KR102214547B1 - Battery Pack - Google Patents

Abstract

The present invention relates to a battery pack, and more particularly, discloses a battery pack capable of maintaining a constant temperature of the battery pack and uniformly managing the temperature of each battery included in the battery pack.

Description

Battery Pack {Battery Pack}

The present invention relates to a battery pack, and more particularly, to a battery pack capable of efficiently and uniformly managing the temperature of the battery pack.

A secondary battery is a battery that converts chemical energy into electrical energy to supply power to an external circuit, and when discharged, it receives external power and converts electrical energy into chemical energy to store electricity, and is generally called a storage battery. . These secondary batteries are widely used because they have the advantage of being able to recharge and increase their capacity.

Among secondary batteries, lithium-ion batteries have three times higher operating voltage than nickel-cadmium batteries or nickel-metal hybrid batteries, and have excellent energy density characteristics per unit weight, so they are cylindrical or prismatic lithium batteries with characteristics such as long life and high capacity. Several ion batteries are connected in series to form one battery pack, which is used in high-power hybrid vehicles.

However, as described above, when dozens of batteries are connected in series or in parallel, heat is generated in each battery, i.e., cell, constituting the battery pack when charging or discharging the battery, and charging or discharging performance of the battery pack according to the temperature of each cell Since is different, it is very important to keep the temperature of each cell properly.

As a prior art for solving this problem, there is a Korean Patent Laid-Open Publication No. 10-2016-0024187, “a vehicle battery cooling device”, and in the prior art, a battery cell, a heat sink disposed between the battery cells, and A heat exchange pad disposed so as to allow heat exchange with the heat sink and having a cooling passage through which a cooling medium flows is provided to cool heat generated from each battery cell.

However, the prior patent has a problem in that the direction of the cooling medium flowing inside the cooling channel is simply directed from one battery cell to the other battery cell, so that the temperature difference between each battery cell is large, which degrades the performance of the battery module. Even if a problem due to overheating occurs in only a part of each of the battery cells forming a battery, there is a problem in that the entire battery pack needs to be replaced, and the development of a battery pack capable of solving this problem is urgent.

1. Korean Patent Publication No. 10-2018-0080614 ("Water-cooled battery module for electric vehicles") 2. Korean Patent Publication No. 10-2016-0030724 ("Water-cooled battery module and water-cooled battery cooling device using the same") 3. Korean Patent Laid-Open Publication No. 10-2016-0024187 ("Vehicle battery cooling device")

The present invention was conceived to solve the above problems, and an object of the present invention is to provide a battery pack capable of constantly managing the temperature of the battery pack.

In addition, it is to provide a battery pack capable of uniformly managing the temperature of each battery included in the battery pack.

On the other hand, the object of the present invention is not limited to the object mentioned above, and other objects not mentioned will be clearly understood from the following description.

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It includes a storage array formed by connecting a plurality of storage housings in which a battery is received and a battery insertion slot is formed to surround the battery in a straight line, and a storage unit for exchanging heat with the battery, provided at both ends of the storage unit and the storage unit A heat exchange unit having at least one pair of heat exchange passages formed to perform heat exchange and communicate with each other from one end to the other end and provided at one or both ends of each of the heat exchange units, and the heat exchange medium is circulated and recovered in the heat exchange passage. A temperature control unit for cooling or heating to a temperature, wherein the heat exchange media circulating through the paired heat exchange passages provided in each heat exchange unit flow in opposite directions, and are disposed adjacent to the heat exchange unit among the battery insertion slot The battery insertion slot is characterized in that a spacer groove formed concave toward the heat exchange part is further formed to limit the thermal conductivity of the battery insertion slot disposed adjacent to the heat exchange part.
In this case, the storage unit may include a storage array formed by connecting a plurality of storage housings having a battery insertion slot surrounding the battery in a straight line between the pair of heat exchange parts.

In addition, a plurality of storage arrays are arranged from one side to the other to form a storage system, and a first storage array, which is one of the storage arrays, and a second storage array disposed adjacent to the first storage array are included in each. It is characterized in that the storage housings are arranged to be staggered.

In detail, the storage housing has a concave groove formed at a connection portion between the storage housings arranged adjacent to each other by curved outer sides of the storage housing, and each concave groove of the first storage array has a curved storage housing of the second storage array. It is characterized in that the outside is seated.

In addition, among the battery insertion slots, the battery insertion slot disposed adjacent to the heat exchange part may further include a spacer groove formed concave toward the heat exchange part.

