BR112018076516B1 - ENERGY STORAGE DEVICE - Google Patents

Abstract

It is an energy storage device capable of preventing the entry of rainwater, washing water and the like into an enclosure. This energy storage device is characterized by comprising a secondary battery, a safety valve, a drain through hole and a casing having a sealed structure, wherein: the casing comprises an external container for housing the secondary battery and a top lid arranged on the external container; the top cover has a recessed portion on the top surface thereof; the safety valve is arranged inside the recessed portion; and the drainage through hole is provided such that it passes through a side wall of the recessed portion.

Description

TECHNICAL FIELD

[0001] The present invention relates to an energy storage device.

PREVIOUS TECHNIQUE

[0002] In recent years, secondary batteries have been used for various applications, and particularly secondary batteries that have a large capacity have been used for applications such as automobile power supplies and electrical energy storage.

[0003] When a secondary battery is used as a single battery, a voltage of the secondary battery may be lower than a voltage required for a device in some cases. In such a case, it is necessary to connect a plurality of secondary batteries in series and increase a supply voltage to a desired voltage. Additionally, in a single battery, there are cases in which it is not possible to supply a sufficient amount of electricity required for a device. In such a case, it is necessary to connect a plurality of secondary batteries in parallel and increase a quantity of supplied electricity to a desired quantity.

[0004] For this reason, electrical energy can be supplied from an energy storage device that has a plurality of secondary batteries connected together in series or in parallel housed in a housing to a device. Additionally, an energy storage device having a battery monitoring unit (BMU) configured to monitor a plurality of secondary batteries built therein is known (e.g., refers to Patent Document 1). The BMU generally measures a voltage or similar of each secondary battery and detects overcharging and overdischarging at the time of charging and discharging. Additionally, the BMU may also have the function of maintaining a voltage balance between the respective secondary batteries.

[0005] On the other hand, lead storage batteries are generally installed in automobiles, motorcycles and the like. There is a disadvantage that a lead storage battery is relatively heavy. In this way, an in-vehicle energy storage device was developed, which includes a relatively lightweight lithium-ion battery.

RELATED ART DOCUMENT PATENT DOCUMENT

[0006] Patent Document 1: Unexamined Patent Application, First Publication in JP 2015-8121 SUMMARY

PROBLEMS TO BE SOLVED BY THE INVENTION

[0007] When a lithium-ion battery is used for a vehicle energy storage device, it is necessary to install an electronic device such as a BMU in an energy storage device to prevent overcharging or the like. Therefore, when rainwater, washing water, or the like enters an energy storage device, a BMU or wiring may corrode, which may cause the energy storage device to fail and cause electrical leakage.

[0008] The present invention was produced in view of such circumstances and provides an energy storage device capable of preventing the ingress of rainwater, wash water or the like into an enclosure. MEANS TO SOLVE THE PROBLEM

[0009] The present invention provides an energy storage device that includes: a secondary battery, a casing that has a sealed structure, a safety valve and a drain through hole, wherein the casing includes an external container that has the secondary battery accommodated therein and a top cover disposed above the outer container, the top cover has an upper surface having a concave portion formed therein, the safety valve is disposed in the concave portion and the drainage through hole is provided to pass through a side wall of the concave portion.

ADVANTAGE OF THE INVENTION

[00010] An energy storage device of the present invention can be charged and discharged due to the energy storage device including a secondary battery.

[00011] The energy storage device of the present invention includes a housing that has a sealed structure. In this way, it is possible to prevent water from entering the housing and it is possible to prevent an energy storage device from failing due to rainwater, washing water and the like.

[00012] The housing includes an outer container that has a secondary battery accommodated therein and a top cover disposed above the outer container. In this way, it is possible to manufacture an energy storage device that has a secondary battery housed in a housing that has a sealed structure by placing the secondary battery in an external container and closing the external container using a top lid.

[00013] The energy storage device of the present invention includes a safety valve. In this way, even when a gas generated in the secondary battery is discharged into the housing and an internal pressure in the housing increases, the gas can be discharged outside the housing through the safety valve. For this reason, it is possible to avoid expansion or rupture of the casing.

