RU2787465C1 - Energy storage device - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the field of electrical engineering, namely, to an energy storage device, namely, to an ultra-capacitor, in which a seal is used between the casing and the electrode terminal. The effect is achieved due to the fact that the energy storage device containing the housing for accommodating the electrolyte, the electrode element located inside the housing, the casing connected to one side of the casing, and the electrode lead inserted into the casing so as to be electrically connected to the electrode element, when this case contains a main element having a through hole into which the electrode lead is inserted, while the device contains a seal associated with the main element and located in the gap between the main element and the electrode lead in the through hole to come into close contact with the electrode lead, thereby sealing the gap between the base element and the electrode terminal. The seal can be molded from an elastically deformable material such as rubber, epoxy resin, polyimide resin, bismaleimide-triazine (BT), epoxy molding sand (EMS), and can also be bonded to the base element by injection molding, and can also be overlaid. onto the base element and cure to bond to the base element.

EFFECT: reducing the amount of electrolyte leakage.

12 cl, 10 dwg

Description

Technical field

The present disclosure relates to a power storage device for storing power such as electric power and the like.

Prior Art

Batteries, capacitors, and the like are typical power storage devices that store electrical energy. Among capacitors, ultra-capacitors (UC) have high efficiency, semi-permanent life and fast charge and discharge characteristics, and thus UC form the market for energy storage devices capable of compensating for the problems of short cycle and instantaneous high voltage, which are disadvantages of secondary batteries.

Based on the above advantages, UCs are widely used as auxiliary power supplies for mobile devices such as mobile phones, tablet personal computers (PCs) and laptops, as well as power supplies for electric vehicles, hybrid vehicles and solar cells that require high capacities, and main power supplies or auxiliary power supplies for night road lighting, uninterruptible power supplies (UPS) and the like.

Fig. 1 is a schematic side view illustrating a power storage device according to conventional technology.

With reference to FIG. 1, the conventional power storage device 100 includes an electrolyte storage case 110 and an electrode member, a case 120 associated with one side of the case 110, and an electrode terminal (terminal) 130 associated with the case 120. The electrode terminal 130 is inserted into the housing 120 and is connected to the electrode element located in the housing 110.

In this case, in the power storage device 100 according to the conventional technology, since the electrolyte contained in the case 110 leaks through the gap between the case 120 and the electrode terminal 130, there are problems in that battery performance is degraded and durability use is reduced.

Disclosure

Technical problem

Accordingly, the present disclosure is directed to providing a power storage device capable of reducing the amount of electrolyte leakage.

Technical solution

In order to achieve the above object, the present invention may include the following configurations.

An energy storage device according to one aspect of the present disclosure includes a housing configured to receive an electrolyte; an electrode element housed in the housing; a casing associated with one side of the housing; and an electrode terminal inserted into the case and electrically connected to the electrode element. The case includes a main member in which a through hole is formed, the through hole configured to allow an electrode lead to be inserted therein; and a seal that is associated with the base member, the seal being configured to seal a gap between the base member and the electrode terminal. The seal includes a lead seal member disposed in the through hole and pressed against the electrode lead to seal a gap between the base member and the electrode lead.

Useful results

In accordance with the present disclosure, the following results can be achieved.

The present disclosure may use a seal to increase the sealing force for the gap between the case and the electrode tab. Accordingly, the present disclosure can reduce the amount of electrolyte leakage through the gap between the case and the electrode terminal, and improve the internal pressure resistance.

DESCRIPTION OF THE DRAWINGS

Fig. 1 is a schematic side view illustrating a power storage device according to conventional technology;

Fig. 2 is a schematic side view illustrating a power storage device according to the present disclosure;

Fig. 3 is a conceptual view for describing an electrode member in a power storage device according to the present disclosure;

Fig. 4 is a schematic side cross-sectional view that illustrates a power storage device according to the present disclosure, taken along line I-I in FIG. 2;

Fig. 5 is a schematic exploded side cross-sectional view illustrating the case and electrode terminal based on FIG. four;

Fig. 6 is a schematic side cross-sectional view illustrating a comparative example of a power storage device according to the present disclosure;

Fig. 7 is a schematic perspective view illustrating a main element of a power storage device according to the present disclosure;

Fig. 8 is a schematic side cross-sectional view for describing a process in which a seal is associated with a main member in a power storage device according to the present disclosure;

Fig. 9 is a schematic side cross-sectional view for describing a main member including a support protrusion in a power storage device according to the present disclosure; and

Fig. 10 is a schematic bottom view illustrating the main element of a power storage device according to the present disclosure.

