JP2019516211A - Battery pack structure for cylindrical batteries - Google Patents

Abstract

The present invention relates to a battery pack structure for a cylindrical battery, in which battery insertion grooves are formed so that four small cylindrical battery cells are respectively inserted side by side, aiding air flow along the circumference of the insertion grooves A battery insertion groove is provided in the same configuration as the first outer frame and the first outer frame having a plurality of circular slots therein so that the opposite electrode of the cell is inserted from the opposite side of the cylindrical battery cell (2) 4 terminal grooves of the terminal form are provided respectively so that the outer frame and the electrode terminal for bolt connection can be seated respectively, and it is positioned at both ends of the outer frame to bind the outer frame and the outer frame respectively Pair of outer frame covers, which are respectively inserted into the terminal grooves from the lower part of the outer frame cover, and are respectively in contact with the outer frames Characterized in that it is configured to include four electrode terminals terminal bolt groove is unity and the spring is provided in order to supply the battery cell is supplied via the ring. [Selected figure] Figure 3

Description

The present invention relates to a battery pack structure for a cylindrical battery, and more specifically, a small-capacity cylindrical lithium ion battery cell which is easy to purchase is connected in series to increase voltage and connected in parallel to increase current amount. The present invention relates to a battery pack structure for a cylindrical battery having a structure that makes it easy to manufacture a large capacity battery pack.

In addition, the present invention assembles a cylindrical battery and makes it possible to manufacture a large capacity battery pack which can be easily separated again, a joint structure of plastic material, a terminal and a spring for flowing current, and a bolt for fixing a case. The present invention relates to a battery pack structure for a cylindrical battery having components, shapes, and structures such as, for example.

At present, batteries are used as devices for storing electrical energy in various fields, and most of primary and secondary batteries have the form of Cylindrical, Prismatic, Pouch. There is. Secondary batteries that can be recharged and used are widely used in portable electronic devices such as smartphones and laptop computers, and in rechargeable electric vehicles that use batteries. Recently, several battery cells have been connected in series / parallel. It is also used in connection with ESS (Energy Storage System) that uses and stores electricity generated by solar light, wind power, etc.

Among lithium batteries, lithium batteries are widely used for IT tools such as power tools, auxiliary batteries, mobile phones, notebook computers, etc. because lithium batteries can be charged and discharged hundreds or thousands of times over a long period of time. Recently, it is also used for ESS combined with electric vehicles and solar light, wind power and the like. In particular, 18650 lithium batteries are standardized to a cylindrical size of 18 mm in diameter and 65 mm in height, and they are the most commonly produced form in the world, and drive electric vehicles in Tesla cars in the US and Audi in Germany. It is applied as

In most of the methods of connecting the cylindrical battery cells in series / parallel, welding is performed using the positive and negative terminals of the battery cells and another external connection bar (Bus Bar). At this time, current capacity can be increased through parallel connection (connection of positive electrodes and connection of negative electrodes), and voltage can be increased through series connection (connection of positive electrode and negative electrode of another battery). In most cases, welding is performed mainly using a nickel plate which is the same material as the positive electrode and the negative electrode of the battery cell. Usually, several to dozens of serial connections are required because the electric devices used (portable, for electric vehicles, for ESS) are 12V, 24V, 48V, 72V, 110V, 200V, 380V, etc. Depending on the amount of energy used, several to hundreds of thousands of parallel connections may be required.

In the conventional method, when connecting the positive electrode and the negative electrode of the battery in series and in parallel, the connection between the separate electrode plate and the battery electrode is made by using spot (spot) welding or laser welding etc. which apply voltage instantaneously. A number of cells can be connected in series and in parallel in the following manner. That is, in this case, the (+) pole, the (+) pole, the (-) pole and the (-) pole of the battery can be connected (parallel connection) to increase the current capacity of the small battery by a desired amount. This is called a battery module in which only the current capacity is increased while having the same voltage as one battery cell. A desired voltage can be obtained by connecting a plurality of battery cells in parallel to increase a current capacity by connecting a plurality of (+) poles of one battery module and a plurality of (-) poles of another battery module (series connection). Can be raised up.

