KR102110514B1 - String for nuclear facility DC power supply device - Google Patents

Abstract

Provided is a string for a nuclear power plant DC power supply device that secures seismic reliability, performs dust protection and shock absorption between end cells, and enables electrical terminal connection by preventing a short circuit. According to a preferred embodiment of the present invention, the string for a nuclear power plant DC power supply device comprises: a string casing made of an insulating material and having a power module storage room opened upward; a plurality of power modules inserted into the module storage room and placed to be in close contact with each other; a flexible bus bar installed to be electrically connected to a neighboring power module and flexibly configured to prevent a short circuit during an earthquake; and a casing cover made of an insulating material and detachably installed on an upper part of the string casing to seal the power module storage room.

Description

String for nuclear facility DC power supply device

The present invention relates to a string used in a nuclear power plant DC power supply device, in particular, to secure seismic reliability, to provide dust and shock absorption between cell cells, and to supply electrical power to the nuclear power plant to make electrical terminal connections reliable by preventing short circuits. It relates to a device string.

After the Fukushima nuclear power plant accident, national interest in nuclear power plant safety has been rising due to international regulations on nuclear power plants and rising atmosphere against nuclear power plant construction. The Fukushima nuclear power plant is a major cause of the explosion of the power plant outage (SBO) accident due to the earthquake and tsunami, and the loss of power and emergency diesel generator and battery function. Following the Fukushima nuclear accident, the U.S. Nuclear Regulatory Commission (NRC) eased accidents for at least 8 hours to prevent cooling and cooling material loss in the event of a power failure in the nuclear power plant operating country and nuclear power plant operators. It is recommended to secure countermeasures and extend these functions to 72 hours. However, in the case of current nuclear power plants in Korea, emergency diesel generators, alternative AC generators, and storage batteries are used to secure countermeasures, and most of them have insufficient capacity of 2 to 4 hours. Load + 22 hours Load Shedding Program) is secured, but Korea Nuclear Safety & Technology Institute (KINS) requires a full load operation 24 hours a day.

Therefore, domestic nuclear power plants need to find a way to operate a full load 24 hours a day. In addition, a system capable of securing more than 72 hours (24 hours full load + 48 hours load shedding program) is needed. In addition, for the rest of the nuclear power plants, except for Singori Units 5 and 6, the lead-acid battery system has a very insufficient capacity of 2 to 4 hours, so a power supply is needed to ensure sufficient emergency power in the event of a power loss accident. In addition, it is possible to utilize the battery room of an existing nuclear power plant, and a system capable of securing a capacity of more than 72 hours (24 hours full load + 48 hours load shedding program) while having a very small weight and volume based on the same power supply amount. .

In the system for supplying DC emergency power in the event of a nuclear power plant accident, a plurality of battery modules are mounted inside using a rack frame. The rack frame mounting battery modules therein is a large-capacity battery due to space limitations. In order to accommodate the power module is made, it is necessary to be arranged in a rack, cabinet, or the like.

However, the conventional power module does not provide earthquake-resistant reinforcement, but also includes devices for connecting power such as separate wires to connect multiple battery modules mounted on the rack frame. There is a problem in that power is not supplied to a nuclear power plant in an emergency because devices for connection are easily disconnected.

In order to solve this, as a background technology of the present invention, as Korean Patent Publication No. 10-2018-0055407, a "battery module and a battery pack including the same" has been proposed. In the background art, the battery module includes: a battery cell stacked body in which a plurality of battery cells are stacked; A plurality of end plates surrounding at least a portion of the battery cell stack; And a support member coupled to a plurality of end plates to support the end plate, so as to facilitate fastening of the end plate in the battery module and reduce overall size. However, the background technology is that the end plate is fastened through the engaging projections and the engaging grooves, so that it is vulnerable to earthquake resistance during an earthquake, so that the bonding can be easily released or damaged.