[00014] The safety valve is arranged in a concave portion of the top cover. In this way, it is possible to provide a safety valve without projecting from a main upper surface of the top cover and it is possible to adapt a size of the energy storage device to an installation space. Additionally, it is possible to effectively use a space below the main upper surface of the top cover.

[00015] The energy storage device of the present invention includes a drainage through hole provided for passing through a side wall of the concave portion. This way, even when rainwater or washing water enters the concave portion, it is possible to drain water through this passage hole. In this way, it is possible to avoid water remaining in the concave portion that has the safety valve arranged in it and it is possible to prevent water from entering the casing through the safety valve. BRIEF DESCRIPTION OF THE DRAWINGS

[00016] Figure 1 is a schematic perspective view of an energy storage device, in accordance with an embodiment of the present invention.

[00017] Figure 2 is a schematic cross-sectional view of the energy storage device taken along the dashed line A-A of Figure 1.

DESCRIPTION OF MODALITIES

[00018] An energy storage device in the present invention includes a secondary battery (a secondary battery cell), a casing having a sealed structure, a safety valve and a drainage through hole, the casing including an external container which has the secondary battery accommodated therein and a top cover disposed above the external container, the top cover has an upper surface which has a concave portion formed therein, the safety valve is disposed in the concave portion and the drainage passage hole is provided to pass through a side wall of the concave portion.

[00019] The safety valve included in the energy storage device of the present invention preferably includes an exhaust cylinder and a plug configured to close an outlet on an external side of the exhaust cylinder. According to such a safety valve, when an internal pressure of the casing increases, a plug elastically deforms due to this internal pressure, a gap can be formed between the plug and the exhaust cylinder and a gas inside the casing can be discharged into the exterior through this gap. When the pressure in the casing decreases to atmospheric pressure, the plug is stored back to its original shape and in this way the inside of the casing can become a sealed space again.

[00020] The casing included in the energy storage device of the present invention preferably includes an internal cover disposed between the secondary battery accommodated in the external container and the upper cover. The inner cover may function as a wiring board in which wiring configured to connect the secondary battery to an external connection terminal or wiring configured to connect the secondary battery to a battery monitoring unit is provided.

[00021] The energy storage device in the present invention preferably includes a battery monitoring unit configured to monitor the secondary battery and the battery monitoring unit is preferably disposed between the inner cover and the top cover . When the battery monitoring unit can monitor the secondary battery, it is thus possible to improve the safety of the energy storage device.

[00022] Also, it is desirable that the battery monitoring unit is accommodated in the housing so that it is not located between the secondary battery and the safety valve. In this way, it is possible to arrange the battery monitoring unit in a position outside a discharge path through which a gas generated in the secondary battery is discharged from the safety valve and to prevent adhesion of a gas generated in the secondary battery or a electrolyte solution ejected from the secondary battery to the battery monitoring unit.

[00023] The energy storage device in the present invention preferably additionally includes a protective case disposed between the inner cover and the top cover and it is preferred that the protective case accommodates the battery monitoring unit and has its interior tight. By providing the protective case, even if a solution in the secondary battery leaks, the leaked electrolyte solution does not enter the protective case that has the battery monitoring unit accommodated therein and it is possible to avoid damage to the battery monitoring unit.

[00024] The secondary battery included in the energy storage device in the present invention preferably includes a positive electrode that includes a positive electrode active material, a negative electrode that includes a negative electrode active material, a separator sandwiched between the positive electrode and the negative electrode, a non-aqueous electrolyte and a container that has the positive electrode, the negative electrode, the separator and the non-aqueous electrolyte accommodated therein.

[00025] An embodiment of the present invention will be described below with reference to the drawings. A constitution shown in the drawings and the following description is merely an example and the scope of the present invention is not limited to what is shown in the drawings and the following description.

[00026] Figure 1 is a schematic perspective view of the energy storage device in this embodiment and Figure 2 is a schematic cross-sectional view of the energy storage device taken along the dashed line A-A in Figure 1.

