KR102159145B1 - Busbar of Ultra Capacitor Module and Ultra Capacitor Module - Google Patents

Abstract

The present invention relates to a first electrode connecting member 31 to be connected to the first bear cell 2a, a second electrode connecting member 32 to be connected to the second bear cell 2b, and the first bear cell ( 2a) and an ultra capacitor including a connecting member 33 to be connected to each of the first electrode connecting member 31 and the second electrode connecting member 32 to electrically connect the second bear cell 2b It relates to a module busbar and an ultra capacitor module.

Description

Busbar of Ultra Capacitor Module and Ultra Capacitor Module}

The present invention relates to an ultra capacitor module for storing electrical energy.

An ultra capacitor is an energy storage device that has intermediate characteristics between an electrolytic capacitor and a secondary battery, and is also called a super capacitor.

These ultracapacitors have high efficiency, semi-permanent life, and fast charge/discharge characteristics, forming a market as an energy storage device that can compensate for the short cycle and instantaneous high voltage problems, which are weaknesses of secondary batteries.

Based on these advantages, ultracapacitors are used not only as auxiliary power supplies for mobile devices such as mobile phones, tablet PCs, notebook computers, etc., but also electric vehicles, hybrid vehicles, solar cell power supplies, night road lights, and uninterruptible power supplies. (UPS, Uninterrupted Power Supply) is widely used as main power or auxiliary power.

Ultra capacitor modules are configured by connecting a plurality of these ultra capacitors as a unit cell in series or parallel.

1 is a perspective view of an ultra capacitor module according to the prior art, and FIG. 2 is an exploded view of an ultra capacitor in the ultra capacitor module according to the prior art.

1 and 2, the ultracapacitor module 100 according to the prior art includes a plurality of ultracapacitors 110, and a plurality of busbars 120 electrically connecting the ultracapacitors 110 to each other. And a module case 130 for accommodating the ultracapacitors 110 electrically connected by the busbars 120.

As shown in FIG. 2, the ultracapacitor 110 includes an aluminum current collector coated with activated carbon and a bare cell 111 in which a separator is wound in a circle, and the bare cell 111 A first inner terminal 112 coupled to one side, a first outer terminal 113 coupled to the first inner terminal 112, a second inner terminal 114 coupled to the other side of the bare cell 111, A second external terminal 115 coupled to the second internal terminal 114 and a cell case 116 accommodating the bare cell 111 are included.

The first external terminal 113 is connected to the positive electrode (+) of the bare cell 111 through the first internal terminal 112. The second external terminal 115 is connected to the negative electrode (-) of the bare cell 111 through the second internal terminal 114.

The bus bar 120 is formed in a square plate shape. When the busbar 120 connects the ultracapacitors 110 in series, one side is connected to the first outward terminal 113 provided in one ultracapacitor 110, thereby connecting the first inward terminal 112. It is connected to the anode of the bare cell 111 through. The other side of the busbar 120 is connected to the second external terminal 115 provided in the other ultra capacitor 110 and connected to the negative electrode of the bare cell 111 through the second internal terminal 114.

In this way, the busbars 120 pass through the first external terminal 113, the first internal terminal 112, the second external terminal 115, and the second internal terminal 114, and the bare cell By being connected to the (111), the ultracapacitors 110 are electrically connected to each other.

Therefore, the ultra-capacitor module 100 according to the prior art requires many connecting means to electrically connect the ultra-capacitors 110 to each other, so there is a problem in that it is difficult to implement a high-capacity module due to an increase in contact resistance. have. In addition, in the ultracapacitor module 100 according to the prior art, there is a risk of occurrence of an accident such as ignition or explosion due to heat generated as the contact resistance increases, and energy efficiency of the entire module is deteriorated.

The present invention has been conceived to solve the above-described problems, and is to provide a busbar for an ultra capacitor module and an ultra capacitor module capable of reducing the number of connection means required to electrically connect the ultra capacitors to each other.

In order to achieve the above-described problems, the present invention may include the following configuration.

The busbar for an ultracapacitor module according to the present invention comprises: a first electrode connecting member 31 for connecting to the first bare cell 2a; A second electrode connecting member 32 to be connected to the second bare cell 2b; And the first electrode connecting member 31 and the second electrode connecting member 32 to electrically connect the first and second bear cells 2a and 2b. An electrode connecting member 31 and a connecting member 33 integrally formed with the second electrode connecting member 32 may be included. The first electrode connection member 31 includes a first electrolyte solution passage hole 311 for passing the electrolyte solution impregnated in the first bare cell 2a, and the second electrode connection member 32 includes the second electrode connection member 32. 2 It may include a second electrolyte passage hole 321 for passing the electrolyte impregnated in the bare cell (2b).

The ultra-capacitor module according to the present invention includes a module case 4 having a plurality of receiving portions 41; A first bearing cell (2a) inserted into the first receiving part (41a) among the receiving parts (41) and accommodated in the module case (4); A second bearing cell (2b) inserted into the second receiving portion (41b) among the receiving portions (41) and accommodated in the module case (4); And a bus bar 3 for electrically connecting the first and second bearing cells 2a and 2b. The bus bar 3 includes a first electrode connecting member 31 connected to the first bare cell 2a, a second electrode connecting member 32 connected to the second bare cell 2b, and the first electrode. And a connection member 33 integrally formed with the first electrode connection member 31 and the second electrode connection member 32 so as to be connected to each of the connection member 31 and the second electrode connection member 32 can do.

The ultra-capacitor module according to the present invention includes a module case 4 having a plurality of receiving portions 41; A plurality of bare cells inserted into each of the receiving portions 41 and accommodated in the module case 4; And it may include a plurality of busbars 3 for electrically connecting the bare cells to each other. Each of the busbars 3 may be directly connected to the bare cells to electrically connect the bare cells to each other.

According to the present invention, the following effects can be achieved.