However, in the structure of a battery pack that uses a plurality of small capacity cylindrical cells connected in series / parallel, in some cases, several thousand can be connected in series and in parallel. In such a case, However, when multiple battery cells are connected through spot welding, a large number of contact defects or welding defects due to vibration occur, and in this case, it is also difficult to find contact defects, Even if this is found, the work of correcting this and rejoining through spot welding is an extremely difficult task due to the possibility of electrical shorts and the heavy weight of the large battery pack itself. When connecting in parallel / after fastening in series / parallel, we have to solve a simple separation method.

The existing fastening method can not solve the above problem by the serial / parallel connection structure through ultrasonic spot welding or laser welding. That is, when the battery pack is used through repeated charging and discharging of the battery cells, some battery cells of the battery cells have problems such as premature aging, increase in terminal resistance, increase in cell heat loss and internal resistance. It is extremely difficult to replace or separate some battery cells that can be a problem when the overall performance of the battery pack is degraded, and virtually no partial replacement or repair of the battery pack is possible. The

As a result, if the life of the entire battery pack to which a large number of cells are combined is reduced due to aging and increase in terminal resistance in some of the battery cells constituting the battery pack, the battery pack is configured The remaining normal battery cells can not be used until their life is over, and there are many cases where the life of the most problematic cell is over.

Also, even when the battery cells are connected in parallel, if the separators separating (+) and (-) are lost inside one cell, not only one cell but also one cell connected in parallel Even if the entire battery module is connected (+) and (-), a short circuit occurs, and even if a large number of battery cells connected in parallel operate normally, the remaining parallel cells are shorted by the battery cells in the short circuit state. There is a problem in that electric energy is consumed in the entire connected battery module and a normal battery can not be used.

The present invention is intended to solve the above-mentioned problems, and has a structure in which a plurality of cylindrical battery cells can be easily connected in parallel and in series, and a large number of small capacity cylindrical cells can be obtained through a simple assembly operation. It is for providing the battery pack structure for cylindrical batteries in which the contact state of a terminal is stably hold | maintained also at the time of vibration by connecting in series / parallel.

Also, the present invention separates or disassembles the battery module or battery cell case from the combined battery pack when a problem occurs in the battery module constituting the battery pack or the individual battery of the battery cell that is the lower stage thereof. It is easy to replace individual battery cells, and when a problem occurs in one battery cell in a battery pack structure in which a plurality of battery cells are connected in series / parallel, the same problem occurs in other battery cells Instead, the present invention is intended to provide a battery pack structure for cylindrical batteries in which only one battery can be maintained in an unusable state.

In order to achieve the above object, the battery pack structure for a cylindrical battery according to an embodiment of the present invention is formed with battery insertion grooves such that four small cylindrical battery cells are respectively inserted side by side, and the circumference of the insertion groove The first external frame is provided with a plurality of circular slots in the inside to support the flow of air, and the opposite electrode of the cell is inserted from the opposite side of the cylindrical battery cell in the same form as the first external frame A second external frame having a battery insertion groove, four terminal grooves in the form of terminals are provided so that electrode terminals for bolt coupling can be respectively seated, and both tips of the external frame A pair of outer frame covers, each of which is placed in a bundle with the outer frame, and inserted into the terminal groove from the lower part of the outer frame cover; Characterized in that it is configured to include four electrode terminals provided with terminal bolt groove tied a spring to power the battery cell is supplied via a spring contact as each.

The battery pack structure for a cylindrical battery according to the embodiment of the present invention is manufactured so as to be able to be bolted together, and assembly of unit modules including battery cells is easy, and when battery cells are connected in series or in parallel Since no additional bus bar (nickel plate) is welded to the +) and (−) poles, assembly, fabrication and disassembly are easy, and efficient use and management of the battery pack are possible.

