(19)
(11)EP 3 261 153 B1

(12)EUROPEAN PATENT SPECIFICATION

(45)Mention of the grant of the patent:
13.05.2020 Bulletin 2020/20

(21)Application number: 17176692.6

(22)Date of filing:  19.06.2017
(51)International Patent Classification (IPC): 
H01M 2/10(2006.01)
H01M 10/6556(2014.01)
H01M 10/613(2014.01)
H01M 2/30(2006.01)
H01M 10/42(2006.01)
H01M 10/6551(2014.01)
H01M 2/20(2006.01)
H01M 10/625(2014.01)

(54)

SECONDARY BATTERY PACK

SEKUNDÄRBATTERIEPACK

BLOC-BATTERIE SECONDAIRE


(84)Designated Contracting States:
AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

(30)Priority: 17.06.2016 KR 20160075922

(43)Date of publication of application:
27.12.2017 Bulletin 2017/52

(73)Proprietor: SK Innovation Co., Ltd.
Seoul 03188 (KR)

(72)Inventors:
  • KWON, Dae Won
    34124 Daejeon (KR)
  • KANG, Ho Chul
    34124 Daejeon (KR)
  • KWON, O Sung
    34124 Daejeon (KR)
  • CHO, Seok Chun
    34124 Daejeon (KR)
  • CHO, Sei Hoon
    34124 Daejeon (KR)

(74)Representative: Stolmár & Partner Patentanwälte PartG mbB 
Blumenstraße 17
80331 München
80331 München (DE)


(56)References cited: : 
EP-A1- 2 955 780
EP-A2- 2 362 463
DE-A1-102014 112 802
US-A1- 2010 052 692
US-A1- 2016 036 019
EP-A1- 3 002 804
WO-A1-2015/083569
JP-A- 2015 076 187
US-A1- 2010 151 312
US-A1- 2016 126 531
  
      
    Note: Within nine months from the publication of the mention of the grant of the European patent, any person may give notice to the European Patent Office of opposition to the European patent granted. Notice of opposition shall be filed in a written reasoned statement. It shall not be deemed to have been filed until the opposition fee has been paid. (Art. 99(1) European Patent Convention).


    Description

    BACKGROUND OF THE INVENTION


    1. Field of the Invention



    [0001] The present invention relates to a secondary battery pack in embodiments thereof.

    2. Description of the Related Art



    [0002] Research into a rechargeable secondary battery capable of being charged and discharged has been actively conducted for various devices such as a digital camera, a cellular phone, a laptop computer, a hybrid automobile, and the like. An example of the secondary battery includes a nickel-cadmium battery, a nickel-metal hydride battery, a nickel-hydrogen battery, and a lithium secondary battery. Among them, the lithium secondary battery, which has operating voltage of 3.6 V or more, is used as a power supply of a portable electronic device, or is used for a high output hybrid automobile. A plurality of lithium secondary batteries are connected in series with each other to be used for a high output hybrid automobile. Since this lithium secondary battery has operating voltage three times higher than that of the nickel-cadmium battery or the nickel-metal hydride battery and has excellent energy density characteristics per unit weight, which exceed that of the nickel-cadmium battery or the nickel-metal hydride battery, the lithium secondary battery has rapidly increased.

    [0003] Referring to FIG. 1, a conventional battery pack 1 includes a printed circuit board, a connector, a wiring harness, and the like, as well as covers and protective structures for protecting these components. As shown in FIG. 1, a wiring harness 2 includes many protective structures such as a stand portion 3 into which the wiring harness 2 is inserted and aligned, an aligning portion 4 for protecting the wiring harness 2, a stand plate 5 on which the stand portion 3 is mounted and aligned, coupling ribs 6, an aligning cover 7, and the like. As such, the conventional battery pack 1 includes many components for protecting the wiring harness 2. Therefore, the number of assembling processes and a size of conventional battery pack 1 are increased.

    [0004] The conventional battery pack 1 includes components for protecting a battery management system (BMS), a connector, and the like, as well as protector components for protecting the wiring harness. Herein, protective components such as upper and lower covers of the battery pack make up a considerable portion of the battery pack. As such, costs, a weight, and a volume density of the conventional battery module tend to increase due to the overlapping portions of a cartridge, a partition, the upper and lower covers, or the like.

    [0005] As a technique relating to the battery pack known in the related art, an apparatus for containing battery pack including a stack in which a plurality of battery housing units are provided is disclosed in Korean Patent Registration No. 10-1355961 (registered on January 21, 2014). Further battery pack examples are described in EP2955780 A1 and EP2362463 A2.

    [SUMMARY OF THE INVENTION]



    [0006] An object of the present invention is to provide a secondary battery pack capable of reducing the number of duplicative protective structures disposed therein and integrating a plurality of functions into one.

    [0007] In addition, another object of the present invention is to provide a secondary battery pack capable of reducing the number of parts by integrating a lower cover structure, a cooling structure, and a vehicle mounting bracket of a secondary battery module into one unit.

    [0008] Further, another object of the present invention is to provide a secondary battery pack capable of reducing a volume and a weight density with the reduced number of parts.

    [0009] Further, another object of the present invention is to provide a secondary battery pack capable of assembling with the reduced number of processes.

    [0010] The invention is defined in the appended claims.

    [0011] According to the embodiments of the present invention, it is possible to provide the secondary battery pack capable of saving costs by reducing the number of protective structures duplicately disposed therein and integrating the plurality of functions into one.

    [0012] Further, it is possible to reduce the number of parts by integrating the lower cover structure, the cooling structure, and the vehicle mounting bracket of the secondary battery module into one unit.

    [0013] Further, it is possible to reduce the number of parts and reduce the volume and weight density.

    [0014] Further, it is possible to reduce the number of assembling processes of the secondary battery pack.

    BRIEF DESCRIPTION OF THE DRAWINGS



    [0015] The above and other objects, features and other advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:

    FIG. 1 is a perspective view showing a conventional battery module;

    FIG. 2 is an exploded perspective view schematically illustrating a secondary battery pack according to an embodiment of the present invention;

    FIG. 3 is a perspective view illustrating a first structure according to an embodiment of the present invention;

    FIG. 4 is a cross-sectional view illustrating a first structure according to an embodiment of the present invention with a cooling structure;

    FIG. 5 is a cross-sectional view illustrating a first structure according to an embodiment of the present invention with secondary battery modules;

    FIG. 6A is a perspective view illustrating a battery cell and FIG. 6B is a exploded view illustrating portion of secondary battery module according to an embodiment of the present invention;

    FIG. 7 is an enlarged cross-sectional view illustrating a snap-fit structure according to an embodiment of the present invention;

    FIG. 8 is a perspective view illustrating a secondary battery module according to an embodiment of the present invention;

    FIG. 9 is a cross-sectional view illustrating a terminal bus bar according to an embodiment of the present invention;

    FIG. 10 is perspective views illustrating a second structure according to an embodiment of the present invention; and

    FIG. 11 is an enlarged perspective view illustrating a second structure according to an embodiment of the present invention.


    DETAILED DESCRIPTION OF THE INVENTION



    [0016] Hereinafter, specific embodiments of the present invention will be described with reference to the accompanying drawings. But, these are only an example, and the present invention is not limited thereto. In the description of the present invention, detailed descriptions of the publicly known functions and configurations that are judged to be able to make the purport of the present invention unnecessarily obscure are omitted. In addition, terms or words used in the specification and claims should not be construed as limited to a lexical meaning, and should be interpreted as definitions known by one of ordinary skill in the art.

    [0017] However, those skilled in the art will appreciate that such embodiments are provided for illustrative purposes and do not limit subject matters to be protected as disclosed in the detailed description and appended claims. Therefore, it will be apparent to those skilled in the art that various alterations and modifications of the embodiments are possible within the scope of the present invention and duly included within the appended claims.

