KR102332931B1 - Can type electric double layer capacitor for high power - Google Patents

Abstract

The present invention relates to a can-type electric double-layer capacitor for high voltage, comprising: a can-type case in which an electrode assembly impregnated with an electrolyte is accommodated therein, and a metal cover having an insertion hole formed on one side thereof is connected; and a safety vent valve inserted and connected to the insertion hole formed in the metal cover of the can-type case, and the electrolyte is C ₄ H ₆ O (divinyl sulfone), C ₃ H ₂ O (vinylene carbonate) and C ₁₂ H ₁₀ (biphenyl). ), and the safety vent valve includes an outer housing inserted into the insertion hole and connected to the metal cover, a gasket disposed inside the outer housing and having a gas discharge hole formed in the center, and disposed inside the outer housing to the upper portion of the gasket a gas blocking block supporting and having a gas blocking hole communicating with the gas discharge hole of the gasket in the center; a plate-shaped elastic member disposed inside the outer housing and positioned above the gas blocking block; An inner housing supporting the plate-shaped elastic member, a disc spring disposed inside the outer housing to support the inner housing, and a gas pressure or plate-shaped elastic member disposed between the gas blocking block and the plate-shaped elastic member and generated inside the can-shaped case It is characterized by having a ball contacting or falling into the gas blocking hole according to the pressure of the

Description

Can type electric double layer capacitor for high power

The present invention relates to a can-type electric double layer capacitor for high voltage, and in particular, by preventing a side reaction between an electrode and an electrolyte in an electrolyte, stable operation at high voltage, and preventing damage due to gas generation, In case of occurrence, the permanent safety vent valve is firmly installed, the pressure of gas release can be precisely set using the elastic force of the plate-shaped elastic member, and the gas can be released or sealed based on the set pressure so that it can be used repeatedly. Thus, it relates to a can-type electric double layer capacitor for high voltage that can be used stably at high voltage.

An electric double layer capacitor (EDLC) uses activated carbon as an electrode, and a technology related to activated carbon used as an electrode of an electric double layer capacitor is disclosed in Korean Patent Application Laid-Open No. 10-2011-0063472 (Patent Document 1). is disclosed.

Korean Patent Application Laid-Open No. 10-2011-0063472 discloses a method for manufacturing activated carbon used for electrodes of electric double-layer capacitors, and is for manufacturing activated carbon having a small average particle diameter, uniform particle size, and relatively large specific surface area in an easy and productive manner. The method for producing activated carbon used for an electrode of an electric double layer capacitor described in Korean Patent Application Laid-Open No. 10-2011-0063472 uses an easily graphitizable carbon material such as petroleum coke or coal coke as a starting material, and the carbon material is an oxidizing gas It is prepared by calcining the starting material under the atmosphere, controlling the particle size of the carbon material and activating it.

As described in Korean Patent Application Laid-Open No. 10-2011-0063472, the electrode of the conventional electric double layer capacitor uses activated carbon as an active material, and in this conventional electric double layer capacitor, a side reaction may occur between the electrode and the electrolyte, When a side reaction occurs between the electrode and the electrolyte, stable operation at high voltage is impossible, and there is a problem that damage may occur due to gas generation.

: Korea Patent Publication No. 10-2011-0063472

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems, and in particular, by preventing a side reaction between an electrode and an electrolyte in an electrolyte, it can operate stably at a high voltage, and can prevent damage due to gas generation, etc. In the event of a high voltage, the permanent safety vent valve is firmly installed, the pressure of gas release can be precisely set using the elastic force of the plate-shaped elastic member, and the gas is released or sealed based on the set pressure. An object of the present invention is to provide a can-type electric double layer capacitor for high voltage that can be used stably.

Another object of the present invention is to be able to precisely set the pressure of gas release by using the elastic force of the plate-shaped elastic member, and to release or seal the gas based on the set pressure so that it can be operated even at a low gas pressure. An object of the present invention is to provide a can-type electric double-layer capacitor for high voltage that can improve the reliability of the device.