In addition, the battery pack includes an upper cover covering an upper surface of the receiving unit and a lower cover covering a lower surface of the receiving unit, wherein at least one of the upper cover and the lower cover includes the respective batteries on the opposite surface of the receiving unit. It is characterized in that a battery fixing groove in a shape corresponding to the insertion slot is further formed.

In this case, the storage array is formed in an odd number, and the upper cover and the lower cover are formed in the same shape.
In addition, the battery pack according to another embodiment of the present invention has a first seating groove formed to surround one side of the battery on one side, and a second seating groove formed to surround the other side of the battery on the other side. Includes a storage system in which a plurality of formed storage plates are arranged from one side to the other side, and the first and second mounting grooves of the storage plates arranged adjacent to each other between each storage plate are engaged with each other to insert a battery A slot is formed to allow storage of the battery, and a storage unit that heats exchanges with the battery inserted in the battery insertion slot, is provided at both ends of the storage unit to exchange heat with the storage unit, and communicates with each other from one end to the other end inside each One or more pairs of heat exchange passages are formed so that the heat exchanger medium circulating through the pair of heat exchange passages flows in opposite directions, provided at one end or both ends of each heat exchange unit, and heat exchange in the heat exchange passage A temperature control unit that cools or heats the heat exchange medium through which the medium is circulated and recovered to a certain temperature, a compression bolt passing through each of the storage plates, and a compression nut that is screwed to one end of the compression bolt so that each storage plate is in close contact with each other. However, the cross-sectional shape of the first and second seating grooves is formed in an arc shape with a central angle of less than 180 degrees so that a clearance is formed between the first and second seating grooves arranged to face each other. It is characterized.

In addition, the battery pack is characterized in that it comprises a crimping bolt penetrating each of the storage plates, and a crimping nut screwed to one end of the crimping bolt so that each storage plate is in close contact with each other.

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In addition, a plurality of the first and second seating grooves are formed in a straight line between the pair of heat exchange parts, and the first and second seating grooves are formed to be formed at positions alternately with each other. do.

In detail, the second seating groove is characterized in that it is disposed between the first seating grooves disposed adjacent to each other.

In addition, the battery pack includes an upper cover covering an upper surface of the receiving unit and a lower cover covering a lower surface of the receiving unit, wherein at least one of the upper cover and the lower cover includes the respective batteries on the opposite surface of the receiving unit. It is characterized in that a battery fixing groove in a shape corresponding to the insertion slot is further formed.

In this case, the storage plate is formed in an even number, and the upper cover and the lower cover are formed in the same shape.

In addition, a thermal pad is inserted between the storage unit and the heat exchange unit.

In addition, each of the receiving part and the heat exchange part is fixed through a bolt, and an insulating material anchor is inserted around the bolt.

The battery pack of the present invention having the above configuration has an effect of preventing a problem due to overcooling or overheating of the battery pack by maintaining the temperature of the battery pack at a constant temperature through the configuration of the temperature controller.

In addition, through the configuration of a pair of heat exchange passages and a temperature control unit that distributes the heat exchange medium in opposite directions to each of the heat exchange passages, there is an effect of improving the performance of the battery pack according to the heat balance by reducing the temperature deviation between each battery. .

In addition, through the configuration of the separation groove, there is an effect that the cooling and heating rates of each battery are uniform and the weight of the battery pack can be reduced.

In addition, there is an effect that the battery pack can be formed more compactly through the configuration of each of the storage arrays and storage plates arranged to be staggered with each other.

In addition, there is an effect that the battery included in the battery pack can be placed in the correct position through the battery fixing groove formed in the upper cover or the lower cover.

In addition, the upper cover and the lower cover are manufactured in the same shape through the configuration of an odd number of storage arrays or an even number of storage plates, thereby reducing processing costs.

In addition, there is an effect of improving heat exchange efficiency through a compression bolt, a compression nut, and a thermal pad.

1 is a perspective view of a battery pack according to a first embodiment of the present invention.
2 is a perspective view of a battery pack according to a first embodiment of the present invention.
3 is a perspective view illustrating a heat exchange part of a battery pack according to a first embodiment of the present invention.
4 is a cross-sectional view taken along the line AA' showing the storage system of the battery pack according to the first embodiment of the present invention.
5 is a perspective view showing a thermal pad and an anchor bolt of a battery pack according to a first embodiment of the present invention.
6 is a perspective view showing an upper cover or a lower cover of a battery pack according to a first embodiment of the present invention.
7 is an exploded perspective view showing an accommodating part of a battery pack according to a second exemplary embodiment of the present invention.
8 is a plan view showing an accommodating part of a battery pack according to a second exemplary embodiment of the present invention.