    [0018] The conventional battery pack has a plurality of battery cells connected with each other in series or in parallel to provide a voltage in a required range and battery capacity, and may include a battery management system, hereinafter, referred to as a BMS, a safety switch such as a fuse and a relay, and the like. Further, a battery module is provided with a connector for measuring voltage values of each of the battery cells, and a wiring harness for transferring measurement signals of the voltage values of each of the battery cells to the BMS. Control equipment, a controller, and electronic parts, or the like in the battery pack are housed in designated regions of battery pack. Protective structures configured to protect the parts such as a protector, a partition, a cover, and the like and are duplicately disposed in the battery pack. Therefore, with the number of parts duplicately disposed is increased, a volume and a weight of the battery pack are increased and the number of assembling processes is also increased.

    [0019] FIG. 2 is an exploded perspective view illustrating a secondary battery pack 1000 according to an embodiment of the present invention. Referring to FIG. 2, the secondary battery pack 1000 according to an embodiment of the present invention may integrate various parts into a single body or unit to simplify the structure of the secondary battery pack. The secondary battery pack 1000 according to an embodiment of the present invention includes a first structure 10, a secondary battery module 20, a second structure 30, and a cover 50.

    [0020] The first structure 10 may be disposed at one side of the secondary battery module 20 to support and protect the secondary battery module 20 and has a cooling system and a mounting structure. Such the first structure 10 serves as a cooling support structure. The second structure 30 is an integration structure of a printed circuit board including the BMS and a sensing module, the wiring harness, and the cover. Such the second structure 30 may serve as a multi-functional structure.

    [0021] The secondary battery module 20 is formed by only a battery cell 210 and cooling fins 220 (shown in Fig. 7). The cover 50 is a cover member that is disposed at a side (the other side) opposite to one side on which the first structure 10 is disposed, the second structure 30, and the secondary battery module 20 are coupled.

    [0022] The first structure 10 and the second structure 30 are formed under and over the secondary battery module 20, respectively, and then are covered with the cover 50. As a result, one secondary battery pack 1000 may be configured. In the secondary battery pack 1000, the first structure 10 serves as the cooling support structure, and the second structure 20 serves as the multi-functional structure. Furthermore, in FIG. 2, the cover 50 is formed in a flat plate shape. Both ends of the cover 50 may be formed with bent portions. Due to the bent portions formed at both ends, the cover 50 may have a shape covering the secondary battery module 20.

    [0023] The secondary battery pack 1000 according to the present invention may simplify the structure by integrating various parts. The secondary battery pack 1000 according to an embodiment of the present invention may reduce the number of parts and the number of assembling processes by employing the first structure 10, the secondary battery module 20, and the second structure 30. As the functions of parts are integrated, the number of parts may be reduced and the assembling costs may be saved. Furthermore, since the number of duplicated parts is reduced, the volume of the secondary battery pack may be reduced. As the volume and the weight are reduced, high power may be implemented with a given weight.

    [0024] FIG. 3 is a perspective view illustrating the first structure 10 according to an embodiment of the present invention. Referring to FIG. 3, the first structure 10 covers one side of the secondary battery module 20. In the first structure 10, a cooling channel and a bracket (or a coupling bracket) are included in an integrated manner. The coupling bracket may be fixedly mounted in a vehicle. The first structure 10 may include a plate 110 and side structures 120.

    [0025] The plate 110 may be formed by extrusion or press processing. For example, the plate 110 may be formed by extruding an aluminum material. The plate 110 may be formed in a rectangular plate shape. The shape of the plate 110 may be determined in consideration of a size and a shape of the secondary battery module 20. For example, when the secondary battery module 20 is a pouched type, the plate 110 may be in a rectangular plate shape. On the other hand, when the secondary battery module 20 is a cylinder type or a prismatic type, the plate 110 may in a shape fit to or compatible with the secondary battery module shape. The secondary battery module 20 may be positioned on one surface of the plate 110 such that the plate 110 may support the secondary battery module 20. In addition, the first structure 10 is formed in a shape corresponding to the secondary battery module 20, and may cover one side of the secondary battery module 20. Therefore, the first structure 10 may support and protect the secondary battery module 20.

    [0026] The side structures 120 may be provided on both sides of the plate 110 in a symmetrical shape to each other. The side structures 120 may be coupled to both sides of the plate 110. The side structures 120 and the plate 110 may be coupled to each other by various coupling methods such as bolting, riveting, welding, brazing, or the like. In addition, the side structures 120 may also be integrated with the plate 110. The side structures 120 may serve as the bracket for mounting in the vehicle. That is, the side structures 120 may correspond in shape to a coupling member of a vehicle, and may be manufactured to be changed or replaced depending on various vehicle model.

    [0027] Furthermore, the side structures 120 may be provided with one or more holes (not shown), and the holes may reduce the weight of the side structure 120. Since the side structures 120 are provided in a length direction of the plate 10, the side structures 120 may provide structural rigidity to the plate 110 in the length direction. The weight of the secondary battery module 20 mounted on an upper surface of the plate 110 may prevent the plate 110 from being bent in the length direction. Furthermore, the side structures 120 may include bolt holes (not shown), which are used to fasten the second structure 30 after the secondary battery module 20 is mounted.

    [0028] The first structure 10 may include a cooling structure. That is, the side structure 120 may be provided with an inflow channel 131a, into which a coolant is introduced, on one side thereof, and an outflow channel 131b, from which the coolant is discharged, on the other side thereof. The plate 110 is provided with a cooling channel 132 in which the coolant flows.

    [0029] FIG. 4 is a cross-sectional view illustrating the first structure 10 according to an embodiment of the present invention with the cooling structure. Referring to FIG. 4, as described above, the first structure 10 may include the cooling structure. The coolant is introduced through the inflow channel 131a on one side of the side structure 120 and may flow in the cooling channel 132 formed in the plate 110. The cooling channel 132 transfers (for example, conduction transfer by contact) a cold air, which is obtained by heat exchange between ambient air and the coolant, to a surface on which the secondary battery module 20 is mounted. Therefore, heat generated from the secondary battery module 20 is cooled by coolant flowing along the cooling channel 132 through the heat exchange.

    [0030] The coolant passing through the cooling channel 132 of the plate 110 may be discharged from the discharge channel 131b. Therefore, the heat of the secondary battery module 20 may be cooled by the coolant flowing through the cooling channel 132. Since the first structure 10 is integrated with the cooling channel 132, even though a separate cooling structure is not provided on an upper side or a lower side of the first structure 10, the secondary battery module 20 may be effectively cooled.

    [0031] Moreover, instead of forming the cooling channel in the plate 110, the plate 110 may include a heat sink or the like for cooling. The heat sink may be formed on a surface (the other surface) opposite to a surface (one surface) on which the secondary battery module 20 is placed. Furthermore, peripheral areas of the inflow channel 131a and the outflow channel 131b, which are provided in the side structures 120, may be sealed by sealing members 170. By preventing the coolant from being leaked from the channel, a damage of the secondary battery module 20 due to the leakage of the coolant may be prevented.

    [0032] As illustrated in any one of FIGS. 3 to 5, the plate 110 of the first structure 10 may include stepped portions 140 and a placing portion 150. A plurality of stepped portions 140 may be arranged on the plate 110 at a predetermined interval. The predetermined interval may be set corresponding to a width of the secondary battery module 20. Specifically, since the secondary battery module 20 is disposed between the two stepped portions 140 and is fixed between the two stepped portions 140. The predetermined interval may be set to correspond to the width of the secondary battery module 20, which will be described below. The stepped portion 140 may extend from one side structure 120 of the plate 110 to the other side structure 120.

    [0033] Switch parts 60 such as a relay, a fuse, and the like may be placed on the placing portion 150. The placing portion 150 may be formed at one end portion of the upper surface of the plate 110. The placing portion 150 may have components such as the switch part 60.