[00027] An energy storage device 40 in this embodiment includes: a secondary battery 5, a casing 4 that has a sealed structure, a safety valve 6 and a drainage through hole 9, the casing 4 includes an external container 1 which has the secondary battery 5 accommodated therein and an upper cover 3 disposed above the external container 1, the upper cover 3 has an upper surface which has a concave portion 8 formed therein, the safety valve 6 is disposed in the concave portion 8 and the drainage through hole 9 is provided for passing through a side wall of the concave portion 8.

[00028] Additionally, the energy storage device 40 in this embodiment may include a battery monitoring unit 15 or a protective case 16.

[00029] The energy storage device 40 in this embodiment will be described below. 1. ENERGY STORAGE DEVICE

[00030] The energy storage device 40 in this embodiment is, for example, an energy storage device used for an automobile power supply, a motorcycle power supply, a photovoltaic power generation storage, a backup power supply and the like. Additionally, the energy storage device 40 may be provided to be capable of being charged and discharged. Furthermore, the energy storage device 40 may be a sealed energy storage device or an in-vehicle energy storage device. 2. SECONDARY BATTERY

[00031] The energy storage device 40 includes the secondary battery 5 housed in the housing 4. The secondary battery 5 has a battery terminal positive electrode and a battery terminal negative electrode (the battery terminal positive electrode or the battery terminal negative electrode). battery terminal is referred to as a "battery terminal 28" in this specification). Additionally, the secondary battery 5 can be accommodated in the outer container 1 in the casing 4 so that the positive battery terminal electrode and the negative battery terminal electrode are arranged on an upper side.

[00032] Furthermore, the energy storage device 40 may include a plurality of secondary batteries 5 accommodated in the housing 4. The plurality of secondary batteries 5 may be connected together in parallel or in series. Additionally, the plurality of secondary batteries 5 can be electrically connected together via wiring and the battery terminals 28 of two neighboring batteries 5 can be electrically connected together by bringing the battery terminals 28 into contact with each other or joining them together. if the battery terminals 28.

[00033] Each of the secondary batteries 5 is, for example, a lithium ion battery, a sodium ion battery, a nickel/hydrogen battery, a nickel/cadmium battery and the like. The secondary battery 5 may be a sealed battery. Additionally, the secondary battery 5 may be of an angular shape, a cylindrical type or a bag type. The secondary battery 5 may include a positive electrode 21 that includes a positive electrode active material, a negative electrode 22 that includes a negative electrode active material, a separator 23 sandwiched between the positive electrode 21 and the negative electrode 22, an electrolyte not aqueous 24 and a container 25 having the positive electrode 21, the negative electrode 22, the separator 23 and the non-aqueous electrolyte 24 accommodated therein. 3. HOUSING, SAFETY VALVE AND DRAIN HOLE

[00034] The energy storage device 40 includes the housing 4 configured to accommodate the secondary battery 5 and which has a sealed structure. The housing 4 includes the outer container 1 which has the secondary battery 5 accommodated therein and the upper cover 3 disposed above the outer container 1. Additionally, the housing 4 may include an inner cover 2 disposed between the outer container 1 and the upper cover. 3. The secondary battery 5 can be accommodated in the housing 4 having a sealed structure by inserting the secondary battery 5 into the external container 1 before these members constituting the housing 4 are connected together.

[00035] The inner cover 2 may function as a wiring board wherein a wiring 33 configured to connect the secondary battery 5 to an external connection terminal 30 or the wiring 33 configured to connect the secondary battery 5 to the battery monitoring unit 15 is provided. Additionally, the inner cover 2 may have a slot through which the battery terminal 28 of the secondary battery 5 passes and the battery terminal 28 may be joined to a connecting portion 23 provided on an upper surface of the inner cover 2. In this way , the wiring 33 on the top surface of the inner cover 2 and the secondary battery 5 can be electrically connected to each other.

[00036] The inner cover 2 may have a through hole 35 immediately above the safety valve 6. In this way, when a gas is generated from the secondary battery 5, the gas may be discharged outside the energy storage device 40 using the through hole 35 and the safety valve 6 as a discharge path. In this way, it is possible to prevent the housing 4 from being filled with a gas generated from the secondary battery 5 and to prevent the battery monitoring unit 15 from being corroded due to the gas generated from the secondary battery 5.