Another object of the present invention is to improve the response speed by making it possible to precisely set the pressure of gas release using the elastic force of the plate-shaped elastic member, and to release or seal the gas based on the set pressure using the elastic force of the elastic member. It is possible to provide a can-type electric double layer capacitor for high voltage that can be miniaturized and thinned.

The can-type electric double-layer capacitor for high voltage of the present invention includes: a can-type case in which an electrode assembly impregnated with an electrolyte is accommodated therein, and a metal cover having an insertion hole formed on one side thereof is connected; and a safety vent valve inserted and connected to the insertion hole formed in the metal cover of the can-type case, wherein the electrolyte is C ₄ H ₆ O (divinyl sulfone), C ₃ H ₂ O (vinylene carbonate), and C ₁₂ H ₁₀ (biphenyl), wherein the safety vent valve includes an outer housing inserted into the insertion hole and connected to the metal cover, a gasket disposed inside the outer housing and having a gas discharge hole in the center, and the outer housing. A gas blocking block disposed inside to support the upper portion of the gasket and having a gas blocking hole communicating with the gas discharge hole of the gasket in the center thereof, and a plate type disposed inside the outer housing and positioned above the gas blocking block an elastic member; an inner housing disposed inside the outer housing to support the plate-shaped elastic member; a disc spring disposed inside the outer housing to support the inner housing; the gas blocking block and the plate-shaped elastic member It is characterized in that it has a ball that is disposed between the can-shaped case and is in contact with or falling into the gas blocking hole according to the gas pressure generated inside the can-shaped case or the pressure of the plate-shaped elastic member.

The can-type electric double-layer capacitor for high voltage of the present invention has the advantage that a permanent safety vent valve is firmly installed in the electric double-layer capacitor, and the pressure of gas release can be precisely set using the elastic force of the plate-shaped elastic member, and the set pressure There is an advantage that it can be used semi-permanently by allowing it to be used repeatedly by releasing gas or sealing it as a standard.

In the can-type electric double layer capacitor for high voltage of the present invention, the pressure of gas release can be precisely set by using the elastic force of the plate-shaped elastic member, and the gas can be released or sealed based on the set pressure, so that even at low gas pressure There is an advantage in that the operation reliability can be improved by allowing it to be operated, and the response speed can be improved, miniaturized, and thinned by allowing gas to be released or sealed by using the elastic force of the plate-shaped elastic member.

1 is a perspective view of a can-type electric double layer capacitor for high voltage of the present invention;
Figure 2 is an enlarged perspective view of the permanent safety vent valve shown in Figure 1;
3 is a cross-sectional view taken along line AA shown in FIG. 1;
4 is an enlarged cross-sectional view of part 'B' shown in FIG. 3;
5 is a cross-sectional view showing a state in which the permanent safety vent valve shown in FIG. 4 is separated from the insertion hole of the metal cover;
6 is a cross-sectional view showing the disassembled and assembled state of the permanent safety vent valve shown in FIG. 4;
7 is an enlarged cross-sectional view of the gas blocking block and the ball shown in FIG. 6;
8 is a plan view of the plate-shaped elastic member shown in FIG. 4;
9 is a plan view showing another embodiment of the plate-shaped elastic member shown in FIG. 8;
10 is a cross-sectional view showing the operating state of the plate-shaped elastic member of the permanent safety vent valve shown in FIG. 4;
11 is a perspective view showing another embodiment of the can-type case shown in FIG.

Hereinafter, an embodiment of the can-type electric double layer capacitor for high voltage of the present invention will be described with reference to the accompanying drawings.

1 to 4 , the can-type electric double layer capacitor for high voltage of the present invention includes a can-type case 110 and a safety vent valve 120 .