The present invention is implemented to reduce the contact resistance generated in the process of electrically connecting bare cells to each other, thereby improving the resistance characteristics as well as reducing the risk of accidents such as ignition or explosion caused by heat, thereby improving safety. And improve the energy efficiency of the entire module.

The present invention is implemented so that the busbar is connected to the bare cells, thereby reducing manufacturing cost and shortening the process time for electrically connecting the bare cells to each other, thereby improving productivity.

1 is a perspective view of an ultra capacitor module according to the prior art
2 is an exploded view of an ultra capacitor in an ultra capacitor module according to the prior art
3 is a schematic combined perspective view of an ultra capacitor module according to the present invention
4 is a schematic exploded perspective view of an ultra capacitor module according to the present invention
5 is a conceptual diagram for explaining a bare cell in the ultra capacitor module according to the present invention
6 is a schematic perspective view of a busbar connected to bare cells in the ultra capacitor module according to the present invention
7 is a schematic perspective view for explaining an embodiment in which bare cells are connected in series in the ultracapacitor module according to the present invention
8 is a schematic perspective view illustrating an embodiment in which bare cells are connected in parallel in the ultra capacitor module according to the present invention
9 is a partially cutaway perspective view showing an ultracapacitor module according to the present invention
10 is a cross-sectional view showing a module case taken along line II of FIG. 4 in the ultracapacitor module according to the present invention.
11 is a cross-sectional view taken along line II-II of FIG. 4 for explaining an embodiment in which bare cells are connected in series in the ultracapacitor module according to the present invention.
12 is a cross-sectional view taken along line II-II of FIG. 4 for explaining an embodiment in which bare cells are connected in parallel in the ultracapacitor module according to the present invention;
13 is an enlarged cross-sectional view of a part of FIG. 10
14 is a schematic exploded side view of an ultra capacitor module according to the present invention
15 is a schematic cross-sectional view for explaining an exhaust member in the ultra capacitor module according to the present invention
16 is a cross-sectional view showing an enlarged portion III of FIG. 14 in the ultracapacitor module according to the present invention
17 is a cross-sectional view showing an enlarged portion IV of FIG. 14 in the ultracapacitor module according to the present invention

Hereinafter, an embodiment of an ultracapacitor module according to the present invention will be described in detail with reference to the accompanying drawings. Since the busbar for the ultracapacitor module according to the present invention may be included in the ultracapacitor module according to the present invention, an embodiment of the ultracapacitor module according to the present invention will be described together.

3 and 4, the ultracapacitor module 1 according to the present invention includes a plurality of bare cells 2, a busbar 3 for electrically connecting the bare cells 2 to each other, and It includes a module case 4 for accommodating the bare cells 2. The busbar 3 is implemented to be directly connected to the bare cells 2 to electrically connect the bare cells 2 to each other. Accordingly, the ultracapacitor module 1 according to the present invention can achieve the following operational effects.

First, as shown in FIGS. 1 and 2, in the ultracapacitor module 100 according to the prior art, the busbars 120 are provided with a first external terminal 113, a first internal terminal 112, and a second external terminal. As the bare cells 111 are connected via the 115 and the second inner terminal 114, there is a problem in that the contact resistance generated in the process of electrically connecting the bare cells 111 to each other increases.

In contrast, in the ultracapacitor module 1 according to the present invention, as shown in FIGS. 3 and 4, the busbar 3 is directly connected to the bare cells 2 to connect the bare cells 2 Is implemented to Accordingly, the ultracapacitor module 1 according to the present invention can improve resistance characteristics by reducing contact resistance generated in a process in which the bare cells 2 are electrically connected to each other, as compared with the prior art. In addition, the ultracapacitor module 1 according to the present invention can improve safety by reducing the risk of occurrence of an accident such as fire or explosion due to heat due to a decrease in contact resistance, and improve energy efficiency of the entire module.

Second, in the ultracapacitor module 1 according to the present invention, since the bus bar 3 is directly connected to the bare cells 2, the conventional method for connecting the bus bars 120 to the bare cells 111 The first external terminal 113, the first internal terminal 112, the second external terminal 115, and the second internal terminal 114 may be omitted. Accordingly, the ultracapacitor module 1 according to the present invention not only reduces manufacturing cost, but also shortens the process time for electrically connecting the bare cells 2 to each other, thereby improving productivity.

Hereinafter, the bare cell 2, the bus bar 3, and the module case 4 will be described in detail with reference to the accompanying drawings.

3 to 5, the bare cell 2 is accommodated in the module case 4. The bare cell 2 is called an electrode element, and as shown in FIG. 5, a first electrode 21, a second electrode 22 having a polarity opposite to that of the first electrode 21, and the second electrode 22 A separator 23 disposed between the first electrode 21 and the second electrode 22 and electrically separating the first electrode 21 and the second electrode 2@ may be wound and formed. have. In one embodiment, when the first electrode 21 is an anode (+), the second electrode 22 becomes a cathode (-). Conversely, when the first electrode 21 is a cathode (-), the second electrode 22 becomes an anode (+).

5 illustrates that the separator 23 is positioned only between the first electrode 21 and the second electrode 22, the first electrode 21 or the second electrode 22 The separator 23 may be additionally disposed outside the first electrode 21 and the second electrode 22 in order to prevent exposure. For example, the bare cell 2 may be arranged and wound in the order of the separator 23, the first electrode 21, the separator 23, the second electrode 22, and the separator 23. The bare cell 2 may be arranged and wound in the order of the separator 23, the second electrode 22, the separator 23, the first electrode 21, and the separator 23.

The first electrode 21 is a first active material layer 211 formed using activated carbon on a current collector (not shown) made of a metal material, and one side of the first active material layer 211 It may include a first electrode lead 212 connected to. In this case, the first electrode lead 212 is formed of a region in the current collector in which the first active material layer 211 is not formed.

The second electrode 22 includes a second active material layer 221 formed using activated carbon on a metal current collector (not shown), and a second active material layer 221 connected to one side of the second active material layer 221. It may include an electrode lead 222. In this case, the second electrode lead 222 is formed of a region in the current collector in which the second active material layer 221 is not formed.