[00037] The members constituting the casing 4 can be adhered so that the interior of the casing 4 is a sealed space. In this way, it is possible to prevent the ingress of water or the like into the casing 4 and to improve the safety and service life characteristics of the energy storage device 40. The members constituting the casing 4 can be adhered using, for example, a sticker. It should be noted that a material of the shell 4 may be a plastic.

[00038] The top cover 3 has an upper surface that has the concave portion 8 formed thereon. Additionally, the safety valve 6 (relief valve) is provided in the concave portion 8 of the top cover 3. The safety valve 6 has a structure in which, when an internal pressure of the casing 4 increases abnormally, the valve opens automatically, a gas inside the shell 4 is discharged outside, the internal pressure decreases, and when the internal pressure decreases, the valve closes automatically. By providing the safety valve 6 in the top cover 3, even when a gas generated in the secondary battery 5 is discharged into the casing 4 and an internal pressure of the casing 4 increases, it is possible to discharge the gas outside the casing 4 through the safety valve 6. For this reason, it is possible to avoid expansion, rupture or damage to the casing 4.

[00039] The safety valve 6 may include an exhaust cylinder 11 and a plug 12 configured to close an outlet on an external side of the exhaust cylinder 11. For example, as in the energy storage device 40 shown in Figure 2, exhaust cylinder 11 and plug 12 can be provided. The exhaust cylinder 11 may be provided in the top cover 3. Additionally, an opening in the exhaust cylinder 11 may be provided to pass through the top cover 3. A material of the plug 12 may be rubber and the plug 12 may be formed into a shape in which the plug 12 covers an outer end of the exhaust cylinder 11. The interior of the casing 4 can be produced in a space sealed by the rubber elasticity of the plug 12. Furthermore, when an internal pressure of the casing 4 increases, the plug 12 elastically deforms due to this internal pressure, a gap can be formed between the plug 12 and the exhaust cylinder 11 and a gas inside the casing 4 can be discharged to the outside through this gap. When the pressure in the casing 4 decreases to atmospheric pressure, the plug 12 is stored back to its original shape and thus the inside of the casing 4 can become a sealed space.

[00040] The safety valve 6 may include a valve pressing plate above the plug 12. In this way, when a gas within the casing 4 is discharged through the safety valve 6, it is possible to prevent removal of the plug 12 at from exhaust cylinder 11.

[00041] The safety valve 6 is arranged in the concave portion 8 of the top cover 3. For this reason, the safety valve 6 can be provided without protruding from a main upper surface of the top cover 3 and a device size energy storage module 40 can be adapted to an installation space. Additionally, it is possible to effectively use a space below the main upper surface of the top cover 3. When the energy storage device 40 is, for example, a battery for a motorcycle, it is necessary to form the energy storage device 40 to that the energy storage device 40 can be installed on various motorcycles of various types of vehicles and it is necessary to match the energy storage device 40 to a predetermined size. For this reason, when the safety valve 6 is provided protrudes from the main upper surface of the upper cover 3, an unavailable dead space is generated above the main upper surface. By providing the safety valve 6 in the concave portion 8, it is possible to avoid the generation of such dead space. Additionally, for example, it is possible to accommodate a battery monitoring unit (BMU) below the main upper surface of the top cover 3 and it is possible to increase the size of the secondary battery 5. In this way, it is possible to increase a battery capacity of the charging device. energy storage 40.

[00042] The energy storage device 40 has the drainage passage hole 9 provided for passing through the side wall of the concave portion 8. Additionally, the drainage passage hole 9 may have an inlet located on a surface of the concave portion of inner wall 8 and an outlet located on a side surface of the top cover 3. In this way, even if rainwater or washing water enters the concave portion 8, it is possible to drain water through the passage hole 9. In this way, it is It is possible to avoid water remaining in the concave portion 8 which has the safety valve 6 arranged therein and prevents water from entering the casing 4 through the safety valve 6.

[00043] The inlet of the through hole 9 can be provided near the bottom part of the concave portion 8. Additionally, the through hole 9 can be provided to be inclined downwards from the inlet towards the outlet.

