FR2518349A1 - Contactor controller for automatic switching during off-peak hours - uses sensor to drive electronic circuit which delays connection of load to supply in proportion to its temp. - Google Patents

Abstract

An electronic controller (8) accepts data from a temp. transducer (7) associated with the appts (12) to determine the delay from the period when off-peak supply becomes available to the switching of the load onto the supply, with a higher temp. leading to a greater delay. The supply for the electronic circuit is derived from the mains supply voltage. This is achieved by a time sharing of both functions. The changeover from one function to the other is achieved through the action of two auxiliary contacts controlled by a delayed contactor. The arrangement can be adapted to existing systems as it requires no extra lines to be installed.

Description

Circuit for connecting a shifting contactor to an electrical energy storage device, and method for connecting the same
The invention relates to a circuit for connecting a shifting contactor to an electrical energy storage device, and to a corresponding connection method.

 Electric energy storage devices, such as water heaters, radiators and storage heaters, are mostly supplied at the reduced rate offered during night hours, between 10 p.m. and 6 a.m. As a result, these devices are all connected simultaneously, which causes a peak load at 10 p.m., while there is a drop in consumption between 2 a.m. and 6 a.m. To avoid these disturbances, it is planned to use to control the connection of an electric storage device, a shifting contactor, that is to say a device which delays the commissioning of the device according to its For this purpose, a temperature probe is mounted on the electrical storage device1 and it is connected to the shifting contactor by a two-conductor line.

 This usual technique has several drawbacks. First of all, the installation of this additional line between the offset switch and the electrical energy storage device entails higher installation costs. Then, in the case of replacing a normal contactor with a shifting contactor, on an old installation, the installation of the additional line often poses major practical problems and entails high installation costs.

 It has been proposed to avoid this additional line and to use the normal supply line of the electrical storage device to transmit the temperature information from the probe to the shift switch.

For this purpose, high frequency signals are superimposed on the normal supply current of the device. However, this solution which requires the use of a transmitter-receiver considerably increases the cost of the shifting contactor and proves to be very expensive.

 An object of the present invention is to provide a method of connecting the shifting contactor which is simple, inexpensive, and which does not require the commissioning of an additional line. Another object of the present invention is to provide a connection circuit for the offset switch allowing its connection to old installations, without major intervention.

 The subject of the invention is a circuit for connecting a shifting contactor, comprising an electronic measurement system, to an electrical energy storage device of the type in which a three-conductor line, comprising a phase conductor, a neutral conductor and a protective or earth conductor, connects the device to a normal contactor controlling the supply of the device, characterized in that on the one hand the electronic measuring system of the shifting contactor, on the other hand the temperature measurement probe of the device are each connected at one end of the line between the neutral conductor and the protective conductor, so as to ensure connection without an additional line.

According to other characteristics of the present invention:
- the connection between the electronic measuring system of the shifting contactor and the two conductors of the appliance supply line is controlled by an auxiliary contactor with at least one opening contact,
- the auxiliary contactor is placed under the control of the normal contactor or of the electronic system, its opening before the closing of the normal contactor and its closing after the opening of the normal contact,
- the auxiliary contact controlled by an auxiliary relay.

 The invention also relates to a method of connecting a shifting contactor comprising an electronic measurement system, to an electrical energy storage device of the type in which a three-conductor line, comprising a phase conductor, a conductor neutral and a protective conductor, connects the device to a normal contactor controlling the power supply of the device, characterized in that the temperature measurement probe of the device and the electronic system of the shifting contactor are connected the neutral conductor and the protective conductor of the line and in that said line is used both and alternately, for supplying electrical power to the apparatus during heating periods, and for measuring the temperature in the appliance outside the heating periods, by separating these two functions over time.

Other characteristics will emerge from the following description made with reference to the attached drawing on which we can see
Figure 1, a diagram of an exemplary embodiment of the circuit for connecting a shifting contactor to an electric storage device, according to the known technique;
Figure 2, a diagram of an exemplary embodiment of the circuit for connecting a shifting contactor to an electric storage device, according to the invention;
Figure 3, a diagram of an alternative embodiment of the connection circuit of a deca'l contactor, according to the invention.

 FIG. 1 shows the circuit for connecting an offset contactor to the electrical accumulator or accumulator device, with additional line of connection between the accumulator probe and the offset contactor.

 In this connection circuit, the normal supply line 1 connects by the power conductors, phase 14 and neutral 15, the resistance 2 of the accumulator 12 to the contactor 3 of the shifting contactor 10, and by the protective conductor 16 the earth. 4 of the accumulator to ground 5 of the chassis of the shifting contactor. On the other hand, the additional line 6 connects the probe 7 for measuring the temperature of the accumulator 12 to the electronic system 8 for measuring the offset contactor 10.

 Figure 2 shows the connection circuit in the proposed solution.