Best Mode

Next, an embodiment of a power storage device according to the present disclosure will be described in detail with reference to the attached drawings.

With reference to FIG. 2, the power storage device 1 according to the present disclosure is an electric power storage device. The energy storage device 1 according to the present disclosure may be implemented as an ultra-capacitor (UC). The energy storage device 1 according to the present disclosure may include an electrode element 2 (see Fig. 3), a housing 3, a casing 4, and electrode leads 5.

With reference to FIG. 2 and 3, the electrode element 2 is referred to as a bare element and may be located in a housing 3. The electrode element 2 may be formed by winding the first electrode 21, the second electrode 22, which has the opposite polarity of the first electrode 21, and the separator 23, which is located between the first electrode 21 and the second electrode 22 and electrically separates the first electrode 21 and the second electrode 22. In one embodiment, when the first electrode 21 has a positive polarity (+), the second electrode 22 has a negative polarity (−). Conversely, when the first electrode 21 has a negative polarity (−), the second electrode 22 has a positive polarity (+).

In FIG. 2 illustrates that a separator 23 is located only between the first electrode 21 and the second electrode 22, but another separator 23 may additionally be located outside the first electrode 21 and the second electrode 22 so that neither the first electrode 21 nor the second electrode 22 is exposed to the outside. For example, in the electrode element 2, the separator 23, the first electrode 21, the separator 23 and the second electrode 22 and the separator 23 may be arranged in series and wound. In the electrode element 2, the separator 23, the second electrode 22, the separator 23, the first electrode 21 and the separator 23 may also be arranged in series and wound.

The first electrode 21 may include a first active material layer 211 that is formed of activated carbon and formed on a current collector (not shown) formed of a metal material, and a first electrode lead (wire) 212 connected to one side of the first active material layer 211. material. In this case, the first electrode terminal 212 is formed as a portion where the first active material layer 211 is not formed on the current collector.

The second electrode 22 may include a second active material layer 221 that is formed from an activated electrode and formed on a current collector (not shown) formed from a metal material, and a second electrode lead 222 connected to one side of the second active material layer 221. In this case, the second electrode terminal 222 may be formed as a portion where the second active material layer 221 is not formed on the current collector.

In the above embodiment, the current collectors constituting the first electrode 21 and the second electrode 22 may be formed using metal films. The current collectors serve as paths for electrical charges emitted from or supplied to the first active material layer 211 and the second active material layer 221. Each of the first active material layer 211 and the second active material layer 221 may be formed by coating both surfaces of the current collector with the first and second active materials. The first active material layer 211 and the second active material layer 221 are layers in which electrical energy is stored.

In one embodiment, in the first electrode 21 and the second electrode 22, the first electrode lead 212 may be wound to be positioned on the underside of the electrode element 2 and the second electrode lead 222 may be wound to be positioned on the top side of the electrode element 2 .

Meanwhile, the electrode member 2 is impregnated with an electrolyte to store electrical energy. In this case, the process of impregnating the electrode element 2 with an electrolyte may be performed by soaking the electrode element 2 in an electrolyte filling a container for a predetermined time.

With reference to FIG. 2 and 3, housing 3 is a housing that holds the electrolyte. Together with the electrolyte, the electrode element 2 may be positioned in the housing 3. The housing 3 may be formed in a mold, one side of which is open. For example, the body 3 may be formed into a mold whose upper surface is open. The housing 3 may be formed in a substantially cylindrical shape, but is not limited to this, and may also be formed in a polygonal shape, such as a rectangular shape, if the housing contains the electrolyte and the electrode element 2.

With reference to FIG. 2-5, the case 4 is a case connected to one side of the case 3. The case 4 can seal the open side of the case 3. The electrode leads 5 can be inserted into the case 4. The electrode leads 5 can be inserted into the case 4 and electrically connected to the electrode an element 2 located in the body 3. The casing 4 may be formed essentially in the form of a disk, but is not limited to this, and may be formed in the form of a polygonal plate, for example, as a rectangular plate, if the casing is able to seal one open side of the body 3.

The casing 4 may include a seal 41 and a main element 42.