    [0034] FIG. 5 is a cross-sectional view illustrating the first structure 10 and the secondary battery modules 20 according to an embodiment of the present invention. Referring to FIG. 5, as described above, the plurality of stepped portions 140 may be disposed on the plate 110 of the first structure 10 at the predetermined interval. Since the stepped portions 140 are formed on the upper surface of the plate 110, the plate 110 may have enhanced structural rigidity. Since the stepped portions 140 are provided in a width direction of the plate 110, it is possible to prevent the plate 110 from being bent in the width direction due to the weight of the secondary battery modules 20 mounted on one surface of the plate 110. The stepped portion 140 may be provided with bus bars 40. The bus bars 40 have a predetermined length and are disposed between electrode tabs 211 (referring to FIG. 5) of the battery cell 210 to connect the electrode tabs 211 to each other. The stepped portions 140 may be a mounting point for mounting the secondary battery modules 20. Furthermore, the stepped portions 140 may provide a step between the plurality of secondary battery modules 20.

    [0035] The stepped portion 140 may be the mounting point while serving as a support member for fixing the secondary battery module 20 and may be a structure for mounting the bus bar 40. Therefore, the first structure 10 according to the embodiment of the present invention may reduce the number of fastening means for fastening the parts.

    [0036] The secondary battery module 20 may be mounted between the stepped portions 140. Although not shown in the drawings, the secondary battery module 20 may further include an expandable pad. The expandable pad having flexibility is provided between the battery cells 210 (referring to FIG. 5) in the secondary battery modules 20, and thus the secondary battery module 20 may have predetermined flexibility. Therefore, when the secondary battery module 20 is mounted between the two stepped portions 140, the expandable pad of the secondary battery module 20 may be compressed in a predetermined amount to be positioned between the two stepped portions 140. For this purpose, a width of the secondary battery module 20 is set to correspond to an interval between the stepped portions 140, and may be ranged equal to or slightly longer (for example, in a range of 0.1 mm to 1 mm) than the interval between the stepped portions 140 so that the expandable pad may be inserted with being compressed.

    [0037] In another embodiment, the secondary battery module 20 may also be fixed to the stepped portions 140 by additional fastening members 160 such as bolts. The fastening member 160 may prevent separation of the secondary battery module 20 from the first structure 10, for example, separation of the secondary battery module 20 from the first structure 10 in a direction perpendicular to the upper surface of the plate 110. The stepped portions 140 may fix the secondary battery module 20 as well as defining a region for mounting the secondary battery module 20. However, it is not limited thereto, and the expandable pad may be positioned in the stepped portion 140 or the stepped portion 140 may be formed to have flexibility.

    [0038] The placing portion 150 serves as a space in which the switch parts 60 such as the relay, the fuse, and the like may be placed. The switch part 60 attached to the secondary battery module 20 may be placed on the placing portion 150 while the secondary battery module 20 is mounted on the upper side of the first structure 10. The placing portion 150 may be configured in such a manner that even after the secondary battery pack 1000 is assembled, the parts placed on the placing portion 150 can be replaced with another part by a hole or a lid member.

    [0039] FIG. 6A is a perspective view illustrating a battery cell and FIG. 6B is a exploded view illustrating portion of secondary battery module according to an embodiment of the present invention.In particular, FIG. 6A illustrates the battery cell 210 and FIG. 6B illustrates an arrangement of the battery cell 210, the cooling fins 220, and adhesive pads 230.The secondary battery module 20 according to the embodiment of the present invention may include a plurality of battery cells 210 and a plurality of cooling fins 220.

    [0040] Referring to FIG. 6A, the battery cell 210 may include electrode tabs 211. The electrode tabs 211 may be formed at one side end or both side ends of a battery cell body 212. The electrode tab 211 may be formed in a pair, including a cathode tab and an anode tab. For example, the cathode tab and the anode tab may be formed at both side ends of the battery cell body 212, respectively. Alternatively, both of the cathode tab and the anode tab may be formed at one side end of the battery cell body 212. Hereinafter, a configuration is illustrated in which the cathode tab and the anode tab are formed at both side ends of the battery cell body 212, respectively. However, the present invention is not limited thereto.

    [0041] Referring to FIG. 6B, the cooling fin 220 is disposed between the plurality of battery cells 210 that are disposed apart from each other at an interval, and the adhesive pad 230 may be disposed between the battery cell 210 and the cooling fin 220 to couple or bond the battery cell 210 and the cooling fin 220 to each other. The electrode tabs 211 of the battery cells 210 may be connected to each other in series or in parallel.

    [0042] FIG. 7 is an enlarged cross-sectional view illustrating a snap-fit 250 structure for coupling the cooling fins 220 to each other according to an embodiment of the present invention. The cooling fin 220 may be formed in various shapes such as in an "I" shape, in a "T" shape, in a "U" shape, and the like. The secondary battery module 20 may have a configuration in which a plurality of cooling fins 220 are arranged, and the battery cell 210 is disposed between the cooling fins 220. To couple the plurality of cooling fins 220, a snap-fit 250 structure is provided. To describe the snap-fit 250 structure, for example, the cooling fin 220 in I shape will be described below, but the shape of the cooling fin 220 is not limited thereto.

    [0043] Referring to FIG. 7, the cooling fin 220 is in an I-shape in a cross section view, and the battery cells 210 are positioned on both sides of the cooling fin 220 in a length direction thereof (both sides of the I-shaped cross section). The cooling fins 220 are continuously arranged in a lateral direction, and the battery cells 210 may be disposed between the cooling fins 220 to form one secondary battery module 20.

    [0044] In this case, the adjacent cooling fins 220 may be fastened to each other by one or more snap-fit 250 structures, which are formed in at least one of the upper and lower portions of the I-letter cross section. The snap-fit 250 has male and female fitting pieces, which are positioned to face each other and coupled with each other in a snap fitting manner. The male fitting piece of a pair of snap-fit snaps-fits 250 may include a hook-shaped locking protrusion 251, and the female fitting piece may include a locked portion 252 to which the hook-shaped locking protrusion 251 is fitted and locked. The locking protrusion 251 and the locked portion 252 are fastened with each other to couple the adjacent cooling fins 220 and prevent the cooling fins 220 from being separated. The snap-fit 250 structure may prevent the battery cell 210 from being separated from the cooling fins 220 even when repetitive vibrations are applied to the battery cell 210 (for example, vibrations of a vehicle are repetitively applied thereto when using as a battery mounted in the vehicle) while the battery cell 210 is positioned within the cooling fins 220. However, the shape of the cooling fin 220 is not limited to the I-shape. The cooling fin may be formed in any shape that may play a role of cooling and housing other battery cells 210.

    [0045] FIG. 8 is a perspective view illustrating the secondary battery module 20 according to an embodiment of the present invention. In the secondary battery module 20, various types of parts are integrated. The secondary battery module 20 includes the cooling fin 220, which serves as a case. Thus, a separate case is not necessary.

    [0046] Referring to FIG. 8, the secondary battery module 20 includes the battery cells 210 and the cooling fins 220. The plurality of battery cells 210 may be disposed apart from each other at an interval and the cooling fin 220 may be disposed between the adjacent battery cells 210. More specifically, the cooling fin 220 is disposed between the battery cells 210 and extends to the upper and lower ends of the battery cells 210 for protecting the battery cells 210 and cooling the battery cells 210. Therefore, the cooling fin 220 may perform a dual function as a cooling structure and serve as a case for housing the battery cell 210.

    [0047] To couple the battery cell 210 to the cooling fins 220, the adhesive pad 230 may be provided between the battery cell 210 to the cooling fins 220. The adhesive pad may be disposed between the battery cell 210 and the cooling fin 220 to attach the battery cell 210 and the cooling fin 220 to each other. Under this structure, a separate connection structure is not necessary, and thus the secondary battery module 20 may be configured with a reduced number of components. The plurality of battery cells 210 and cooling fins 220 may be integrated to form the secondary battery module 20.

    [0048] The secondary battery module 20 may include one or more terminal bus bars 240 that may electrically connect the plurality of battery cells 210 to each other to measure a voltage. The terminal bus bar 240 may contact a contact terminal piece 331 of a printed circuit board, which is assembled in the second structure 30 shown in FIGS. 10 and 11, without a separate connector to measure a voltage. The printed circuit board assembled in the second structure 30 may perform the BMS and sensing functions, which will be described in detail below.

