The voltage regulator 16 forms a component of the power supply unit 9. The microcomputer 8, the scanning filter 3 and the amplifier 12 are supplied with the operating voltage of 5 volts. A buffer condensate 17 is connected to the output of the voltage regulator.

A circuit 20 is arranged between the output of the line rectifier 10 and an input 18 for resetting the microcomputer 6, which generates a reset signal when a certain minimum voltage is still present at the line rectifier 10.

The circuit 20 contains a zener diode 19 connected to the output of the rectifier 10, which is connected in series with a resistor 21. The second, unspecified output of the rectifier 10 is connected to ground, as is the second connection of the resistor 21. The network rectifier 10 can be connected to the network via resistors, not shown, or via a transformer. The connection point between the Zener diode 19 and the resistor 21 is connected to the reset input 18 via a further resistor 22. A clamping diode 23 is arranged between the reset input 18 and the output of the voltage regulator 16.

The Zener voltage of the diode 19 is selected such that it is only slightly greater than the regulated output voltage of the voltage regulator 16. In contrast, the rectifier 10 outputs a much higher voltage.

The series connection of a resistor 29 and a diode 30, via which a capacitor 31 is fed, is connected to the output of the mains rectifier 10. The capacitor 31 is connected to the amplifier 12 at a connection 32. The other connection of the capacitor 31, not specified, is connected to ground potential. The output stages of the amplifier 12, not shown in detail, are supplied with the operating voltage for the relays 13, 14, 15 and the further output 33 via the connection 32. The input stages of the amplifier 12 are connected to the output of the voltage regulator 16.

The read-only memory 7 is supplied with operating voltage from the voltage regulator 16 via a switching element 34. The switching element 34 is switched on or off via the output 33 of the amplifier 12. The switching element 34 is a transistor which is arranged in the course of the operating voltage lines of the read-only memory 7 and is connected to ground potential with its emitter. A resistor 35 is arranged between the emitter and the base. The base is connected to the output 33 via the series circuit of a further resistor 36 and a zener diode 37. The line rectifier 10 is supplied with the line voltage directly via a high-resistance resistor 38.

If the mains voltage fails, the capacitor 11 first discharges via the voltage regulator 16. If no mains periods are determined within the time period specified by the first time monitor, this is determined in the microprocessor 6, which initiates the start of the second time monitor. The time period of the second time monitoring is selected so that the voltage at the output of the regulator 16 is still so high that the microcomputer 8 can work properly despite the absence of the mains voltage. The capacitance of the capacitor 31 is also determined with reference to this period. The capacitor 31 has a sufficiently large capacitance to provide sufficient energy for the actuation of at least one of the relays 13, 14, 15 after the time period has elapsed.

If no mains voltage return has been determined by the end of the period of the second time monitoring, the microcomputer 8 generates output signals with which at least one relay is set to a defined end position. With this relay actuation, the capacitor 31 is also discharged. The microprocessor 6 is only reset after the switchover of at least one predefined relay into a defined end position.

The reset works as follows:

A current flows through the Zener diode 19 and the resistor 21, the voltage present at the reset input 18 being approximately equal to the output voltage of the voltage regulator 16

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speaks. When the voltage across the buffer capacitor 11 falls below the voltage, the zener diode 19 becomes non-conductive. Ground potential thus reaches the reset input 18. Since the Zener voltage is higher than the output voltage of the voltage regulator 16, the output voltage is still present at all consumers when the microprocessor 6 is reset.

If the voltage occurs again before the time period of the second time monitoring has expired, the microcomputer 8 ends the second time monitoring, triggers the first time monitoring again and processes the received signals without interruption.

Since the zener voltage is substantially lower than the output voltage of the rectifier 10 and the buffer capacitor 11 has a higher capacitance, it takes a certain time after a mains voltage failure until the reset signal occurs. If the mains voltage is switched on to the mains before this time has elapsed, the microprocessor 6 is also not reset. Short-term mains voltage faults or interruptions therefore do not cause the relays 13, 14, 15 to be reset to the defined end position.

The microprocessor 6 briefly actuates the switching element 34 before data is read from the read-only memory 7. After reading out the data, the microprocessor 6 opens the switching element 34 again. The power consumption of the ripple control receiver 1 is thus reduced overall. In particular, this measure has a favorable effect if the read-only memory 7 has a high power consumption compared to the other components of the ripple control receiver.

The switching element 34, a transistor, is held in a non-conductive state via the resistor 35 when no further signal is present at the base of the transistor. The Zener voltage of the Zener diode 37 is selected so high that only a current flows through the resistor 35 and the Zener diode 37 if the voltage at the output 33 is so high that the operating voltage of the microcomputer is also sufficiently high for the proper functioning. The read-only memory 7 can therefore only be connected to the operating voltage when the microcomputer 8 is in an operational state. This means that in the start-up phase, i.e. after the ripple control receiver 1 is switched on for the first time or when

Occurrence of the mains voltage after termination of a mains voltage failure from the read-only memory 7, no current is consumed. Since in this case only a relatively small current flows through the resistor 29 to the capacitor 31, the current fed in via the high-resistance resistor 38 is predominantly available for charging the capacitor 11, so that the latter can be used relatively quickly for operation of the regulator 16 can build up the necessary voltage. The ripple control receiver 1 is therefore ready for operation again in a very short time, io The charging of the capacitor 31 is adapted to the duration until the microcomputer 8 is ready for operation, by first selecting the minimum voltage required for actuating the relays 13, 14, 15 via an appropriately selected capacity is reached when the microprocessor 6 has reached its operational readiness. Incorrect actuations of the relays 13, 14, 15 are thus avoided. If output signals which are not defined by the microcomputer 8 are supplied to the relays 13, 14, 15 during the start-up phase, they do not trigger any actuation.