In addition, the battery pack structure for a cylindrical battery according to the embodiment of the present invention disassembles only some battery cells that become a problem when individual battery cells have a problem in a battery pack in which a plurality of battery modules are coupled. Thus, the entire performance of the battery pack can be maintained and continuously used, and the performance of the low-cost battery pack can be efficiently maintained and managed.

In addition, the battery pack structure for a cylindrical battery according to the embodiment of the present invention has a structure in which battery cells can be connected in series / parallel only by the assembly method, not by spot welding. There is an effect that maintenance is easy through disassembly and assembly without increasing.

In addition, the battery pack structure for a cylindrical battery according to the embodiment of the present invention provides a structure that facilitates stacking of a large number of cylindrical battery cells in series and in parallel, and is easy to assemble and disassemble, even during vibration. The contact state of the terminals can be stably held, and the heat generated from the electrode plate and the unit battery cell itself can be easily dissipated through the space between the external frame during use of the battery product, and the battery fires It has the effect of being able to prevent.

Further, in the battery pack structure for a cylindrical battery according to the embodiment of the present invention, the (+) and (-) polarity portions of the first outer frame and the second outer frame are provided with grooves so as to allow confirmation of polarity when connecting batteries. The battery cell can be provided to check between the positive electrode and the negative electrode terminal of the battery cell, and the short circuit connection between the batteries can be prevented.

In the battery pack structure for a cylindrical battery according to an embodiment of the present invention, the first outer frame and the second outer frame can be manufactured and coupled centering on the battery cell including the negative electrode terminal and the positive electrode terminal. A terminal that can connect the positive and negative electrodes to the outer frame and the second outer frame is coupled with a spring, and each outer frame is coupled to the first outer frame and the second outer frame, respectively, as one unit module. It can be configured to variably adjust its rated power supply as needed, providing convenience in use.

1 is an exploded view of a battery pack structure according to an embodiment of the present invention. It is the perspective view which showed the fastening state of the battery pack concerning the present invention. 1 is a front view of a battery pack structure according to an embodiment of the present invention. FIG. 2 is a cross-sectional view and a perspective view showing a structure of an outer frame of the battery pack according to FIG. 1; FIG. 2A is a cross-sectional view and a perspective view showing a structure of an outer frame cover of the battery pack according to FIG. 1; FIG. 2A is a cross-sectional view and a perspective view showing a structure of an outer frame cover of the battery pack according to FIG. 1; FIG. 2 is a perspective view showing the form and assembly structure of an electrode terminal of a battery pack structure according to FIG. 1; FIG. 2 is a perspective view showing the form and assembly structure of an electrode terminal of a battery pack structure according to FIG. 1; FIG. 2 is a perspective view showing the form and assembly structure of an electrode terminal of a battery pack structure according to FIG. 1; FIG. 2 is a perspective view showing the form and assembly structure of an electrode terminal of a battery pack structure according to FIG. 1; FIG. 2 is a perspective view of a spring of a battery pack structure according to FIG. 1; FIG. 2 is a perspective view showing a form of a fixing screw of a battery pack structure according to FIG. 1; FIG. 5 is a perspective view of a coupling key used for coupling between external frames according to the present invention. FIG. 5 is a perspective view of a coupling key used for coupling between external frames according to the present invention. FIG. 10 is a perspective view showing a structure in which a plurality of battery modules are connected using a battery pack structure according to another embodiment of the present invention.

The battery pack structure according to the present invention will be described with reference to FIGS. 1 and 2 attached hereto. The battery pack structure according to the present invention generally comprises outer frames 100a and 100b, an outer frame cover 200, an electrode terminal 300 and a spring 400. However, the outer frame is comprised of a first outer frame 100a and a second outer frame 100b having a fastening structure. The battery insertion groove 110 is formed such that the four small cylindrical battery cells 700 are inserted side by side, and a plurality of first outer frames 100a are internally formed to support air flow along the circumference of the insertion groove 110. The second outer frame 100b has the same shape as the first outer frame 100a, and the second outer frame 100b has a battery insertion groove so that the opposite electrode of the cell is inserted from the opposite side of the cylindrical battery cell 700. It is fastened with the outer frame 100a.

