KR101209877B1 - Thyristor composite module - Google Patents

Abstract

The present invention is equipped with a thyristor (Thyristor) element to control the large alternating current power in one module to reduce the number of parts required to configure the thyristor composite module and to reduce the volume of the thyristor to increase the cost and productivity It relates to a composite module.
The present invention for implementing this, the thyristor chip, the power input busbar for connecting the main power to the thyristor chip and the power output busbar, the connector for connecting the control signal to the thyristor chip is mounted on the printed circuit board circuit A connected substrate assembly; A frame made of a non-conductive material in which the substrate assembly is assembled to a bottom surface, and a plurality of auxiliary terminal blocks for connecting an external control power line and a plurality of main terminal blocks for connecting an external main power line to an upper surface thereof; A current sensor for detecting the current of the power input busbar or the power output busbar through which the main power flows, and a temperature sensor for detecting the temperature are mounted on the auxiliary substrate and adjacent to the power input busbar or the power output busbar at the bottom of the substrate assembly. It consists of an auxiliary substrate assembly that is installed so.

Description

Thyristor composite module {THYRISTOR COMPOSITE MODULE}

The present invention relates to a thyristor composite module in which elements required for controlling large AC power, including a thyristor, are mounted in a single module. The present invention relates to a thyristor composite module that can reduce cost and increase productivity.

A thyristor is a power control element that can control a large AC power with a small gate current. In general, a thyristor is used to package a plurality of thyristors in one module, and to connect a main power supply to the thyristors in order to construct a power control circuit. Main terminal block, auxiliary terminal block for connecting gate control power supply, fuse for circuit protection in case of overload, temperature sensor for detecting temperature rise of thyristor module, current transformer for detecting current of main power, these parts and A number of busbars (power circuit connecting bars made of copper plates with good conductivity) are used to connect the main power supply to each other.

1 illustrates an example of a conventional thyristor module, in which a plurality of thyristors are built in the thyristor module 10, and a nut 12 for fastening and connecting with a power line or a control line is installed outside thereof. In addition, a fixing hole 14 for connecting the thyristor module 10 to another substrate such as a printed circuit board or a heat sink is provided.

FIG. 2 illustrates a conventional embodiment in which a power controller is configured using the thyristor module 10 shown in FIG. 1. Since the thyristor module 10 generates a lot of heat, the thyristor module 10 is mainly installed on the heat sink 20. In order to control the power using the thyristor module 10, the terminal block 21 having a main terminal block and an auxiliary terminal block 21, a fuse 22, a plurality of bus bars 23 connecting the same, a CT for current detection (24) and various components, such as the temperature sensor 25 for monitoring the temperature rise of the thyristor module 10, are needed.

Such a power controller has a relatively large number of parts and a lot of workmanship is put into the manufacturing cost increases, there is a disadvantage that the volume is increased because the assembly by placing a number of peripheral parts, including the thyristor module (10).

The present invention has been invented in view of the above circumstances, and in constructing a power controller using a thyristor module, a thyristor module, a main terminal block, an auxiliary terminal block, a bus bar connecting the same, and a current for the power supply are detected. Integrate the current sensor, temperature sensor, etc. into one module to form a composite module, and in particular, the current sensor uses a current detecting element made of semiconductor, and a plurality of busbars, busbar fixing bolts, fuse fixing bolts It is an object of the present invention to provide a thyristor composite module capable of minimizing the overall volume of a power controller using a thyristor module by reducing the number of components, and reducing the number of parts, thereby lowering manufacturing costs and maximizing productivity.

Thyristor composite module of the present invention for achieving the above object,

A substrate assembly having a thyristor chip, a power input busbar for connecting a main power source to the thyristor chip, a power output busbar, and a connector for connecting a control signal to the thyristor chip mounted on a printed circuit board and circuit-connected by a printed circuit;

A frame made of a non-conductive material in which the substrate assembly is assembled to a bottom surface, and a plurality of auxiliary terminal blocks for connecting an external control power line and a plurality of main terminal blocks for connecting an external main power line to an upper surface thereof;

A current sensor for detecting the current of the power input busbar or the power output busbar through which the main power flows, and a temperature sensor for detecting the temperature are mounted on the auxiliary substrate and adjacent to the power input busbar or the power output busbar at the bottom of the substrate assembly. It consists of an auxiliary substrate assembly that is installed so.

The current sensor is characterized in that the semiconductor Hall sensor.

One side of the power output busbar is installed to be extended to the sensing piece is bent to the rear of the frame, and disposed close to the temperature sensor and the current sensor installed on the auxiliary substrate of the sensing piece auxiliary substrate assembly.

A fuse holder may be installed at one side of the upper surface of the frame to fix the fuse to the main terminal block.

