Patent Description:
Recently, secondary batteries capable of charging and discharging have been widely used as an energy source for wireless mobile devices. In addition, secondary batteries are attracting attention as a power source for electric vehicles (EVs) and hybrid electric vehicles (HEVs), which are proposed as a solution to air pollution such as existing gasoline vehicles and diesel vehicles that use fossil fuels.

In small mobile devices, one or two or three battery cells per device are used, whereas in medium and large devices such as automobiles, due to the need for high power and large capacity, medium and large battery modules electrically connecting multiple battery cells are used. A battery pack implemented by connecting such multiple battery cells is used.

Since such battery packs are preferably manufactured in a small size and weight as possible, battery packs may be stacked with a high degree of integration, and square shape cells, pouch type cells, etc. having a small weight to capacity are mainly used as battery cells applied to a battery pack.

In addition, in order for the battery pack to provide output and capacity required in a given apparatus or device, it is necessary to electrically connect a plurality of battery cells in series, in parallel, or in a combination of series and parallel. For example, the battery cells included in the battery pack may be welded to a plurality of bus bar plates provided with electrode terminals in the form of metal plates and electrically connected in series, in parallel, or in a combination of series and parallel.

Moreover, since the battery pack has a structure in which a plurality of battery cells are combined, the battery pack requires a sensing means capable of sensing a current generated from the battery cells in order to detect when some battery cells are overvoltage, overcurrent, or overheating. Such sensing means are individually connected to the battery cells to provide voltage/current information of the battery cells to a battery management unit.

Such a battery management unit may include a printed circuit board in which a printed circuit is embedded. In addition, the battery management unit needs a connector mounted on the printed circuit board in order to exchange signals with an external device or to receive power from the outside to charge the battery cells or to supply power to the external device to discharge the battery cells. Such a connector may be repeatedly connected to and disconnected from a counterpart connector.

However, in the related art, because a high current flows through a connector applied to a high capacity and high current battery pack, it is easy to heat up to a high temperature due to electrical resistance. Accordingly, a high temperature connector may damage a printed circuit board which is an internal configuration of the battery pack, or a contacted pack housing may melt, and there is a high possibility of getting burned when a user holds the battery pack with his or her hand.

<CIT>, <CIT> and <CIT> relate to connection terminals.

The present disclosure is designed to solve the problems of the related art, and therefore the present disclosure is directed to providing a connector with increased heat dissipation efficiency and ease of use.

The invention is defined in the set of claims. In one aspect of the present disclosure, there is provided a connector including a mounting portion electrically connected to a printed circuit board of a battery management unit configured to manage voltages of a plurality of battery cells; and a connection portion comprising two or more connection terminals configured to contact a counterpart connection terminal and comprising a concave-convex structure formed on an outer surface of the connection terminal.

The concave-convex structure includes a plurality of grooves respectively formed in the two or more connection terminals.

The plurality of grooves is formed in an inner side surface of the two or more connection terminals facing each other, and an outer side surface that is an opposite surface to the inner side surface.

The concave-convex structure includes a plurality of protrusions respectively formed in the two or more connection terminals.

The plurality of protrusions are formed on an inner side surface of the two or more connection terminals facing each other and an outer side surface that is an opposite surface to the inner side surface.

The two or more connection terminals have a shape extending side by side in one direction from a main body of the mounting portion.

The two or more connection terminals are configured such that the counterpart connection terminal is inserted between the two or more connection terminals.

An end portion of each of the plurality of protrusions formed on the inner side surface of the connection terminal protrude to contact the counterpart connection terminal.

The plurality of protrusions formed on the inner side surface of the connection terminal may have different sizes protruding toward the counterpart connection terminal.

The end portion of each of the plurality of protrusions formed on the inner side surface of the connection terminal may include a bending structure bent in a direction in which the counterpart connection terminal is inserted.

In another aspect of the present disclosure, there is provided a battery management unit including a connector and a printed circuit board electrically connected to the connector.

In another aspect of the present disclosure, there is provided a battery pack including the battery management unit.