The outer frame covers 200a and 200b are respectively provided with four terminal grooves 210 in the form of terminals in which the electrode terminals 300 are seated at the lower part of the cover for bolt coupling, and are positioned at the tip of the first outer frame 100a. A first outer frame cover 200a bundled with the first outer frame 100a and a second outer frame cover 200b positioned at the tip of the second outer frame 100b and tied with the second outer frame 100b are formed.

The electrode terminals 300 each include four terminals, and are inserted into the terminal grooves 210 from the lower portions of the outer frame covers 200a and 200b, respectively, and the power supply of the battery cell 700 via the springs 400 respectively contacting the outer frames 100a and 100b. A terminal bolt groove 310 is provided which is bundled with the spring 400 to be supplied.

FIG. 4 of the attached drawings shows a cross-sectional view and a perspective view of the outer frame 100, and when looking at the detailed configuration and operation of the outer frame 100 with reference to the attached FIGS. The first outer frame 100a and the second outer frame 100b are fastened, and their structures are formed to correspond to each other, but first, air is formed along the circumference of the formed battery insertion groove 110 A plurality of circular slots 111 are formed in the interior to support the flow of the circular holes, wherein six or eight circular slots are provided.

Center holes 120a and 120b are formed for flowing or cooling of air generated at the center by the operation of the battery cell 700 located at the center of the four battery insertion grooves 110, and the respective outer frames 100a and 100b Two integrally formed guide bars 130a and 130b are attached in a diagonal direction in a square shape, and integrated holes 132a and 132b are formed integrally with the tips of the guide bars 130a and 130b and into which fastening bolts are inserted. Two insertion guide grooves 133a and 133b may be inserted through the fastening holes 132a and 132b such that the guide bars 130a and 130b may be seated in directions.

That is, the fastening holes of the guide bar of the first outer frame and the guide grooves of the second outer frame are fastened to each other.

Also, four first coupling key grooves 136, 137, 138, and 139 are provided in the center of the side surface of each external frame so that the plurality of external frames can be coupled in a slot shape, and are positioned at the top of the external frames 100a and 100b. The four protrusions 145, 146, 147, and 148 are formed and inserted into and fixed to the outer frame covers 200a and 200b.

The external frame 100a, 100b and the external frame cover 200a, 200b are connected to form a terminal hole 140 where it can be confirmed that the (+) and (-) poles of the battery cell 700 are connected to the spring 400 and the hexagonal terminal. Be done.

The attached FIGS. 5-6 show a cross-sectional view and a perspective view of the outer frame cover 110, and when looking at the detailed configuration and operation of the outer frame cover 110 with reference to the attached FIGS. The outer frame covers 200a and 200b are positioned at the ends of both of the outer frames 100a and 100b and are bound to the outer frame, and the electrode terminals 300 for bolt connection may be seated. As can be done, four terminal grooves 210a, 210b in the form of terminals are provided respectively. That is, the four terminal grooves 211a, 212a, 213a, and 214a of the first outer frame cover 200a and the four terminal grooves 211b, 212b, 213b, and 214b of the second outer frame cover 200b.

Formed in the center of the side of the outer frame cover in a slot shape so as to face the four first combined key grooves 136, 137, 138, 139 of each outer frame when fastened with the outer frames 100a, 100b And a second coupling key groove 211, 212, 213, 214 in which a plurality of frames can be coupled, and the center holes 120a, 120b of the outer frame and the outer frames 100a, 100b are fastened. Air flow holes 220a and 220b for air flow or cooling of heat generated at the center of the seated battery cells 700 facing each other and having four battery insertion grooves 110 are formed, and the outer frame covers 200a and 200b The outer frames 100a and 100b are coupled to each other and provided with holes for fixing screws at the time of fastening. Fixing screw holes holes inserted and fastened when the electrical contact is not so external frame cover 200a, the protection projections 230 which protrude from the 200b is provided.