Hereinafter, an embodiment of the present invention as described above will be described in detail with reference to the drawings.

[First embodiment]

As shown in FIG. 1, the battery pack 10 according to the first preferred embodiment of the present invention includes a storage unit 100, a heat exchange unit 300, a temperature control unit (not shown), and a cover unit 500. ).

First, a brief description of the role and coupling relationship of each component is as follows.

The cover part 500 is composed of an upper cover 510 and a lower cover 530, serves to cover and protect the upper and lower surfaces of the receiving part 100, and at the same time, the battery pack according to the first preferred embodiment of the present invention. It serves to electrically connect the batteries included in (10).

The receiving part 100 is disposed between the upper cover 510 and the lower cover 530 as shown in FIG. 2. A battery insertion slot into which a battery can be inserted is provided in the storage unit 100 to accommodate a battery in the battery insertion slot, and heat exchange with the stored battery.

The heat exchange unit 300 is provided at both ends of the receiving unit 100, and a heat exchange passage 310 is formed therein to heat exchange with the receiving unit 100.

The temperature control unit is to allow the temperature of the battery housed in the battery pack 10 to fall within a certain temperature range, and is provided at one or both ends of each heat exchange unit to circulate and recover the heat exchange medium in the heat exchange passage 310. It serves to cool or heat to a preset temperature.

In summary, the storage unit 100 directly contacts the battery to heat exchange by absorbing heat from the battery or radiating heat to the battery, and the heat exchange unit 300 transfers the heat absorbed by the storage unit 100 again or , Transfers heat to be transferred to the battery to the storage unit 100. In addition, the temperature controller recovers and cools the heat transferred from the heat exchange unit 300 through the heat exchange medium flowing through the heat exchange unit 300, or circulates the heated heat exchange medium to the heat exchange passage 310 of the heat exchange unit 300. To transfer heat.

When describing the configuration of each part in more detail, as shown in FIG. 3, the storage unit 100 has a shape surrounding the battery, and the storage housing 131 having the battery insertion slot 132 formed thereon is a pair of heat exchangers. A plurality of units 300 are connected in a straight line to form the storage array 130.

Here, the battery may be a cylindrical battery, and accordingly, the outer surfaces of the battery insertion slot 132 and the storage housing 131 are curved in a cylindrical shape. In addition, a concave groove 133 is formed between the storage housings 131 disposed adjacent to each other due to the shape of the curved storage housings 131.

In addition, contact protrusions 137 are formed at both ends of the storage array 130 to extend a predetermined length to both sides for contact with the heat exchange unit 300 and have flat ends thereof.

In addition, both ends of the storage array 130, that is, the battery insertion slots 132 disposed adjacent to each of the heat exchange units 300 are concavely spaced apart grooves 135 inside the contact protrusions 137, In this case, the direction of formation of the spaced groove 135 is preferably formed toward the heat exchange part 300.

The separation groove 135 artificially reduces the heat transfer area of the storage array 130 disposed at both ends of the storage array 130 to cool or heat between the batteries disposed at both ends of the storage array 130 and the battery disposed at the center. By alleviating the difference in speed, the temperature difference between the batteries forming the storage array 130 is reduced, and the effect of reducing the weight of the battery cells is achieved.

Meanwhile, a plurality of storage arrays 130 are arranged from one side to the other to form a storage system 110.

In detail, the storage array 130 is arranged so that a plurality of storage arrays 130 are connected to each other in a direction perpendicular to the extension direction of the storage array 130, and at this time, the first one of the storage arrays 130 constituting the storage system 110 The storage array 130a includes a portion of the curved outer surface of the second storage array 130b disposed adjacent to each other in each concave groove 133 of the first storage array 130a so as to be connected to the first storage array 130a. They are placed alternately.

Each storage array 130 constituting the storage system 110 is arranged as described above, so that the battery pack 10 according to the first embodiment of the present invention provides a more compact battery pack 10 This is possible.

As described above, the heat exchange unit 300 is provided at both ends of the storage unit 100, that is, the storage system 110, and the heat exchange unit 300 includes all of the storage arrays 130 forming the storage unit 100. At least one pair of the heat exchange passages 310 formed to communicate with each other from one end to the other along a direction in which the contact protrusion 137 and one side are in contact is formed therein.

At this time, the temperature controller connected to the heat exchange unit 300 flows in each of the heat exchange passages 310 paired with each other, that is, the first heat exchange passage 310a and the second heat exchange passage 310b, as shown in FIG. The heat exchange medium is circulated so that the flow directions of the heat exchange medium are opposite to each other.