According to an aspect of the present disclosure, a connection portion includes two or more connection terminals configured to contact a counterpart connection terminal, and a concave-convex structure formed on an outer surface of the connection terminal, and thus, when a connector of the present disclosure transmits a current to the counterpart connection terminal, the connector may effectively dissipate heat generated by resistance to air. Accordingly, it is possible to prevent the connector from having high heat and damaging a printed circuit board. In addition, it is possible to effectively reduce an increase in the internal temperature of a battery pack.

In addition, according to an aspect of the present disclosure, a plurality of grooves are formed in inner side surfaces and outer side surfaces of the two or more connection terminals facing each other, and thus, compared to the case where the concave-convex structure is formed only on one side of the inner side surface and the outer side surface, it is possible to further increase a heat dissipation area. Accordingly, it is possible to effectively increase the amount of heat dissipation of the connector.

Moreover, according to an aspect of the present disclosure, a plurality of protrusions are formed on inner side surfaces and outer side surfaces of the two or more connection terminals facing each other, and thus, compared to the case where the concave-convex structure is formed only on one side of the inner side surface and the outer side surface, it is possible to further increase a heat dissipation area. Accordingly, it is possible to effectively increase the amount of heat dissipation of the connector.

In addition, according to an aspect of the present disclosure, an end portion of each of a plurality of protrusions formed on the inner side surface of the connection terminal protrudes to contact the counterpart connection terminal, and thus the present disclosure may effectively increase contact points between the connection terminal and the counterpart connection terminal. Accordingly, it is possible to improve the connection reliability of the connector 100A. Furthermore, the protrusions may elastically guide an insertion direction of the counterpart connection terminal.

<FIG> is a front perspective view schematically showing a connector and a battery pack according to an embodiment of the present disclosure. <FIG> is a rear perspective view schematically showing a connector and a battery pack according to an embodiment of the present disclosure. <FIG> is a perspective view schematically showing a connector according to an embodiment of the present disclosure.

Referring to <FIG>, a connector <NUM> according to an embodiment of the present disclosure includes a mounting portion <NUM> and a connection portion <NUM>.

Specifically, the mounting portion <NUM> may be configured to be electrically connected to a printed circuit board <NUM> provided in a battery management unit <NUM> configured to manage voltages of a plurality of battery cells <NUM>. The mounting portion <NUM> may include a lead 110b connected to a printed circuit embedded in the printed circuit board <NUM>. The lead 110b may have a shape protruding downward.

A part of the lead 110b may be inserted through the printed circuit board <NUM>. The lead 110b may have a structure extending downward to be electrically connected to the printed circuit board <NUM>. The lead 110n may be inserted into the through hole H1 provided in the printed circuit board <NUM> and electrically connected to the printed circuit of the printed circuit board <NUM> by soldering.

In addition, the mounting portion <NUM> may include a main body 110a having an end portion connected to the lead 110b. For example, as shown in <FIG>, when viewed in the F direction of <FIG>, the mounting portion <NUM> may include the main body 110a of a plate shape extending in a horizontal direction, and two leads 110b bent downward and extending from both ends of the main body 110a in a front and rear direction.

Here, terms representing directions such as before, after, left, right, up, and down described in the present specification may vary depending on the position of an observer or the shape of an object that is placed. However, in the present specification, for convenience of description, the directions such as front, rear, left, right, up, and down are indicated separately based on when viewed in the F direction.

Specifically, the connection portion <NUM> may have a plate shape erected in a vertical direction to contact a counterpart connection terminal (see <NUM> of <FIG>). Here, the 'counterpart connection terminal <NUM>' refers to a connection terminal that contacts the connector <NUM> in order for the connector <NUM> to transfer a current transferred from a plurality of battery cells <NUM> to an external device or receive power from a charger to charge the plurality of battery cells <NUM>. That is, power of a battery pack <NUM> may be supplied to an external device through the counterpart connection terminal <NUM>. The external device may be, for example, an electric motor (not shown) of a vacuum cleaner.

The counterpart connection terminal <NUM> may include an alloy having aluminum, nickel, copper, or the like having excellent electrical conductivity. Likewise, the connection portion <NUM> and the mounting portion <NUM> may include an alloy having aluminum, nickel, copper, etc. having excellent electrical conductivity.