In addition, the (+) and (-) polarity of the battery cell 700 is confirmed by coupling of the outer frame 100a, 100b and the outer frame cover 200a, 200b, and the heat generated during charging and discharging of the battery cell 700 is released. Four heat dissipation grooves 240 are provided.

In addition, the electrode terminals 300 are separately seated in the terminal grooves 210 of the lower portions of the outer frame covers 200a and 200b, and power is supplied to the battery cells 700 from the upper portions of the outer frame covers 200a and 200b. A groove is provided.

On the other hand, as shown in FIGS. 7 to 10 of the attached drawings, the electrode terminal has a fastening structure of a square plate and a nut, a hexagonal rod, an octagonal rod, or a splined rod instead of a hexagonal rod. It can be processed and selectively applied in the form provided with a tab inside.

The electrode terminal 300 is internally provided with a tab for screw fastening, is formed of a copper alloy material having high electrical conductivity, and is plated with tin or nickel to prevent corrosion. Four battery cells 700 are coupled to the first outer frame cover 200a and the second outer frame cover 200b, and paths through which current flows through the four springs 400 respectively at the (+) pole and the (−) pole of the battery cell 700 I will provide a. In addition, it is connected to the back surface of the battery cell through the hole of the outer frame cover to provide a passage through which current flows from the outside through the bolt fastening.

As shown in FIG. 11 attached, the spring 400 according to the present invention has a flat shape with a rectangular cross section by tin plating a bronze / brass material, and is fitted in the bolt groove 310 of the electrode terminal 300 Also, when the outer frame 100a, 100b and the outer frame cover 200a, 200b are deformed, the battery cell's (+) and (-) contacts maintain elasticity through contact and the current flows smoothly by maintaining elasticity. Are tin-plated to have a rectangular cross section.

In the present invention, the first outer frame 100a and the second outer frame 100b are respectively coupled and fastened with the first outer frame cover 200a and the second outer frame cover 200b, and the guide of the first outer frame 100a After the fastening holes 132a of the bar 130a are combined with the fastening grooves 133b of the second outer frame, the first outer frame 100a and the first outer frame cover 200a, and the second outer frame 100b and the second outer via the fixing screw 500. The frame cover 200b can be strongly tied while biting in the plastic material without the additional nut.

The fixing screw 500 is formed as shown in FIG. 12 attached thereto, and the outer frame and the outer frame cover are bound via a total of eight fixing screws.

On the other hand, after being assembled through the fixing screw 500 according to the above configuration, the protective protrusion 230 protects the electrical connection when performing an additional operation from the outside such as a bus bar for connecting the power source.

Although a plurality of outer frames can be connected using the combination key 600 shown in FIGS. 13 to 14, the first combination key groove 136 of the outer frame can be stacked so that the outer frames 100a and 100b can be stacked in multiple stages, A plurality of coupling keys 601, 602, 603, 604 are respectively inserted between the second coupling key grooves 211, 212, 213, 214 of the outer frame cover 200a, 200b facing the members 137, 138, 139. The outer frames 100a and 100b are stacked to provide rigidity of the device, and desired through a series / parallel connection with a plurality of outer frames 100a and 100b as shown in FIG. 15 attached thereto through the respective terminal grooves 210 of the outer frame covers 200a and 200b. To provide rated voltage and power supply.

Also, as presented in the attached FIGS. 4 to 6, when the outer frames 100a, 100b and the outer frame covers 200a, 200b are fastened, the first coupling key of the outer frame is attached to the center edge of the rectangle. A coupling key groove is formed including the grooves 136, 137, 138, 139 and the second coupling key grooves 211, 212, 213, 214 of the outer frame cover, and the coupling key 600 is inserted into the coupling key groove. A large number of battery modules 1000 can be stacked to complete a robust battery pack.