In the above-described embodiment, the current collector constituting the first electrode 21 and the second electrode 22 may be formed using a metal foil. The current collector serves as a passage for electric charges discharged or supplied from the first active material layer 211 and the second active material layer 221. The first active material layer 211 and the second active material layer 221 may be formed by being coated on both surfaces of the current collector. The first active material layer 211 and the second active material layer 221 are portions in which electric energy is stored.

In one embodiment, in the first electrode 21 and the second electrode 22, the first electrode lead 212 is positioned under the bare cell 2, and the second electrode lead ( 222 may be wound so as to be positioned above the bare cell 2.

Meanwhile, the bare cell 2 is impregnated with an electrolyte for charging electric energy. In this case, the process of impregnating the bare cell 2 with the electrolyte may be performed by immersing the bare cell 2 in a container filled with the electrolyte for a predetermined time.

3 to 6, the bus bar 3 electrically connects the bare cells 2 to each other. The bus bar 3 is directly connected to the bare cells 2 to electrically connect the bare cells 2 to each other. Accordingly, the ultracapacitor module 1 according to the present invention has an advantage of improving resistance characteristics, safety and energy efficiency of the entire module by reducing contact resistance.

The bus bar 3 may include a first electrode connection member 31, a second electrode connection member 32, and a connection member 33.

The first electrode connecting member 31 is connected to the first bare cell 2a among the bare cells 2. The first electrode connecting member 31 may be coupled to the first bare cell 2a through laser or ultrasonic welding while being connected to the first bare cell 2a. The first electrode connecting member 31 may be directly connected to the first electrode 21 of the first bare cell 2a. In this case, the first electrode 21 of the first bare cell 2a is wound so as to protrude toward one side of the first bare cell 2a, and the first electrode connecting member 31 is In (2a), the first electrode 21 is connected to the protruding side, so that the first electrode 21 may be directly connected. The first electrode connecting member 31 may be connected to the first electrode lead 212 of the first electrode 21.

The second electrode connecting member 32 is connected to the second bare cell 2b among the bare cells 2. The second bare cell 2b is located adjacent to the first bare cell 2a among the bare cells 2 accommodated in the module case 4. The second electrode connecting member 32 may be coupled to the second bear cell 2b through laser or ultrasonic welding while being connected to the second bear cell 2b. When the bus bar 3 connects the first and second bear cells 2a and 2b in series, the second electrode connecting member 32 is formed of the second bare cell 2b. It may be directly connected to the second electrode 22. In this case, the second electrode 22 of the second bear cell 2b is wound so as to protrude toward one side of the second bear cell 2b, and the second electrode connecting member 32 is In (2b), the second electrode 22 may be directly connected to the second electrode 22 by being connected to the protruding side. The second electrode connecting member 32 may be connected to the second electrode lead 222 of the second electrode 22.

On the other hand, when the bus bar 3 connects the first and second bare cells 2a and 2b in parallel, the second electrode connecting member 32 is formed of the second bare cell 2b. ) May be directly connected to the first electrode 21. In this case, the first electrode 21 of the second bear cell 2b is wound to protrude toward one side of the second bear cell 2b, and the second electrode connecting member 32 is In (2b), the first electrode 21 is connected to the protruding side, so that the first electrode 21 may be directly connected. The second electrode connecting member 32 may be connected to the first electrode lead 212 of the first electrode 21.

The connection member 33 is formed to be connected to each of the first electrode connection member 31 and the second electrode connection member 32. Accordingly, the first bear cell 2a directly connected to the first electrode connecting member 31 and the second bear cell 2b directly connected to the second electrode connecting member 32 are the connecting member ( 33) are electrically connected to each other. The connection member 33 may be integrally formed with the first electrode connection member 31 and the second electrode connection member 32. Accordingly, the ultracapacitor module 1 according to the present invention connects the first electrode connecting member 31 to the first bear cell 2a, and the second electrode connecting member 31 to the second bear cell 2b. As an operation of connecting 32), an operation of electrically connecting the first and second bearing cells 2a and 2b to each other may be performed. Accordingly, the ultracapacitor module 1 according to the present invention can shorten the time taken for an operation of electrically connecting the bare cells 2 to each other, thereby improving productivity.

The connection member 33 may be formed in a rectangular plate shape as a whole, but is not limited thereto, and if it is formed to be connected to each of the first electrode connection member 31 and the second electrode connection member 32, other It can also be formed in a shape.

Here, the first electrode connection member 31 may be formed to have a larger size than the connection member 33. The first electrode connecting member 31 may be formed in a shape corresponding to a side from which the first electrode 21 protrudes from the first bare cell 2a. For example, when the first bearing cell 2a is wound to form a circular column shape, the first electrode connecting member 31 may be formed in a disk shape. Accordingly, the ultracapacitor module 1 according to the present invention may further reduce contact resistance by increasing a connection area between the first electrode connecting member 31 and the first bare cell 2a.

The first electrode connecting member 31 may include a first electrolyte solution passage hole 311 for passing the electrolyte solution immersed in the first bare cell 2a. Accordingly, while the first electrode connecting member 31 is connected to the first bare cell 2a, a process of impregnating the first bare cell 2a with an electrolyte may be performed. A plurality of first electrolyte passage holes 311 may be formed in the first electrode connecting member 31. In this case, the first electrolyte passage holes 311 may be formed at positions spaced apart from each other.

The second electrode connecting member 32 may be formed to have a larger size than the connecting member 33. The second electrode connecting member 32 may be formed in a shape corresponding to a side from which the first electrode 21 or the second electrode 22 protrudes from the second bare cell 2b. For example, when the second bearing cell 2b is wound in a circular column shape, the second electrode connecting member 32 may be formed in a circular plate shape. Accordingly, the ultracapacitor module 1 according to the present invention may further reduce contact resistance by increasing a connection area between the second electrode connecting member 32 and the second bare cell 2b. The second electrode connecting member 32 may be formed in a shape corresponding to the first electrode connecting member 31. In this case, the bus bar 3 may be formed in a plate shape forming a dog bone shape.

