KR20240030287A - Block type terminal block module device for durability test - Google Patents

Abstract

An invention regarding a terminal block module device for durability testing is disclosed. The disclosed terminal block module device for durability testing includes a base plate in the shape of a plate, an input terminal block provided on the base plate and connected through an input wire on the test sample side, and having a plurality of input channels, and a test device. An output terminal block having a plurality of output channels each connected through an output wire connected to a load channel on the equipment side, and each connected to the output side of the input channel and the input side of the output channel to transfer the capacity of the input channel to the capacity of the output channel. A variable capacity control unit that connects a plurality of connection bus bars and one or more connection bus bars adjacent to each other to adjust the power capacity to be measured in the test sample and transmits it to the load channel side of the test equipment; It is characterized by including.

Description

Terminal block module device for durability test {BLOCK TYPE TERMINAL BLOCK MODULE DEVICE FOR DURABILITY TEST}

The present invention relates to a terminal block module device for durability testing. More specifically, when constructing a terminal block module, the input terminal block connected to the test sample and the output terminal block connected to the test equipment are block to facilitate attachment, detachment and repair. Rather, it relates to a terminal block module device for durability testing that can easily adjust the capacity according to the power of the test sample using a variable capacity control unit when connecting the input terminal block and the output terminal block.

In general, test samples such as wiring blocks and charged current terminals are tested to determine whether there are any abnormalities such as temperature, heat generation, melting, or burnout within a certain amount of time relative to the power capacity (Watt = voltage × current) set during the manufacturing process. A durability test will be performed to determine whether or not it is possible.

This durability test is implemented using a durability test device. The durability test device connects the power supply unit provided on the test equipment side and supplies the power supply unit to the input side of the test sample, and a plurality of devices provided on the output side of the test sample. It includes a terminal block channel and a plurality of load channels provided on the test equipment side where the terminal block channel is connected to the input side.

However, the existing durability test device can connect terminal blocks in multiple rows, but the terminal block channel and the load channel have a 1:1 matching structure, which makes it difficult to adjust the capacity to suit the test situation. In addition, it has the disadvantage of being limited to low-capacity, low-power terminal blocks, making high-power testing difficult.

Therefore, there is a need to improve this.

Related background technology includes Public Utility Model Publication No. 2019-0002438 (2019.10.01, Title of invention: Combination structure of terminal block and base).

The present invention was created in response to the above-mentioned need. In constructing a terminal block module, the input terminal block connected to the test sample and the output terminal block connected to the test equipment are blocked to facilitate attachment, detachment and repair, as well as the input terminal block. The purpose is to provide a terminal block module device for durability testing that can easily adjust the capacity according to the power of the test sample by using a variable capacity control unit when connecting the output terminal block.

In order to achieve the above object, a terminal block module device for durability testing according to the present invention includes a base plate in the shape of a plate; An input terminal block provided on the base plate, connected to the test sample through an input wire, and having a plurality of input channels; An output terminal block provided on the base plate and having a plurality of output channels each connected through output wires connected to a load channel on the test equipment side; a plurality of connection bus bars respectively connected to the output side of the input channel and the input side of the output channel to transfer the capacity of the input channel to the capacity of the output channel; And a variable capacity control unit that connects one or more of the connection bus bars to another neighboring connection bus bar to adjust the power capacity to be measured in the test sample and transmits it to the load channel side of the test equipment. It is characterized by

The base plate is provided with a terminal material for power connection, and is connected to a power supply unit to which a load channel of the test equipment is connected to supply power capacity to the test sample through the power supply unit.

The base plate is provided with a mounting bracket for installation of the base plate, and the mounting bracket is arranged to overlap in an L-shape on one edge and side of the base plate and extends outward. A hook for hanging at a set position is provided on the base plate. It is characterized by the formation of a hole.

The base plate is provided with an installation bracket to fix the output wire connected to the output channel using a position fixing part, and the position fixing part includes a pair of mounting holes formed through each of the output wires; And a band member that is fitted into the mounting hole and winds and secures the output wire.

The input terminal block is provided with a first seating groove in which one side of the connection bus bar is seated, and a second seating groove in which the input side of the test sample is connected to the opposite position of the first seating groove, wherein the first, The second seating groove is characterized in that it is divided into multiple units so that they can be separated into blocks to facilitate replacement and repair.

The output terminal block is provided with a third seating groove where the other side of the connection bus bar is seated, and a fourth seating groove having a socket into which the connector terminal provided on the output wire is inserted at an opposite position opposite to the third seating groove. However, the third and fourth seating grooves are characterized in that they are divided into a plurality of separately separable blocks to facilitate replacement and repair.