<FIG> is a plan view schematically showing a connector according to an embodiment of the present disclosure.

Referring back to <FIG> along with <FIG>, the connection portion <NUM> includes a concave-convex structure <NUM> to increase a heat dissipation surface area. For example, the concave-convex structure <NUM> may include a plurality of grooves <NUM> formed in the respective two or more connection terminals <NUM>. The groove <NUM> may have a shape linearly extending in a vertical direction in an outer surface of the connection portion <NUM>. The plurality of grooves <NUM> may be arranged to be spaced apart by a predetermined distance in a front and rear direction.

Accordingly, according to this configuration of the present disclosure, the connection portion <NUM> includes the two or more connection terminals <NUM> configured to contact the counterpart connection terminal <NUM>, and the concave-convex structure <NUM> formed on the outer surface of the connection terminal <NUM>, and thus, when the connector <NUM> of the present disclosure transmits a current to the counterpart connection terminal <NUM>, the connector <NUM> may effectively dissipate heat generated by resistance to air. Accordingly, it is possible to prevent the connector <NUM> from having high heat and damaging the printed circuit board <NUM>. In addition, it is possible to effectively reduce an increase in the internal temperature of the battery pack <NUM>.

More specifically, the plurality of grooves <NUM> may be formed in an inner side surface 132a of each of the two or more connection terminals <NUM> facing each other, an outer side surface 132b that is an opposite surface to the inner side surface 132a, or the inner side surface 132a and the outer side surface 132b. For example, as shown in <FIG>, the plurality of grooves <NUM> may be provided in the inner side surface 132a and the outer side surface 132b of the two or more connection terminals <NUM>.

Accordingly, according to this configuration of the present disclosure, the plurality of grooves <NUM> are formed in the inner side surfaces 132a and the outer side surfaces 132b of the two or more connection terminals <NUM> facing each other, and thus, compared to the case where the concave-convex structure <NUM> is formed only on one side of the inner side surface 132a and the outer side surface 132b, the heat dissipation area may further increase. Accordingly, the amount of heat dissipation of the connector <NUM> may effectively increase.

Referring back to <FIG> and <FIG>, the two or more connection terminals <NUM> may have a shape extending side by side in one direction from the main body 110a of the mounting portion <NUM>. For example, as shown in <FIG>, the two connection terminals <NUM> may have a plate shape extending in an upper direction from both ends of the main body 110a of the mounting portion <NUM> in the left and right direction. A part of the two connection terminals <NUM> may have a shape protruding forward from the main body 110a of the mounting portion <NUM>.

In addition, the two or more connection terminals <NUM> may be configured such that the counterpart connection terminal (<NUM> of <FIG>) is inserted between the two or more connection terminals <NUM>. For example, as shown in <FIG>, the two connection terminals <NUM> may be configured such that the counterpart connection terminal <NUM> is inserted between the two connection terminals <NUM>.

Moreover, the connection terminal <NUM> may be elastically deformable and may have a contact structure 132c. For example, the contact structure 132c of each of the two or more connection terminals <NUM> may be configured to contact the counterpart connection terminal <NUM>. As shown in <FIG>, the counterpart connection terminal (<NUM> of <FIG>) may be interposed between the respective contact structures 132c of the two connection terminals <NUM>. In this regard, the elastically deformed contact structure 132c of the connection terminal <NUM> may pressurize an outer surface of the counterpart connection terminal <NUM>.

Further, the contact structures 132c of the two or more connection terminals <NUM> may extend in a direction in which the contact structures 132c are closer to each other forward, and then extend in a direction in which the contact structures 132c are away from each other at a predetermined distance. For example, as shown in <FIG>, the contact structures 132c are provided in the respective two connection terminals <NUM>, and the contact structures 132c may extend in a direction in which the contact structures 132c are closer to each other forward, and then extend in a direction in which the contact structures 132c are away from each other at a predetermined distance.