    [0049] Replaceable parts such as the switch part 60, including the relay and the fuse, may be mounted on one side of the secondary battery module 20. The switch part 60 mounted on one side of the secondary battery module 20 may be placed on the placing portion 150 of the first structure 10. Accordingly, when there is a need to replace parts such as the relay and the fuse, the parts may be simply replaced by replacing only the placing portion 150 of the first structure 10, thereby more efficiently performing maintenance operations such as the replacement of the parts.

    [0050] In the secondary battery module 20 according to the present invention, the cooling fin 220 serves as an exterior of the secondary battery module 20. Therefore, the conventional structure such as the cover structure and the support structure of the battery module may be simplified, reducing the number of duplicated structures.

    [0051] FIG. 9 is a cross-sectional view illustrating the terminal bus bar 240 for connecting the electrode tabs 12 according to an embodiment of the present invention. Referring to FIG. 9, the battery cell 210 may include the electrode tabs 211. The electrode tab 211 may include the cathode tab and the anode tab. The electrode tabs 211 may be connected to each other in series or in parallel. FIG. 9(a) shows that the electrode tabs 211 having same polarities (for example, (+) polarity in FIG. 9(a)) are connected to each other in a parallel connection, and FIG. 9(b) shows that a pair of electrode tabs 211 having one polarities (for example, (+) polarity in the left side of FIG. 9(b)) are connected to a pair of electrode tabs 211 having the other polarities (for example, (-) polarity in the right side of FIG. 9(b)) by combination of series and parallel. The secondary battery module 20 may include the terminal bus bar 240 configured to electrically connect the plurality of battery cells 210 to each other. Specifically, the electrode tabs 211 may be connected by the terminal bus bar 240. Terminal portions 41 may be provided for connecting the electrode tabs 211 using the terminal bus bar 240.

    [0052] Furthermore, since the cooling fin 220 serves as an exterior of the battery cell 210, additional protective structures may not necessary, and thereby an interval between the battery cells 210 may be narrowed. In this case, in order to connect the battery cells 210 using the terminal bus bar 240, the terminals 41 may be disposed.

    [0053] The secondary battery module 20 according to an embodiment of the present invention includes the terminal unit 41 that may connect the electrode tabs 211 of the adjacent battery cells 210 to each other, and the terminal unit 41 may include a contact terminal 41a disposed between the electrode tabs 211 of the adjacent battery cells 210 to contact the electrode tabs 211 and a wing terminal 41b. The wing terminal 41b extends from the contact terminal 41a toward the electrode tabs 211.

    [0054] In more detail, the terminal unit 41 may be disposed to contact the cathode electrode tab 211 led out from one electrode cell 210 and the anode electrode tabs 211 led out from the battery cells 210 adjacent thereto. The terminal unit 41 may include the contact terminal 41a and the wing terminal 41b. The contact terminal 41a is disposed between the cathode and anode electrode tabs 211, which are led out from each of one battery cells 210 and the battery cells 210 adjacent thereto to contact with each other. The wing terminal 41b, which extends outwardly from one end of the contact terminal 41a.

    [0055] The contact terminal 41a may be formed in a U shape to contact the cathode and anode electrode tabs 211, which are respectively lead out from the battery cells 210 adjacent to each other. The wing terminal 41b may extend outwardly from one end of the contact terminal 41a having the U shape. The wing terminals 41b of the adjacent battery cells 210 may be formed in a pair and face each other in a length direction. In other words, the wing terminal 41b of the terminal unit 41 may be positioned to face the wing terminal 41b of another terminal unit 41 adjacent to the terminal unit 41.

    [0056] The terminal bus bar 240 is coupled with the wing terminal 41b and may be provided on the wing terminals 41b disposed to face each other. The adjacent battery cells 210 may be electrically connected to each other by the terminal bus bar 240. The terminal bus bar 240 is coupled with the wing terminals 41b disposed to face each other. That is, the terminal unit 41 disposed at the adjacent battery cells 210 among the plurality of battery cells 210 may be provided with the terminal bus bar 240 to electrically connect the adjacent battery cells 210 with each other.

    [0057] The terminal bus bar 40 formed as described above may contact a contact terminal piece 331 mounted on a printed circuit board 330 to measure a voltage of the battery cells 210, which will be described in detail below with reference to FIG. 11.

    [0058] Furthermore, a jig insertion space A, to which a jig for welding is inserted, may be provided inside the wing terminals 41b that are disposed to face each other in a direction toward the battery cell 210. Furthermore, the jig insertion space A, to which a jig for welding is inserted, may be defined by (i) two battery cells 210 adjacent to each other, (ii) the wing terminals 41b disposed to face each other, and (iii) the opposite electrode tabs 211. Therefore, the jig may be inserted into the jig insertion space A and welded without a separate component for welding. When the welding is completed, the jig may be removed from the jig insertion space A.

    [0059] When the secondary battery module 20 is mounted under the second structure 30, the terminal bus bar 240 of the secondary battery module 20 and the contact terminal piece 331 of the second structure 30 may contact each other to measure a voltage, which will be described in detail below.

    [0060] FIG. 9(A) and 9(B) illustrates the electrode tabs 211 are connected to each other in series or in a parallel connection. However, the embodiment of the present invention is not limited thereto. The electrode tabs 211 may be connected to each other in various ways (for example, three battery cells may be connected to one another in a parallel connection, and three sets of battery cells connected in a parallel connection may be connected to one another in series (3P3S)).

    [0061] FIG. 10 is a view illustrating the second structure 30 according to the embodiment of the present invention. Referring to FIGS. 10, the second structure 30 may be mounted at the other side of the secondary battery module 20. In the second structure 30, the printed circuit board and the wiring harness are integrated into one unit. In detail, protective structures for the BMS, the sensing module, and the wiring harness are integrated together. The protective structures of various parts are combined and integrated in the second structure 30 as one unit. Furthermore, the second structure 30 may also serve as a cover. Specifically, the second structure 30 covers and protects for protecting electronic parts so that a case of a module, a partition, a wiring harness case, a BMS case, an upper cover of a pack, and a relay case are integrated in one large injection part.

    [0062] The second structure 30 may be formed by plastic injection. The second structure 30 may include the printed circuit board 330 performing the BMS and the sensing module. The second structure 30 is coupled to the first structure 10 and may be mounted over the secondary battery module 20. The second structure 30 may support and connect a side surface portion of the secondary battery module 20. The second structure 30 may support and encloses the side surface of the secondary battery module 20 and the upper and lower sides may be a penetrated frame shape. The housing 310 of the second structure 30 includes a plurality of through holes 360 corresponding to the shape and size of the secondary battery module 20 so that the secondary battery module 20 may be inserted into and placed on the second structure 30.

    [0063] Therefore, the lower portion of the secondary battery module 20 is connected to the first structure 10, the side surface of the secondary battery module 20 is connected to the second structure 30, and the upper portion of the secondary battery module 20 is connected to the cover 50 such that the secondary battery pack 1000 having the final shape may be obtained. The second structure 30 is formed in a shape corresponding to the size and the shape of the secondary battery module 20, and may cover the side surface of the secondary battery module 20. Therefore, the second structure 30 may support and protect the side surface of the secondary battery module 20.

    [0064] Furthermore, the second structure 30 includes the printed circuit board 330 on which the BMS and the sensing module are mounted. That is, the second structure 30 includes a measurement control circuit including the BMS and the sensing module, which may measure and control the power of the secondary battery module 20.