20 The ripple control receiver 1 is located under a transparent cover 24 which is attached to a carrier. The cover 24 has a device 25 in order to be able to connect it to the carrier 26 by means of a seal 27.

An input of the microprocessor 6 is connected to a device 25 28, which are supplied with operating voltage by the power supply 9. When the contacts 28 are actuated, a test program is triggered, for example, via an input of the microprocessor 6, by means of which the relays 13, 14, 15 are brought into a specific position. For example, the test program can be structured in such a way that the bistable relays 13, 14, 15 assume one or the other end position with every even or odd number of operations. It is thus possible to check the function of the microprocessor 6, the amplifier 12 and the relays 13, 14, 15. 35 At the same time, the consumers controlled by relays 13, 14, 15 can be controlled. The contacts 28 are also located under the cover 24 and, like the relays 13, 14, 15, are only accessible for work on the ripple control receiver 1 after the cover 24 has been sealed after the seal 27 and the cover 40 24 have been removed.

The device 28 can be a contact. There are also other elements, e.g. Photoelectric receiver possible.

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Claims (11)

666 580 1.Ripple control receiver with a power supply unit, with a filter connected to a transmission line and with an evaluation part connected downstream of the filter for decoding the ripple control commands of a received pulse program and for comparing the decoded ripple control commands with a pulse image contained in a memory, with at least one relay depending on the comparison result is operated, which is designed to be bistable, does not consume any power in its end positions and receives the operating voltage from a line rectifier via a resistor and a capacitor arranged in parallel with the relay, and the voltage at the capacitor required for relay actuation only after the evaluation part is ready for operation and at Mains voltage interruption before the voltage necessary for the operational readiness of the evaluation part to be undershot is reached, characterized in that the evaluation part is designed as a microcomputer (8) which has a voltage Regulator (16), upstream and downstream of which a buffer capacitor (11, 17) is arranged, is connected to the mains rectifier (10) such that the capacitor (31) is connected via a diode (30) arranged in series with the resistor (29) It can be charged that a time monitoring can be initiated with each period of the line voltage in the microcomputer (8), with which the occurrence of a further period of the line voltage can be determined after a predeterminable period of time and, in the absence of which, a further time monitoring can be initiated which is connected to the Discharge time of the buffer capacitors (11, 17) and of the capacitor connected to the relay (13, 14, 15) is adjusted in such a way that after their expiry another one for actuating the microcomputer (8) and the relay (13, 14, 15) sufficient operating voltage is available, with the expiration of the further time monitoring of the relay (13, 14, 15) via the microcomputer (8) being able to be set into a defined position. 2. ripple control receiver according to claim 1, characterized in that the memory (7) is connected via a switching element (34) with its operating voltage input to the voltage regulator (16) and that the switching element (34) of a microprocessor (8) arranged in the microcomputer (8) 6) can be switched on and off via a voltage discriminator arrangement (35, 36, 37). 2nd PATENT CLAIMS 3. ripple control receiver according to claim 2, characterized in that the microprocessor (6) via an amplifier circuit (12) to the relay and to the voltage discriminator gate circuit (35, 36, 37) is connected. 4. ripple control receiver according to claim 2 or 3, characterized in that the switching element (34) is a transistor, the base of which is connected via a resistor (35) to a reference potential blocking the transistor in the absence of any other base voltage, and in that the base is also connected to the a resistor (36) and a Zener diode (37) existing voltage discriminator circuit is connected to the output (33) of the amplifier (12). 5. ripple control receiver according to one of claims 1 to 4, characterized in that between the mains rectifier (10) and the reset input (18) of the microcomputer, a circuit (20) is arranged, which is a reset signal at a pending at the output of the mains rectifier (10) Generates voltage that is less than the voltage that is generated at the mains rectifier (10) by a mains voltage that is within the permissible tolerances. 6. ripple control receiver according to claim 5, characterized in that the circuit (20) for resetting the microcomputer (8) has a Zener diode (19) connected to the output of the mains rectifier (10), which is connected in series with a resistor (21) that the tap between the resistor (21) and the Zener diode (19) is connected to the reset input (18) of the microcomputer (8) via a further resistor (22) and that the reset input (18) is connected to the output via a clamping diode (23) of the voltage regulator (16) is connected. 7. ripple control receiver according to one of claims 1 to 6, characterized in that the microcomputer is connected to the transmission line via a programmable scanning filter (3). 8. ripple control receiver according to one of claims 1 to 7, characterized in that at least for three bistable relays (13, 14, 15) plug-in base (16, 17, 18) are provided, in each of which, if necessary, a bistable relay can be inserted. 9. ripple control receiver according to one of claims 1 to 8, characterized in that at least the scanning filter (3), the microcomputer (8), the power supply (9) and the bistable relays (13, 14, 15) under a cover (24) are arranged, which is secured with a seal (27). 10, characterized in that the relays (13, 14, 15) are polarized relays. 12. ripple control receiver according to one of claims 1 to 10. ripple control receiver according to claim 9, characterized in that under the cover (24) devices (28) for a manually triggering actuation of the microcomputer (8) and the bistable relays (13, 14, 15) are provided. 11. ripple control receiver according to one of claims 1 to 11, characterized in that the line rectifier (10) is fed directly from the line voltage via a high-resistance resistor.