On the other hand, the applicant has proposed a 'battery module for a DC emergency power supply device of nuclear power plant' as Korean Registered Patent Registration No. 10-1799540. It consists of a unit member consisting of a lithium-polymer battery cell and a cartridge formed of a flame-retardant material on the outside, and is combined in parallel to form an independent BMS per battery module to stably mount it on a rack frame. However, even in the case of this technology, it is not necessary to reinforce the seismic resistance because it is not integrated due to the cartridge shape.

Korean Patent Publication No. 2015-0031449 Korean Registered Patent Registration No. 10-1799540

An object of the present invention is to provide a string for a nuclear power plant DC power supply device that secures seismic reliability, provides dust and shock absorption between cell cells, and provides reliable electrical terminal connection by preventing short circuit.

A string for a nuclear power plant DC power supply device according to a preferred embodiment of the present invention includes: a string casing made of an insulating material and having a power module storage compartment opened upward; A plurality of power modules inserted into the module storage room and positioned in close contact with each other; A flexible bus bar installed to be electrically connected to a neighboring power supply module and flexibly configured to prevent a short circuit during an earthquake; It is made of an insulating material and is detachably installed on the upper portion of the string casing, and characterized in that it includes a casing cover that seals the power module storage compartment.

In addition, it is characterized in that the FRP filler is installed in close contact between adjacent power modules to prevent resonance.

In addition, in order to securely install the string casing to the rack frame, a plurality of coupling keys protruding from the lower surface of the string casing and extending in the width direction are further formed.

In addition, it is characterized in that it further comprises an insulating mold formed between the string casing and the power module is filled with an insulating resin in the power module storage room.

In addition, a module case having a constant width, length and height and having a battery pack storage chamber opened to the top; A battery pack stored in a module case through the battery pack storage room; A printed circuit board disposed on the top of the battery pack and electrically connected to the battery pack; It has a busbar opening hole arranged in two rows in the width direction of the module case and a wiring guide groove of a certain depth transverse to the width direction in the center, and is disposed on the top of the printed circuit board and connected to the output terminal of the battery pack. A wiring guide frame for guiding electrical wiring through the guide groove; It is characterized in that it comprises; a battery pack insulation mold that is filled with an insulating resin in the battery pack storage chamber to fill an empty gap between the periphery of the battery pack and the module case, thereby integrating the battery pack and the module case to suppress resonance of the battery pack. .

In addition, the battery pack is provided with an even number of lithium polymer single cell cells so that the cell terminals are located on top, stacked side by side in the width direction of the module case, adjacent lithium polymer single cell for seismic safety of the lithium polymer single cell It is characterized in that the buffer pads are adhered to each other by means of an adhesive tape between cells.

In addition, an insulating rubber is further installed between the bottom of the battery pack and the inner bottom surface of the module case to prevent a short circuit.

In addition, the printed circuit board is arranged in a position where the first row lower bus bar and the second row lower bus bar having fastening holes are displaced from each other, and the lithium polymer stages on both sides of the first row lower bus bar and the second row lower bus bar. A short-circuit protection terminal fitting binding slit is formed so that the terminal of the battery cell is inserted; A first row upper bus bar and a second row upper bus bar are respectively disposed on the first row lower bus bar and the second row lower bus bar; The first row upper bus bar and the second row upper bus bar are respectively coupled to the first row lower bus bar and the second row lower bus bar through a combination of a fastening bolt and a nut; It is characterized in that the cell terminals of the single cell are bent to be in close contact between the first and second row upper bus bars and the first and second row lower bus bars to be in electrical contact.

According to the string for a nuclear power supply DC power supply of the present invention, an insulation mold is formed between the power module and the scrub casing to ensure seismic reliability.

In addition, a shock absorbing pad is provided between the cell cells in the power module to absorb the shock, so that even if the power module receives an external shock, the safety between the cell cells can be secured, and the battery pack and the module case are integrated to form a battery pack. Resonance can be suppressed to ensure seismic characteristics, and insulation is secured by preventing metallic short circuits and blocking leakage of moisture and moisture that may be generated in a single cell by an insulating mold in the power module.