    [0065] Furthermore, the housing 310 forming the second structure 30 may be provided with an opening 311, which is formed in one side surface of the second structure 30. The housing 310 is provided with the plurality of through holes 360. The through holes 360 may be formed to correspond to the size and shape of the secondary battery module 20. Accordingly, the secondary battery module 20 is mounted in the through hole 360, and thus the second structure 30 may support and protect the side surface of the secondary battery module 20. The housing 310 may have the opening 311 to facilitate the replacement of the switch part 60 mounted in the secondary battery module 20. The opening 311 is formed to conveniently replace the switch parts 60 such as a relay, a fuse, and the like, which is mounted at one side of the secondary battery module 20. Typically, the parts such as the relay and the fuse need to be replaced in the battery pack. To more conveniently replace parts, the opening 311 may be formed. The opening part 311 may be formed at a place corresponding to the position of the switch part 60. Therefore, the opening 311 may be formed at a place corresponding to the position of the placing portion 150, which is formed in the first structure 10. The opening 311 may be further provided with a cover member (not shown) that may be opened and closed to safely protect the parts. Therefore, the parts disposed on the placing portion 140 may be conveniently replaced.

    [0066] Furthermore, a fastening portion 350 of the housing 310 may be provided with a fastening structure so that the housing 310 is coupled with the first structure 10. The fastening structure may be fastened to the side structure 120 of the first structure 10.

    [0067] The housing 310 forming the second structure 30 may have the opening 311 formed in one side surface to facilitate the replacement of the switch parts 60, which is mounted in the secondary battery module 20. The opening 311 is formed to conveniently replace the switch parts 60, including the relay, the fuse, and the like, which is mounted at one side of the secondary battery module 20. Typically, the parts such as the relay and the fuse need to be replaced in the battery pack. The opening potion 311 may be formed to facilitate the approach to the parts to be replaced. The opening part 311 may be formed at a place corresponding to the position at which the switch part 60 is positioned. Therefore, the opening 311 may be formed at a place corresponding to the position of the placing portion 150, which is formed in the first structure 10. The opening 311 may be further provided with a cover member (not shown) that may be opened and closed to safely protect parts. Therefore, the parts disposed on the placing portion 140 may be conveniently replaced.

    [0068] Furthermore, the housing 310 may be formed with the fastening structure to be coupled with the first structure 10. The fastening structure may be formed to be fastened with the side structure 120 of the first structure 10.

    [0069] FIG. 11 is an enlarged perspective view illustrating the second structure 30 according to an embodiment of the present invention. Referring to FIG. 11, the second structure 30 is provided with the printed circuit board 330 forming various types of control circuits and is provided with a barrier 320 in which the printed circuit board 330 is mounted. The printed circuit board 330 may be disposed outside the barrier 320 and, the secondary battery module 20 may be mounted inside the barrier 320.

    [0070] The printed circuit board 330 may serve as the BMS and the sensing module. Specifically, the printed circuit board 330 has the BMS and the sensing portion to read a signal and control the secondary electronic pack 1000. The printed circuit board 330 has the contact terminal piece 331 to measure a voltage without the separate welding and the connector connection.

    [0071] The barrier 320 may be formed to mount the printed circuit boards 330 forming various types of control circuits. The printed circuit board 330 may be mounted in the barrier 320 while securing the minimum power. The printed circuit board 330, including the BMS and sensing module functions, may be disposed between the housing 310 and the barrier 320. The secondary battery module 20 may be mounted inside the barrier 320. As a result, it is possible to mount the secondary battery module 20 while protecting the printed circuit board 330 without a separate case. Furthermore, the barrier wall 320 may be provided with a groove so that the contact terminal piece 331 mounted on the printed circuit board 330 protrudes toward the inside of the barrier 320.

    [0072] The printed circuit board 330 may include the contact terminal piece 331 that contacts the terminal bus bar 240 of the secondary battery module 20 to measure a voltage. More specifically, the printed circuit board 330 includes the contact terminal piece 331. The contact terminal piece 331 is made of an elastic member such as a spring, and thus the contact terminal piece 331 may be expanded and contracted. The terminal bus bar 40 and the contact terminal piece 330 may contact each other so that the secondary battery module 20 and the second structure 30 are separated from each other and may be coupled to each other. When the secondary battery module 20 is mounted in the second structure 30, in order to prevent the contact terminal piece 331 protruding toward the inside of the second structure 30 from being damaged, the contact terminal piece 331 may be made of the elastic member having an elastic force. Accordingly, when the secondary battery module 20 and the second structure 30 are coupled to each other, the terminal bus bar 240 and the contact terminal piece 330 may more stably contact each other. Furthermore, a wiring harness 340 led out from the printed circuit board 330 may be disposed between the housing 310 and the barrier 320. As a result, it is possible to protect the printed circuit board 330, the wiring harness 340, and the like without a separate protective structure. Furthermore, since the contact terminal piece 331 and the terminal bus bar 240 directly contact each other to measure a voltage, mounting the separate connector is not required. As a result, the secondary battery module 20 is mounted in the first structure 10, the second structure 30 including the printed circuit board 330 is mounted on the secondary battery module 20, and the cover 50 covers the second structure 30 to form the secondary battery pack 1000. However, an order in which the first structure 10, the secondary battery module 20, the second structure 30, and the cover 50 are mounted is not particularly limited.

    [0073] Although the representative embodiments of the present invention have been described in detail, it will be understood by persons who have a common knowledge in the technical field to which the present invention pertains that various modifications and variations may be made therein without departing from the scope of the present invention. Accordingly, the scope of the present invention should not be limited to the above-described embodiments, but be defined by the appended claims.


    Claims

    1. A secondary battery pack (1000), comprising;
    a secondary battery module (20) including battery cells (210) and cooling fins (220);
    a first structure (10) formed under the secondary battery module (20) and including a cooling channel (132) and coupling brackets;
    a second structure (30) which is formed in a shape enclosing side faces of the secondary battery module (20) and includes a printed circuit board (330); and
    a cover (50) mounted over the second structure (30),
    wherein the second structure (30) includes:

    a housing (310);

    a wiring harness (340);

    a barrier (320) formed in the housing (310) to mount the printed circuit board (330); and

    holes (360) formed in the housing (310),

    wherein the printed circuit board (330) and the wiring harness (340) are disposed between the housing (310) and the barrier (320).


     
    2. The secondary battery pack (1000) of claim 1,
    wherein the first structure (10) further includes a plate (110) and a side structure (120),
    wherein the side structure (120) is provided over first and second sides of the plate (110), wherein the plate (110) includes the cooling channel (132), and
    wherein the side structures (120) include the brackets.
     
    3. The secondary battery pack (1000) of claim 2,
    wherein the side structure (120) includes an inflow channel(131a) and an outflow channel (131b),
    wherein a coolant is introduced into the inflow channel (131a) and discharged to the outflow channel (131b),
    wherein the inflow channel (131a) and the outflow channel (131b) are respectively located over the first and the second sides of the plate (110).
     
    4. The secondary battery pack (1000) of claim 2, further comprising:

    stepped portions (140) formed over the plate (110) and spaced apart from each other, and

    wherein the secondary battery module (20) is placed between the stepped portions (140).


     
    5. The secondary battery pack (1000) of claim 2, further comprising:

    a placing portion (150) provided over a third side of the upper surface of the plate (110); and

    a switch member placed on the placing portion (150),

    wherein the switch member includes a relay, a fuse, or both.


     
    6. The secondary battery pack (1000) of claim 1,
    wherein the cooling fins (220) are arranged side by side at a first interval, and
    wherein each of the battery cells (210) is disposed between the cooling fins (220).
     
    7. The secondary battery pack (1000) of claim 6,
    wherein the secondary battery module (20), the first structure (10), and the second structure (30) are stacked in a first direction,
    wherein the cooling fins (220) are arranged side by side in a second direction, wherein the second direction is perpendicular to the first direction,
    wherein each of the cooling fins (220) includes an upper extension and a lower extension,
    wherein the upper extension extends from a top of each of the cooling fins (220) to a neighboring upper extension in the second direction,
    wherein the lower extension extends from a bottom of each of the cooling fins (220) to a neighboring lower extension in the second direction,
    wherein the upper extension is coupled to the neighboring upper extension to form an upper exterior of the secondary battery module (20), and
    wherein the lower extension is coupled to the neighboring lower extension to form a lower exterior of the secondary battery module (20).
     