The can-shaped case 110 has an electrode assembly 112 impregnated with an electrolyte is accommodated therein, and a metal cover 111 having an insertion hole 111a formed on one side is connected thereto. Here, the electrolyte includes C ₄ H ₆ O (divinyl sulfone), C ₃ H ₂ O (vinylene carbonate), and C ₁₂ H ₁₀ (biphenyl). The safety vent valve 120 is inserted into and connected to the insertion hole 111a formed in the metal cover 111 of the can-type case 110 , and is connected to the outer housing 121 , the gasket 122 , the gas blocking block 123 , and the plate type. It has an elastic member 124 , an inner housing 125 , a disc spring 126 and a ball 127 . The outer housing 121 is inserted into the insertion hole 111a and connected to the metal cover 111 , and the gasket 122 is disposed inside the outer housing 121 and a gas discharge hole 122a is formed in the center. The gas blocking block 123 is disposed inside the outer housing 121 to support the upper portion of the gasket 122 , and a gas blocking hole 123a communicating with the gas discharge hole 122a of the gasket 122 is formed in the center. And, the plate-shaped elastic member 124 is disposed inside the outer housing 121 is located on the upper portion of the gas blocking block (123). The inner housing 125 is disposed inside the outer housing 121 to support the plate-shaped elastic member 124 , and the disc spring 126 is disposed inside the outer housing 121 to support the plate-shaped elastic member 124 . do. The ball 127 is disposed between the gas blocking block 123 and the plate-shaped elastic member 124 and according to the gas pressure generated inside the can-shaped case 110 or the pressure of the plate-shaped elastic member 124, the gas blocking hole 123a ) touches or falls.

The configuration of the can-type electric double layer capacitor for high voltage of the present invention having the above-described configuration will be described in detail as follows.

The can-shaped case 110 is formed in a cylindrical shape as in FIGS. 1 and 3, is made of a metal, and an electrode assembly 112 impregnated with an electrolyte is accommodated therein, and an insertion hole 111a is formed on one side. A cover 111 is included. Here, the electrolyte contains C ₄ H ₆ O (divinyl sulfone), C ₃ H ₂ O (vinylene carbonate), and C ₁₂ H ₁₀ (biphenyl), and C ₄ H ₆ O (divinyl sulfone) suppresses swelling. C ₃ H ₂ O (vinylene carbonate) is added to improve lifespan, and C ₁₂ H ₁₀ (biphenyl) is added for an overcharge inhibitor, so that the can-type electric double layer capacitor for high voltage of the present invention is stable at high voltage. can operate with

The metal cover 111 is formed in a circular shape and is fastened to the can-shaped case 110 via a curling part 113 and a sealing member 114 formed on one side of the can-shaped case 110 . The electrode assembly 112 is disposed inside the can-shaped case 110 in a state of being impregnated with an electrolyte, and is connected to a pair of external terminals 115 and 116 through metal connecting plates 115a and 116a, respectively. The connection relationship between the electrode assembly 112 , the metal connecting plates 115a and 116a and the external terminals 115 and 116 is omitted because a known technique is applied.

The electrode assembly 112 is a stacked type in which a positive electrode (not shown), a negative electrode (not shown) and a separator (not shown) are stacked on top of each other or a winding type is used when winding, and the positive electrode is made of lithium cobalt oxide or activated carbon. is used, and carbon or activated carbon is used for the negative electrode. For example, when the electrode assembly 112 is applied to a lithium ion secondary battery, lithium cobalt oxide is used for the positive electrode (not shown) and carbon is used for the negative electrode, and when applied to an electric double charge capacitor device, a positive electrode or a negative electrode Activated carbon is used for The detailed configuration of the electrode assembly 112 is omitted because a known technique is applied.

The safety vent valve 120 is inserted and connected to the insertion hole 111a formed in the metal cover 111 of the can-type case 110 as shown in FIGS. 2, 3 and 4, and the outer housing 121, the gasket ( 122 ), a gas blocking block 123 , a plate-shaped elastic member 124 , an inner housing 125 , a disc spring 126 , and a ball 127 .