In addition, it is possible to facilitate the electric wiring by the wiring guide frame provided in the power module, it is possible not only to perform the electrical contact of the cell terminal of the cell unit close by the assembly of the printed circuit board and the upper bus bar, as well as It is possible to prevent electrical short circuits by using a short-term protection terminal fitting binding slit on the printed circuit board.

The following drawings attached in this specification are intended to illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the present invention, so the present invention is only described in the accompanying drawings. It should not be interpreted as limited.
1 is an exploded perspective view of a string for a nuclear power supply DC power supply according to the present invention.
FIG. 2 is a perspective view of a string for a DC power supply shown in FIG. 1;
Figure 3 is a combined state of the casing cover and the string casing shown in Figure 1;
4 is a plan view of a power module assembled to a string casing according to the present invention.
5 is a perspective view of a flexible bus bar applied to the present invention.
6 is a perspective view of a power module applied to the present invention.
Fig. 7 is a plan view of Fig. 6;
8 is a cross-sectional view taken along line AA of FIG. 7;
9 is an exploded perspective view of the power module shown in FIG. 6;
FIG. 10 is an exploded perspective view of unit cells constituting a battery pack applied to the power module of FIG. 6.
Figure 11 is an exploded perspective view of the printed circuit board and the upper bus bar applied to the power module of Figure 6;

The present invention will be described in detail below with reference to the embodiments presented in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention and the invention is not limited thereto.

1 to 4, the nuclear power plant DC power supply string 1 includes a string casing 5, a power module 10, a flexible bus bar 30, and a casing cover 6.

The string casing 5 is made of an insulating material and has a power module storage chamber 5a that is opened upward. The insulating material may be, for example, a flame retardant synthetic resin or a composite material. The volume of the power module storage room 5a may increase or decrease depending on the number of installations of the power module 10. In order to securely install the string casing 5 to the rack frame 50, a plurality of coupling keys 5b protruding from the lower surface of the string casing 5 and extending in the width direction may be further formed.

The power supply module 10 is inserted into the power supply module storage chamber 5a and is in close contact with each other to be located inside the string casing 5. In this embodiment, four power modules 10 are provided by adopting a four-series method. The detailed configuration of the power module 10 will be described later.

The flexible bus bar 30 is installed to electrically connect neighboring power modules 10 and 10. The flexible bus bar 30 is flexibly configured to prevent a short circuit during an earthquake. For example, the flexible bus bar 30 may be manufactured by stacking a plurality of thin plates made of copper as shown in FIG. 5.

The casing cover 6 is detachably installed on the upper portion of the string casing 5 to seal the power module storage compartment 5a. The casing cover 6 is an insulating material, for example, a flame retardant synthetic resin may also be made of a composite material.

Here, FRP filler 32 may be further installed to prevent resonance between adjacent power modules 10 and 10 as shown in FIG. 3. In addition, the insulation mold 7 may be formed between the string casing 5 and the power module 10 by being filled with an insulating resin in the power module storage room 5a to increase seismic reliability.

On the other hand, the power supply module 10, as shown in Figures 6 to 9, the module case 12, the battery pack 14, the printed circuit board 16, the wiring guide frame 18 and the battery pack insulation mold 20 Includes.

The module case 12 has a battery pack storage chamber 121 that has a constant width (w), a length (l), and a height (h) and is opened upward. The module case 12 may be made of a hard flame retardant synthetic resin or composite material for insulation.

The battery pack 14 is accommodated in the module case 12 through the battery pack storage room 121.

As shown in FIG. 3, the battery pack 14 is provided with an even number of single cell 141 and is stacked side by side in the width (w) direction of the module case 12. The unit cell 141 is installed such that the cell terminal 141a is positioned upward.

