FR2655490A3 - Control appliance for a low-voltage power supply circuit, in particular a thermostat - Google Patents

Abstract

A charging circuit (16) for a low-voltage accumulator (15) is mounted in parallel with the cut-off switch (14) of the mains input device capable of being switched by the active part (11'), which includes a low-resistance charging path (18r) and a high-resistance charging path (18R). When the input device (12) is cut off, the top-up power supply to the accumulator (15) is maintained via the high-resistance charging path (18R), with a parallel arrangement of an anti-overcharge bleed circuit (24). Before the input device (12) is placed in circuit, the low-resistance path (18r) is first used, for the purposes of rapid charging, but then, with the input device (12) placed in circuit, the top-up path (18R) is returned to, depending on the charged state of the accumulation (15).

Description

The present invention relates to a control device comprising a low voltage supply circuit for obtaining the low operating voltage from the load circuit of a network utilization receiver, which is in series with a switch on which a rectifier circuit for supplying a low voltage accumulator is mounted in parallel in the control unit,
A control device of this type is known from DE-A-35 37 447 and, similarly, from patent US-A-4,300,090. In both cases, an electronic phase adjustment drive circuit is present in the AC network load circuit, which releases the passage of current through the receiver only with a slight delay compared to the passage through zero of the AC network voltage, so that with the voltage drop of the phase adjustment which occurs up to a rectifier circuit for charging a low voltage accumulator is supplied periodically for the operation of the control assembly. Thus, it is possible to obtain, without the use of transformers and only with a connection 3 two conductors to the network, the low operating voltage for the control device. Such a drive control in fact builds up parasitic voltages containing harmonics in the network requiring complex filtering means.

 If the control unit opens the charging circuit to put the receiver out of operation, these periodic voltage peaks for the supply of the rectifier circuit, as well as disturbances, certainly do not appear any more, but the accumulator can then discharge via the control device until the latter, in the absence of a sufficient operating voltage, is out of operation. As a result, a thermostat can no longer enter the circuit or a timer cannot continue to function until the next switch-on point, and the receiver circuit remains finally disconnected (if it is not put back into operation manually with correction of the position of the timer for a new time function command later).

 To avoid such failure of the receiver control device, according to DE-A-35 37 447, a high resistance capacitive shunt of the load switch in the network is provided. I7 is inactive due to short circuit when the main switch is closed. If, however, the switch is open, it passes through it the alternating current necessary to cause the voltage pulses in the drive circuit for maintaining the supply of the low-voltage accumulator via the rectifier circuit. This capacitive residual current, bypassing the lines of passage of the charge current open per se, is so small that it cannot yet operate the receiver of the network. In the case of receivers which are cut relatively long and connected only during one relatively short duration, this residual current is however added significantly (to maintain the operating state of the supply circuit), so that ultimately the low operating voltage is only maintained at the cost of current losses relatively high residual, with relatively high assembly complexity for the drive circuit necessary only for obtaining the low voltage, without taking into account the disturbing effect of the drive circuit then appearing, even when the load is disconnected .

 Given these data, the object of the invention is to provide a control device of the type indicated so as to improve its operation without disturbances with reduced technical complexity of the circuits.

 To achieve this objective, according to the invention, before a closing of the main switch, a low resistance fast charge path towards the accumulator is transiently in operation, while, when the accumulator is charged or when the receiver is disconnected, a strong resistance holding charge path is in operation.

 According to this solution, the recharging of the low operating voltage accumulator takes place by one of two charge paths of different characteristics, depending on the switching state for the charge control. If for example the receiver is connected, therefore if the network charging circuit must be closed, the recharging of the low-voltage accumulator is first switched to a charging path with a low charging time constant, to also connect the circuit charging after rapid charging, with a slight delay. If, on the other hand, the control unit interrupts the charging circuit, we switch to a high resistance charging path and the accumulator is recharged from the network with a low holding current which is much lower than the network load current. There is therefore no longer any need for a charge phase adjustment command for the operation of the control device, since there is no longer any particular delay, but only one command delay once load) .The active part of the control device then no longer directly enters the load switching on, but first only the activation of the fast charge path, with activation effective circuit of the receiver only when returning to the holding path due to the recharging of the accumulator.