In the battery pack structure of the present invention, when the battery is connected to the tip of the first external frame 100a and the second external frame 100b, the states of the positive and negative electrodes of the battery cell are confirmed through the terminal slot 140 so that the polarity can be confirmed. The presence or absence of the polarity change of the battery cell can be confirmed.

The external connection key groove can be fixed between unit modules when connecting the multiple unit modules to provide the necessary voltage and capacity after connecting with the external frame and having a complete unit module structure There is a groove into which the coupling key 600 can be inserted.

For example, as the battery pack of 4S4P structure, three battery cells are incorporated since eight battery packs must be connected with (+) poles being (+) poles, and (−) poles being (−) poles. Parallel connection is possible by bolting two unit modules and one unit module in which two battery cells are incorporated to the bus bar connection groove of the external frame.

The outer frames 100a and 100b and the outer frame covers 200a and 200b have the same outer shape, but a coupling key groove is formed at the center of the square so as to couple a large number of unit modules. By inserting the coupling key 600 in accordance with the shape of the above, it is possible to make the instrumental rigidity and prevent movement between unit modules.

100a first external frame 100b second external frame 110 insertion groove 111 circular slot 120a, 120b central hole 130a, 130b guide bar 131a, 131b insertion guide
132a, 132b fastening holes
133a, 133b insertion guide groove
136, 137, 138, 139 first combined key groove 140 terminal slot 145, 146, 147, 148 protrusion 200a first outer frame cover
200b second outer frame cover 210a, 210b terminal groove 211, 212, 213, 214 second coupling key groove 220a, 220b air flow hole
230 Protrusion 240 Heat dissipation groove
300 electrode terminal 400 spring 500 fixing screw 600 coupling key 700 battery cell 1000 battery module

Claims (7)