The second electrode connection member 32 may include a second electrolyte solution passage hole 321 for passing the electrolyte solution immersed in the second bare cell 2b. Accordingly, while the second electrode connecting member 32 is connected to the second bear cell 2b, a process of impregnating the second bear cell 2b with an electrolyte may be performed. A plurality of second electrolyte passage holes 321 may be formed in the second electrode connecting member 32. In this case, the second electrolyte passage holes 321 may be formed at positions spaced apart from each other.

3 to 8, the ultracapacitor module 1 according to the present invention may include a plurality of bus bars 3.

When the bare cells 2 are connected in series, the module case 4 (shown in FIG. 3) has a first electrode 21 (shown in FIG. 5) in one direction (A The order of the second bearing cells 2b arranged so that the first and second electrodes 22 (shown in FIG. 5) and the first and second electrodes 22 (shown in FIG. 5) face the direction of the arrow (arrow direction). Alternately, the bare cells 2a and 2b may be accommodated. In this case, the first bus bar 3a disposed in the one direction (arrow A direction) and the second bus bar 3b disposed in the other direction (arrow B direction) based on the bare cells 2a and 2b ) Alternately in order, the busbars 3a and 3b may be disposed along a direction in which the bare cells 2a and 2b are disposed (in the direction of arrow C). The other direction (arrow B direction) is a direction opposite to the one direction (arrow A direction). Each of the busbars 3a and 3b may connect two bare cells 2a and 2b in series.

When the bare cells 2 are connected in parallel, the module case 4 (shown in FIG. 3) has the first electrode 21 (shown in FIG. 5) in one direction (A The bare cells 2 may be accommodated in the direction of the arrow). In this case, a first booth bar 3a disposed in the one direction (arrow A direction) with respect to the bare cells 2, and a second bus bar 3b disposed in the other direction (arrow B direction) May be provided. The first bus bar 3a may connect the first electrodes 21 (shown in FIG. 5) of the bare cells 2 in parallel. The second busbar 3b may connect the second electrodes 22 (shown in FIG. 5) of the bare cells 2 in parallel. In this case, each of the bus bars 3a and 3b may include a plurality of electrode connecting members. In FIG. 8, the busbars 3a and 3b are shown to include three electrode connection members, but the present invention is not limited thereto, and the busbars 3a and 3b are each connected in parallel with a bare cell 2 It may include a corresponding number of electrode connection members of the number of. The electrode connecting members are connected to each other by the connecting members.

3 to 10, the module case 4 accommodates the bare cells 2. The module case 4 includes a plurality of receiving portions 41 for accommodating the bare cells 2. The bare cells 2 are accommodated in the module case 4 to be physically and electrically separated from each other by being inserted into each of the receiving portions 41. Accordingly, since the ultracapacitor module 1 according to the present invention can omit the cell case 116 (shown in FIG. 2) in the prior art, manufacturing cost can be reduced. In addition, since the ultracapacitor module 1 according to the present invention can omit the process of coupling the cell case 116 (shown in FIG. 2) to the bare cell 2, productivity can be improved.

For example, the module case 4 may include a first receiving portion 41a in which the first bare cell 2a is accommodated, and a second receiving portion 41b in which the second bearing cell 2b is accommodated. I can. The first bearing cell (2a) is inserted into the first receiving portion (41a) and accommodated in the module case (4), and the second bearing cell (2b) is inserted into the second receiving portion (41b) It may be accommodated in the module case 4. In this way, the first and second bearing cells 2a and 2b are inserted into different receiving portions 41a and 41b, so that they are stored in the module case 4 so that they are physically and electrically separated from each other. Can be. In this state, by connecting the bus bar 3 to the first and second bearing cells 2a and 2b, the first and second bear cells 2a and 2b are They can be electrically connected to each other.

The module case 4 may be formed of an insulating material. Each of the receiving portions 41 may be formed in a shape and size corresponding to the bare cells 2. In FIG. 10, it is shown that the module case 4 has six accommodating parts 41 formed therein, but the present invention is not limited thereto, and the module case 4 includes 2 or more but less than 5 or 7 or more accommodating parts 41 ) May be formed. It is preferable that the module case 4 has an even number of the receiving portions 41. When the module case 4 has an even number of the receiving portions 41, the two bare cells 2 connected to an external device among the bare cells 2 have electrodes of different polarities in the other direction. It may be accommodated in the module case 4 to face (in the direction of arrow B). For example, when one bare cell 2 connected to the external device is accommodated in the module case 4 so that the first electrode 21 faces the other direction (arrow B), it is connected to the external device. The other bare cell 2 may be accommodated in the module case 4 so that the second electrode 22 faces the other side (direction of arrow B). Accordingly, in the ultracapacitor module 1 according to the present invention, when the bare cells 2 are connected in series, the wiring is drawn in the same direction for the two bare cells 2 connected to the external device. It is implemented so that it can be connected to external devices. Accordingly, the ultracapacitor module 1 according to the present invention can improve ease of operation for connecting the bare cells 2 with external devices.

9 to 12, the module case 4 may include an insertion groove 42 into which the bus bar 3 is inserted.

The connecting member 33 of the bus bar 3 is inserted into the insertion groove 42. Accordingly, even if the busbar 3 is connected to the bare cells 2 inserted into the different receiving portions 41, the module 33 is inserted into the insertion groove 41 It does not protrude to the outside of the case 4. The insertion groove 42 may be formed in a shape and size corresponding to the connection member 33.