    8. The secondary battery pack (1000) of claim 1,
    wherein the secondary battery module (20) further includes a terminal bus bar (240) and electrode tabs (211),
    wherein each of the electrode tabs (211) extends from each of the battery cells (210),
    wherein the terminal bus bar (240) electrically connects the electrode tabs (211) to each other, and
    wherein the terminal bus bar (240) contacts the printed circuit board (330).
     
    9. The secondary battery pack (1000) of claim 1,
    wherein the secondary battery module (20) further includes a terminal unit (41) and first and second electrode tabs (211),
    wherein the battery cells (210) includes first and second battery cells (210),
    wherein the first and the second electrode tabs (211) extend from the first and the second battery cells (210), respectively,
    wherein the terminal unit (41) includes a first contact terminal (41a) and a first wing terminal (41b),
    wherein the first contact terminal (41a) is disposed between the first and the second electrode tabs (211) and connects the first and the second electrode tabs (211) to each other, and
    wherein the first wing terminal (41b) extends from one end of the first contact terminal (41a) towards the outsides of the electrode tabs (211).
     
    10. The secondary battery pack (1000) of claim 9,
    wherein the secondary battery module (20) further includes third and fourth electrode tabs (211),
    wherein the battery cells (210) include third and fourth battery cells (210),
    wherein the third battery cell (210) is located next to the second battery cell (210),
    wherein the third and the fourth electrode tabs (211) extend from the third and the fourth battery cells (210), respectively,
    wherein the terminal unit (41) further includes a second contact terminal (41a) and a second wing terminal (41b),
    wherein the second contact terminal (41a) is disposed between the third and the fourth electrode tabs (211) and connects the third and the fourth electrode tabs (211) to each other,
    wherein the second wing terminal (41b) extends from the second contact terminal (41a), and
    wherein the second wing terminal (41b) faces the first wing terminal (41b).
     
    11. The secondary battery pack (1000) of claim 10, further including:

    a jig insertion space (A),

    wherein the jig insertion space (A) is defined by (i) the first and the second wing terminals (41b), (ii) the second and the third battery cells (210), and (iii) the second and the third electrode tabs (211).


     
    12. The secondary battery pack (1000) of claim 10, further comprising:

    a terminal bus bar (240),

    wherein the terminal bus bar (240) is coupled to the first and the second wing terminals (41b).


     
    13. The secondary battery pack (1000) of claim 12,
    wherein the terminal bus bar (240) is coupled to the printed circuit board (330).
     
    14. The secondary battery pack (1000) of claim 1,
    wherein the printed circuit board (330) includes a contact terminal piece (331),
    wherein the contact terminal piece (331) is configured to measure a voltage, and
    wherein the contact terminal piece (331) contacts a terminal bus bar (240) of the secondary battery module (20) to measure a voltage.
     
    15. The secondary battery pack (1000) of claim 5,
    wherein the second structure (30) includes an opening (311), and
    wherein the opening (311) is formed directly over the placing portion (150), so that the switch member is replaced with a new switch member through the opening.
     
    16. A secondary battery pack (1000), comprising:

    a secondary battery module (20) including battery cells (210) and cooling fins (220);

    a first structure (10) provided under the secondary battery module (20) to protect the secondary battery module (20) and cool the secondary battery module (20);

    a second structure (30) which is mounted on the other side of the secondary battery module (20) to protect the secondary battery module (20), and has a measurement control circuit mounted therein to measure and control a voltage of the secondary battery module (20); and

    a cover (50) mounted over the second structure (30),

    wherein the second structure (30) includes:

    a housing (310);

    a wiring harness (340); and

    a barrier (320) formed in the housing (310) to mount the measurement control circuit,

    wherein the measurement control circuit and the wiring harness (340) are disposed between the housing (310) and the barrier (320), and

    holes (360) formed in the housing (310).


     
    17. The secondary battery pack (1000) of claim 16,
    wherein the second structure (20) includes a contact terminal piece (331), and
    wherein the contact terminal piece (331) elastically contacts the measurement control circuit and the secondary battery module (20) and electrically connects the measurement control circuit and the secondary battery module (20) to each other.
     


    Ansprüche

    1. Sekundärbatteriepack (1000), umfassend;
    ein Sekundärbatteriemodul (20), das Batteriezellen (210) und Kühlrippen (220) enthält;
    eine erste Struktur (10), die unter dem Sekundärbatteriemodul (20) ausgebildet ist und einen Kühlkanal (132) und Kopplungsklammern enthält;
    eine zweite Struktur (30), die in einer Form ausgebildet ist, die die Seitenflächen des Sekundärbatteriemoduls (20) umschließt, und die eine Leiterplatte (printed circuit board) (330) enthält; und
    eine Abdeckung (50), die über der zweiten Struktur (30) angebracht ist,
    wobei die zweite Struktur (30) enthält:

    ein Gehäuse (310);

    einen Kabelbaum (340);

    eine in dem Gehäuse (310) ausgebildete Barriere (320) zur Montage der Leiterplatte (330); und

    Löcher (360), die im Gehäuse (310) ausgebildet sind,

    wobei die Leiterplatte (330) und der Kabelbaum (340) zwischen dem Gehäuse (310) und der Barriere (320) angeordnet sind.


     
    2. Sekundärbatteriepack (1000) nach Anspruch 1,
    wobei die erste Struktur (10) ferner eine Platte (110) und eine Seitenstruktur (120) enthält,
    wobei die Seitenstruktur (120) über ersten und zweiten Seiten der Platte (110) vorgesehen ist, wobei die Platte (110) den Kühlkanal (132) enthält, und
    wobei die Seitenstrukturen (120) die Klammern enthalten.
     
    3. Sekundärbatteriepack (1000) nach Anspruch 2,
    wobei die Seitenstruktur (120) einen Einströmkanal (131a) und einen Ausströmkanal (131b) aufweist,
    wobei ein Kühlmittel in den Einströmkanal (131a) eingeführt und in den Ausströmkanal (131b) abgelassen wird,
    wobei der Einströmkanal (131a) und der Ausströmkanal (131b) jeweils über den ersten und den zweiten Seiten der Platte (110) angeordnet sind.
     
    4. Sekundärbatteriepack (1000) nach Anspruch 2, das ferner umfasst:

    abgestufte Abschnitte (140), die über der Platte (110) ausgebildet und voneinander beabstandet sind, und

    wobei das Sekundärbatteriemodul (20) zwischen den abgestuften Abschnitten (140) angeordnet ist.


     
    5. Sekundärbatteriepack (1000) nach Anspruch 2, das ferner umfasst:

    einen Platzierungsabschnitt (150), der über einer dritten Seite der oberen Oberfläche der Platte (110) vorgesehen ist; und

    ein Schaltelement, das auf dem Platzierungsabschnitt (150) angeordnet ist,

    wobei das Schaltelement ein Relais, eine Sicherung oder beides enthält.


     
    6. Sekundärbatteriepack (1000) nach Anspruch 1,
    wobei die Kühlrippen (220) in einem ersten Abstand nebeneinander angeordnet sind, und
    wobei jede der Batteriezellen (210) zwischen den Kühlrippen (220) angeordnet ist.
     
    7. Sekundärbatteriepack (1000) nach Anspruch 6,
    wobei das Sekundärbatteriemodul (20), die erste Struktur (10) und die zweite Struktur (30) in einer ersten Richtung gestapelt sind,
    wobei die Kühlrippen (220) nebeneinander in einer zweiten Richtung angeordnet sind,
    wobei die zweite Richtung senkrecht zur ersten Richtung verläuft,
    wobei jede der Kühlrippen (220) eine obere Verlängerung und eine untere Verlängerung aufweist,
    wobei sich die obere Verlängerung von einer Oberseite jeder der Kühlrippen (220) zu einer benachbarten oberen Verlängerung in der zweiten Richtung erstreckt,
    wobei sich die untere Verlängerung von einer Unterseite jeder der Kühlrippen (220) zu einer benachbarten unteren Verlängerung in der zweiten Richtung erstreckt,
    wobei die obere Verlängerung mit der benachbarten oberen Verlängerung gekoppelt ist, um eine obere Außenseite des Sekundärbatteriemoduls (20) zu bilden, und
    wobei die untere Verlängerung mit der benachbarten unteren Verlängerung gekoppelt ist, um eine untere Außenseite des Sekundärbatteriemoduls (20) zu bilden.
     