To this end, the temperature controller is provided one at each end of the heat exchange unit 300, and each is connected to communicate with the first heat exchange passage 310a and the second heat exchange passage 310b. At this time, the temperature controller connected to one side of the heat exchange unit 300 recovers the heat exchange medium flowing from the second heat exchange passage 310b, cools or heats it, and then distributes it to the second heat exchange passage 310b, and the temperature connected to the other side of the heat exchange unit The controller may recover the heat exchange medium flowing from the first heat exchange passage 310a, cool or heat it, and then distribute it to the first heat exchange passage 310a.

Alternatively, the temperature control unit is provided as a single unit on one side or the other side of the heat exchange unit 300 and is connected to communicate with the first heat exchange channel 310a and the second heat exchange channel 310, and the temperature control unit is a second heat exchange channel ( 310b) is connected to collect and cool or heat the heat exchange medium flowing into the second heat exchange passage 310b, and the first heat exchange passage 310a is connected to the other side of the heat exchange unit 300 to which the temperature control unit is connected. A connection pipe (not shown) connecting the second heat exchange passage 310b may be provided.

The temperature control unit and the heat exchange passage 310 have a coupling relationship as described above, so that the distribution of heat is prevented from being concentrated on one side, so that cooling or heating is evenly performed along the extending direction of the heat exchange unit 300 so that each storage array Reduce the temperature deviation between (130).

Meanwhile, as shown in FIG. 5, a thermal pad 330 is inserted into the contact surface between the heat exchange unit 300 and the storage unit 100.

The thermal pad 330 is made of a material having a high thermal conductivity, and is in close contact with the unevenness that may be formed in each of the storage unit 100 and the heat exchange unit 300 to heat exchange between the storage unit 100 and the heat exchange unit 300 It aims to increase the efficiency.

The heat exchange unit 300 and the receiving unit 100 are coupled by inserting a bolt 350 into a plurality of coupling holes 301 formed to communicate with each other, at this time, the coupling hole 301 and the bolt 350 It is preferable that the anchor 351 is made of an insulating material and is inserted in the shape of a bolt to prevent a short circuit between each battery included in the receiving unit 100.

The cover part 500 has a plate shape as shown in FIG. 6 and includes an upper cover 510 covering an upper surface of the receiving unit and a lower cover 530 covering a lower surface of the receiving unit.

At this time, the upper cover 510 and the lower cover 530 are further formed with a battery fixing groove 501 having a shape corresponding to each battery insertion slot and the storage array on opposite surfaces of the storage unit. That is, in each battery insertion slot of the storage array, when the battery is inserted, the central portion of the battery is seated, and the upper and lower portions of the battery are in the battery fixing grooves 501 formed in the upper cover 510 and the lower cover 530, respectively. It is settled and its position is fixed.

In addition, the upper cover 510 and the lower cover 530 are coupled to the heat exchanger through screws, so that the arrangement between the components may be fixed.

Meanwhile, it is preferable that the storage array of the battery pack 10 according to the first embodiment of the present invention is formed in an odd number.

When the number of storage arrays is formed in an odd number, the shape of the upper cover 510 and the lower cover 530 is the same, so that both the upper cover 510 and the lower cover 530 can be manufactured with one casting. This easy effect can be expected.

[Second Example]

The battery pack according to the second preferred embodiment of the present invention has the same shape and configuration as in the first embodiment, but has a different shape of the accommodating part, and a description of the remaining configurations excluding the accommodating part will be omitted.

The storage part 100 includes a storage plate 170, the storage plate 170 is formed to be elongated in a straight line between the pair of heat exchange parts, as shown in FIG. A plurality of first seating grooves 171 formed to surround one side of the battery are formed along the formation direction of the storage plate 170, and a second seating groove 172 formed on the other side to appreciate the other side of the battery. ) Are formed in a plurality along the formation direction of the storage plate 170.

Here, the formation position of the second seating groove 172 is disposed between the first seating grooves 171 disposed adjacent to each other, so that the first seating groove 171 and the second seating groove 172 are staggered. It is preferable to be arranged in a form.

In addition, separation holes 136 in the form of penetrating the storage plate 170 are formed at both ends of the storage plate 170 so that the cooling or heating rate between the central portion and both ends of the storage plate 170 is uniform. May be.