The variable capacity control unit includes a first coupling hole formed on one side of the center of one of the connection bus bars and the other connection bus bar; a second coupling hole formed on the other side of the center of one of the connection bus bars and the other connection bus bar; Connecting the first coupling hole of one of the connection bus bars with the first coupling hole of another connection bus bar, or connecting the second coupling hole of one of the connection bus bars with the other one. A joint bus bar that connects one or more of the second coupling holes of the bus bar to adjust power capacity; and a fastening fixing part that couples and fixes the joint bus bar to the first and second coupling holes.

The variable capacity control unit includes an integrated joint bus bar that integrally connects all of the connection bus bars to enable maximum power capacity, and the integrated joint bus bar connects the first and second connection bus bars of all of the connection bus bars. Each of the two coupling holes is provided with a corresponding fitting hole part, and is coupled to each of the first coupling hole or the second coupling hole via a coupling member through the plurality of fitting holes, and is connected to all of the connection bus bars to provide maximum power. It is characterized by implementing capacity.

The fastening fixing part includes a through-hole part formed through both sides of the joint bus bar; and fastening members respectively inserted into the through-hole portions and fastened to the first and second coupling holes.

The terminal block module device for durability testing according to the present invention not only facilitates attachment, detachment and repair by blocking the input terminal block connected to the test sample and the output terminal block connected to the test equipment when configuring the terminal block module, but also facilitates installation and repair of the input terminal block and output terminal block. When connecting the terminal block, the capacity can be easily adjusted according to the power of the test sample by using the variable capacity control unit.

Figure 1 is a state diagram of a terminal block module device for durability testing according to an embodiment of the present invention, in which five channels are connected using four joint bus bars to increase capacity.
Figure 2 is an exploded perspective view of a terminal block module device for durability testing according to an embodiment of the present invention, and shows a state in which five channels are connected using four joint bus bars to increase capacity.
Figure 3 is an assembled perspective view of a terminal block module device for durability testing according to an embodiment of the present invention, showing a state in which five channels are connected using four joint bus bars to increase capacity.
Figure 4 is an exploded perspective view of the main terminal block module device for durability testing according to an embodiment of the present invention, showing five channels connected using four joint bus bars.
Figure 5 is a state diagram of the terminal block module device for durability testing according to an embodiment of the present invention, and shows the state of use of 1500W for 5 channels when each channel is 300W.
Figure 6 is a state diagram of the terminal block module device for durability testing according to an embodiment of the present invention, showing a state in which all channels are connected using an integrated joint bus bar to maximize capacity.
Figure 7 is an exploded perspective view of a terminal block module device for durability testing according to an embodiment of the present invention, showing a state in which all channels are connected using an integrated joint bus bar to maximize capacity.
Figure 8 is an exploded perspective view of the main parts of the terminal block module device for durability testing according to an embodiment of the present invention, and is a state diagram in which all channels are connected using an integrated joint bus bar to maximize capacity.

Hereinafter, a terminal block module device for durability testing according to an embodiment of the present invention will be described with reference to the attached drawings.

In this process, the thickness of lines or sizes of components shown in the drawing may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

Figure 1 is a state diagram of a terminal block module device for durability testing according to an embodiment of the present invention, in which five channels are connected using four joint bus bars to increase capacity, and Figure 2 is a state diagram of an embodiment of the present invention. This is an exploded perspective view of the terminal block module device for durability testing according to the present invention, and is a state diagram in which five channels are connected using four joint bus bars to increase capacity. Figure 3 is an assembled perspective view of the terminal block module device for durability testing according to an embodiment of the present invention. , This is a state diagram in which capacity is increased by connecting five channels using four joint bus bars, and Figure 4 is a main exploded perspective view of a terminal block module device for durability testing according to an embodiment of the present invention, using four joint bus bars. It is a diagram of five channels connected, and Figure 5 is a state diagram of the terminal block module device for durability testing according to an embodiment of the present invention. It is a state diagram of five channels using 1500W when each channel is 300W.

Figure 6 is a state diagram of the use of the terminal block module device for durability testing according to an embodiment of the present invention, where all channels are connected using an integrated joint bus bar to maximize capacity, and Figure 7 is a state diagram of an embodiment of the present invention. This is an exploded perspective view of the terminal block module device for durability testing according to the present invention, with all channels connected using an integrated joint bus bar to maximize capacity. Figure 8 is an exploded perspective view of the main portion of the terminal block module device for durability testing according to an embodiment of the present invention. This is a state diagram in which all channels are connected using an integrated joint bus bar to maximize capacity.

