KR101523588B1 - Secondary battery assembly - Google Patents

Abstract

Disclosed is a secondary battery assembly comprising, in a case, a plurality of second battery cells and a controller for controlling charging and discharging thereof. The disclosed second battery assembly comprises: a plurality of second battery cells; a battery box for accommodating and protecting a plurality of second battery cells; a controller for controlling charging and discharging of a plurality of second battery cells; and a controller box fixedly coupled to the upper end or lower end of the battery box to accommodate the controller inside and protect the same, wherein the controller box has a circuit board accommodation unit to which a circuit board is fixedly equipped and a plurality of circuit board decks deposited in a plurality of layers; and the controller has a plurality of circuit boards in which circuits are formed to perform predetermined functions; and a plurality of circuit boards is configured to be distributed and accommodated in a plurality of circuit board decks.

Description

Secondary battery assembly < RTI ID = 0.0 >

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a secondary battery, and more particularly, to a secondary battery assembly in which a plurality of secondary battery cells and a controller for controlling charging and discharging thereof are included in the case.

The secondary battery is a battery that repeats discharging and charging, and is applied to small electronic devices such as a mobile phone, and large devices such as automobiles and satellites. Secondary batteries applied to devices such as automobiles and satellites are designed to electrically connect a plurality of secondary battery cells and form a stack together to meet high voltage, large power, and long usage time have.

A conventional secondary battery includes a plurality of secondary battery cells and a case enclosing them. A controller for controlling charging and discharging of a plurality of secondary battery cells is implemented on a single printed circuit board (PCB) and mounted inside or outside the case. However, when the circuit board on which the controller is implemented is disposed inside the case, the plurality of secondary battery cells and the heat generated in the circuit board are combined during the charging and discharging processes, resulting in malfunction and failure due to overheating , Short-circuiting may occur between the circuit board and the electric wires and terminals connecting the electrodes of the plurality of secondary battery cells in the case.

On the other hand, when the circuit board on which the controller is mounted is disposed outside the case, the electric wires connecting the plurality of secondary battery cells and the circuit board are long, so that there is a high possibility of occurrence of noise and a possibility of physical damage . Further, there is a need for additional space for fixing the circuit board on which the controller is implemented. Meanwhile, since the controller is implemented on one circuit board regardless of the positions where the circuit boards are disposed, the parts where the circuits performing the different functions are mixed are mixed, and the possibility of noise due to the interference of these parts is increased.

Korean Registered Patent No. 10-1051446

The present invention provides a secondary battery assembly in which a plurality of secondary battery cells and a controller for controlling charging and discharging thereof are separately disposed and the controllers are also divided into a plurality of circuit boards according to functions.

According to the present invention, there is provided a secondary battery assembly in which a controller box separating and accommodating circuit boards of a controller divided into a plurality of circuit boards is stacked on or below a battery box accommodating the secondary battery cells do.

The present invention relates to a secondary battery including a plurality of secondary battery cells, a battery box for receiving and protecting the plurality of secondary battery cells, a controller for controlling charging and discharging of the plurality of secondary battery cells, And a controller box fixedly coupled to an upper end or a lower end of the battery box. The controller box includes a circuit board accommodating portion on which a circuit board is fixedly mounted, and a plurality of And a plurality of circuit boards, each of which has a circuit formed therein so as to perform a predetermined function, wherein the plurality of circuit boards are divided into a plurality of circuit board decks Thereby providing a battery assembly.

The plurality of circuit boards of the controller may include a CEM circuit board corresponding to a battery cell equalization module (CEM) that performs a function of uniformly charging the plurality of secondary battery cells, And a BCM circuit board corresponding to a battery control module (BCM) for controlling the state of the plurality of secondary battery cells and controlling a state of the plurality of secondary battery cells, wherein the plurality of circuit board decks A CEM circuit board deck to which a CEM circuit board is fixedly mounted and a BCM circuit board deck which is stacked on the CEM circuit board deck to be spaced further from the battery box than the CEM circuit board deck and on which the BCM circuit board is fixedly mounted .

The plurality of circuit boards of the controller may include a CEM circuit board corresponding to a battery cell equalization module (CEM) performing a function of uniformly charging the plurality of secondary battery cells, A PBCM circuit board corresponding to a primary battery control module (PBCM) that performs a function of determining the states of the plurality of secondary battery cells, and a function of the main battery control module And an RBCM circuit board corresponding to a redundant battery control module (RBCM) that operates in place of the main battery control module when the main battery control module is not operating, The substrate deck includes a CEM circuit board deck on which the CEM circuit board is fixedly mounted, A PBCM circuit board deck on which the PBCM circuit board is fixedly mounted, and a PBCM circuit board deck which is stacked on the PBCM circuit board deck more distant from the battery box than the PBCM circuit board deck, And an RBCM circuit board deck on which the RBCM circuit board is fixedly mounted.