In the present invention as described above, when constructing a power controller using a thyristor module, a plurality of main terminal blocks, an auxiliary terminal block for control power, a fuse, a bus bar connecting the same, a current sensor for detecting a current of the main power, and the like are accommodated in the composite module. Reduces the number of busbars, busbar fixing bolts, fuses, and fixing bolts, and reduces the current detection CT by miniaturizing and accommodating them in the composite module. Therefore, the workmanship is greatly reduced when manufacturing a power controller By reducing the number of busbars and wiring, the cost can be reduced to increase price competitiveness.

1 is a perspective view of a conventional thyristor module,
2 is a perspective view of a conventional power controller using a thyristor module,
3 is an assembled perspective view of a thyristor composite module according to the present invention;
4 is an exploded perspective view of a thyristor composite module according to the present invention;
5 is a view illustrating an assembly process of a thyristor composite module according to the present invention;
6 is an assembly view of the auxiliary substrate assembly according to the present invention,
7 is a circuit diagram of a power controller using a thyristor composite module according to the invention.

Figure 3 shows an assembly perspective view of the thyristors composite module according to the present invention, the frame 31 accommodates the components constituting the composite module according to the present invention to form an overall appearance, for example formed of a non-conductive material plastic Can be.

A front terminal of the frame 31 is a main terminal block for connecting with an external main power line, and a power input terminal block 33 for connecting a power supply terminal block 32 and an inlet wire connected to one side of a power source and an electric power for connecting an output line The output terminal block 34 is installed, and auxiliary terminal blocks 35 to 37 used to detect the power supply voltage and the load voltage are installed. The auxiliary terminal block 35 is used as a common terminal when detecting the power supply voltage and the load voltage. The terminal block 36 is a terminal block for power supply voltage detection connected to one end of the power supply, and the auxiliary terminal block 37 is a terminal block for load voltage detection connected to one end of the load.

In addition, both ends of the fuse 41 are bolted to the power terminal block 32 and the power input terminal block 33, respectively.

In addition, a connector fastening groove 43 for fastening the external device and the gate connector 42 is formed at one side of the frame 31 and in one example of the upper surface thereof, and the gate connector 42 is fastened to the connector. Exposure to the outside through the groove 43 facilitates electrical connection between the gate connector 42 and an external device.

4 is an exploded perspective view of the thyristor composite module shown in FIG.

As described above, the frame 31 is provided with a power terminal block 32, a power input terminal block 33, a power output terminal block 34, and auxiliary terminal blocks 35 to 37, and a connector fastening groove 43 is formed. It is.

The substrate assembly 50 assembled to one side of the bottom surface of the frame 31 has a pair of thyristor chips 52 and a power inlet busbar 53 and a power on a printed circuit board 51 having a printed circuit pattern formed on a surface thereof. The output busbar 54 and the connector 42 for the gate connection of the thyristor chip 52 are fixed by soldering. The printed circuit board 51 is preferably a ceramic substrate that is heat resistant and non-conductive. And the connection relationship between the components mounted on the substrate assembly 50 is as shown in FIG.

The power input busbar 53 and the power output busbar 54 are for connecting the main power to the thyristor chip 52, and since the thyristor is for controlling a large current, these busbars 53, 54 are mainly It is made of relatively wide and thick using copper plate with good conductivity. In addition, bent grooves 53a and 54a and fixing pieces are formed at ends of the busbars 53 and 54 so as to correspond to the structures of the respective terminal blocks 33 and 34 formed in the frame 31. 53b) 54b and bolt grooves 53c and 54c are formed.

In addition, a heat sink 55 for dissipating heat generated from the thyristor chip 52 may be attached to the bottom surface of the printed circuit board 51.

On the power output terminal block 34 of the frame 31 and the auxiliary terminal block 37 for detecting the load voltage, a terminal piece 61 for electrically connecting both terminal blocks is seated, and the auxiliary terminal block 35 has a terminal piece for power connection. 62 is seated, and a terminal piece 63 for electrically connecting both terminal blocks is mounted on the power supply terminal block 32 and the power supply voltage detecting auxiliary terminal block 36.

Screw grooves 61a, 61b, 62a, 63a, 63b for bolting are drilled in the terminal pieces 61-63, and nuts 81-86 are provided in each terminal block 32-37. Inserted and fastened with bolts 71 to 76 corresponding thereto, wherein the terminal pieces 61 to 63 are fastened together by bolts 71 to 75.

One end of the fuse 41 is fixed to the power supply terminal block 32 by the bolt 74 together with the terminal piece 63, and the other end of the fuse 41 is connected to the power input terminal block 33 by the bolt 76. Is fixed to.

On the other hand, Figure 5 is a view showing a process of assembling the substrate assembly 50 to the frame 31, the substrate assembly 50 is assembled in the lower portion of the frame 31 as shown in Figure 5 (a), the substrate The power input bus bar 53 and the power output bus bar 54 mounted on the assembly 50 pass through the respective power input terminal blocks 33 and the power output terminal blocks 34 formed on the frame 31, and the ends thereof. This frame 31 is exposed to the upper surface (see FIG. 5B).