Referring to Figures 1 to 8, the terminal block module device for durability testing according to an embodiment of the present invention includes a base plate 100, an input terminal block 200, an output terminal block 300, a connection bus bar 400, and a variable Includes a capacity adjustment unit 500.

The base plate 100 has a plate shape and serves as a basic frame for the terminal block module device for durability testing according to an embodiment of the present invention.

The base plate 100 is roughly rectangular and can be mounted on a wall such as a general wall or chamber. It can be hung using the hanging groove 112 provided in the mounting bracket 110, which will be described later, or attached to the wall by welding, etc. It can also be attached integrally.

The base plate 100 is equipped with a terminal material 105 for power connection, and is connected to a power supply unit 50 to which the load channel 40 of the test equipment 30 is connected, so that the test sample ( 10) Power capacity can be supplied.

The test sample 10 may include, for example, a junction block, a high current terminal, etc. For example, the load channel 40 is indicated with a maximum capacity of 300W per channel, but in some cases, it may be configured to have a capacity of 600W or 900W or more per channel.

In the case of 30 channels in one embodiment of the present invention, the power supply unit 50 may supply 30 It is possible to adjust it to supply only 1500W. In this way, it is possible to adjust the power capacity and use it by combining it in various ways depending on the type of test sample 10.

The base plate 100 may be provided with a mounting bracket 110 for installing the base plate 100. The mounting bracket 110 is arranged to overlap in an L-shape on one edge and side of the base plate 100 and extends outward, and a hanging hole 112 for hanging it at a set position may be formed.

The input terminal block 200 is provided on the base plate 100, is connected to the test sample 10 through the input wire 20, and has a plurality of input channels 210.

The output terminal block 300 is provided on the base plate 100 and has a plurality of output channels 310 each connected through output wires 340 connected to the load channel 40 on the test equipment 30 side. It is a composition.

The base plate 100 may be provided with a first installation groove 140 in which the input terminal block 200 is installed and a second installation groove 150 in which the output terminal block 300 is installed. The first and second installation grooves 140 and 150 ensure that the input terminal block 200 and the output terminal block 300 are stably fixed to the base plate 100 to prevent shaking.

A plurality of connection bus bars 400 are connected to the output side of the input channel 210 and the input side of the output channel 310, respectively, so as to directly transfer the capacity of the input channel 210 to the capacity of the output channel 310.

Meanwhile, in one embodiment of the present invention, the first example (see FIGS. 1 to 5) of supplying 1500W from the power supply unit 50 to test the 1500W power capacity of the test sample 10, and the test sample 10 In order to test the 9000W maximum power capacity, the second example (see FIGS. 6 to 8) in which 9000W is supplied from the power supply unit 50 is shown and explained.

At this time, in one embodiment of the present invention, both the first and second examples are described based on 300W per channel and shown as having 30 channels. Of course, the capacity of each channel is 300W, 600W, 900W, etc., so the appropriate number can be used in combination. Power capacity is made up of the sum of voltage (V) and current (A), and power is derived by appropriately determining voltage and current.

The input terminal block 200 is a first seating groove 220 in which one side of the connection bus bar 400 is seated, and the input side of the test sample 10 is connected to the opposite position of the first seating groove 220. It is provided with two seating grooves 230, and the first and second seating grooves 210 and 220 can be divided into multiple units and separated into blocks to facilitate replacement and repair.

The output terminal block 300 includes a third seating groove 320 in which the other side of the connection bus bar 400 is seated, and a connector terminal provided on the output wire 340 at an opposite position facing the third seating groove 320 ( 342) is provided with a fourth seating groove 330 having a socket into which it is inserted, and the third and fourth seating grooves 320 and 340 are block-blocked into separate units to facilitate replacement and repair. You may.

The base plate 100 may be provided with an installation bracket 120 to fix the output wire 340 connected to the output channel 310 using the position fixing part 130. The installation bracket 120 is formed to extend outward while overlapping in an L-shape on one edge and side of the base plate 100 at an opposite position corresponding to the mounting bracket 110. Like the mounting bracket 110, the installation bracket 120 may also be provided with a plurality of hanging holes.

The position fixing part 130 is provided on the installation bracket 120 and is fitted with a pair of mounting hole parts 132 formed through each output wire 340 and the mounting hole parts 132 to secure the output wire 340. It includes a band member 134 that is wound and fixed.

The band member 134 may include a pair of fitting parts fitted into the mounting hole 132, and a feeler part respectively connected to the pair of fitting parts and winding the output wire 340. As a result, a plurality of output wires 340 can be stably fixed and installed side by side on the installation bracket 120 through the plurality of band members 1340.

