FI86783C - Device for connecting a number of three-phase loads to a three-phase network - Google Patents

Description

! «« 783

A device for connecting a specific set of three-phase loads to a three-phase network. - Anordning för inkoppling av ett antal trefasbelast-ningar account ett trefasnät.

The invention relates to a device for connecting a certain number of three-phase loads, e.g. electrical resistors, to a three-phase network, which loads are divided into three equal parts, each intended for its own phase.

In the case where the electrical resistor comprises, for example, three three-phase elements, it has not hitherto been possible to connect the total load of the two elements to more than two parts, and thus the control possibilities are limited to either the entire load or in most cases only half the load. In order to achieve even control without unnecessarily loading the network, it is desirable to be able to switch the load in several smaller stages. This is particularly desirable when using a temperature controller in conjunction with a load monitor so that the desired temperature can be maintained as much as possible even if the load. . The guard requires limitation of the load and thus the input power.

It is an object of the present invention to provide a device which solves the above-mentioned problem and achieves the above-mentioned objects.

This object is solved according to the present invention by connecting the phase parts in series, connecting each end of the series connections to their phase and connecting the phase parts in each series connection to a third phase, with circuit breakers arranged between the different phases and terminals. In the case where two three-phase resistors, each comprising an element for each phase, are intended to be connected to a three-phase network in more than two stages, 2 86783 are arranged so that the elements are connected in series, three series circuits are connected to phases (RST) in a three-phase network. the ends and connections in the series circuits are each in their own phase, and that the circuit breakers are arranged between the ends and the phases and the connections and phases to make different connections.

By means of the device according to the present invention, it is possible in a simple manner to enable the connection of six phase parts of two electric resistors in eight stages instead of the previously known connection in only three stages. By using the device according to the present invention in combination with a combination of a controller providing a certain temperature, for example in a boiler, and a load monitor, considerable advantages are achieved, since the desired temperature level can also be achieved when the load monitor requires limited output.

An embodiment of the present invention will be described in more detail below with reference to the accompanying drawings.

Figure 1 shows a block diagram of an embodiment of a device according to the present invention.

..... Figure 2 shows a circuit diagram of a block belonging to the above block diagram.

Figure 3 shows a graph of the operation of the device according to the present invention.

In the two diagrams of the accompanying drawings, the same reference numerals are used for the same joints and parts. The temperature controller and the load monitor, shown in more detail in Figure 2 of Figure 3 86783, are connected to the three-phase network R, S, T and 0 by means of their terminals 1 and 2. In order to maintain the temperature of the water in the heating boiler, for example, a boiler trough T placed in a submersible pipe is arranged, which is connected to the device 10 via connection points 8 and 9. The operating terminals of the two contactors K1 and K2 are connected to the junctions of the device 1, 3 or 4 so that they can be operated by two operating switches K1 or K2, which in turn are controlled by the solenoids K1, K2 belonging to the device 10. The fuse further includes two relays R1 and R2. R1, R2 go to junctions 6 or 5 and to steps S or R.

Two electrical resistors each with 3 elements E1, E2, E3, E4, E5 and E6 are connected as shown in Fig. 1 via contactors K1 and K2 and relays R1 and R2 to three phases RST. Elements E1 and E2 are connected in series, as are elements E3 and E4 and elements E5 and E6. The upper end of the series connection of elements E1 and E2 is connected to phase S, while the connection between elements E1 and E2 is connected to phase T via a circuit breaker in contactor K2 and the other end of series connection of elements E1 and E2 is connected to phase R through a circuit breaker in contactor K1. The upper end of the series connection of the elements E3 and E4 is connected to phase T via a circuit breaker R1 of the relay R1, while the connection between the elements E3 and E4 is connected to phase R via a circuit breaker in contactor K2 and the series connection end is connected to phase S via a switch in contactor K1. The upper end of the series connection of elements E5 and E6 is connected to phase R via a circuit breaker of relay R2 while the connection between elements E5 and E6 is connected to phase S via a circuit breaker in contactor K2 and the lower end of series connection is connected to phase T via a circuit breaker in contactor K1. 1: The combination of the temperature controller and the load monitor 4 86783 shown in more detail in Fig. 2 is connected to the current converter S1 of phase R and to the current converter S2 of phase S and to the current converter S3 of phase T. These current transducers are not described in more detail because they are well known in the art. As previously mentioned, the boiler sensor T is connected to the connection points 8 and 9 located in the upper left of Fig. 2 and this part of the circuit acts as a temperature controller, while the lower left side of the circuit acts as a load monitor which can limit the power output according to different parameters. The upper right in Fig. 2 shows a step counter with a coding network which controls a certain set of solenoid operating circuits, the top two R1 and R2 can be viewed as the aforementioned relays R1 and R2, while the bottom two can be viewed as contactors K1 and K2 in Fig. 1 and K2. The temperature controller in the circuit causes the step counter to output a signal that represents the required power to reach the desired set temperature, for example in the boiler water. However, the load monitor can limit the possible output power, in which case the step counter may be prevented from continuing to count to three or two or only the last power stage. The output of the coding network calculator is. . arranged so that zeros at all outputs do not cause the relays R1 and R2 or the circuit breakers K1 and K2 to be energized. The number one at output 14 and zeros in the others cause the operating switch K1 to be pulled and thus the contactor K1 to be pulled. The connection of the contactor K1 causes the connection of the elements E1: 1 and E2 between the stages S and T and in the accompanying embodiment a load of 2 kW. The load provided by the elements E1-E6 together is 24 kW. If relay R1 is also caused to close •; its circuit breaker R1 becomes an output power of 4 kW and if, in addition, relay R2 is made to close its contact R2 becomes a power of 6 kW. When the next step counter is lowered, contactor K2 closes, while K1 opens in the same way as relay R1, while relay R2 closes. This achieves a power of 8 kW. In the next stage 86783, contactor K2 is closed, while contactor K1 is open and relays R1 and R2 are closed. This stage gives a load of 12 kW. The next stage causes both contactors K1 and K2 to close and relays R1 and R2 to open, and then a power of 16 kW is achieved. In the next stage, the relay R1 is also closed, which together with the closing of the contactors K1 and K2 provides a power of 20 kW and finally when both the contactors K1 and K2 and the relays R1 and R2 are closed, a maximum power of 24 kW is reached. This is illustrated in more detail in Figure 3.