Then, as shown in (c) of FIG. 5, the ends of the power input bus bar 53 and the power output bus bar 54 are bent by 90 degrees with respect to the bending grooves 53a and 54a, respectively, to each terminal block. It is seated. At this time, the power output bus bar 54 is fixed to the locking groove (31a) formed in the frame 31 is fixed to the fixing piece (54b) formed at the end of the flow is prevented, the power inlet booth The fixing piece 53b of the bar 53 is also firmly fixed to the locking groove 31b formed in the frame 31 to prevent flow.

5 (d) shows a state in which the substrate assembly 50 is assembled to the frame 31.

6 shows an assembly view of an auxiliary substrate assembly according to the present invention.

As shown in FIG. 6, a substrate assembly 50 is assembled on one side of the frame 31, and an auxiliary substrate assembly 90 is assembled side by side with the substrate assembly 50.

The auxiliary substrate assembly 90 is equipped with a temperature sensor 91 and a current sensor 92 on the auxiliary substrate 93, the temperature sensor 91 and the current sensor 92 is a composite module of the present invention. In order to easily detect the temperature rise and the current of the main power supply, it is preferable to be installed in close contact with the bus bar. In this embodiment, the structure is installed in close contact with the power output bus bar 54. In addition, the current sensor 92 to reduce the volume occupied by the current sensor by using the Hall sensor in the embodiment of the present invention.

In addition, one side of the power output bus bar 54 is provided so that the sensing piece 54d is extended to protrude toward the rear of the frame 31, and the auxiliary substrate assembly 90 has a groove 94 formed therein. When the substrate assembly 90 is coupled to the rear of the frame 31, the sensing piece 54 penetrates the groove 94 and is disposed close to the temperature sensor 91 and the current sensor 92.

In this way, the auxiliary substrate assembly 90 is coupled to the rear of the frame 31 and then covered with a cover 95 to protect the inside.

7 shows a circuit diagram according to an example of a power controller using a thyristor composite module according to the invention.

The thyristor composite module 100 according to the present invention is provided with a plurality of thyristor chips 52 so that one side of the main power supply terminal is connected to the power input terminal block 33 while the other side is connected to the power output terminal block 34. A temperature sensor 91 and a current sensor 92 are installed at adjacent portions of the power output bus bar 54 connected to the power output terminal block 34, and a connector 42 is connected to a gate of the thyristor chip 52. It is made to be connected to the external power control unit, the power input terminal 33 has a structure in which the power supply terminal 32 is connected through the fuse 41.

As described above, in the thyristor composite module 100 according to the present invention, the peripheral elements required to control AC power using the thyristor are integrally assembled with the thyristor to reduce the volume of the thyristor composite module 100, and the thyristor composite module 100. When constructing a power controller using), the labor cost is reduced, which increases productivity and reduces production costs.

In the present specification, a preferred embodiment of the thyristor composite module according to the present invention has been described, but the present invention is not limited thereto. Auxiliary terminal block can be changed with connector and it can be manufactured for three phases by attaching three thyristor composite modules in this paper. As such, the present invention may be practiced in various ways within the scope of the claims and the accompanying drawings, which also fall within the scope of the invention.

31-frame, 32-power terminal,
33-power input terminal block, 34-power output terminal block,
35--37-auxiliary terminal, 41-fuse,
42-connector, 43-connector fastening groove,
50-board assembly, 51-printed circuit board,
52-thyristor chips, 53-power entry busbars,
54-power output busbar, 55-heat sink,
90-Auxiliary board assembly, 91-Temperature sensor,
92-current sensor, 93-auxiliary board,
95-cover.

Claims (4)

A substrate assembly having a thyristor chip, a power input busbar for connecting a main power source to the thyristor chip, a power output busbar, and a connector for connecting a control signal to the thyristor chip mounted on a printed circuit board and circuit-connected by a printed circuit;
A frame made of a non-conductive material in which the substrate assembly is assembled to a bottom surface, and a plurality of auxiliary terminal blocks for connecting an external control power line and a plurality of main terminal blocks for connecting an external main power line to an upper surface thereof;
A current sensor for detecting the current of the power input busbar or the power output busbar through which the main power flows, and a temperature sensor for detecting the temperature are mounted on the auxiliary substrate and adjacent to the power input busbar or the power output busbar at the bottom of the substrate assembly. Thyristor composite module comprising an auxiliary substrate assembly that is installed. The thyristor composite module according to claim 1, wherein a temperature sensor and a current sensor installed on the auxiliary substrate of the auxiliary substrate assembly are disposed in close proximity to one side of the power output bus bar in the frame. The thyristor composite module according to claim 1, wherein the upper side of the frame has a structure capable of fixing the fuse to the main terminal block. The thyristor composite module according to claim 1, wherein the current sensor is a semiconductor Hall sensor.

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