When the bare cells 2 are connected in series, as shown in FIG. 11, the module case 4 is disposed in the one direction (arrow A direction) with respect to the bare cells 2a and 2b. The first bus bar (3a) and the second bus bar (3b) disposed in the other direction (direction of arrow B) are alternately arranged, so that the bus bars (3a, 3b) are It may be arranged along the arranged direction (C arrow direction). In this case, the module case 4 has a first insertion groove 42a formed in the one direction (arrow A direction) and the other direction (arrow B direction) with respect to the bare cells 2a and 2b. The insertion grooves 42a and 42b may be formed along a direction (arrow C) in which the bare cells 2a and 2b are arranged alternately in the order of the second insertion grooves 42b.

When the bare cells 2 are connected in parallel, as shown in FIG. 12, the module case 4 includes a first electrode disposed in the one direction (arrow A direction) with respect to the bare cells 2 A bus bar 3a and a second bus bar 3b disposed in the other direction (direction of arrow B) may be provided. In this case, a plurality of first inserts into which the connecting members 33 of the first busbars 3a are inserted in the one direction (in the direction of arrow A) based on the bare cells 2 in the module case 4 A groove 42a and a plurality of second insertion grooves 42b into which the connecting members 33 of the second busbars 3b are inserted may be formed in the other direction (direction of arrow B).

9 to 13, the module case 4 includes a plurality of inner partition walls 43 (shown in FIG. 13) on which the receiving portion 41 is formed, and an outer portion located outside the inner partition wall 43. It may include a partition wall 44 (shown in FIG. 13), and a plurality of coupling members 45 (shown in FIG. 13) that couple the inner partition walls 43 to the outer partition wall 44.

Each of the inner partition walls 43 accommodates the bare cell 2 (shown in FIG. 9). Each of the bare cells 2 is inserted into the receiving portions 41 formed in the inner partition walls 43 and is accommodated in the inner partition walls 43. Accordingly, the internal partition walls 43 may physically and electrically separate the bare cells 2 from each other. In addition, the internal partition walls 43 may physically and electrically separate the electrolyte impregnated into each of the bare cells 2 from each other.

The outer partition walls 44 are located outside the inner partition walls 43. That is, the inner partition walls 43 are located inside the outer partition walls 44. The external partition wall 44 includes a partition hole 441 through which the inner partition walls 43 are located. The partition wall hole 441 may be formed through the outer partition wall 44.

The coupling members 45 couple the inner partition walls 43 to the outer partition wall 44 so that the inner partition walls 43 are located inside the outer partition wall 44. The coupling members 45 couple the inner partition walls 43 to the outer partition wall 44 so that each of the inner partition walls 43 are spaced apart from the inner surface of the outer partition wall 44. Accordingly, the module case 4 is implemented in a double partition wall structure. Therefore, the ultracapacitor module 1 according to the present invention can achieve the following operational effects.

First, in the ultracapacitor module 1 according to the present invention, the module case 4 is implemented in a double partition structure, so that the space between the inner partition walls 43 and the outer partition wall 44 functions as a buffer space. I can. Accordingly, in the ultracapacitor module 1 according to the present invention, even if the internal pressure increases due to the internal gas generated when the bare cells 2 are driven, the internal partition walls 43 and the external partition walls 44 It can prevent deformation or damage. Therefore, the ultracapacitor module 1 according to the present invention can increase the operation rate by increasing the period for maintenance through improved durability.

Second, in the ultracapacitor module 1 according to the present invention, the module case 4 is implemented in a double partition structure, so that the space between the inner partition walls 43 and the outer partition wall 44 functions as an insulating space. I can. Accordingly, the ultracapacitor module 1 according to the present invention reduces the lifetime of the bare cells 2 due to internal heat generated when the bare cells 2 are driven and external heat generated in the surrounding environment. Can be prevented. Accordingly, the ultracapacitor module 1 according to the present invention can extend the service life of the bare cells 2.

The coupling members 45 may couple the inner partition walls 43 to the outer partition walls 44 so that the inner partition walls 43 are located at a position spaced apart from each other by a predetermined distance. The coupling members 45 are coupled to be spaced apart from each other along the outer circumferential surfaces of the inner partition walls 43, thereby increasing the size of the buffer space and the space functioning as the heat insulation space.

13 to 16, the ultracapacitor module 1 according to the present invention may include an exhaust member 5 for discharging gas.

The exhaust member 5 is for discharging gas from the receiving portion 41. When the internal pressure of the internal partition 43 increases by gas generated during the driving of the bare cells 2, the exhaust member 5 reduces the gas present in the internal partition 43 to the internal It can be discharged to the outside of the partition (43).

To this end, the module case 4 includes an exhaust hole 46 (shown in FIG. 15). The exhaust hole 46 is formed through the inner partition wall 43 so that the receiving portion 41 and the exhaust member 5 communicate with each other. The exhaust member 5 is connected in communication with each of the partition hole 441 (shown in FIG. 13) and the receiving part 41 positioned between the inner partition walls 43, so that the inner partition wall 43 The gas present in the interior may be discharged to the external partition 44. Accordingly, in the ultracapacitor module 1 according to the present invention, even if the internal pressure increases due to the internal gas generated when the bare cells 2 are driven, the internal partition walls 43 and the external partition walls 44 It can prevent deformation or damage.

As shown in FIG. 15, the exhaust member 5 includes an exhaust body 51 coupled to the inner partition wall 43, a discharge hole 52 formed through the exhaust body 51, and the exhaust body It may include an opening and closing member 53 that is movably coupled to the inside of 51, and an elastic member 54 that provides an elastic force to the opening and closing member 53.

The exhaust body 51 is coupled to the inner partition wall 43 so as to communicate with the exhaust hole 46. The ship body 51 may be coupled to the inner partition wall 43 to be positioned in the partition hole 441 (shown in FIG. 13) positioned between the inner partition walls 43.

The discharge hole 52 is formed through the exhaust body 51, so that one end communicates with the receiving part 41 through the exhaust hole 46 and the other end is between the inner partition walls 43. It may communicate with the located partition hole 441 (shown in FIG. 13).