The seal 41 may be associated with the base member 42. The seal 41 may seal the gap between the base member 42 and the electrode lead 5. The seal 41 may also seal the gap between the base member 42 and the body 3. The seal 41 may be associated with the base member 42 so that surround the outer surface of the main element 42. The seal 41 may be molded from an elastically deformable material. For example, the seal 41 may be molded from rubber, epoxy resin, polyimide resin, bismaleimide triazine (BT), epoxy sand (EMC), or the like. Seal 41 may be associated with the main element 42 by injection molding. Seal 41 may also be applied to body 42 and cured to bond to body 42.

The seal 41 may include an outlet seal element 411 .

The lead seal member 411 is a member sealing the gap between the main member 42 and the electrode lead 5. The lead seal member 411 can be positioned in the through holes 420 formed in the main member 42. Accordingly, since the lead seal member 411 is disposed inside the through holes 420, the lead sealing member 411 can be pressed against the electrode lead 5 inserted in the case 4. Accordingly, the lead sealing member 411 can seal the gap between the electrode lead 5 and the main body 42. Accordingly, the power storage device 1 according to the present disclosure can reduce the amount of leakage electrolyte through the gap between the electrode terminal 5 and the main body 42 by increasing the sealing force for the gap between the electrode terminal 5 and the main body 42 using the seal 41. Accordingly, in the power storage device 1 according to the present disclosure, due to this, t be improved not only the electrolyte leakage prevention performance, but also the resistance to withstand internal pressure.

An insertion hole 411a (see FIG. 5) into which the electrode terminal 5 is inserted may be formed in the terminal seal member 411 . The electrode terminal 5 can be inserted into the insertion hole 411a to press the terminal seal member 411 . Accordingly, the terminal seal member 411 can be strongly pressed against the electrode terminal 5 using the restoring force generated due to contraction due to the compressive force. The lead seal member 411 may be in contact with the entire inner surface of the main member 42 formed towards the through hole 420. Accordingly, since the power storage device 1 according to the present disclosure is implemented such that the lead seal member 411 is pressed over the entire electrode lead portion 5 inserted into the case 4, the leakage prevention performance and durability can be further improved.

Seal 41 may include a sealing element 412 of the upper surface.

The top surface sealing member 412 is a member located on the upper surface of the main member 42. Accordingly, a sealing force for the upper surface of the main member 42 can be generated due to the upper surface sealing member 412. The upper surface of the main member 42 is a surface positioned on the side opposite the lower surface of the main member 42 formed towards the inner portion of the body 3. The upper surface of the main member 42 can be positioned outside the body 3. The sealing member 412 of the upper surface and the upper surface of the main member 42 may have substantially the same area. The top surface seal 412 may also have a sufficient area to cover the entire top surface of the base member 42. The top surface seal 412 and the outlet seal 411 may be molded to be connected to each other. The top surface seal 412 and the outlet seal 411 may also be molded as a single piece.

When the top surface sealing member 412 is provided, the outlet seal member 411 may have a thickness 411T that is larger than the thickness of the top surface sealing member 412. That is, the thickness 411T of the outlet seal member 411 may be greater than the thickness 412T of the top surface seal member 412. Accordingly, in the power storage device 1 according to the present disclosure, the thickness 411T of the terminal seal member 411 positioned at the portion where the leakage generation probability is high may be larger. Accordingly, in the power storage device 1 according to the present disclosure, since the thickness 412T of the top surface sealing member 412 is relatively thin, an increase in material costs can be suppressed, and at the same time, since the thickness 411T of the outlet sealing member 411 is relatively thick , the leakage prevention performance can be improved.

The seal 41 may include a bottom surface seal 413.

The bottom surface sealing member 413 is a member located on the bottom surface of the main member 42. Accordingly, a sealing force for the bottom surface of the main member 42 can be generated due to the bottom surface sealing member 413. The bottom surface sealing member 413 and the bottom surface of the base member 42 may have substantially the same area. The bottom surface sealing member 413 may also have a sufficient area to cover the entire bottom surface of the main member 42. The bottom surface sealing member 413 and the outlet seal member 411 may be molded to be connected to each other. The bottom surface sealing member 413 and the outlet sealing member 411 may be molded as an integral part.