The outer housing 121 is inserted into the insertion hole 111a as shown in FIG. 4 and is connected to the metal cover 111, and as shown in FIGS. 2, 4 and 6, the first hollow cylindrical member 121a, the hollow It includes a mold disk (121b) and a second hollow cylindrical member (121c).

The first hollow cylindrical member 121a is inserted into the insertion hole 111a formed in the metal cover 111 of the can-type case 110 as shown in FIG. 4 and communicates with the inner side of the can-type case 110 through a first through hole. (11) is formed. The hollow disk 121b extends from one side of the first hollow cylindrical member 121a to form a second through hole 12 to communicate with the first through hole 11, and the first hollow cylindrical member 121a. When inserted into the insertion hole (111a), the other side is in contact with the surface of the metal cover (111) as shown in FIG. The second hollow cylindrical member 121c extends from one side of the hollow disk 121b to form a third through hole 13 to communicate with the second through hole 12 .

The size of the outer diameter D1 of the first hollow cylindrical member 121a is smaller than the outer diameter D2 of the hollow disk 121b and the outer diameter D3 of the second hollow cylindrical member 121c, and the hollow disk ( The size of the outer diameter (D2) of 121b) and the outer diameter (D3) of the second hollow cylindrical member (121c) are equal to each other, so that the outer housing 121 is supported on the surface of the metal cover 111, and the insertion hole ( 111a), that is, it is connected by press-fitting by pressing with pressure. The outer housing 121 has screw grooves on the surface of the insertion hole 111a of the metal cover 111 and the outer peripheral surface of the first hollow cylindrical member 121a, respectively, in order to make the connection of the metal cover 111 more robust. not shown) to form and fasten. Techniques for forming screw grooves on the surface of the insertion hole 111a and the outer circumferential surface of the first hollow cylindrical member 121a, respectively, will be omitted since a known technique is applied. That is, the outer housing 121 is firmly fastened to the insertion hole 111a formed in the metal cover 111 when an insulating material is used using an adhesive and press-fitting, and when a metal material is used, it is the same as in the case described above. Similarly, by forming and fastening screw grooves on the outer circumferential surface, the safety vent valve 120 can be more firmly fixed and fastened to the metal cover 111 .

The length LS of the first hollow cylindrical member 121a is greater than the thickness LT of the metal cover 111 as shown in FIG. 5 so that the first hollow cylindrical member 121a passes through the metal cover 111 . to be inserted into the can-shaped case 110 . The diameter R3 of the third through hole 13 of the third hollow cylindrical member 121c is the diameter R2 and the first through hole 11 of the second through hole 12 as shown in FIG. 4 . is larger than the diameter R1 of the first through hole 11, so that the diameter length R1 of the first through hole 11 and the diameter length R2 of the second through hole 12 are equal to each other. When gas is generated from the inside of the can-shaped case 110 through the 122 , the gas blocking block 123 , the plate-shaped elastic member 124 , the inner housing 125 , and the disc spring 126 may be sequentially disposed. The hollow disk 12 extends from one side and protrudes, and a cylindrical protrusion member 121d in which a fourth through-hole 14 is formed to communicate with the second through-hole 12 is formed, and the fourth through-hole 14 is formed. The diameter length (not shown) of is formed to be the same as the diameter length R2 of the second through hole 12 .

The gasket 122 is disposed inside the outer housing 121 as shown in FIGS. 4 to 6 and a gas discharge hole 122a is formed in the center. That is, the gasket 122 is pressed by the disc spring 126 and is disposed inside the outer housing 121 so as to be in contact with the hollow disk 121b of the outer housing 121, and the ball 127 as shown in FIG. It prevents the electrolyte located inside the can-shaped case 110 from being exposed to the outside through the safety vent valve 120 in a state in close contact with the gas blocking block 123 . The gasket 122 includes a first through hole 11 formed in the first hollow cylindrical member 121a, a second through hole 12 formed in the hollow disk 121b, and a first through hole formed in the cylindrical protruding member 121d. A gas discharge hole 122a is formed in the center so as to communicate with the four through-holes 14, respectively, and an insertion hole 122b into which the gas discharge hole 122a is inserted into the cylindrical protrusion member 121d is formed on the other side, and the outer circumferential surface An insertion groove (122c) is formed along the outer peripheral surface on the other side of the.