The opening and closing member 53 is coupled to the inside of the ship body 51 so as to be located in the discharge hole 52. The opening/closing member 53 may be moved according to the internal pressure of the receiving portion 41 transmitted through the exhaust hole 46.

One side of the elastic member 54 is supported inside the ship body 51, and the other side of the elastic member 54 supports the opening/closing member 53. The elastic member 54 provides an elastic force to the opening/closing member 53 so that the opening/closing member 53 is located between one end and the other end of the discharge hole 52. Accordingly, when the internal pressure of the receiving portion 41 is smaller than the elastic force of the elastic member 54, the opening and closing member 53 is located between one end and the other end of the discharge hole 52 to exhaust the The ball 46 and the discharge hole 52 are blocked so as not to communicate with each other. In this state, when the opening/closing member 53 is pushed against the internal pressure of the accommodation part 41 as the internal pressure of the accommodation part 41 increases, the elastic member 54 moves the opening/closing member 53 Is tensioned according to. When the opening/closing member 53 moves to the other end of the discharge hole 52, the discharge hole 52 and the exhaust hole 46 communicate with each other, so that gas is discharged from the receiving part 41. When the internal pressure of the receiving part 41 decreases as the gas is discharged from the receiving part 41, the opening/closing member 53 becomes the discharge hole 52 as the elastic member 54 is compressed by a restoring force. ) To be located between one end and the other end. Accordingly, the opening and closing member 53 blocks the exhaust hole 46 and the exhaust hole 52 from communicating with each other.

As described above, the exhaust member 5 is implemented so that gas is automatically discharged from the receiving unit 41 according to the internal pressure of the receiving unit 41, thereby providing airtightness to the bare cells 2 At the same time, it is possible to prevent the module case 4 from being deformed or damaged due to gas generated when the bare cells 2 are driven.

13 to 16, the ultracapacitor module 1 according to the present invention may include a plurality of the exhaust members 5.

The exhaust members 5 may be coupled to each of the inner partition walls 43 so as to discharge gas from each of the receiving portions 41 of the module case 4. The ultracapacitor module 1 according to the present invention may include the same number of exhaust members 5 as the number of the internal partition walls 43. The ultracapacitor module 1 according to the present invention may include a larger number of exhaust members 5 than the number of the internal partition walls 43. In this case, a plurality of the exhaust members 5 may be coupled to one inner partition wall 43.

Two of the exhaust members 5 may be arranged to face each other in a pair. For example, as shown in FIG. 16, a first exhaust member 5a for discharging gas from the first receiving part 41a, and a second exhaust member for discharging gas from the second receiving part 41b (5b) can be arranged to face each other.

In this case, the first exhaust member 5a may be coupled to the first inner partition wall 43a so as to communicate with the first exhaust hole 46a formed through the first inner partition wall 43a. Accordingly, the first exhaust member 5a may automatically discharge gas from the first receiving part 41a according to the internal pressure of the first receiving part 41a.

The second exhaust member 5b may be coupled to the second inner partition wall 43b so as to communicate with the second exhaust hole 46b formed through the second inner partition wall 43b. Accordingly, the first exhaust member 5a may automatically discharge gas from the first receiving part 41a according to the internal pressure of the first receiving part 41a.

The second exhaust member 5b and the first exhaust member 5a may be disposed to face each other between the first inner partition wall 43a and the second inner partition wall 43b. Accordingly, the gas discharged by the second exhaust member 5b and the first exhaust member 5a is discharged between the first inner partition wall 43a and the second inner partition wall 43b. 16, the second exhaust member 5b and the first exhaust member 5a are on the busbar 3 disposed in the one direction (arrow A direction) with respect to the bare cells 2a and 2b. Although shown to be installed in an adjacent position, the second exhaust member 5b and the first exhaust member 5a are spaced apart from the booth 3 in the other direction (arrow B direction). It can also be installed on site.

Referring to FIGS. 6 and 13 to 17, the ultracapacitor module 1 according to the present invention may include a harness 6 for adjusting voltage deviation between the bare cells 2.

Since the harness 6 is connected to the bus bar 3, a voltage deviation between the bare cells 2 connected to the bus bar 3 can be adjusted. One side of the harness 6 may be connected to the bus bar 3 and the other side may be connected to a balancing unit (not shown). The balancing unit is for adjusting a voltage deviation between the bare cells 2 and may be installed outside the module case 4. When the ultracapacitor module 1 according to the present invention includes a plurality of harnesses 6, the harnesses 6 may be connected to the balancing unit after the other ends are connected to each other.

Here, the busbar 3 may include a connection hole 331 (shown in FIG. 6) into which the harness 6 is inserted. The connection hole 331 may be formed through the connection member 33 of the bus bar 3. The harness 6 is inserted into the connection hole 331 and connected to the busbar 3, thereby being electrically connected to the bare cells 3 connected to the busbar 3. Accordingly, the ultracapacitor module 1 according to the present invention can not only improve the ease of work of electrically connecting the harness 6 to the bare cells 3, but also the harness 6 It is possible to shorten the time it takes to electrically connect the bare cells (3). The harness 6 may be coupled to the busbar 3 through laser or ultrasonic welding while being inserted into the connection hole 331.

When the busbars 3 are divided and arranged in the one direction (arrow A direction) and the other direction (arrow B direction) based on the bare cells 2, the harness 6 is Can be connected to cells (2).