When the bottom surface sealing member 413 is provided, the outlet seal member 411 may have a thickness 411T that is larger than the thickness of the bottom surface sealing member 413. That is, the thickness 411T of the outlet seal member 411 may be larger than the thickness 413T of the bottom surface seal member 413. Accordingly, in the power storage device 1 according to the present disclosure, since the thickness 413T of the bottom surface sealing member 413 is relatively thin, an increase in material costs can be suppressed, and at the same time, since the thickness 411T of the outlet sealing member 411 is relatively large, leakage prevention performance can be improved.

The seal 41 may include a sealing element 414 side surface.

The side surface sealing member 414 is an member located on the side surface of the main member 42. Accordingly, a sealing force for the side surface of the main member 42 can be generated due to the side surface sealing member 414 . Sealing element 414 side surface and the side surface of the main element 42 may have essentially the same area. The side surface seal 414 may also have sufficient area to cover the entire side surface of the main member 42. The side surface seal 414 may be molded to couple with the top surface seal 412 and the bottom surface seal 413. The side surface seal 414, the top surface seal 412, and the bottom surface seal 413 may also be molded as a single piece.

Seal 41 may include a sealing lip 415.

The sealing lug 415 is a lug supporting the folded member 31 (see FIG. 4) of the housing 3. The sealing lug 415 may be inserted into the folded member and may support the folded member 31 by a grip. Accordingly, the power storage device 1 according to the present disclosure can improve the internal pressure resistance by increasing the bonding force between the case 4 and the body 3 using the sealing protrusion 415 and the folded member 31. In addition, since the power storage device 1 according to with the present disclosure can maintain a state in which the seal 41 and the body 3 are pressed against each other using the sealing protrusion 415 and the bent member 31, the sealing force for the gap between the case 4 and the body 3 can be increased.

The sealing protrusion 415 may protrude upward from the sealing element 412 of the upper surface. The sealing protrusion 415 may be located on the edge of the sealing element 412 of the upper surface. In this case, the sealing protrusion 415 may also be formed at a position where the top surface sealing member 412 and the side surface sealing member 414 are connected to each other. The sealing protrusion 415 and the top surface sealing member 412 may also be molded as a single piece. The folded member 31 may be molded to surround the sealing lip 415. Accordingly, the folded member 31 may be engaged and supported by the sealing ledge 415 while resting on it. The folded member 31 may be molded to extend from the upper end of the body 3 and positioned to surround the sealing lip 415 by a bending process in the direction of the electrode terminal 5 inserted into the housing 4. The folded member 31 may be molded to have a curved surface . In this case, the sealing protrusion 415 may have a size that decreases as the sealing protrusion 415 protrudes upward and its end may be molded to have a curved surface.

In this case, the body 3 may include a curved element 32 (see Fig. 4). The bent member 32 may protrude to support the bottom surface of the casing 4. In this case, the bent member 31 may be supported by a sealing protrusion 415 located on the top surface of the casing 4. Accordingly, the casing 3 can support the top surface and bottom surface of the casing 4 using the bent member. 31 and the bent member 32. Accordingly, the power storage device 1 according to the present disclosure can be implemented to securely maintain the state in which the case 4 is connected to the body 3. The bent member 32 can support the bottom surface sealing member 413. The curved member 32 may also be realized by a process of bending a portion of the body 3 so that the portion protrudes inward.

With reference to FIG. 2-6, the main member 42 is the part to which the seal 41 is associated. Through holes 420 may be formed in the main member 42. The through holes 420 may be formed to pass through the main member 42. the base member 42. In this case, a plurality of electrode leads 5 may be inserted into the case 4. The through holes 420 may be located at positions spaced apart from each other.

The main member 42 may have a higher strength than the seal 41. Accordingly, the casing 4 may be implemented to have a sealing force through the seal 41 in addition to having a predetermined force through the main member 42. The main member 42 may be configured to have a higher blocking force than seal 41 against gas. Accordingly, the casing 4 can block the electrolyte from leaking in liquid form using the seal 41 in addition to blocking the electrolyte from leaking in gaseous form using the main body 42. For example, the main body 42 can be molded from plastic.

The main body 42 may be molded from a material having a higher strength than Bakelite and a lower absorbency than Bakelite. Accordingly, as illustrated in FIG. 6, the power storage device 1 according to the present disclosure can be implemented to have improved durability and moisture resistance compared to the comparative example. This will be specifically described below.