The variable capacity control unit 500 connects one connection bus bar 400 and one or more neighboring connection bus bars 400 to adjust the power capacity to be measured in the test sample 10 for testing. It is configured to transmit to the load channel 40 of the equipment 30.

The variable capacity control unit 500 is a first example, and includes a first coupling hole 510 formed on one side of the center of one connection bus bar 400 and the other connection bus bar 400, and one connection bus bar 400. A second coupling hole 520 formed on the other side of the center of the connection bus bar 400 and another connection bus bar 400, and a second coupling hole 520 formed on the other side of the center of the connection bus bar 400 and another connection bus bar 400. The first coupling holes 510 of one connection bus bar 400 are connected to each other, or the second coupling holes 520 of one connection bus bar 400 and the second coupling holes 510 of the other connection bus bar 400 are connected. A joint bus bar 530 that controls power capacity by connecting one or more coupling holes 420 to each other, and a fastener that couples and secures the joint bus bar 530 to the first and second coupling holes 510 and 520. Includes government (550).

When the joint bus bar 530 is coupled to the first and second coupling holes 510 and 520 of the connection bus bar 400, the joint bus bar 530 is alternately arranged in the upper, lower, upper and lower directions, etc. to enhance the output. . If four joint bus bars 530 are used, a total of five connection bus bars 400 are connected. At this time, the number of installed joint bus bars 530 can be increased or decreased depending on the power capacity for testing the test sample 10.

The fastening fixing part 550 is inserted into the through-hole part 552 formed through both sides of the joint bus bar 530 and the through-hole part 552 and fastened to the first and second coupling holes 510 and 520. Includes fastening member 554.

The through hole portion 552 is an open hole, and the first and second coupling holes 510 and 520 are screw holes. The fastening member 554 may include a screw or bolt.

First, with reference to FIGS. 1 to 5, let us look at the state of testing the test sample 10 with a power capacity of 1500W in the first example.

1500W is supplied from the power supply unit 400 provided in the test equipment 30 and transmitted to the test sample 10, and 1500W is supplied from the test sample 10 to any one of the input channels 210 of the five input terminal blocks 200. Please input . At this time, during manufacturing, each of the input channels 210 is manufactured to withstand 1500W, so it is okay for a slightly high output to be input.

In succession, the five connection bus bars (400) are connected in series through four joint bus bars (530) alternately connected to the first and second coupling holes (510) and (502). As a result, it is supplied to the load channels 40 of the test equipment 30 through the output wires 430 through the five output channels 310, respectively, and a power of 300W × 5 = 1500W per load channel 40 is supplied to the test sample (10). ) is considered to be implemented, and a durability test is conducted to determine how long the test sample 10 can withstand the temperature, heat generation, melting, and burnout.

In this way, it is possible to adjust the power capacity of the test sample 10 according to the number of joint bus bars 530, which are the variable capacity control unit 500, connected to the connection bus bars 400.

Meanwhile, the variable capacity control unit 500, as a second example (see FIGS. 6 to 8), is an integrated joint bus bar that connects all of the connection bus bars 400 as one body to enable maximum power capacity. It may include (540).

The integrated joint bus bar 540 is provided with fitting holes 542 corresponding to the first and second coupling holes 510 and 520 of the entire connecting bus bar 400, respectively, and has a plurality of fitting holes 542. By coupling them to each of the first coupling hole 510 or the second coupling hole 520 through the coupling member 544 and connecting them to all connection bus bars 400, it can be configured to implement maximum power capacity.

First, with reference to FIGS. 6 to 8, let us look at the state of testing the test sample 10 with a power capacity of 9000W in the second example.

9000W is supplied from the power supply unit 400 provided in the test equipment 30 and transmitted to the test sample 10, and the input wire 20 from the test sample 10 is directly connected to the integrated joint bus bar 540. do. At this time, the reason why input is not made through the input channel 210 of the input terminal block 200 is because the allowable capacity of the input channel 210 of the input terminal block 200 cannot support the maximum power capacity.

Subsequently, 30 connection bus bars (400) connected to the integrated joint bus bar 540 through the coupling member 54 are all connected in series and test equipment (400) is connected through the output wire 430 through 30 output channels 310. It is assumed that the test sample 10 is supplied to all 30 load channels 40 of 30) and implements the total power of 30 A durability test will be conducted to determine how long it can withstand melting and burnout.

Therefore, the terminal block module device for durability testing according to an embodiment of the present invention not only facilitates attachment, detachment and repair by blocking the input terminal block connected to the test sample and the output terminal block connected to the test equipment when constructing the terminal block module. In addition, when connecting the input terminal block and the output terminal block, the capacity can be easily adjusted according to the power of the test sample by using the variable capacity control unit.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those skilled in the art will recognize that various modifications and other equivalent embodiments are possible therefrom. You will understand.