Further, in order to improve the reliability of contact between the contact structure 132c of each of the two or more connection terminals <NUM> and the counterpart connection terminal <NUM>, the two or more connection terminals <NUM> may include cutting structures 13j to be divided into a plurality of individual terminals. The cutting structure 132j may have a slit <NUM> extending in a horizontal direction so that some of the two or more connection terminals <NUM> are divided in a vertical direction. That is, as shown in <FIG>, the two or more connection terminals <NUM> may include the cutting structure 132j that is cut in a horizontal direction from a front end thereof to a predetermined depth. Accordingly, the connection portion <NUM> may have four connection points with the counterpart connection terminal (<NUM> in <FIG>).

<FIG> is a perspective view schematically showing a connector according to another embodiment of the present disclosure. <FIG> is a plan view schematically showing a connector according to another embodiment of the present disclosure.

Referring to <FIG> and <FIG>, the concave-convex structure <NUM> of a connector 100A according to another embodiment may include a plurality of protrusions 134p formed on the respective two or more connection terminals 132A. Here, the protrusion 134p may have a shape linearly extending in a vertical direction on an outer surface of the connection portion 130A. The plurality of protrusions 134p may be arranged spaced apart by a predetermined distance in a front and rear direction.

More specifically, the plurality of protrusions 134p may be formed on the inner side surface 132a of each of the two or more connection terminals 132A facing each other, the outer side surface 132b that is an opposite surface to the inner side surface 132a, or the inner side surface 132a and the outer side surface 132b. For example, as shown in <FIG>, the plurality of protrusions 134p may be provided on the inner side surface 132a and the outer side surface 132b of the two or more connection terminals 132A.

Accordingly, according to this configuration of the present disclosure, the plurality of protrusions 134p are formed on the inner side surfaces 132a and the outer side surfaces 132b of the two or more connection terminals 132A facing each other, and thus, compared to the case where the concave-convex structure <NUM> is formed only on one side of the inner side surface 132a and the outer side surface 132b, the heat dissipation area may further increase. Accordingly, the amount of heat dissipation of the connector 100A may effectively increase.

Referring back to <FIG>, an end portion of each of the plurality of protrusions 134p1 formed on the inner side surface 132a of the connection terminal 132A may protrude to contact the counterpart connection terminal <NUM>. That is, the plurality of protrusions 134p1 may protrude in a direction in which the counterpart connection terminal <NUM> is located. In addition, the end portions of the plurality of protrusions 134p1 in a protruding direction may be configured to contact a side surface of the connection terminal 132A in the horizontal direction.

In addition, the plurality of protrusions 134p1 formed on the inner side surface 132a of the connection terminal 132A may have different sizes protruding toward the counterpart connection terminal <NUM>. For example, as shown in <FIG>, the plurality of protrusions 134p1 may be configured to have a longer length protruding toward the counterpart connection terminal <NUM> as the plurality of protrusions 134p1 are located on the rear. In this regard, the protrusion may be integral with the connection terminal 132A, and may include an electrically conductive metal.

Accordingly, according to this configuration of the present disclosure, the end portion of each of the plurality of protrusions 134p1 formed on the inner side surface 132a of the connection terminal 132A protrudes to contact the counterpart connection terminal <NUM>, and thus the present disclosure may effectively increase contact points between the connection terminal 132A and the counterpart connection terminal <NUM>. Accordingly, the connection reliability of the connector 100A may be improved. Furthermore, the protrusions 134p1 may elastically guide an insertion direction of the counterpart connection terminal <NUM>.

<FIG> is a plan view schematically showing a connector according to another embodiment of the present disclosure. When compared with the connector 100A of <FIG>, a connector 100B shown in <FIG> has the same structures and configurations, except that the formation of protrusions provided on the inner side surface 132a is different. Therefore, descriptions of the remaining configurations of the connector 100B of <FIG> are omitted.

Referring back to <FIG>, in the connector 100B according to another embodiment, an end portion of each of a plurality of protrusions 134p2 formed on the inner side surface 132a of the connection terminal 132B of a connection portion 130B may have a bending structure bent in a direction in which the counterpart connection terminal <NUM> is inserted. This is to prevent an increase in the friction when the counterpart connection terminal <NUM> is inserted and contacts the plurality of protrusions 134p2. The bent end portion of each of the plurality of protrusions 134p2 may be configured to guide the direction in which the counterpart connection terminal <NUM> is inserted.