First, the comparative example illustrated in FIG. 6 can be implemented as a structure in which an ethylene propylene diene monomer (EPDM) layer 4a and a Bakelite layer 4b are stacked in series. The sealing force may be generated due to the EPDM layer 4a. The EPDM layer 4a can only be located on the upper surface of the Bakelite layer 4b. Bakelite layer 4b is a sheet of phenolic and serves as a support to provide sealing and rigidity. In such a comparative example, since the Bakelite layer 4b is molded from a material having properties similar to paper, there is a disadvantage in being susceptible to moisture because the Bakelite layer 4b can absorb an electrolyte. In addition, in the comparative example, since the EPDM layer 4a is located only on the upper surface of the Bakelite layer 4b, there is a high possibility that the electrolyte may leak through the gap between the EPDM layer 4a and the electrode terminal 5.

However, in the embodiment illustrated in FIG. 4 and 5, since the main body 42 is molded from a material having higher strength than Bakelite and at the same time lower electrolyte absorption capacity than Bakelite, the case 4 can be configured to have higher strength and more high moisture resistance than the comparative example. Further, in the embodiment, the seal 41 is located not only on the top surface, bottom surface, and side surface of the main body 42, but also in the through hole 420, and hence the amount of electrolyte leakage through the gap between the electrode terminal 5 and the main body 42 may be reduced.

With reference to FIG. 2-8, the main member 42 may include top surface protrusions 421.

The top surface projections 421 are projections protruding from the top surface of the main member 42. A plurality of top surface projections 421 may be provided on the top surface of the main member 42. The top surface projections 421 may be spaced apart from each other. When the seal 41 is associated with the main body 42 by injection molding, since the top surface protrusions 421 rest on the mold 10 (see FIG. 8), the top surface of the main body 42 can be spaced from the mold 10. FIG. 8, one downward surface of the main member 42 corresponds to the upper surface, and the other upward surface of the main member 42 corresponds to the lower surface. Since the molding resin for molding the seal 41 is introduced between the mold 10 and the top surface of the main body 42 due to the top surface protrusions 421, the seal 41 can be molded on the top surface of the main body 42. Accordingly, in the power storage device 1 according to With the present disclosure, the process of molding the seal 41 on the top surface of the base member 42 can be simplified using the top surface protrusions 421. In addition, in the power storage device 1 according to the present disclosure, since the contact area between the seal 41 and the main body 42 can be increased by using the upper surface protrusions 421, the bonding force between the seal 41 and the main body 42 can be increased. In FIG. 7 illustrates that six top surface projections 421 protrude from the top surface of the body 42, but the present disclosure is not limited thereto, and five or less, or seven or more top surface projections 421 may protrude from the top surface of the main body 42. Top surface projections 421 and main member 42 may also be molded as a single piece.

With reference to FIG. 2-8, the base member 42 may include a support protrusion 422.

The anvil 422 is a protrusion protruding from the top surface of the main member 42. The anvil 422 may protrude from a central portion of the main member 42. When the main member 42 is molded into a disc shape, the abutment 422 may protrude from the center of a circle defined by the upper surface of the main member 42. When the seal 41 is associated with the main body 42 by injection molding, even if the molding resin for molding the seal 41 is located on the lower surface of the main body 42, since the support protrusion 422 rests on the mold 10 to support the upper surface of the main body 42, deflection of the base member 42 may be prevented. The anvil 422 may be molded into a substantially disc shape, but is not limited thereto, and may also be molded into a polygonal shape, such as a rectangular shape, if the anvil prevents deflection of the base member 42.

With reference to FIG. 2-8, main member 42 may include communication holes 423.

The communication holes 423 are holes formed to pass through the main member 42. When the seal 41 is connected to the main member 42 by injection molding, a molding resin for molding the seal 41 can fill the communication holes 423 so that the connecting seal members can be molded. 416. Connecting seals 416 may be formed in the communication holes 423 to connect the top surface seal 412 located on the top surface of the main body 42 and the bottom surface seal 413 located on the bottom surface of the main body 42. Accordingly, in device 1 storage of energy according to the present disclosure, the top surface sealing member 412 and the bottom surface sealing member 413 are prevented from rising from the main member 42 by using the communication holes 423 and the connection seals. pulling members 416. Communication holes 423 may be formed at positions spaced apart from the through holes 420 to pass through the main member 42. A plurality of communication holes 423 may be formed in the main member 42. The communication holes 423 may be spaced apart from each other. Accordingly, since the seal 41 includes connecting sealing members 416 connecting the upper surface sealing member 412 and the lower surface sealing member 413 at separate positions, each of the upper surface sealing member 412 and the lower surface sealing member 413 can increase the prevention force to prevent lifting. from the main element 42.