Therefore, the true technical protection scope of the present invention should be determined by the scope of the patent claims below.

10: Test sample 20: Input wire
30: Test equipment 40: Load channel
50: Power supply unit 100: Base plate
105: Terminal block for power connection 110: Mounting bracket
112: Hanging groove 120: Installation bracket
130: Position fixing part 132: Mounting hole part
134: Band member 140: Installation groove
150: Second installation groove 200: Input terminal block
210: input channel 220: first seating groove
230: Second seating groove 300: Output terminal block
310: Output channel 320: Third seating groove
330: Fourth seating groove 340: Output wire
342: Connector terminal 400: Connection bus bar
500: Variable capacity control unit 510: First coupling hole
520: second coupling hole 530: joint bus bar
540: Integrated joint bus bar 542: Fitting hole
544: Coupling member 550: Fastening fixing unit
552: Through hole portion 554: Fastening member

Claims (9)

A base plate in the shape of a plate;
An input terminal block provided on the base plate, connected to the test sample through an input wire, and having a plurality of input channels;
An output terminal block provided on the base plate and having a plurality of output channels each connected through output wires connected to a load channel on the test equipment side;
a plurality of connection bus bars respectively connected to the output side of the input channel and the input side of the output channel to transfer the capacity of the input channel to the capacity of the output channel; and
A variable capacity control unit that connects one or more of the connection bus bars to another neighboring connection bus bar to adjust the power capacity to be measured in the test sample and transmits it to the load channel side of the test equipment;
A terminal block module device for durability testing, comprising:
According to clause 1,
A terminal block module device for durability testing, characterized in that the base plate is provided with terminal materials for power connection, is connected to a power supply unit to which a load channel of the test equipment is connected, and supplies power capacity to the test sample through the power supply unit.
According to clause 1,
The base plate is provided with a mounting bracket for installation of the base plate,
A terminal block module device for durability testing, wherein the mounting bracket is arranged to overlap in an L-shape on one edge and side of the base plate, extends outward, and has a hanging hole for hanging at a set position.
According to clause 1,
The base plate is provided with an installation bracket to secure the output wire connected to the output channel using a position fixing part,
The position fixing part is,
A pair of mounting holes formed through each of the output wires; and
A band member that is fitted into the mounting hole and secures the output wire by winding it.
A terminal block module device for durability testing, comprising:
According to clause 1,
The input terminal block is provided with a first seating groove in which one side of the connection bus bar is seated, and a second seating groove in which the input side of the test sample is connected to the opposite position of the first seating groove,
A terminal block module device for durability testing, characterized in that the first and second seating grooves are divided into a plurality of separately separable blocks to facilitate replacement and repair.
According to clause 1,
The output terminal block is provided with a third seating groove where the other side of the connection bus bar is seated, and a fourth seating groove having a socket into which the connector terminal provided on the output wire is inserted at an opposite position opposite to the third seating groove. However,
A terminal block module device for durability testing, characterized in that the third and fourth seating grooves are divided into a plurality of separately separable blocks to facilitate replacement and repair.
According to clause 1,
The variable capacity control unit,
a first coupling hole formed on one side of the center of one of the connection bus bars and the other connection bus bar;
a second coupling hole formed on the other side of the center of one of the connection bus bars and the other connection bus bar;
Connecting the first coupling hole of one of the connection bus bars with the first coupling hole of another connection bus bar, or connecting the second coupling hole of one of the connection bus bars with the other one. A joint bus bar that connects one or more of the second coupling holes of the bus bar to adjust power capacity; and
A fastening fixing part that couples and secures the joint bus bar to the first and second coupling holes;
A terminal block module device for durability testing, comprising:
According to clause 7,
The variable capacity control unit,
It includes an integrated joint bus bar that connects all of the connection bus bars as one unit to enable maximum power capacity,
The integrated joint bus bar is provided with fitting hole portions corresponding to the first and second coupling holes of the entire connecting bus bar, respectively, and is connected to each of the first coupling holes and the second coupling holes through the plurality of fitting holes. A terminal block module device for durability testing, characterized in that it is all coupled through a coupling member and connected to all of the connection bus bars to realize maximum power capacity.
According to clause 7,
The fastening fixing part is,
Through-hole portions formed on both sides of the joint bus bar; and
Fastening members each inserted into the through-hole portion and fastened to the first and second coupling holes;
A terminal block module device for durability testing, comprising:

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