The gas blocking block 123 is disposed inside the outer housing 121 as shown in FIGS. 4 to 6 to support the upper portion of the gasket 122 and to communicate with the gas discharge hole 122a of the gasket 122 in the center. A gas blocking hole 123a is formed.

The gas blocking hole 123a includes a first gas blocking hole 21 and a second gas blocking hole 22 as shown in FIG. 7 . The first gas blocking hole 21 is located at one side of the gas discharge hole 122a, and the second gas blocking hole 22 is formed to extend from one side of the first gas blocking hole 21 . The first gas blocking hole 21 is formed in a cylindrical shape, and diameter lengths RD1 and RD2 of one side and the other side are the same (RD1 = RD2). The second gas blocking hole 22 is formed in a cylindrical shape, the diameter length RD4 of one side is larger than the diameter length RD3 of the other side, and the diameter length RD3 of the other side of the second gas blocking hole 22 is the second. The first gas blocking hole 21 is the same as the diameter RD2 of one side, and the second gas blocking hole 22 has a diameter RD4 of one side that is larger than the diameter RD5 of the ball 127, 2 The depth DL of the gas blocking hole 22 is smaller than the diameter length RD5 of the ball 127 . Here, the first gas blocking hole 21 and the second gas blocking hole 22 are formed to communicate with each other, so that the diameter length RD3 of the other side of the second gas blocking hole 22 and the first gas blocking hole 21 are formed to communicate with each other. ), the diameter length RD2 of one side is shared with each other. That is, the second gas blocking hole 22 of the gas blocking hole 123a has a diameter length RD4 and a depth DL of one side larger than the diameter length RD5 of the ball 127, so that the other side has a diameter length. (RD3) is formed in a cone-shaped cut so that the movement of the ball (ball) 127 is firmly guided so that the gas generated from the inside of the can-shaped case 110 through the gas blocking hole (123a) is easily discharged or blocked. do.

The plate-shaped elastic member 124 is disposed inside the outer housing 121 as shown in FIGS. 5, 6 and 8 and is located on the gas blocking block 123, the first hollow disk 124a, the first It includes a double hollow disk (124b) and a connecting member (124c). The first hollow disk 124a is formed with an insertion hole 33 into which the ball 127 is inserted in the center, and the diameter length RD6 of the insertion hole 33 of the first hollow disk is the length of the ball 127. It is formed to be smaller than the diameter length RD5 to prevent the ball 127 from being separated from the safety vent valve 120 by the deformation of the plate-shaped elastic member 124 . The second hollow disk 123b is disposed to be spaced apart from the inside of the first hollow disk 124a, and is disposed inside the outer housing 121 to be positioned between the inner housing 125 and the disk spring 126. .

The connecting member 124c is formed between the first hollow disk 123a and the second hollow disk 123b to connect the first hollow disk 123a and the second hollow disk 123b. The connecting member 124c includes at least two straight members 31 and at least two curved members 32 .

The two or more straight members 31 are spaced apart from each other at a predetermined angle based on the center of the first hollow disk 123a on the first hollow disk 123a and the second hollow disk 123b, and two or more The curved members 32 are respectively spaced apart from each other at regular intervals based on the center of the first hollow disk 123a and are connected to the two straight members. That is, the connecting member 124c is formed in which two or more straight members 31 are spaced apart at a predetermined angle with respect to the center of the first hollow disk 123a, and the two or more curved members 32 are first hollow. The elastic force is provided to the ball 127 by the pressure of the gas generated inside the can-shaped case 110 by being spaced apart from each other in a direction away from the center of the disk 123a. In this way, the plate-shaped elastic member 124 is formed by dividing the straight member 31 of the connecting member 124c into four as shown in FIG. As shown in FIG. 10 , the ball 127 is moved.