The controller box may be made of metal.

The battery box may include a plurality of secondary battery cells arranged in a matrix and arranged in a row so that the lower ends of the plurality of secondary battery cells are inserted one by one, A bottom wall, a box wall surrounding the plurality of secondary battery cells and fixed to the bottom plate, and upper ends of the plurality of secondary battery cells, wherein the upper ends of the plurality of secondary battery cells are inserted one by one A plurality of cell mounting holes may be formed spaced apart from each other, and may have an upper holder fixedly coupled to the box wall.

The upper holder includes a plurality of first beams and a second beam extending linearly so as to intersect with each other and defining the plurality of cell mounting holes, and a plurality of first and second beams, at least one of the first beam and the second beam, And a latching protrusion protruding inwardly from the cell mounting hole. The latching jaw is hooked on the outer peripheral edge of the upper end of the plurality of secondary battery cells to prevent the upper holder from falling.

The outer end of the upper holder is fixedly coupled to the box wall by a bolt, and a spring is interposed between the head of the bolt and the outer end of the upper holder.

According to the present invention, a plurality of secondary battery cells and a controller for controlling the charging and discharging thereof are separately arranged, and the controller is also divided into a plurality of circuit boards according to the functions, do. Accordingly, the plurality of secondary battery cells and the controller are separated from each other and protected from intrusion of external impacts or external impurities, and a short between the electric wires and terminals connecting the electrodes of the plurality of secondary battery cells and the circuit board And overheating due to the combination of the heat generated in the plurality of secondary battery cells and the circuit board, and thus malfunctions and failures, are prevented.

In addition, since the circuit board on which the controller is implemented and the plurality of secondary battery cells are electrically connected to the connector by short electric wires, there is less possibility of noise generation and less possibility of physical damage. In addition, since the controller is divided into a plurality of circuit boards according to functions and separated into separate circuit board decks, the possibility of occurrence of noise due to interference is reduced.

1 is an exploded perspective view illustrating a secondary battery assembly according to an embodiment of the present invention.
2 is a plan view showing the battery box of FIG. 1 and a plurality of secondary battery cells housed therein.
FIG. 3 is a perspective view explaining a configuration for fixing a plurality of secondary battery cells in the battery box of FIG. 2. FIG.
Figure 4 is a perspective view of the top holder of Figure 3 viewed from below.
FIG. 5 is a block diagram illustrating a configuration of a controller included in a secondary battery assembly according to an embodiment of the present invention. Referring to FIG.

Hereinafter, a secondary battery assembly according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The terminology used herein is a term used to properly express the preferred embodiment of the present invention, which may vary depending on the intention of the user or operator or the custom in the field to which the present invention belongs. Therefore, the definitions of these terms should be based on the contents throughout this specification.

FIG. 1 is an exploded perspective view showing a secondary battery assembly according to an embodiment of the present invention, FIG. 2 is a plan view showing a battery box of FIG. 1 and a plurality of secondary battery cells housed therein, 2 is an exploded perspective view illustrating a structure for fixing a plurality of secondary battery cells in a battery box. FIG. 4 is a perspective view of the upper holder of FIG. 3 viewed from below. 1 to 4, a secondary battery assembly 1 according to an embodiment of the present invention includes eight secondary battery cells 3 and eight secondary battery cells 3 housed therein A controller 70 for controlling the charging and discharging of the eight secondary battery cells 3 and the controller 70 are accommodated and protected inside the battery box 10, And a controller box 50 fixedly coupled to the upper end of the box 10.

The battery box 10 accommodates eight secondary battery cells 3 arranged in a 4 × 2 matrix in a state in which the pair of electrodes 4 and 5 protrude upward from the upper side in an inner space, A bottom plate 11, a box wall 20, and an upper holder 30. The bottom plate 11 is formed with eight cell seating grooves 13 in which the lower ends of eight secondary battery cells 3 are inserted one by one on the upper side. The eight cell seating grooves 13 are spaced apart from the adjacent cell seating grooves 13 at regular intervals and arranged in a 4x2 matrix. The eight cell seating grooves 13 have a plurality of first ribs 15 protruding from the top surface of the bottom plate 11 and extending parallel to the Y axis and a plurality of second ribs 15 projecting from the top surface of the bottom plate 11 And is defined by a plurality of second ribs 16 extending parallel to the X axis so as to intersect the first ribs 15.