[00044] The drain through hole 9 may be a through hole configured to pass through a part of the top cover 3. Additionally, the drain through hole 9 can be formed by forming a tubular portion in the top cover 3 The drain through hole 9 can be formed by combining a tubular member with the top cover 3. 4. BATTERY MONITORING UNIT

[00045] The battery monitoring unit 15 is a part configured to monitor the secondary battery 5. The battery monitoring unit 15 may be arranged between the inner cover 2 and the upper cover 3. Additionally, the battery monitoring unit 15 may not be provided to overlap the concave portion 8. The battery monitoring unit 15 may not be arranged to be located in the discharge path through which a gas generated from the secondary battery 5 is discharged from the safety valve 6 .

[00046] The battery monitoring unit 15 may be, for example, an electronic circuit board obtained by mounting electronic components thereon. The battery monitoring unit 15 may be a part of an electronic circuit board. The battery monitoring unit 15 may include a plurality of electronic circuit boards. Additionally, the battery monitoring unit 15 can be accommodated in the protective case 16. The battery monitoring unit 15 can be electrically connected to the secondary battery 5, a fuse, a relay or the external connection terminal 30. In this way, the battery monitoring unit 15 to monitor the battery.

[00047] The battery monitoring unit 15 may be provided to measure a voltage of each secondary battery 5. Additionally, the battery monitoring unit 15 may be provided to detect overcharging based on voltage measurement results of the secondary battery 5 The battery monitoring unit 15 may be provided to output a signal to disconnect the connection between the secondary battery 5 and the external connection terminal 30 via the fuse or the relay when it detects overload in at least one of the secondary batteries 5. In this way, it is possible to forcibly cut off a current and improve the safety of the energy storage device 40 when overload is generated in at least one of the secondary batteries 5.

[00048] The battery monitoring unit 15 may be provided to detect over-discharge of the secondary battery 5, to measure a temperature inside the housing 4, or to detect an overcurrent. Additionally, the battery monitoring unit 15 can be provided to maintain a balance between voltages of a plurality of secondary batteries 5 accommodated in the external container 1. In this way, it is possible to reduce damage to the plurality of secondary batteries 5 generated due to imbalance in voltages. of the secondary batteries 5 and increase the service life characteristics of the energy storage device 40. It should be noted that the battery monitoring unit 15 may include a balancer that corresponds to each of the secondary batteries 5. 5. PROTECTIVE CASE

[00049] The protective case 16 is a case that has the battery monitoring unit 15 accommodated therein, is accommodated in the casing 4 and is sealed so that the inside thereof is a sealed space. For this reason, it is possible to separate a space that has the secondary battery 5 in the housing 4 accommodated therein from a space that has the battery monitoring unit 15 accommodated therein. With this constitution, even if a solution in the secondary battery 5 leaks, the leaked electrolyte solution does not enter the protective case 16 which has the battery monitoring unit 15 accommodated therein and it is possible to avoid damage to the battery monitoring unit 15. For this reason, it is possible to improve the security of the energy storage device 40. The protective case 16 can be arranged between the inner cover 2 and the upper cover 3. The protective case 16 is, for example, a plastic case.

[00050] As in the energy storage device 40 shown in Figure 2, a sealed space having the battery monitoring unit 15 disposed therein may be formed by the protective case 16 and a sealing member 17. Furthermore, this The sealed space may be formed by the protective case 16, the sealing member 17 and the housing 4, may be formed by the protective case 16 and the housing 4, and may be formed only by the protective case 16. The sealing member 17 is , for example, a rubber blade. As in the energy storage device 40 shown in Figure 2, the sealing member 17 may be provided to line an opening of the protective case 16. Additionally, the sealing member 17 may be provided between the housing 4 and an upper surface of a side wall of the protective case 16. The sealing member 17 can be pressed between the protective case 16 and the casing 4. In this way, the sealing member 17, the protective case 16 and the casing 4 can be brought into contact with each other. contact between themselves and the interior of the protective case 16 may become a sealed space. Additionally, for example, the interior of the protective case 16 can be produced from a sealed space by adhering the protective case 16 to the casing 4 using an adhesive.