 According to an advantageous feature of the invention, when the holding charge path is in operation, a bypass circuit is connected in parallel to the accumulator.

 A voltage control, operating circuit can be provided for switching the low resistance load path to the high resistance load path and optionally for switching on the receiver, when a predetermined nominal low voltage is reached on the 'accumulator.

 According to another characteristic, a limiter circuit is provided for switching over the high resistance charging path when the low voltage on the accumulator exceeds a predetermined maximum value.

 According to another characteristic of the invention, the circuit includes a thermostat as an active part.

It also includes a control circuit as a function of time which cooperates with its active part.

 External devices can be connected to the low voltage battery.

 Other improvements, variants and advantages of the invention will emerge from the detailed description which follows of an exemplary embodiment of the invention described below and shown in the accompanying drawing, limiting the essentials, the single figure of which shows an embodiment of the invention in the case of a thermostat control device for the charging circuit.

 The low-voltage control device 11 shown operates, like the high-intensity use receiver 12 located in the charging circuit 10, which it controls, from an alternative network 13.

A bidirectional electronic switch 14 serves as the main switch for the load (receiver 12), as well as a low-voltage decoupling member for the low voltage U, for the operation of the control device 11. The supply of the low voltage U at the active part 11 ′ of the control device 11 is produced by a high capacity charge accumulator (electrochemical or electrophysical) 15 which is supplied via a charge circuit 16 from a rectifier 17. It is produced in the form of a full-wave circuit (Graetz coupling) and it is supplied by the AC voltage drop u on the main switch 14.

 The charging circuit 16 for the low voltage accumulator 15 in the control device 11 has two parallel paths 18r, 18R between which the active part 11 ′ of the control device 11 can switch, by means of a electronic switch (19) (shown in the drawing in the form of series 20rut 20R transistors which can switch alternately to the conducting state) so that at most one of the two paths 18r / R is conducting.

 When the active part 11 'of the control device 11 delivers a connection signal 21 to the switching bridge 22 of the electronic power switch 14 comprising thyristors mounted in parallel in opposite directions or a bidirectional triac, the voltage drop u on the switch or circuit breaker u is, when the switch 14 is first still kept open, transmitted to the input of the supply circuit 23 mounted in parallel on the switch 14 in the apparatus 11 and, consequently, its low rectifier voltage 17, are supplied. At the same time, the charge path switch 19 is attacked by means of a switching logic 35 so that a fast charge signal 43 switches a transistor to the conducting state. series 20r of the path 18r of lower falling resistance value r, therefore through it the low voltage accumulator 15 is charged with a small time constant by an intense charging current I from of the rectified input voltage drop U, to quickly dispose in the control unit 11 of all the low operating voltage U. Then, a voltage control circuit 30 delivers a completion signal 34 to the logic of switching 35 with the connection signal 21, so that the fast charge path 18r is disconnected and the load 12 is connected by means of a switching signal 44 sent to the switching bridge 22.

 If, on the other hand, the active part 11 ′ does not deliver a switching-on signal 21 to the logic 35, the switch 14 is open and the circuit of the receiver (charging circuit 10) is interrupted. The fast charge path 18r is no longer conductive either, but a recharging signal 45 then makes the transistor 20R of the path 18R of resistance R of high conductive value.

 At the terminals of the switch 14 and, consequently, on the rectifier 17 in parallel with it at the input of the supply circuit 23, there reigns again, as voltage drop u, all the network voltage, from which now the accumulator 15 is kept charged with a low recharging current i which is much lower than the operating current of the receiver 12 in the charging circuit 10. To then avoid an excessive rise in the low voltage U, a circuit of bypass 24 with a shunt 24 'and a bypass switch 24 "is mounted in parallel on the accumulator 15, which is put into service with the high resistance holding path 18R when it appears a signal 34 signaling an overload, therefore that the switching logic 35-27 provide a shunt signal 36.