The device according to the present invention thus makes it possible to divide two three-phase elements into eight power stages. This, of course, as illustrated in more detail in Figure 3, offers considerable possibilities to maintain the desired temperature level even if the load intensity does not give full power. In the embodiment described above, the power of each element E1-E6 is 4 kW, whereby the different switching combinations increase the power in the first four stages by 2 kW and in the other stages by 4 kW.

The device according to the present invention described above is particularly suitable for use when it is desirable to combine 6 elements in one and the same resistor or in one and the same tube, e.g. E1-E6.

Claims (4)

6 86783 Device for connecting a certain number of three-phase loads, e.g. electrical resistors, to a three-phase network (RST), which loads (E1-E6) are divided into three equal parts, each intended for its own phase, characterized in that the phase parts (E1-E6) are connected in series (E1, E2; E3, E4; E5, E6) that each end of the series connections (E1, E2; E3, E4; E5, E6) is connected to its phase and that the connection between the phase parts in each series connection (E1, E2; E3, E4 ; E5, E6) are connected to the third phase, in addition to which circuit breakers (K1, K2, R1, R2) are arranged between the different phases and the terminals in order to make different connections. Device according to claim 1, wherein two three-phase resistors, each comprising an element for each phase, are intended to be connected to a three-phase network (RST) in more than two stages, characterized in that the elements (E1-E6) are connected in series (E1, E2; E3, E4; E5, E6) that the three series circuits (E1, E2; E3, E4; E5, E6) are connected to the phases (RST) in a three-phase network so that the ends of the series circuits (E1, E2; E3, E4; E5, E6) and the connections in the series circuits are each in their own phase, and that circuit breakers (K1, K2, R1, R2) are arranged between the ends and the phases and the connections and phases to provide different connections. Device according to Claim 2, characterized in that the second end of the first series connection (E1, E2) is connected to the first stage (S), while a second circuit breaker of the first contactor (K2) is connected to the second stage (T) between the connecting elements (E1, E2). and the other end of the series connection (E1, E2) is connected to the third phase (R) via a circuit breaker in the second contactor (K1), that the other end of the second series connection (E3, E4) is connected to the second phase (T) via the relay circuit breaker (R1), while the connection is 7 86783 connected to the third phase (R) via a circuit breaker in the first contactor (K2) and the other end of the series connection (E3, E4) is connected to the first phase (S) via a circuit breaker in the second contactor (K1), and that the second the end is connected to the third stage (R) via a relay switch (R2), while the connection is connected to the first stage (S) in the first via a third circuit breaker in the contactor (K2) and the other end is connected to the second phase (T) via a third circuit breaker in the second contactor (K1). Device according to Claim 3, characterized in that the contactors (K1, K2) and the relay switches (R1, R2) are connected to a controller (10) with a step counter, the calculator having a binary coding network which controls the relay switches (R1, R2) and contactors (K1, K2), where zeros at all outputs of the step counter give an output power of 0 kW, in which case all relay and contactor switches (K1, K2, R1, R2) are open, while full power is reached when all outputs have ones and thus all relays and the contactor circuit breakers (K1, K2, R1, R2) are closed and the intermediate binary numbers give seven other switching combinations and power levels. e 86783