The inner housing 125 includes a housing hollow disk 125a and a housing hollow cylindrical member 125b as shown in FIGS. 4 to 6 . The housing hollow disk 125a supports one side of the plate-shaped elastic member 124 and a first housing through hole 41 is formed in the center, and the hollow cylindrical member 125b is the other side of the housing hollow disk 125a. The second housing through-hole 42 is formed to extend from the central first housing through-hole 41 and communicates with the through-hole 42 is formed.

The diameter length RM1 of the first housing through-hole 41 of the housing hollow disk 125a is greater than the diameter RD6 of the first hollow disk 124a of the plate-shaped elastic member 124 and the second hollow It is formed smaller than the diameter length RD7 of the disk 124b. The diameter length RM2 of the second housing through hole 42 of the housing hollow cylindrical member 125b is the outer diameter of the gasket 122 (not shown), the outer diameter of the gas blocking block 123 (not shown), and the plate-like elasticity. The outer diameter of the member 124, that is, the diameter length RD7 of the second hollow disk 124b is formed so that each is inserted into the inner side of the housing hollow cylindrical member 125b. The housing hollow cylindrical member 125b is inserted into the insertion groove 122c formed on the other side of the outer peripheral surface of the gasket 122 by forming a curling part 125c on the other side as shown in FIG. 6 to be inserted and fastened. .

The disc spring 126 is disposed inside the outer housing 121 as shown in FIGS. 5 and 6 to support the plate-shaped elastic member 124, a through hole 126a is formed in the center, and the through hole 126a is formed. When the plate-shaped elastic member 124 is stretched by the ball 127 through the ball 127, it provides a movement path of the elastic member 124. The disc spring 126 is disposed inside the outer housing 121, that is, it is press-fitted, and when the plate-shaped elastic member 124 is stretched or contracted by the movement of the ball 127 by gas pressure, the plate-shaped elastic member ( 124) is firmly supported.

The ball 127 is disposed between the gas blocking block 123 and the plate-shaped elastic member 124 as in FIGS. 5 to 7 , and the gas pressure generated inside the can-shaped case 110 or the plate-shaped elastic member 124 is Depending on the pressure, the gas blocking hole 123a comes into contact with or falls. When the ball 127 moves, that is, when moving in a direction away from the gas blocking block 123 in a state in close contact with the ball 127, the gas generated from the inside of the can-shaped case 110 strikes the plate-shaped elastic member 124. leaked out through Conversely, when the gas pressure inside the can-shaped case 110 is appropriate, the ball 127 is in close contact with the gas blocking block 123 by the elastic force of the plate-shaped elastic member 124 to prevent gas from being discharged to the outside.

When the gas is discharged to the outside by the movement of the ball 127 and the gas pressure inside the can-shaped case 110 is appropriate, the ball 127 is moved to the gas blocking block 123 by the elastic force of the plate-shaped elastic member 124 . In order to ensure reliability of the operation of preventing the gas from being discharged to the outside in close contact, the outer housing 121, the gasket 122, the gas blocking block 123, the plate-shaped elastic member 124, the plate-shaped elastic member 124 and the Of the balls 127, the material of the outer housing 121 is made of an insulating material, and the insulating material is polypropylene, and the gasket 122 and the ball 127 are made of rubber, respectively, and a gas blocking block. The material of the 123 and the plate-shaped elastic member 124 and the plate-shaped elastic member 124 is metal. That is, the material of the gasket 122 and the ball 127 is formed of rubber to increase the sealing effect, and the material of the gas blocking block 123 is made of metal to prevent deformation due to pressure, thereby preventing the ball 127 from being deformed by pressure. ) to be accurately adhered or spaced apart, and by using metal as the material of the plate-shaped elastic member 124, the durability of the gas vent operation is improved.