The box wall 20 surrounds the eight secondary battery cells 3 and is fixed to the outer peripheral portion of the bottom plate 11. The box wall 20 is spaced apart from each other by eight secondary battery cells 3, A pair of first wall portions 21 formed parallel to each other and spaced apart from each other such that eight secondary battery cells 3 are perpendicular to the first wall portion 21, And a second wall portion 25. The cross section of the box wall 20 is formed by alternately connecting the first wall portion 21 and the second wall portion 25 with the side ends of the first wall portion 21 and the side ends of the second wall portion 25 being coupled, do. The first wall portion 21 and the second wall portion 25 are tightly coupled to the inner circumferential surface of the second wall portion 25 by a bolt 45 and a coupling portion 36 provided at an outer end of the upper holder 30, The bolt fastening portions 22 and 26 are formed to protrude inward.

The upper holder 30 fixes the upper ends of the eight secondary battery cells 3 and forms eight cell mounting holes 38 in which the upper ends of the eight secondary battery cells 3 are inserted one by one. Eight cell mounting holes 38 are spaced apart at regular intervals from neighboring cell mounting holes 38 and are arranged in a 4x2 matrix. The eight cell mounting holes 38 include a plurality of first beams 31 extending in parallel with the Y axis and a plurality of second beams 31 extending in parallel with the X axis so as to intersect the first beams 31. [ Is defined by beam (32).

The upper holder 30 further includes a hooking protrusion 34 protruding horizontally from the upper end of the first beam 31 to the inside of the cell mounting hole 38. Therefore, eight secondary battery cells 3 are inserted into the eight cell seating grooves 13 of the bottom plate 11 (see FIG. 2) one by one, and the box wall 20 is fixedly connected to the bottom plate 11 And the upper holder 30 is aligned with the eight secondary battery cells 3 and lowered so that the eight secondary battery cells 3 are inserted one by one into the eight cell mounting holes 38, The latching jaw 34 is caught by the upper outer peripheral edge of the upper holder 3 so that the upper holder 30 does not fall any more. The first beam 31 contacts the upper end of the side surface 8 of the secondary battery cell 3 and the second beam 32 contacts the upper end of the front surface 7 of the secondary battery cell 3. The spacing between adjacent secondary battery cells 3 arranged in the same column in the 4x2 matrix is uniformly matched to the width of the second beam 32. [

When the upper holder 30 is mounted in alignment with the eight secondary battery cells 3, the plurality of engaging portions 36 protruding outward from the outer end of the upper holder 30 are engaged with the plurality of bolt fastening portions 22, 26 and fastening the bolts 45 so that the screw bodies 48 of the bolts 45 penetrate the engaging portions 36 and the bolt fastening portions 22, Is fixed to the box wall (20). The upper holder 30 is fixed in the inner space of the box wall 20 so that the outer surface of the stack of secondary battery cells 3 arranged in a 4x2 matrix and the inner surface of the box wall 20 are spaced apart from each other Respectively.

A washer spring 40 is placed on the upper side of the engaging portion 36 before the engaging portion 36 and the bolt fastening portions 22 and 26 are fastened by the bolts 45. [ A washer spring 40 is provided between the head 46 and the engaging portion 36 of the bolt 45 when the engaging portion 36 and the bolt fastening portions 22 and 26 are fastened by the bolt 45. [ ). The washer spring 40 is a ring-shaped leaf spring having a through hole through which the screw body 48 of the bolt 45 passes. The inner peripheral portion around the inner peripheral surface of the through hole protrudes above the outer peripheral portion around the outer peripheral surface do. Therefore, the engaging portion 36 of the upper holder 30 is elastically biased by the washer spring 40 so as to strongly adhere to the upper surfaces of the bolt fastening portions 22, 26. Therefore, even if a strong shock or vibration occurs from the outside of the secondary battery assembly 1, the upper holder 30 and the secondary battery cell 3 are fully shocked or vibrated by the washer springs 40 and transmitted.

The upper holder 30 may be made of a polyoxymethylene resin or a metal whose surface is coated with a polyoxymethylene resin. The metal may be aluminum (Al), for example. The polyoxymethylene resin is a resin also referred to as a product name delrin. Due to its rigidity, adjacent secondary battery cells 3 can be fixed in a state of being separated from each other, It is possible to prevent an accident such as a short circuit or a short circuit of the secondary battery cell 3. In addition, the eight secondary battery cells 3 can be protected by buffering an external impact due to elasticity. On the other hand, when the upper holder 30 is formed of a metal material coated with a polyoxymethylene resin on the surface, heat conduction characteristics of the metal can help dissipate heat in the inner space of the secondary battery case 10.