At this time, for the seismic safety of the lithium polymer unit cell 141, between the neighboring lithium polymer unit cell 141 and 141, as shown in FIGS. ) Is preferably composed of adhesive. Here, the unit cell 141 is preferably a 'lithium polymer unit cell' excellent in volume / weight, operating life and discharge characteristics.

The printed circuit board 16 is disposed on the top of the battery pack 14 and is electrically connected to the battery pack 14.

11, the first row lower bus bar 161 and the second row lower bus bar 162 having fastening holes 161a and 162a, respectively, are arranged at positions shifted from each other. In addition, the printed circuit board 16 has a short protection that allows the terminals 141a of the lithium polymer unit cell 141 to be inserted into both sides of the first row lower bus bar 161 and the second row lower bus bar 162, respectively. A combined terminal fitting binding slit 161b is formed. Meanwhile, a first row upper bus bar 163 and a second row upper bus bar 164 are disposed on the first row lower bus bar 161 and the second row lower bus bar 162, respectively.

The first row upper bus bar 163 and the second row upper bus bar 164 are the first row lower bus bar 161 and the second row lower bus through the combination of fastening bolts 167 and nuts (not shown). Each is coupled to a bar 162. At this time, the cell terminals 141a of the unit cell 141 are bent so as to be in close contact between the first and second row upper bus bars 163 and 164 and the first and second row lower bus bars 161 and 162 to make electrical contact.

In this way, the printed circuit board 16 is formed with a short-term protection terminal fitting binding slit 161b to prevent shorts from occurring between unit cells 141 of the battery pack 14.

The wiring guide frame 18 is disposed on the printed circuit board 16. The wiring guide frame 18 has a bus bar opening hole 181 arranged in two rows in the width direction of the module case 12 and a wiring guide groove 182 of a certain depth transverse to the center in the width direction. The wiring guide frame 18 safely guides the electric wiring 11 connected to the output terminal of the power module 10 through the wiring guide groove 182. The wiring guide frame 18 may be made of a hard synthetic resin.

The battery pack insulation mold 20 is formed by charging the battery pack storage chamber 121 with an insulating resin. The battery pack insulation mold 20 fills an empty gap between the periphery of the battery pack 14 and the module case 12. Therefore, the battery pack insulation mold 20 integrates the battery pack 14 and the module case 12 to suppress resonance of the battery pack 14. In addition, the battery pack insulation mold 20 secures insulation by preventing metallic short circuits and blocking leakage of moisture and moisture that may be generated in the unit cell 141.

Meanwhile, an insulating rubber 22 may be further installed between the lower end of the battery pack 14 in the power module 10 and the inner bottom surface of the module case 12 to prevent a short circuit.

The power module 10 configured as described above is provided with a buffer pad 143 capable of absorbing shock between the unit cells 141 and 141, so that even if the power module 10 receives an external shock, the unit cells 141 and 141 ) Can ensure safety.

In addition, the power module 10 is composed of a battery pack 14 and the module case 12 to suppress the resonance of the battery pack 14, and at the same time, the battery pack insulation mold 20 is configured to function as an insulation, resonance It is possible to secure the seismic properties that can be prevented, and it is possible to prevent metallic short circuits and to prevent leakage of moisture and moisture that may be generated in the unit cell 141, thereby ensuring insulation.

In addition, the electrical wiring by the wiring guide frame 18 can be facilitated, and the electrical connection of the cell terminals 141a of the unit cell 141 by assembly of the printed circuit board 16 and the upper bus bars 163,164 is possible. Not only can the contact be carried out in close contact, but also an electrical short can be prevented by the configuration of the short-circuit protection terminal fitting binding slit 161b on the printed circuit board 16.

The present invention has been described in detail with reference to the presented embodiments so far, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such modified and modified inventions, but is limited by the appended claims.