Finally, for additional security against an excessive rise in the operating voltage U of the device, it is also possible to provide a limiter circuit 25. It may simply be a correlated calculated voltage divider circuit with Zener diodes, which stacks of on the one hand the discharge of a possible overvoltage and on the other hand thus delivers a switching signal 26 to a logic or 27 of the charge path switch 19, with the consequence that the recharging of the accumulator 15 is constantly forced by 1 intermediary of the charge path 18r at high resistance for the duration of such an operating disturbance, to avoid an overcharging of the accumulator 15 or an excessive rise in the low operating voltage U. This permanent charging current i represents certainly a leakage current by the electronic switch 14 open per se
however, as has been said, it is so weak that it does not put the receiver 12 in operation, while the operating capacity of the control device 11 remains ensured. However, there is in itself constant control of the accumulator voltage U via the circuit 30 with a voltage comparator 31 which is acted on the one hand from an instantaneous voltage divider 32 and, from on the other hand, a reference voltage divider 33. When the low voltage reference value predetermined here Ur is exceeded, the voltage comparator 31 supplies the signal 34 to the switching logic 35-27, as described above.

 External low-voltage devices 28 can be connected in parallel to the low-voltage operating accumulator 15 by supply connections 29. They can be, on the one hand, other accumulators (to increase the storage capacity) , or other control circuits 42, such as, for example, a timer, to act as a function of the time on the operation of the control device 11 (symbolized in the drawing by the dashed link).

 The usage receiver control apparatus 11 is, in the preferred embodiment shown in the drawing, provided with a thermostat 36, as the active part 11 '. It essentially comprises a temperature comparator 37 which is requested on the one hand from an instantaneous temperature divider 38 and, on the other hand, from a prescribed temperature divider 39, by its input quantities of comparison. When the instantaneous temperature drops below the prescribed temperature, the comparator 37 causes the connection signal 21 to be delivered, to briefly connect the fast charge current I and, when the operating voltage U is reached, the load 12 (as described above).

 For the prescription of the temperature set point Ts, a switch 40 can be provided which can be influenced, for example manually or by means of a timer 42, to pass, for example, from a divider of prescribed temperature 39 with fixed setting for the night temperature at a prescribed temperature divider 39 'with manual temperature regulation. The timer necessary for this or any other switching device can operate from the low-voltage accumulator 15 (fixedly installed in parallel on the active temperature setting part 11 ′ or, if necessary, connected in the form of an external auxiliary device 28>.

 In particular in the case of a thermostat 36 as the active part 11 ′ of the low-voltage control apparatus 11, the high intensity use receiver 12 in the network 10 is, for example, an electric radiation heater or a Electric motor for a fan, or a circulation pump, so that the slightly delayed start-up remains practically without effect. The receiver 12 can also, however, enter a network load in the form of a power relay which then switches a heavy load relay itself.

 To avoid inductive switching voltage spikes at the input of the supply circuit 23, the electronic switch 14 is suitably with its bridge 12, as shown, shunted by a varistor or a limiter. analog overvoltage 41.

Claims (7)

REYENDICATIONS  1. Control apparatus (11) comprising a low voltage supply circuit (23) for obtaining the low operating voltage (8) from the load circuit (10) of a network utilization receiver (12 ) which is in series with a switch (14) on which a rectifier circuit (17) for supplying a low voltage accumulator (15) is mounted in parallel in the control device (11), characterized in that '' before closing the main switch (14) temporarily, a low resistance fast charge path (18r) to the accumulator (15) is in operation, while, when the accumulator (15) is charged or when the receiver (12) is cut, a high resistance holding load path (18R) is in operation.  2. Control device (11) according to claim 1, characterized in that, when the holding charge path (18R) is in operation, a bypass circuit (24) is in parallel on the accumulator (15).  3. Control device according to claim 1 or 2, characterized in that a voltage, operating control circuit (30) is provided for switching the load path of low resistance to the load path of high resistance ( 18r-18R) and possibly to switch on the receiver (12), when a predetermined nominal low voltage (U) is reached on the accumulator (15).  4. Control device according to one of the preceding claims, characterized in that a limiter circuit (24) is provided for switching on the high resistance load path (18R) when the low voltage (U) on the accumulator (15) exceeds a predetermined maximum value.  5. Control device according to one of the preceding claims, characterized in that it includes a thermostat (36) as the active part (11 ').  6. Control device according to one of the preceding claims, characterized in that a control circuit as a function of time (42) cooperates with its active part (11 ').  7. Control device according to one of the preceding claims, characterized in that external devices (28) can be connected to the low voltage accumulator (15).