As shown in FIGS. 4 to 6, the can-type electric double layer capacitor for high voltage of the present invention has a gas permeable membrane ( 128 and an anti-condensation film 129 are disposed. The gas permeable membrane 128 is located inside the outer housing 121 and is disposed between the outer housing 121 and the gasket 122, and a nonwoven fabric or fabric manufactured using a fiber coated with a fluororesin layer on the surface is used. And, the material of the fiber is one of polyvinylidene fluoride resin and polyacrylonitrile resin is used. The anti-condensation film 129 is located inside the outer housing 121 and disposed between the gas blocking block 123 and the plate-shaped elastic member 124. do. Another embodiment of the can-type electric double layer capacitor for high voltage of the present invention is shown in FIG. The electric double layer capacitor 200 having the permanent safety vent valve 120 of the present invention shown in FIG. 11 is for the high voltage of the present invention, except that the can-type case 210 and the metal cover 211 are each square. Since it is the same as that of the can-type electric double layer capacitor, a description thereof will be omitted.

The operation of the above-described can-type electric double layer capacitor for high voltage of the present invention will be schematically described with reference to FIGS. 5 and 10 as follows.

In the can-type electric double-layer capacitor for high voltage of the present invention, when the electrolyte impregnated in the electrode assembly 112 disposed inside the can-type case 110 has a stable state, the permanent safety vent valve 120 is an enlarged view shown in FIG. maintain the same status as That is, the permanent safety vent valve 120 has the ball 127 in close contact with the gas blocking block 123 by the elastic force of the plate-shaped elastic member 124 when the gas pressure inside the can-shaped case 110 is appropriate. to prevent it from escaping to the outside. Conversely, when gas is generated above a preset gas pressure inside the can-type case 110 , the permanent safety vent valve 120 maintains the state as shown in the enlarged view of FIG. 10 . That is, the permanent safety vent valve 120 moves in a direction in which the ball 127 is spaced apart from the gas blocking block 123 by the gas pressure, so that the gas generated inside the can-shaped case 110 is released from the plate-shaped elastic member 124 . ) to be discharged to the outside.

The can-type electric double layer capacitor for high voltage of the present invention can precisely set the pressure of gas release by using the elastic force of the plate-shaped elastic member 124 of the permanent safety vent valve 120, and releases or seals the gas based on the set pressure. By making it possible, the above-described operation can be repeatedly performed depending on whether gas is generated.

The can-type electric double layer capacitor for high voltage of the present invention can be applied to the battery manufacturing industry.

100: electric double layer capacitor 110: can-type case
111: metal cover 120: safety vent valve
121: outer housing 122: gasket
123: gas blocking block 124: plate-shaped elastic member
125: inner housing 126: disk spring
127: ball 128: gas permeable membrane
129: anti-condensation film

Claims (13)