[00051] The protective case 16 may include a connection terminal on an external side of the protective case 16. This connection terminal is electrically connected to the battery monitoring unit 15. Additionally, a portion of a wiring between the protective case 16. connection and the battery monitoring unit 15 can be embedded in the protective case 16. In this way, the connection terminal and the battery monitoring unit 15 can be electrically connected to each other in a state in which the inside of the protective case 16 is a sealed space. Additionally, the protective case 16 may include a plurality of connection terminals. In this way, the battery monitoring unit 15 can be electrically connected to wires between secondary batteries 5 and to wires between the secondary batteries 5 and the external connection terminal 30 and the battery monitoring unit 15 can monitor a voltage of each between the secondary batteries 5. The connection terminal can be joined to a terminal wiring on the battery monitoring unit side of the inner cover 2. In this way, the battery monitoring unit 15 and the secondary battery 5 can be electrically connected between itself through the wiring 33. BRIEF DESCRIPTION OF REFERENCE SYMBOLS 1: External container 2: Internal cover 3: Upper cover 4: Casing 5: 5a, 5b: Secondary battery 6: Safety valve 8: Concave portion 9: Passage hole drain 11: Exhaust cylinder 12: Plug 15: Battery monitoring unit 16: Protective case 17: Sealing member 21: Positive electrode 22: Negative electrode 23: Separator 24: Non-aqueous electrolyte 25: Container 28: Battery terminal 30, 30a, 30b: External connection terminal 32: Connection portion 33: Wiring 35: Through hole 40: Energy storage device

Claims (6)

1. Energy storage device (40) comprising: a secondary battery (5, 5a, 5b), a housing (4) having a sealed structure, a safety valve (6) and a drainage through hole ( 9), characterized by the fact that the casing (4) includes an external container (1) which has the secondary battery (5, 5a, 5b) accommodated therein and an upper cover (3) disposed above the external container (1) , the upper cover (3) has an upper surface that has a concave portion (8) formed therein, the safety valve (6) is disposed in the concave portion (8), and the drainage passage hole (9) is provided to pass through a side wall of the concave portion (8), the safety valve (6) has a convex shape along the side wall of the concave portion (8) and is provided without the top cover (3) projecting from a main upper surface of the top cover (3), the safety valve (6) has an exhaust cylinder (11) and the cover (12) configured to close an external outlet of the exhaust cylinder (11), and the cover (12) is arranged above a drainage inlet through the hole (9) 2. Energy storage device (40) according to claim 1, characterized in that the exhaust cylinder (11) is provided in the upper cover (11) and is configured to close the external outlet of the exhaust cylinder (11) so that a gap can be formed between the cover (12) and the exhaust cylinder (11) by elastic deformation, the drain passage hole (9) has an inlet close to a bottom of the concave portion (8 ), and a lower end of the cover (12) is configured to be disposed above the inlet of the drain passage hole (9). 3. Energy storage device (40), according to claim 1 or 2, characterized by the fact that it further comprises a battery monitoring unit (15) configured to monitor the secondary battery (5, 5a, 5b), wherein the battery monitoring unit (15) is accommodated in the housing (4) so as not to be located between the secondary battery (5, 5a, 5b) and the safety valve (6). 4. Energy storage device (40), according to claim 3, characterized by the fact that it further comprises a protective case (16) arranged between the secondary battery (5, 5a, 5b) and the top cover (3 ), wherein the protective case (16) has the battery monitoring unit (15) accommodated therein and an interior thereof is sealed. 5. Energy storage device (40), according to any one of claims 1 to 4, characterized by the fact that the secondary battery (5, 5a, 5b) includes a positive electrode (21), which includes an active material positive electrode; a negative electrode (22), which includes a negative electrode active material; a separator (23) pressed between the positive electrode (21) and the negative electrode (22); and a non-aqueous electrolyte (24); and a container (25) that has the positive electrode (21), the negative electrode (22), the separator (23) and the non-aqueous electrolyte (24) accommodated therein. 6. Energy storage device (40), according to any one of claims 1 to 5, characterized in that an inner cover (2) is provided between the upper cover (3) and the outer container (1).