With reference to FIG. 2-7, main member 42 may include compression recesses 424.

The compression recesses 424 are formed to connect with the through holes 420. Each of the compression recesses 424 may be formed as a recess molded to have a predetermined depth from the top surface of the main member 42. When the compression recesses 424 are provided, the seal 41 may include a sealing element 417 compression. The sealing element 417 compression may be associated with the main element 42 to cover the recess 424 compression. Accordingly, in the seal 41, the portion on which the compression seal 417 is positioned may be thicker than other portions. Accordingly, since the electrode terminal 5 can communicate with the case 4 when the compression sealing member 417 is compressed, the electrode terminal 5 can be more securely bonded with the case 4. This is because the electrode terminal 5 can be bonded with the case 4 when the compression sealing member 417 is compressed more strongly. because the compression sealing member 417 may be deformed due to displacement according to the thickness. The compression sealing member 417 may be compressed by the flange 51 included in the electrode terminal 5. When the plurality of electrode terminals 5 are connected to the case 4, a plurality of compression recesses 424 may be formed in the main member 42.

With reference to FIG. 2-7 and 9, the base member 42 may include a support protrusion 425.

The anvil 425 is a protrusion supporting the folded member 31. The anvil 425 may protrude from the top surface of the main member 42. When the anvil 425 is provided, the seal 41 may include a support hole 418. The support hole 418 may be formed to pass through the upper seal portion 41. In this case, the support hole 418 may be formed to pass through the upper surface sealing member 412. Because the lip 425 is inserted into the mount 418 and is exposed outward from the seal 41 through the mount 418, the lip 425 can support the fold 31 located outside the seal 41. Accordingly, since the fold 31 is supported by the lip 425 with more force than the seal 41, the folded member 31 can be more securely supported by the casing 4. One surface of the support projection 425 supporting the folded member 31 can be formed as a flat surface.

With reference to FIG. 2-7 and 10, the main element 42 may include reinforcing projections 426 (see FIG. 10).

Reinforcement protrusions 426 may protrude from the bottom surface of main member 42. A plurality of reinforcing protrusions 426 may protrude from the bottom surface of main member 42. Reinforcement protrusions 426 may protrude in various positions. Accordingly, in the power storage device 1 according to the present disclosure, since the strength of the main member 42 can be increased by using the reinforcing projections 426, the durability of the casing 4 can be further increased. In addition, in the power storage device 1 according to the present disclosure, since the contact area between the seal 41 and the main body 42 can be increased by using the reinforcing projections 426, the bonding force between the seal 41 and the main body 42 can be increased. Accordingly, in the power storage device 1 according to the present disclosure, the preventing force to prevent the seal 41 from lifting up from the main member 42 can be increased. The reinforcing projections 426 and the body 42 may be molded as a single piece.

In FIG. 10 illustrates that reinforcing ribs 426 are formed on the bottom surface of main member 42, but the present disclosure is not limited thereto, and reinforcing ribs 426 may also be formed on the upper surface of main member 42. Reinforcement ribs 426 may also be formed on both the bottom surface and and on the top surface of the main member 42. Meanwhile, in FIG. 10 illustrates that the reinforcing ribs 426 are formed in angular shapes and connected to each other, but the present disclosure is not limited to this, and the reinforcing ribs 426 may be formed in various shapes if the reinforcing ribs increase the strength of the main member 42.

With reference to FIG. 2-5, the electrode terminal 5 represents a terminal inserted into the housing 4 and electrically connected to the electrode element 2. The electrode terminal 5 can be inserted into the housing 4 through the insertion hole 411a and electrically connected to the electrode element 2 disposed in the housing 3.

The electrode terminal 5 may include a flange 51. The flange 51 may be supported by the upper surface of the housing 4. In this case, the flange 51 may include a compression seal 417.