    8. Sekundärbatteriepack (1000) nach Anspruch 1,
    wobei das Sekundärbatteriemodul (20) ferner eine Anschlusssammelschiene (240) und Elektrodenzungen (211) aufweist,
    wobei jede der Elektrodenzungen (211) sich von jeder der Batteriezellen (210) aus erstreckt,
    wobei die Anschlusssammelschiene (240) die Elektrodenzungen (211) elektrisch miteinander verbindet, und
    wobei die Anschlusssammelschiene (240) die Leiterplatte (330) kontaktiert.
     
    9. Sekundärbatteriepack (1000) nach Anspruch 1,
    wobei das Sekundärbatteriemodul (20) ferner eine Anschlusseinheit (41) und erste und zweite Elektrodenzungen (211) enthält,
    wobei die Batteriezellen (210) erste und zweite Batteriezellen (210) enthalten,
    wobei sich die ersten und die zweiten Elektrodenzungen (211) von der ersten beziehungsweise der zweiten Batteriezelle (210) aus erstrecken,
    wobei die Anschlusseinheit (41) einen ersten Kontaktanschluss (41a) und einen ersten Flügelanschluss (41b) umfasst,
    wobei der erste Kontaktanschluss (41a) zwischen den ersten und den zweiten Elektrodenzungen (211) angeordnet ist und die ersten und die zweiten Elektrodenzungen (211) miteinander verbindet, und
    wobei sich der erste Flügelanschluss (41b) von einem Ende des ersten Kontaktanschlusses (41a) zu den Außenseiten der Elektrodenzungen (211) erstreckt.
     
    10. Sekundärbatteriepack (1000) nach Anspruch 9,
    wobei das Sekundärbatteriemodul (20) ferner dritte und vierte Elektrodenzungen (211) enthält,
    wobei die Batteriezellen (210) dritte und vierte Batteriezellen (210) enthalten,
    wobei die dritte Batteriezelle (210) neben der zweiten Batteriezelle (210) angeordnet ist,
    wobei sich die dritten und die vierten Elektrodenzungen (211) von der dritten beziehungsweise vierten Batteriezelle (210) aus erstrecken,
    wobei die Anschlusseinheit (41) ferner einen zweiten Kontaktanschluss (41a) und einen zweiten Flügelanschluss (41b) umfasst,
    wobei der zweite Kontaktanschluss (41a) zwischen den dritten und den vierten Elektrodenzungen (211) angeordnet ist und die dritten und die vierten Elektrodenzungen (211) miteinander verbindet,
    wobei sich der zweite Flügelanschluss (41b) von dem zweiten Kontaktanschluss (41a) aus erstreckt, und
    wobei der zweite Flügelanschluss (41b) dem ersten Flügelanschluss (41b) zugewandt ist.
     
    11. Sekundärbatteriepack (1000) nach Anspruch 10, das ferner enthält:

    einen Betätigungselement-Einsetzraum (A),

    wobei der Betätigungselement-Einsetzraum (A) durch (i) den ersten und den zweiten Flügelanschluss (41b), (ii) die zweiten und die dritten Batteriezellen (210) und (iii) die zweiten und die dritten Elektrodenzungen (211) definiert ist.


     
    12. Sekundärbatteriepack (1000) nach Anspruch 10, das ferner enthält:

    eine Anschlusssammelschiene (240),

    wobei die Anschlusssammelschiene (240) mit dem ersten und dem zweiten Flügelanschluss (41b) gekoppelt ist.


     
    13. Sekundärbatteriepack (1000) nach Anspruch 12,
    wobei die Anschlusssammelschiene (240) mit der Leiterplatte (330) gekoppelt ist.
     
    14. Sekundärbatteriepack (1000) nach Anspruch 1,
    wobei die Leiterplatte (330) ein Kontaktanschlussstück (331) enthält,
    wobei das Kontaktanschlussstück (331) so eingerichtet ist, dass es eine Spannung misst, und
    wobei das Kontaktklemmenstück (331) eine Anschlusssammelschiene (240) des Sekundärbatteriemoduls (20) kontaktiert, um eine Spannung zu messen.
     
    15. Sekundärbatteriepack (1000) nach Anspruch 5,
    wobei die zweite Struktur (30) eine Öffnung (311) aufweist, und
    wobei die Öffnung (311) direkt über dem Platzierungsabschnitt (150) ausgebildet ist, so dass das Schaltelement durch die Öffnung durch ein neues Schalterelement ersetzt wird.
     
    16. Sekundärbatteriepack (1000), umfassend:

    ein Sekundärbatteriemodul (20), das Batteriezellen (210) und Kühlrippen (220) enthält;

    eine erste Struktur (10), die unter dem Sekundärbatteriemodul (20) vorgesehen ist, um das Sekundärbatteriemodul (20) zu schützen und das Sekundärbatteriemodul (20) zu kühlen;

    eine zweite Struktur (30), die auf der anderen Seite des Sekundärbatteriemoduls (20) montiert ist, um das Sekundärbatteriemodul (20) zu schützen, und die eine darin montierte Messsteuerschaltung aufweist, um eine Spannung des Sekundärbatteriemoduls (20) zu messen und zu steuern; und

    eine Abdeckung (50), die über der zweiten Struktur (30) angebracht ist,

    wobei die zweite Struktur (30) enthält:

    ein Gehäuse (310);

    einen Kabelbaum (340); und

    eine im Gehäuse (310) ausgebildete Barriere (320) zur Befestigung der Messsteuerschaltung,

    wobei die Messsteuerschaltung und der Kabelbaum (340) zwischen dem Gehäuse (310) und der Barriere (320) angeordnet sind, und

    Löcher (360), die im Gehäuse (310) ausgebildet sind.


     
    17. Sekundärbatteriepack (1000) nach Anspruch 16,
    wobei die zweite Struktur (20) ein Kontaktanschlussstück (331) enthält, und
    wobei das Kontaktanschlussstück (331) die Messsteuerschaltung und das Sekundärbatteriemodul (20) elastisch kontaktiert und die Messsteuerschaltung und das Sekundärbatteriemodul (20) elektrisch miteinander verbindet.
     


    Revendications

    1. Bloc de batterie secondaire (1000), comprenant :

    un module de batterie secondaire (20) incluant des cellules de la batterie (210) et des ailettes de refroidissement (220) ; une première structure (10) formée sous le module de batterie secondaire (20) et incluant un canal de refroidissement (132) et des supports d'attelage ;

    une deuxième structure (30) qui est réalisée avec une forme comportant des faces latérales du module de batterie secondaire (20) et inclut une carte de circuit imprimé (330) ; et

    un couvercle (50) monté sur la deuxième structure (30), dans lequel la deuxième structure (30) inclut :

    un boîtier (310) ;

    un faisceau de câbles (340) ;

    une barrière (320) formée dans le boîtier (310) pour monter la carte de circuit imprimé (330) ; e

    des trous (360) formés dans le boîtier (310),

    dans lequel la carte de circuit imprimé (330) et le faisceau de câbles (340) sont disposés entre le boîtier (310) et la barrière (320).


     
    2. Bloc de batterie secondaire (1000) selon la revendication 1,
    dans lequel la première structure (10) inclut en outre une plaque (110) et une structure latérale (120),
    dans lequel la structure latérale (120) est fournie au-dessus du premier côté et du deuxième côté de la plaque (110), dans lequel la plaque (110) inclut le canal de refroidissement (132), et
    dans lequel les structures latérales (120) incluent les supports.
     