As shown in FIG. 8, a plurality of storage plates 170 are arranged from one end to the other end along the extending direction of the heat exchanger to form one storage system 150, each of which is disposed adjacent to each other. 170) between the first and second seating grooves 171 and second seating grooves 172 formed in each of the storage plates 170 are engaged with each other to form a battery insertion slot 173, and the battery insertion slot 173 Allow the battery to be inserted.

The storage plates 170 included in the storage system 150 are in close contact with each other by coupling the pressing bolts 190 through each of the pressing nuts 191.

At this time, the cross-sectional shape of the first and second seating grooves 171 and 172 is formed in an arc shape rather than a semicircular shape, and is formed on the storage plates 170 adjacent to each other, and is arranged to face each other. It is preferable that the seating groove 171 and the second seating groove 172 are formed so that the battery insertion slot 173 formed by coupling with each other does not completely surround the outer surface of the battery inserted into the battery insertion slot 173.

This, by forming an artificial clearance between the first mounting groove 171 and the second mounting groove 172 arranged to face each other, the first mounting groove according to the diameter of the battery inserted into each battery insertion slot 173 By allowing the 171 and the second mounting groove 172 to be more closely contacted to the battery and spaced between the storage plates 170, the effect of smooth ventilation can be expected.

On the other hand, if the storage plate 170 is formed in an even number, as in the first embodiment, the upper cover and the lower cover can be manufactured in the same shape, so that economical and easy manufacturing effects can be achieved.

The technical idea should not be interpreted as limited to the above-described embodiment of the present invention. As well as a variety of application ranges, various modifications can be made at the level of those skilled in the art without departing from the gist of the present invention claimed in the claims. Therefore, these improvements and changes will fall within the scope of protection of the present invention as long as it is apparent to those skilled in the art.

10: battery pack
100: storage unit
110: storage system
130: storage array 130a: first storage array 130b: second storage array
131: storage housing
132: battery insertion slot
133: recessed groove
135: separation groove
137: contact protrusion
150: storage system
170: storage plate
171: first mounting groove 172: second mounting groove
173: battery insertion slot
190: crimping bolt 191: crimping nut
300: heat exchange part
301: coupling hole
310: heat exchange passage 310a: first heat exchange passage 310b: second heat exchange passage
330: thermal pad
350: bolt 351: anchor
500: cover
501: battery fixing groove
510: upper cover 530: lower cover

Claims (15)

delete delete delete delete delete delete delete A plurality of storage plates with a first mounting groove formed on one side to surround one side of the battery and a second mounting groove formed on the other side to surround the other side of the battery are arranged from one side to the other. A storage system, wherein the first and second mounting grooves of the storage plates disposed adjacent to each other are engaged with each other to form a battery insertion slot to allow storage of the battery, A storage unit for exchanging heat with the battery inserted in the battery insertion slot;
One or more pairs of heat exchange passages are formed at both ends of the receiving unit to heat exchange with the receiving unit, and formed to communicate with each other from one end to the other end, and heat exchange media circulating through the pair of heat exchange passages are in opposite directions. Heat exchanger characterized in that flowing;
A temperature control unit provided at one or both ends of each of the heat exchange units to cool or heat the heat exchange medium to be circulated and recovered in the heat exchange passage to a predetermined temperature;
A pressing bolt penetrating through each of the storage plates; And
Including; a crimping nut screwed to one end of the crimping bolt so that each receiving plate is in close contact with each other,
The cross-sectional shape of the first and second seating grooves is formed in an arc shape with a central angle of less than 180 degrees to form a gap between the first and second seating grooves arranged to face each other. Battery pack.
delete The method of claim 8,
A plurality of the first and second seating grooves are formed in a straight line between the pair of heat exchange parts,
The first mounting groove and the second mounting groove is a battery pack, characterized in that the formation position is formed to cross each other.
The method of claim 10,
The second mounting groove,
Battery pack, characterized in that disposed between the first mounting grooves disposed adjacent to each other.
The method of claim 8,
The battery pack,
An upper cover covering an upper surface of the receiving part and a lower cover covering a lower surface of the receiving part,
A battery pack, wherein at least one of the upper cover and the lower cover further includes a battery fixing groove having a shape corresponding to each of the battery insertion slots on an opposite surface of the receiving part.
The method of claim 12,
The storage plate is formed in an even number,
The battery pack, characterized in that the upper cover and the lower cover are formed in the same shape.
The method of claim 8,
A battery pack, characterized in that a thermal pad is inserted between the storage unit and the heat exchange unit.
The method of claim 8,
Each of the storage unit and the heat exchange unit are fixed through bolts,
A battery pack, characterized in that an anchor made of an insulating material is inserted around the bolt.

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