5: string casing
6: Casing cover
12: module case
14: battery pack
141: lithium polymer single cell
143: buffer pad
16: Printed circuit board
161: Row 1 lower bus bar
161b: Short-fit terminal fitting binding slit
162: Second row lower bus bar
163: Row 1 upper bus bar
164: Second row upper bus bar
18: Wiring guide frame
20: battery pack insulation mold
22: insulating rubber
30: flexible bus bar

Claims (8)

A string casing 5 made of an insulating material and having a power module storage compartment 5a opened upward;
A plurality of power modules 10 inserted into the power module storage compartment 5a and positioned in close contact with each other;
A flexible bus bar 30 installed to electrically connect neighboring power modules 10 and 10 and flexibly configured to prevent a short circuit during an earthquake;
A casing cover 6 made of an insulating material and detachably installed on an upper portion of the string casing 5 to seal the power module storage chamber 5a;
An insulating mold 7 filled with an insulating resin in the power module storage compartment 5a and formed between the string casing 5 and the power module 10;
The power supply module 10 includes: a module case 12 having a battery pack storage compartment 121 which has a constant width (w), a length (l), and a height (h) and is opened upward; A battery pack 14 stored in the module case 12 through the battery pack storage room 121; A printed circuit board 16 disposed on the top of the battery pack 14 and electrically connected to the battery pack 14; A busbar opening hole 181 arranged in two rows in the width direction of the module case 12 and a wiring guide groove 182 of a certain depth transverse to the width direction in the center, and an upper portion of the printed circuit board 16 A wiring guide frame 18 which is disposed on and connected to the output terminal of the battery pack 14 to guide electrical wiring through the wiring guide groove 182; The battery pack storage chamber 121 is filled with an insulating resin to fill an empty gap between the periphery of the battery pack 14 and the module case 12, thereby integrating the battery pack 14 and the module case 12 to integrate the battery pack ( 14) includes a battery pack insulation mold 20 to suppress resonance;
The battery pack 14 is provided with an even number of lithium polymer unit cell 141 so that the cell terminal 141a is positioned upward, and stacked side by side in the width (w) direction of the module case 12, lithium polymer For the seismic safety of the unit cell 141, the buffer pad 143 is constructed by bonding the intercell adhesive tape 142 between adjacent lithium polymer unit cell 141 and 141;
A string for a nuclear power plant DC power supply, characterized in that an insulating rubber 22 is further installed between the bottom of the battery pack 14 and the inner bottom surface of the module case 12 to prevent a short circuit. According to claim 1,
A string for a nuclear power plant DC power supply, characterized in that a FRP filler (32) is installed in close contact between adjacent power modules (10 and 10) to prevent resonance. According to claim 1,
Nuclear power DC, characterized in that a plurality of coupling keys 5b protruding from the lower surface of the string casing 5 and extending in the width direction are further formed to securely install the string casing 5 to the rack frame 50. String for power supply. delete delete delete delete According to claim 1,
In the printed circuit board 16, the first row lower bus bar 161 and the second row lower bus bar 162 having fastening holes 161a and 162a, respectively, are arranged at positions deviated from each other, and the first row lower bus Short protection combined terminal fitting binding slits 161b are formed on both sides of the bar 161 and the second row lower bus bar 162 so that the terminals 141a of the lithium polymer single cell 141 are inserted;
The first row upper bus bar 163 and the second row upper bus bar 164 are disposed on the first row lower bus bar 161 and the second row lower bus bar 162, respectively;
The first row upper bus bar 163 and the second row upper bus bar 164 are respectively coupled to the first row lower bus bar 161 and the second row lower bus bar 162 through a combination of fastening bolts and nuts. Combined;
The cell terminal 141a of the unit cell 141 is bent so that the first and second rows of upper bus bars 163 and 164 and the first and second rows of lower bus bars 161 and 162 are in electrical contact with each other. Characterized by a nuclear power plant DC power supply string.

Images