    3. Bloc de batterie secondaire (1000) selon la revendication 2,
    dans lequel la structure latérale (120) inclut un canal de flux d'entrée (131a) et un canal de flux de sortie (131b),
    dans lequel un réfrigérant est introduit dans le canal de flux d'entrée (131a) et déchargé du canal de flux de sortie (131b),
    dans lequel le canal de flux d'entrée (131a) et le canal de flux de sortie (131b) sont respectivement positionnés au-dessus du premier côté et du deuxième côtés de la plaque (110).
     
    4. Bloc de batterie secondaire (1000) selon la revendication 2, comprenant en outre :

    parties étagées (140) formées sur la plaque (110) et espacées l'une de l'autre,

    dans lequel le module de batterie secondaire (20) est placé entre les parties étagées.


     
    5. Bloc de batterie secondaire (1000) selon la revendication 2, comprenant en outre :

    une partie de placement (150) fournie sur un troisième côté de la surface supérieure de la plaque (110); et

    un élément de commutation placé sur la partie de placement (150), dans lequel l'élément de commutation inclut un relais, un fusible, ou tous les deux.


     
    6. Bloc de batterie secondaire (1000) selon la revendication 1,
    dans lequel les ailettes de refroidissement (220) sont disposées côte à côte à un premier intervalle, et dans lequel chacune des cellules de la batterie (210) est disposée entre les ailettes de refroidissement (220).
     
    7. Bloc de batterie secondaire (1000) selon la revendication 6,
    dans lequel le module de batterie secondaire (20), la première structure (10), et la deuxième structure (30) sont empilées dans une première direction,
    dans lequel les ailettes de refroidissement (220) sont disposées côte à côte dans une deuxième direction, dans lequel la deuxième direction est perpendiculaire à la première direction,
    dans lequel chacune des ailettes de refroidissement (220) inclut une extension supérieure et une extension inférieure,
    dans lequel l'extension supérieure s'étend d'une partie supérieure de chacune des ailettes de refroidissement (220) à une extension supérieure voisine dans la deuxième direction,
    dans lequel l'extension inférieure s'étend d'une partie inférieure de chacune des ailettes de refroidissement (220) à une extension inférieure voisine dans la deuxième direction,
    dans lequel l'extension supérieure est couplée à l'extension supérieure voisine pour former une partie externe supérieure du module de batterie secondaire (20), et
    dans lequel l'extension inférieure est couplée à l'extension inférieure voisine pour former une partie externe inférieure du module de batterie secondaire (20).
     
    8. Bloc de batterie secondaire (1000) selon la revendication 1,
    dans lequel le module de batterie secondaire (20) inclut en outre une borne de barre de bus (240) et des languettes d'électrode (211),
    dans lequel chacune des languettes d'électrode (211) s'étend de chacune des cellules de la batterie (210),
    dans lequel la borne de barre de bus (240) relie électriquement les languettes d'électrode (211) les unes aux autres, et
    dans lequel la borne de barre de bus (240) est en contact avec la carte de circuit imprimé (330).
     
    9. Bloc de batterie secondaire (1000) selon la revendication 1,
    dans lequel le module de batterie secondaire (20) inclut en outre une unité de borne (41) et une première et une deuxième languettes d'électrode (211),
    dans lequel les cellules de la batterie (210) incluent une première et une deuxième cellules de la batterie (210),
    dans lequel la première et la deuxième languettes d'électrode (211) s'étendent, respectivement, de la première et de la deuxième cellule de la batterie (210),
    dans lequel l'unité e borne (41) inclut une première borne de contact (41a) et une première borne à ailettes (41b),
    dans lequel la première borne de contact (41a) est disposée entre la première et la deuxième languettes d'électrode (211) et relie la première et la deuxième languettes d'électrode (211) les unes aux autres, et
    dans lequel la première borne à ailettes (41b) s'étend d'une extrémité de la première borne de contact (41a) vers les parties externes des languettes d'électrode (211).
     
    10. Bloc de batterie secondaire (1000) selon la revendication 9,
    dans lequel le module de batterie secondaire (20) inclut en outre la première et la deuxième languettes d'électrode (211),
    dans lequel les cellules de la batterie (210) incluent la troisième et la quatrième cellules de la batterie (210), dans lequel la troisième cellule de la batterie (210) est positionnée à côté de la deuxième cellule de la batterie (210),
    dans lequel la troisième et la quatrième languettes d'électrode (211) s'étendent, respectivement, de la troisième et de la quatrième cellules de la batterie (210),
    dans lequel l'unité de borne (41) inclut en outre une deuxième borne de contact (41a) et une deuxième borne à ailettes (41b),
    dans lequel la deuxième borne de contact (41a) est disposée entre la troisième et la quatrième languettes d'électrode (211) et relie la troisième et la quatrième languettes d'électrode (211) les unes aux autres,
    dans lequel la deuxième borne à ailettes (41b) s'étend de la deuxième borne de contact (41a), et
    dans lequel la deuxième borne à ailettes (41b) se trouve face à la première borne à ailettes (41b).
     
    11. Bloc de batterie secondaire (1000) selon la revendication 10, incluant en outre : un espace d'insertion d'un gabarit (A),
    dans lequel l'espace d'insertion d'un gabarit (A) est défini par (i) la première et la deuxième bornes à ailettes (41b), par (ii) la deuxième et la troisième cellules de la batterie (210), et par (iii) la deuxième et la troisième languettes d'électrode (211).
     
    12. Bloc de batterie secondaire (1000) selon la revendication 10, comprenant en outre : une borne de barre de bus (240),
    dans lequel la borne de barre de bus (240) est couplée à la première et à la deuxième bornes à ailettes (41b).
     
    13. Bloc de batterie secondaire (1000) selon la revendication 12,
    dans lequel la borne de barre de bus (240) est couplée à la carte de circuit imprimé (330).
     
    14. Bloc de batterie secondaire (1000) selon la revendication 1,
    dans lequel la carte de circuit imprimé (330) inclut une pièce de borne de contact (331), dans lequel la pièce de borne de contact (331) est configurée pour mesurer une tension, et dans lequel la pièce de borne de contact (331) est en contact avec une borne de barre de bus (240) du module de batterie secondaire (20) pour mesurer une tension.
     
    15. Bloc de batterie secondaire (1000) selon la revendication 5,
    dans lequel la deuxième structure (30) inclut une ouverture (311), et
    dans lequel l'ouverture (311) est formée directement sur la partie de placement (150), de sorte que l'élément de commutation soit remplacé par un nouvel élément de commutation à travers l'ouverture.
     
    16. Bloc de batterie secondaire (1000), comprenant :

    un module de batterie secondaire (20) incluant des cellules de la batterie (210) et des ailettes de refroidissement (220) ; une première structure (10) fournie sous le module de batterie secondaire (20) pour protéger le module de batterie secondaire (20) et refroidir le module de batterie secondaire (20) ;

    une deuxième structure (30) qui est montée sur l'autre côté du module de batterie secondaire (20) pour protéger le module de batterie secondaire (20), et a un circuit de contrôle de mesure monté dans celle-ci pour mesurer et contrôler une tension du module de batterie secondaire (20) ; et

    un couvercle (50) monté sur la deuxième structure (30), dans lequel la deuxième structure (30) inclut :

    un boîtier (310) ;

    un faisceau de câbles (340) ; et

    une barrière (320) formée dans le boîtier (310) pour monter le circuit de contrôle de mesure, dans lequel le circuit de contrôle de mesure et le faisceau de câbles (340) sont disposés entre le boîtier (310) et la barrière (320), et les trous (360) formés dans le boîtier (310).


     
    17. Bloc de batterie secondaire (1000) selon la revendication 16, dans lequel la deuxième structure (20) inclut une pièce de borne de contact (331), et
    dans lequel la pièce de borne de contact (331) relie élastiquement le circuit de contrôle de mesure et le module de batterie secondaire (20) et relie électriquement le circuit de contrôle de mesure et le module de batterie secondaire (20) l'un à l'autre.
     




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    Cited references

    REFERENCES CITED IN THE DESCRIPTION



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    Patent documents cited in the description