The bottom plate 11 and the box wall 20 may be made of a metal such as aluminum (Al) or an aluminum alloy, for example, to maintain structural rigidity and promote heat radiation. In particular, the bottom plate 11 may be formed of a metal material whose surface is coated with polyoxymethylene resin. In this case, the bottom plate 11 maintains the structural rigidity and promotes heat radiation, as well as absorbs the external impact transmitted from the bottom plate 11 to the inside due to the elasticity of the polyoxymethylene resin, The battery cell 3 can be protected.

FIG. 5 is a block diagram illustrating a configuration of a controller included in a secondary battery assembly according to an embodiment of the present invention. Referring to FIG. Referring to FIGS. 1 and 5 together, the controller 70 is called a so-called BMS (battery management system) and includes a plurality of circuit boards 71, 73, and 75 that are formed with circuits to perform predetermined functions. The controller box 50 includes a plurality of circuit board decks each having circuit board receiving portions 52, 57 and 62 on which the plurality of circuit boards 71, 73 and 75 are fixedly mounted, (51, 56, 61), and a cover (66). The plurality of circuit boards 71, 73 and 75 are distributed and accommodated in the plurality of circuit board receiving portions 52, 57 and 62 of the plurality of circuit boards 71, 73 and 75, respectively.

Specifically, the controller (BMS) 70 includes a battery cell equalization module (CEM) 72 functioning to uniformly charge the eight secondary battery cells 3, a battery cell equalization module A primary battery control module (PBCM) 74 for controlling the primary battery control module 72 and the secondary battery cell 3 and determining the state of the eight secondary battery cells 3, And a redundant battery control module (RBCM) 76 that operates in place of the main battery control module 74 when the main battery control module 74 does not operate.

The battery cell equalization module (CEM) 72 has a function of uniformly charging the eight secondary battery cells 3 and a function of preventing overcharging, overdischarging, overcurrent, and short-circuiting of the secondary battery cell 3 . The main battery control module (PBCM) 74 and the auxiliary battery control module (RBCM) 76 measure the voltage and current of the secondary battery cell 3 in order to grasp the state of the secondary battery cell 3, The temperature of the secondary battery cell 3 is measured through the sensor. The main battery control module (PBCM) 74 and the auxiliary battery control module (RBCM) 76 are connected to a computer mounted on an apparatus powered by the secondary battery assembly 1, (Not shown), and is supplied with power necessary for the operation of the controller (BMS) 70 from a power supply (not shown).

The CEM circuit board 71 on which the circuit performing the function of the battery cell equalization module (CEM) 72 is formed is mounted on the CEM circuit board receiving portion 52 of the CEM circuit board deck 51, The PBCM circuit board 73 on which the circuit performing the function of the PBCM 74 is mounted is mounted on the PBCM circuit board receiving portion 57 of the PBCM circuit board deck 56 and the auxiliary battery control module The RBCM circuit board 75 on which the circuit for performing the function of the RBCM circuit board deck 61 is mounted is mounted on the RBCM circuit board receiving portion 62 of the RBCM circuit board deck 61.

The CEM circuit board deck 51 is coupled to the top edge of the box wall 20 to close the interior space of the battery box 10. The PBCM circuit board deck 56 is coupled to the top edge of the CEM circuit board deck 51 to close the CEM circuit board receiving portion 52 of the CEM circuit board deck 51. The RBCM circuit board deck 61 is connected to the PBCM And is coupled to the upper edge of the circuit board deck 56 to close the PBCM circuit board receiving portion 57 of the PBCM circuit board deck 56. [ The cover 66 is coupled to the upper edge of the RBCM circuit board deck 61 to close the RBCM circuit board receiving portion 62 of the RBCM circuit board deck 61. The circuit board decks 51, 56, 61 and the cover 66 stacked in three layers may be made of a metal such as aluminum (Al) or aluminum alloy, for example, in order to maintain structural rigidity and promote heat radiation.

As described above, the eight secondary battery cells 3 and the controller (BMS) 70 are separated from each other and protected from external impacts or intrusion of external impurities. The electrodes 4, 5 of the eight secondary battery cells 3 73 and 75 constituting the controller 70 are prevented from being shorted and the eight secondary battery cells 3 and the circuit boards 71, 73, and 75 are prevented from being overheated due to heat integration, malfunctions and failures thereof.