First, as shown in FIG. 16, when the harness 6 is connected to the busbar 3 disposed in the one direction (arrow A direction) with respect to the bare cells 2a and 2b, the harness One side of (6) is inserted into the connection hole 331 of the bus bar 3 and is connected to the bus bar 3. Accordingly, the harness 6 is provided with the first and second bearing cells 2a and 32 through the first electrode connecting member 31 and the second electrode connecting member 32 of the busbar 3. It is electrically connected to (2b). The harness 6 is formed to extend from one side inserted into the connection hole 331 in the direction of the other side (in the direction of arrow B) so that the other side protrudes outward of the outer partition wall 44 (shown in FIG. 14). The harness 6 may be inserted into the connection hole 331 between the first inner partition wall 43a and the second inner partition wall 43b. In this case, the harness 6 includes a first exhaust member 5a for discharging gas from the first receiving part 41a, and a second exhaust member for discharging gas from the second receiving part 41b (5b) may be inserted into the connection hole 331 so as to be positioned between. Accordingly, the first exhaust member 5a and the second exhaust member 5b may support the harness 6 inserted into the connection hole 331. Therefore, the ultracapacitor module 1 according to the present invention is implemented so that the harness 6 can be firmly maintained while being inserted into the connection hole 331, so that the harness 6 It is possible to prevent separation from the connection hole 331.

Next, as shown in FIG. 17, when the harness 6 is connected to the busbar 3 disposed in the other direction (arrow B direction) with respect to the bare cells 2, the harness 6 One side is inserted into the connection hole 331 of the bus bar 3 and is connected to the bus bar 3. Accordingly, the harness 6 is electrically connected to the bare cells 2 through the first electrode connecting member 31 and the second electrode connecting member 32 of the bus bar 3. The harness 6 is formed to extend from one side inserted into the connection hole 331 in the direction of the other side (in the direction of arrow B) so that the other side protrudes outward of the outer partition wall 44 (shown in FIG. 14).

The harness 6 (hereinafter referred to as'first harness') connected to the bus bar 3 disposed in the one direction (arrow A direction) with respect to the bare cells 2 is the bare cell 2 ) Is formed to have a longer length than the harness 6 (hereinafter referred to as “second harness”) connected to the busbar 3 disposed in the other direction (direction of arrow B). That is, the second harness is formed to have a shorter length than the first harness. When the bare cells 2 are connected in series, the first harness and the second harness are arranged in the module case 4 along the direction in which the bare cells 2a and 2b are arranged (arrow C). Can be arranged alternately. The first harnesses and the second harnesses may be connected to the balancing unit after the other side protrudes to the outside of the module case 4 and is connected to each other. The module case 4 may be provided with a plurality of through holes (not shown) for passing the first harnesses and the second harnesses. The through holes provide a passage function for protruding the first harnesses and the second harnesses to the outside of the module case 4, and the gas discharged into the module case by the exhaust members 5. An exhaust function for discharging to the outside of the module case 4 may be implemented.

3 to 17, the module case 4 may include a first cover member 47 (shown in FIG. 14) and a second cover member 48 (shown in FIG. 14 ).

The first cover member 47 is coupled to the outer partition 44 so as to be positioned in the other direction (direction of arrow B) with respect to the outer partition 44. Accordingly, the first cover member 47 may seal the other side direction (in the direction of arrow B) of the outer partition wall 44.

The first cover member 47 may include a through hole 471 (shown in FIG. 14 ). The through hole 471 is formed through the first cover member 47. Among the bare cells 2 accommodated in the module case 4, a bare cell 2 connected to an external device (not shown) may be connected to the external device through the through hole 471. A connection terminal 7 (shown in FIG. 3) for connection with the external device may be coupled to the bare cell 2. The connection terminal 7 protrudes to the outside of the module case 4 through the through hole 471. The first cover member 47 may include two through holes 471 so that the external device may be connected to the first electrode and the second electrode of the bare cells 2, respectively. In this case, among the bare cells 2 accommodated in the module case 4, two bare cells 2 may be connected to the external device through the through holes 471. For example, as shown in FIG. 3, connection terminals 7 may be coupled to two bare cells 2 located at both ends of the module case 4, respectively.

The second cover member 48 is coupled to the outer partition 44 so as to be positioned in the one direction (in the direction of arrow A) with respect to the outer partition 44. Accordingly, the second cover member 48 may seal one side direction (in the direction of arrow A) of the outer partition wall 44.

After the second cover member 48 and the first cover member 47 are inserted into the receiving portions 41 and connected by the bus bars 3, the outer partition wall Can be combined in (44). Looking at this in detail, it is as follows.

First, the module case 4 is in a state in which the first cover member 47 and the second cover member 48 are not coupled, and the one direction (arrow A) and the other direction (arrow B) Is in an open state.

Next, the bare cells 2 are inserted into each of the receiving portions 41. Accordingly, the bare cells 2 are accommodated in the inner partition walls 43 different from each other.

Next, the busbars 3 are connected to the bare cells 2. The busbars 3 are inserted into the module case 4 through both sides opened from the module case 4 and are then laser or ultrasonically welded to the bare cells 2 so that the bare cell 2 Can be combined in the field. In this case, the bus bars 3 have the first electrode connecting member 31 and the second electrode connecting member 32 connected to different bare cells 2, and the connecting member 33 It can be inserted into the insertion groove (42).

Next, the first cover member 47 and the second cover member 48 are coupled to the outer partition wall 44. The first cover member 47 and the second cover member 48 are coupled to the outer partition wall 44 using at least one of fastening means such as laser or ultrasonic welding, interference fit, and bolts. Can be.

When the ultracapacitor module 1 according to the present invention includes the exhaust members 5, the exhaust members 5 may be used before inserting the bare cells 2 into each of the receiving portions 41 or the After inserting the bare cells 2 into each of the receiving portions 41, it may be installed to be coupled to the inner partition walls 43.

When the ultracapacitor module 1 according to the present invention includes the harnesses 6, the harnesses 6 are connected to the bare cells 2 and then the connection holes ( 331) can be installed by being inserted into each. The harness 6 may be installed by being inserted into each of the connecting holes 331 after the exhaust members 5 are installed. The harnesses 6 may be coupled to the busbars 3 through laser or ultrasonic welding after being inserted into each of the connecting holes 331.