 It can be noted that only the normal supply line 1 exists, as in FIG. 1, connecting the resistor 2 to the contactor 3 as well as the masses 4 ′ and 5.

 The temperature measurement probe 7 is connected between earth 4 and terminal 9 of the neutral conductor 15.

In the same way, the electronic system 8 for measuring the shifting contactor is connected between the ground 5 and the neutral conductor 15 downstream of the contactor 3 which is itself supplied by the conductors N (neutral) and Ph (phase).

 The electrical connection between the electronic system 8 and the conductors 15 and 16 is made by means of an auxiliary contact 11 with opening.

 In the case of FIG. 2, only the connection to the neutral conductor 15 is controlled by the auxiliary contact 11, which can be controlled by the contactor 3 or be part of an additional auxiliary relay.

 In the variant embodiment of FIG. 3, the two connections to the conductors 15 and 16 are controlled by the auxiliary contact 11 which is with two contacts. When this auxiliary contact 11 is closed, the probe 7 is connected to the electronic measurement system 8 of the contactor.

 shift.

The operation of the assembly is as follows:
Outside off-peak hours, between 6 a.m. and 10 p.m., the contactor 3 is normally open and the auxiliary contact 11 is closed.

 The probe 7 of the accumulator 12 is therefore connected to the electronic system 8 of the offset switch 10.

 As in the case of Figure 1, the electronic system records the temperature of the accumulator and calculates 12 heating times that will be necessary during off-peak hours to obtain the desired temperature.

 The heating time will in particular be calculated and recorded until, during off-peak hours between 10 p.m. and 6 a.m., the electronic system 8 instructs the contactor 3 to close.

 A fraction of a second before this closing, either mechanically or electronically, the auxiliary contact 11 will open cutting the connection between the probe 7 and the electronic system 8.

 This cut will not be detrimental to the proper functioning of the accumulator because on the one hand the electronics will have calculated and recorded the necessary heating time and on the other hand, the accumulator 12 includes a thermostat 13 which, if necessary , will cut the current circulating in the resistance 2.

 At the end of the heating time, the contactor 3 will open and after a short delay the auxiliary contact 11 will close, re-establishing the connection between the probe and the electronic system.

 According to the invention, the normal supply line of the electrical accumulator device with three conductors 14 (phase), 15 (neutral) and 16 (protective conductor) is used, both and alternately for the supply. tation in electrical energy of the device and for the measurement of the temperature, by separating in time these two functions. Outside the heating periods, line 1 is only used for temperature measurement, and during the heating periods it is only used for supplying energy to the accumulator.

 The passage from one function to another is ensured by the tilting of the auxiliary contact 11, with one or two contacts, this tilting being triggered by the shift contactor.

 The method of connecting according to the invention a shifting contactor to an electrical storage device consists in connecting the probe and the electronic system of the shifting contactor between the neutral conductor and the safety or ground conductor of the devices. It is particularly well suited to the case of the adaptation on an old device of a shifting contactor, because there is no new line to set up.

Claims (5)

 1. Circuit for connecting an offset contactor, comprising an electronic measurement system, to an electrical energy storage device of the type in which a three-conductor line, comprising a phase conductor. a neutral conductor and a protective or earth conductor. connects the device to a normal contactor controlling the power supply to the device. characterized in that on the one hand the electronic measurement system of the shifting contactor (10), on the other hand the temperature measurement probe (7) of the apparatus (12) are each connected at one end of the line (11 between the neutral conductor (15) and the protective conductor (16). so as to ensure connection without additional line.  2. Circuit according to claim 1, characterized in that the connection between the electronic measurement system (8) of the shifting contactor (10) and the two conductors (15, 16) of the line (1) supplying the device (12) is controlled by an auxiliary contactor (11) with at least one opening contact.  3. Circuit according to claim 2, characterized in that the auxiliary contactor (11) is placed under the control of the normal contactor (3) or of the electronic system (8), its opening preceding the closing of the normal contactor (3) and its closing following the opening of the normal contact (3).  4. Circuit according to claim 2, characterized in that the auxiliary contact (11) is controlled by an auxiliary relay.  5. Method for connecting a shifting contactor (10) comprising an electronic measurement system (8), to an electrical energy storage device (12) of the type in which a line (1) with three conductors, comprising a phase conductor (14), a neutral conductor (15) and a protective conductor (16), connects the device to a normal contactor controlling the supply of the device, characterized in that the temperature measurement probe (7) of the device (12) and the .......... electronic system (8) of the offset contactor (10) between the neutral conductor (15) and the protective conductor (16) of the line (1) and in that said line (1) is used at the same time and alternatively, for the supply of electrical energy to the appliance (12) during the heating periods, and for the measurement of the temperature in the appliance (12) outside the heating periods, by separating in time these two functions.