a can-type case in which an electrode assembly impregnated with an electrolyte is accommodated therein, and a metal cover having an insertion hole formed on one side is connected thereto; and
and a safety vent valve inserted and connected to an insertion hole formed in the metal cover of the can-type case,
The electrolyte includes C ₄ H ₆ O (divinyl sulfone) and C ₃ H ₂ O (vinylene carbonate) and C ₁₂ H ₁₀ (biphenyl),
The safety vent valve is
A first hollow cylindrical member inserted into an insertion hole formed in the metal cover of the can-type case and having a first through-hole communicating with the inside of the can-type case, and the first hollow cylindrical member communicating with the first through-hole an outer housing having a hollow disk having two through-holes formed thereon and a second hollow cylindrical member having a third through-hole to communicate with the second through-hole of the hollow disk;
A gas discharge hole is disposed in the center of the outer housing so as to communicate with the first through hole formed in the first hollow cylindrical member, the second through hole formed in the hollow disk, and the fourth through hole formed in the cylindrical protruding member, respectively. a gasket having an insertion hole inserted into the cylindrical protrusion member at the other side of the gas discharge hole and having an insertion groove formed along the outer circumferential surface on the other side of the outer circumferential surface;
a gas blocking block disposed inside the outer housing to support an upper portion of the gasket and having first and second gas blocking holes communicating with the gas discharge hole of the gasket in the center thereof;
A first hollow disk having an insertion hole into which a ball is inserted in the center; a plate-shaped elastic member formed therebetween and having a connecting member for connecting the first hollow disk and the second hollow disk;
an inner housing disposed inside the outer housing to support the plate-shaped elastic member;
a disc spring disposed inside the outer housing to support the inner housing;
a ball disposed between the gas blocking block and the plate-shaped elastic member to contact or fall into the gas blocking hole according to the gas pressure generated inside the can-shaped case or the pressure of the plate-shaped elastic member; and
A can-type electric double layer capacitor for high voltage, wherein a gas permeable membrane is disposed between the outer housing and the gasket, and a condensation preventing layer is disposed between the gas blocking block and the plate-shaped elastic member. delete According to claim 1,
The size of the outer diameter of the first hollow cylindrical member is smaller than the outer diameter of the hollow disk and the outer diameter of the second hollow cylindrical member, the outer diameter of the hollow disk and the outer diameter of the second hollow cylindrical member are equal to each other, and The diameter length of the third through hole of the second hollow cylindrical member is greater than the diameter length of the first through hole of the first hollow cylindrical member and the diameter length of the second through hole of the hollow disk, and the diameter length of the first through hole and the second through hole length The two through-holes have the same diameter and length, and the hollow disk extends from one side and protrudes, and a cylindrical protrusion member having a fourth through-hole to communicate with the second through-hole is formed. delete According to claim 1,
The first gas blocking hole of the gas blocking block is formed in a cylindrical shape, and diameter lengths of one side and the other side are the same, and the second gas blocking hole of the gas blocking block is formed in a cylindrical shape, and the diameter length of one side is the diameter length of the other side. larger than, the diameter of the other side of the second gas blocking hole is the same as the diameter of one side of the first gas blocking hole, the diameter of one side of the second gas blocking hole is greater than the diameter of the ball, the second The depth of the gas barrier hole is smaller than the diameter of the ball. Can-type electric double layer capacitor for high voltage. delete According to claim 1,
The connecting member of the plate-shaped elastic member may include two or more straight-shaped members spaced apart from each other at a predetermined angle with respect to the center of the first hollow disk; and
A can-type electric double-layer capacitor for high voltage comprising two or more curved members spaced at regular intervals based on the center of the first hollow disk and connected to the two or more straight members. According to claim 1,
The inner housing includes a housing hollow disk supporting one side of the plate-shaped elastic member and having a first housing through hole in the center;
and a housing hollow cylindrical member formed to extend to the other side of the housing hollow disk and having a second housing through-hole communicating with the central first housing through-hole,
The diameter length of the first housing through-hole of the housing hollow disk is larger than the diameter of the first hollow disk of the plate-shaped elastic member and smaller than the diameter of the second hollow disk, and the second housing through-hole of the housing hollow cylindrical member A can-type electric double layer capacitor for high voltage that is larger than the outer diameter of the silver gasket, the outer diameter of the gas barrier block, and the outer diameter of the plate-shaped elastic member. 9. The method of claim 8,
A can-type electric double-layer capacitor for high voltage, wherein a curling part is formed on the other side of the hollow cylindrical member of the housing and inserted into an insertion groove formed on the other side of the outer circumferential surface of the gasket to be fastened. According to claim 1,
The material of the outer housing is an insulating material made of polypropylene, the material of the gasket and the ball is rubber, respectively, and the material of the gas blocking block, the plate-shaped elastic member, and the inner housing is metal. . delete According to claim 1,
The gas-permeable membrane is a non-woven fabric or fabric manufactured using a fiber coated with a fluororesin layer on the surface, and the material of the fiber is one of polyvinylidene fluoride resin and polyacrylonitrile resin. delete

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