In the ultracapacitor module 1 according to the present invention, the internal partition walls 43 are arranged in one row to implement the module case 4, and accordingly, the bare cells 2 are arranged in one row. Can be implemented. Although not shown, in the ultracapacitor module 1 according to a modified embodiment of the present invention, the internal partition walls 43 are arranged in a matrix to implement the module case 4, and accordingly, the bare cell (2) may be implemented by being arranged in a matrix.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope of the technical spirit of the present invention. It will be obvious to those who have the knowledge of.

1: ultra capacitor module 2: bare cell
3: bus bar 4: module case
5: exhaust member 6: harness
21: first electrode 22: second electrode
23: separator 31: first electrode connecting member
32: second electrode connecting member 33: connecting member
41: receiving portion 42: insertion groove
43: internal bulkhead 44: external bulkhead
45: coupling member 46: exhaust hole
47: first cover member 48: second cover member
51: ship body 52: discharge hole
53: opening and closing member 54: elastic member

Claims (13)

A module case 4 having a plurality of accommodating portions 41;
A first bearing cell (2a) inserted into the first receiving part (41a) among the receiving parts (41) and accommodated in the module case (4);
A second bearing cell (2b) inserted into the second receiving portion (41b) among the receiving portions (41) and accommodated in the module case (4); And
And a bus bar (3) for electrically connecting the first and second bearing cells (2a) and (2b),
The bus bar 3 includes a first electrode connecting member 31 connected to the first bare cell 2a, a second electrode connecting member 32 connected to the second bear cell 2b, and A connection member 33 integrally formed with the first electrode connection member 31 and the second electrode connection member 32 so as to be connected to each of the first electrode connection member 31 and the second electrode connection member 32 Including,
The first electrode connecting member 31 includes a first electrolyte solution passage hole 311 for passing the electrolyte solution impregnated in the first bare cell 2a,
The second electrode connecting member (32) is an ultra capacitor module, characterized in that it comprises a second electrolyte solution passing hole (321) for passing the electrolyte solution impregnated in the second bare cell (2b). The method of claim 1,
The module case 4 includes an insertion groove 42 into which a connecting member 33 of the bus bar 3 connected to each of the first and second bearing cells 2a and 2b is inserted. Ultra capacitor module, characterized in that. The method of claim 1,
And a first exhaust member (5a) for discharging gas from the first receiving portion (41a);
The module case 4 includes the first internal partition wall 43a on which the first receiving part 41a is formed, and the first receiving part 41a and the first exhaust member 5a to communicate with each other. Ultra capacitor module, characterized in that it comprises a first exhaust hole (46a) formed through the inner partition (43a). The method of claim 3, wherein the first exhaust member (5a) is
An exhaust main body 51 coupled to the first inner partition wall 43a to communicate with the first exhaust hole 46a;
A discharge hole 52 formed through the ship body 51;
An opening and closing member 53 movably coupled to the inside of the ship body 51; And
An elastic member 54 that provides an elastic force to the opening and closing member 53 so that the first exhaust hole 46a and the discharge hole 52 are selectively communicated according to the internal pressure of the first receiving part 41a. Ultra capacitor module comprising a. delete The method of claim 1,
The first electrode connection member 31 is formed to have a larger size than the connection member 33, and is formed in a shape corresponding to one side from which the first electrode 21 protrudes from the first bare cell 2a. Become;
The second electrode connection member (32) is formed in a larger size than the connection member (33), and is formed in a shape corresponding to the first electrode connection member (31). The method of claim 1,
It includes a harness (Harness) 6 for adjusting the voltage deviation between the first and second bearing cells (2a) and 2b,
The connection member (33) is an ultra capacitor module, characterized in that it comprises a connection hole (331) into which the harness (6) is inserted. The method of claim 7,
A first exhaust member (5a) for discharging gas from the first receiving part (41a), and a second exhaust member (5b) for discharging gas from the second receiving part (41b);
The harness 6 is inserted into the connection hole 331 so as to be positioned between the first exhaust member 5a and the second exhaust member 5b;
The first exhaust member (5a) and the second exhaust member (5b) support the harness (6) inserted into the connection hole (331). A module case 4 having a plurality of accommodating portions 41;
A plurality of bare cells (2) inserted into each of the receiving portions (41) and accommodated in the module case (4); And
It includes a plurality of busbars (3) for electrically connecting the bare cells (2) to each other,
Each of the busbars (3) is directly connected to the bare cells (2) to electrically connect the bare cells (2) to each other. The method of claim 1 or 9,
The module case 4 includes a plurality of inner partition walls 43 on which the receiving portions 41 are formed, an outer partition wall 44 positioned outside the inner partition walls 43, and the inner partition walls 43 from the outside. It includes a plurality of coupling members 45 coupled to the partition wall 44;
The coupling members 45 are characterized in that coupling the inner partition walls 43 to the outer partition wall 44 so that each of the inner partition walls 43 are spaced apart from the inner surface of the outer partition wall 44 Capacitor module. A first electrode connecting member 31 to be connected to the first bare cell 2a;
A second electrode connecting member 32 to be connected to the second bare cell 2b; And
The first electrode is connected to each of the first electrode connecting member 31 and the second electrode connecting member 32 to electrically connect the first and second bear cells 2a and 2b. A connection member 31 and a connection member 33 formed integrally with the second electrode connection member 32,
The first electrode connecting member 31 includes a first electrolyte solution passing hole 311 for passing the electrolyte solution impregnated in the first bare cell 2a,
The second electrode connecting member (32) is a bus bar for an ultra capacitor module, characterized in that it comprises a second electrolyte solution passage hole (321) for passing the electrolyte solution impregnated in the second bare cell (2b). The method of claim 11,
The first electrode connection member 31 is formed to have a larger size than the connection member 33, and is formed in a shape corresponding to one side from which the first electrode 21 protrudes from the first bare cell 2a. Busbar for an ultra capacitor module, characterized in that the. The method of claim 11,
The connection member 33 includes a connection hole 331 into which a harness 6 is inserted for adjusting a voltage deviation between the first and second bearing cells 2a and 2b. Busbar for Ultra Capacitor Module characterized by.

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