The battery insertion groove (110) is formed such that four small cylindrical battery cells (700) are respectively inserted side by side, and a plurality of insides are formed to facilitate air flow along the circumference of the insertion groove (110). The battery has the same configuration as the first outer frame (100a) and the first outer frame (100a) provided with the circular slot (111) so that the opposite electrode of the cell is inserted from the opposite side of the cylindrical battery cell (700) A second outer frame (100b) provided with an insertion groove;
Four terminal grooves (210) in the form of terminals are respectively provided so that electrode terminals (300) for bolt coupling can be seated respectively, and are respectively provided on both ends of the outer frame (100a, 100b) A pair of outer frame covers (200a, 200b) positioned and bound with the outer frames (100a, 100b);
Via the spring (400) which is respectively inserted into the terminal groove (210) from the lower part of the outer frame cover (200a, 200b) and makes contact with the outer frame (100a, 100b) and the outer frame cover (200a, 200b) respectively And four electrode terminals (300) provided with terminal bolt grooves (310) which are bundled with springs (400) to supply power of the battery cell (700). Battery pack structure for cylindrical batteries. The external frame (100a, 100b) is
A plurality of circular slots (111) along a circular line to aid air flow circumferentially inside the battery insertion groove (110),
Center holes (120a, 120b) located at the center of the four battery insertion grooves (110) and formed at the center for air flow or cooling,
Four first combined key grooves (136, 137, 138, 139) formed in the shape of a slot in the center of the side of each outer frame so that a plurality of outer frames can be connected.
Four protrusions (145, 146, 147, 148) located at the top of the outer frame (100a, 100b) so as to be inserted and fixedly engaged with the outer frame cover (200a, 200b),
Check the battery cell's (+) and (-) poles, the spring (400) and the hexagonal terminal connected by fastening the outer frame (100a, 100b) and the outer frame cover (200a, 200b). Equipped with terminal holes (140) that can
Two rectangular rectangular insertion guides (131a, 131b) and fastening holes (132a, 132b) integrally formed on the tip of the insertion guide and into which the fastening bolts (500) are inserted. Two guide grooves (133a, 133b) provided with the formed guide bars (130a, 130b), the guide bars (130a, 130b) being seated diagonally and inserted through the fastening holes (132a, 132b) The battery pack structure for a cylindrical battery according to claim 1, comprising: The outer frame cover (200a, 200b) is
Four terminal grooves (210a, 210b) in the form of terminals are respectively provided so that electrode terminals (300) for bolt coupling can be seated respectively, and both tips of the outer frame (100a, 100b) A pair of outer frame covers (200a, 200b), which are respectively bound to the outer frame,
A slot in the center of the side of the outer frame cover to face the four first combined keyways (136, 137, 138, 139) of each outer frame when fastened with the outer frame (100a, 100b) Second key grooves (211, 212, 213, 214), each of which is formed in a shape so that a plurality of frames can be connected.
At the center of the seated battery cell (700) of the four battery insertion grooves (110) facing the center holes (120a, 120b) of the outer frame at the time of fastening with the outer frames (100a, 100b) Air flow holes (220a, 220b) for air flow or cooling of the heat generated
The outer frame cover (200a, 200b) and the outer frame (100a, 100b) are coupled to each other and provided with holes for fixing screws at the time of fastening, and fixing screws are inserted into the holes and electrically at the time of fastening. A protective projection (230) projecting on the outer frame cover (200a, 200b) so as not to be touched
Check the (+) and (-) polarity of the battery cell (700) by coupling the outer frame (100a, 100b) and the outer frame cover (200a, 200b), and when charging and discharging the battery cell (700) The battery pack structure for a cylindrical battery according to any one of claims 1 or 2, comprising four heat dissipation grooves (240) for heat release. The electrode terminal (300) is
Because the battery cells 700 are supplied with power from the top of the outer frame covers 200a and 200b, which are independently seated in the lower terminal grooves 210 of the outer frame covers 200a and 200b. A nut groove is provided,
It can be selectively applied in the form of having a fastening structure of a square plate and a nut, having a hexagonal bar, an octagonal bar, or processing a spline-like bar instead of a hexagonal bar and providing an inner tab The battery pack structure for a cylindrical battery according to claim 1, characterized in that The spring (400) is
It is seated in the bolt groove (310) of the electrode terminal (300) and held in elasticity through contact with the (+) and (-) poles of the battery cell even when the external frame and external frame cover are deformed The battery pack structure for a cylindrical battery according to claim 1, wherein the bronze / brass material is tin-plated so that the current flows smoothly, and has a rectangular shape with a flat cross section. The second combined key groove (200a, 200b) of the outer frame cover (200a, 200b) facing the first combined keyway (136, 137, 138, 139) of the outer frame so that the outer frame (100a, 100b) can be stacked in multiple stages. 211, 212, 213, 214), respectively inserting four coupling keys and laminating a number of outer frames (100a, 100b) to provide rigidity of the device, the outer frame covers (200a, 200b) The battery pack structure for a cylindrical battery according to claim 3, wherein a desired rated voltage and power are provided through serial / parallel connection with a plurality of outer frames (100a, 100b) through each of the terminal grooves (210). A first outer frame (100a) and a second outer frame (100b) are respectively coupled to the first outer frame cover (200a) and the second outer frame cover (200b) for fastening the first outer frame (100a). The fastening holes (132a) of the guide bar (130a) are inserted into the insertion guide grooves (133b) of the second outer frame (130b), and the fastening holes (132b) of the guide bar (130b) of the second outer frame (100b) are After being respectively coupled with the insertion guide grooves (133a) of the outer frame (130a), the first outer frame (100a), the first outer frame cover (200a), and the second outer frame (100b) via the fixing screws (500). ) And the second outer frame cover (200b) are strongly connected while biting in the plastic material without a separate nut Cylindrical battery The battery pack structure according to claim 3, characterized in that it is.

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