Since the circuit boards 71, 73 and 75 on which the controller (BMS) 70 is implemented and the eight secondary battery cells 3 are electrically connected to the connector by short electric wires, Less likely to cause physical damage. Since the controller (BMS) 70 is divided into a plurality of circuit boards 71, 73 and 75 according to functions and separately housed in the separate circuit board decks 51, 56 and 61, the possibility of occurrence of noise due to interference .

In the embodiment shown in FIG. 1, the controller box 50 is stacked on the battery box 10 and the controller (BMS) 70 is divided into three circuit boards. However, The secondary battery assembly of Fig. For example, the controller box may be disposed under the battery box, the controller (BMS) may include one BCM circuit board corresponding to the battery control module (BCM), one CEM corresponding to the battery cell equalization module (CEM) And a circuit board may be provided.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

1: secondary battery assembly 3: secondary battery cell
10: battery box 11: bottom plate
20: box wall 30: upper holder
51, 56, 61: circuit board deck 70: controller

Claims (7)

A plurality of secondary battery cells; A battery box that accommodates and protects the plurality of secondary battery cells; A controller for controlling charging and discharging of the plurality of secondary battery cells; And a controller box that houses and protects the controller and is fixedly coupled to the upper or lower end of the battery box,
The controller box includes a plurality of circuit board decks each having a circuit board accommodating portion on which a circuit board is fixedly mounted,
Wherein the controller is provided with a plurality of circuit boards on which circuits are formed so as to perform predetermined functions, and the plurality of circuit boards are distributed and accommodated in the plurality of circuit board decks. The method according to claim 1,
The plurality of circuit boards of the controller may include a CEM circuit board corresponding to a battery cell equalization module (CEM) that performs a function of uniformly charging the plurality of secondary battery cells; And a BCM circuit board corresponding to a battery control module (BCM) that controls the battery cell equalization module and performs a function of determining a state of the plurality of secondary battery cells,
The plurality of circuit board decks of the controller box include: a CEM circuit board deck to which the CEM circuit board is fixedly mounted; And a BCM circuit board deck which is stacked on the CEM circuit board deck so as to be spaced further from the battery box than the CEM circuit board deck, and on which the BCM circuit board is fixedly mounted. The method according to claim 1,
The plurality of circuit boards of the controller may include a CEM circuit board corresponding to a battery cell equalization module (CEM) that performs a function of uniformly charging the plurality of secondary battery cells; A PBCM circuit board corresponding to a primary battery control module (PBCM) that controls the battery cell equalization module and grasps the states of the plurality of secondary battery cells; And a redundant battery control module (RBCM) that performs the same function as that of the main battery control module and operates on behalf of the main battery control module when the main battery control module does not operate An RBCM circuit board,
The plurality of circuit board decks of the controller box include: a CEM circuit board deck to which the CEM circuit board is fixedly mounted; A PBCM circuit board deck which is stacked on the CEM circuit board deck so as to be further away from the battery box than the CEM circuit board deck and on which the PBCM circuit board is fixedly mounted; And an RBCM circuit board deck which is stacked on the PBCM circuit board deck so as to be further away from the battery box than the PBCM circuit board deck, and on which the RBCM circuit board is fixedly mounted. The method according to claim 1,
Wherein the controller box is made of metal. The method according to claim 1,
The battery box may include a plurality of secondary battery cells arranged in a matrix and arranged in a row so that the lower ends of the plurality of secondary battery cells are inserted one by one, Bottom plate; A box wall surrounding the plurality of secondary battery cells and fixed to the bottom plate; And an upper holder fixed to an upper end of the plurality of secondary battery cells, the upper holder being formed with a plurality of cell mounting holes to which upper ends of the plurality of secondary battery cells are inserted one by one and being fixed to the box wall; And a second battery assembly (100). 6. The method of claim 5,
The upper holder includes: a plurality of first beams and a second beam that extend straight to intersect with each other and define the plurality of cell mounting holes; And a jaw protruding from the at least one of the first beam and the second beam toward the inside of the plurality of cell mounting holes,
Wherein the latching jaws are hooked on outer peripheral corners of upper ends of the plurality of secondary battery cells to prevent the upper holder from dropping. The method according to claim 6,
Wherein an outer end of the upper holder is fixedly coupled to the box wall by a bolt and a spring is interposed between the head of the bolt and the outer end of the upper holder. Battery assembly.

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