The electrode terminal 5 may include a pin (contact) 52 of the output. The output contact 52 may be inserted into the housing 4 and positioned in the housing 3. In this case, the sealing element 411 of the output 411 may be pressed against the outer surface of the output contact 52. The output contact 52 can be electrically connected to the electrode element 2 located in the housing 3.

The electrode lead 5 may include a connecting member 53. The connecting member 53 may be connected to the lead pin 52 protruding from the bottom surface of the case 4. Accordingly, the electrode lead 5 may be connected to the case 4. The connecting member 53 may be positioned in the case 3 A portion of the inner surface of the connecting member 53 and a portion of the outer surface of the terminal contact 52 may be threaded.

The electrode terminal 5 may include a first electrode terminal 5a (see FIG. 2) connected to one or more first wire lines (not shown) and a second electrode terminal 5b (see FIG. 2) connected to one or more second wire lines (not shown). The first electrode terminal 5a and the second electrode terminal 5b may be connected to the case 4 when inserted into the case 4 and electrically connected to the electrode member 2 via the first wire line and the second wire line.

In the power storage device 1 according to the present disclosure, various types of electrode leads 5 may be associated with the case 4. As illustrated in FIG. 2, the electrode terminal 5 realized with the structure connected to the busbar may be connected to the case 4. In this case, the electrode terminal 5 may be formed in a substantially cylindrical shape. Although not illustrated in the drawings, the electrode terminal 5 realized with a structure connected to a printed circuit board (PCB) may also be associated with the case 4. In this case, the electrode terminal 5 may be formed into a plate shape bent into an L-shape. .

The present disclosure described above is not limited to the above described embodiments and the accompanying drawings, and those skilled in the art will appreciate that various substitutions, modifications, and changes are possible without departing from the technical spirit of the embodiment.

Claims (39)

1. An energy storage device, comprising: a housing configured to receive the electrolyte; an electrode element housed in the housing; a casing connected to one side of the housing; and an electrode terminal inserted into the housing and electrically connected to the electrode element, wherein the case includes: a main member in which a through hole is formed, the through hole being configured to allow an electrode lead to be inserted therein; and a seal associated with the main element, wherein the seal is configured to seal the gap between the main element and the electrode terminal, and the seal includes a lead seal member disposed in the through hole and pressed against the electrode lead to seal the gap between the base member and the electrode lead. 2. The device according to claim 1, in which the seal includes: a top surface sealing member disposed on an upper surface of the main member; a side surface sealing member disposed on a side surface of the main member; and a lower surface sealing element located on the lower surface of the main element. 3. The device according to claim 1, in which: the seal includes a top surface sealing member disposed on an upper surface of the base member; and the outlet sealing member is formed so that it has a thickness greater than the upper surface sealing member. 4. The device according to claim 1, wherein the main body is molded from a material having a higher strength than bakelite and an electrolyte absorption capacity less than bakelite. 5. The device according to claim. 1, containing: a plurality of top surface protrusions protruding from the top surface of the base member; and the protrusions of the upper surface are located at a distance from each other. 6. The device according to claim. 1, containing a support protrusion protruding from the Central section of the upper surface of the main element. 7. The device according to claim. 1, containing a communication hole formed to ensure its passage through the main element, wherein the seal includes: a top surface sealing member disposed on an upper surface of the main member; a bottom surface sealing member disposed on a bottom surface of the main member; and a connecting sealing member formed in the communication hole for connecting the upper surface sealing member and the lower surface sealing member. 8. The device according to claim 1, in which: the body includes a folded element that is engaged and supported by the seal; and the seal includes a sealing protrusion that is inserted into the folded element and configured to support the folded element by means of a grip. 9. The device according to claim 8, in which: the main element includes a support protrusion configured to support the folded element; the seal includes a support hole into which a support protrusion is inserted; and the support protrusion is open outward from the seal through the support hole and is configured to support the folded element. 10. The device according to claim 8, in which: the folded element is a supported sealing protrusion located on the upper surface of the casing; and the housing includes a curved member projecting to support the lower surface of the housing. 11. The device according to claim 1, and: the main element includes a compression recess formed to connect with the through hole; the seal includes a compression sealing member associated with the base member to cover the compression recess; and the compression sealing element is configured to be compressed by the electrode lead connected to the casing. 12. The device according to claim 1, comprising a plurality of reinforcing protrusions protruding from at least one of the upper surface of the main element and the lower surface of the main element.

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