For example, as shown in <FIG>, the end portion of each of the plurality of protrusions 134p2 formed on the inner side surface 132a of the connection terminal 132B has the structure bent in the direction into which the counterpart connection terminal <NUM> is inserted, and thus the friction generated in a process of inserting the counterpart connection terminal <NUM> may be effectively reduced, so that the counterpart connection terminal <NUM> may be inserted smoothly. Accordingly, there is an advantage in that it is easy to connect the counterpart connection terminal <NUM> and the connection terminal 132B.

<FIG> is an exploded perspective view schematically showing components of a battery pack according to an embodiment of the present disclosure.

Referring to <FIG>, the battery management unit <NUM> according to the present disclosure includes the plurality of connectors <NUM> and the printed circuit board <NUM> electrically connected to the plurality of connectors <NUM>.

Moreover, the battery pack <NUM> according to the present disclosure includes the battery pack <NUM> including the plurality of battery cells <NUM> and the battery management unit <NUM>. That is, the battery pack <NUM> according to the present disclosure may include the battery management unit <NUM> as various devices for controlling charging and discharging of the plurality of battery cells <NUM>.

Specifically, the battery cell <NUM> may be a cylindrical battery cell. In addition, the cylindrical battery cell <NUM> may include a cylindrical battery can <NUM> and an electrode assembly (not shown) accommodated in the battery can <NUM>.

Here, the battery can <NUM> includes a material having high electrical conductivity, and for example, the battery can <NUM> may include aluminum, steel, or copper. In addition, electrode terminals 211a and 211b may be respectively formed on both ends of the battery can <NUM> in a horizontal direction.

Specifically, the electrode terminal <NUM> may include a first electrode terminal 211a and a second electrode terminal 211b having different electrical polarities. In addition, when viewed in the F direction (shown in <FIG>), the first electrode terminal 211a may be formed on one end (a front end) of the battery can <NUM> in the horizontal direction, and the second electrode terminal 211b may be formed on the other end (a rear end) in the horizontal direction.

Further, the electrode assembly may be formed in a structure wound in a jelly-roll type with a separator interposed between a positive electrode and a negative electrode. In addition, a positive electrode tab (not illustrated) may be attached to the positive electrode (not illustrated) to be connected to the first electrode terminal 211a on the front end of the battery can <NUM>. Furthermore, a negative electrode tab (not illustrated) may be attached to the negative electrode (not illustrated) to be connected to the second electrode terminal 211b on the rear end of the battery can <NUM>.

For example, as shown in <FIG>, the battery pack <NUM> may include <NUM> cylindrical battery cells <NUM> arranged in one direction. In addition, the first electrode terminals 211a of the <NUM> cylindrical battery cells <NUM> may be disposed to be adjacent to the second electrode terminals 211b having different polarities.

However, the battery cell <NUM> according to the present disclosure is not limited to the cylindrical battery cell <NUM> described above, and various types of battery cells <NUM> known at the time of filing of the present application may be employed.

The battery pack <NUM> may further include a pack housing <NUM> in which an internal space accommodating the plurality of battery cells <NUM> is formed.

Specifically, the pack housing <NUM> may include an electrically insulating material. For example, the pack housing <NUM> may include a plastic material such as polyvinyl chloride. In addition, the pack housing <NUM> may include a first case <NUM> and a second case <NUM>. A plurality of hollow structures H2 may be formed in the first case <NUM> and the second case <NUM> to surround an outer surface of an upper portion or a lower portion of the cylindrical battery cell <NUM> so that a plurality of cylindrical battery cells <NUM> may be accommodated.

Furthermore, a bolt fastening structure may be formed in the first case <NUM> and the second case <NUM>. For example, as shown in <FIG>, fastening holes S1 configured to make four bolts <NUM> inserted thereinto may be formed in the first case <NUM> and the second case <NUM>. In addition, the four bolts <NUM> are fastened to the fastening holes S1 of the first case <NUM> and the second case <NUM>, so that a rear portion of the first case <NUM> and a front portion of the second case <NUM> may be coupled to each other.

In addition, inlet grooves <NUM> may be formed in outer surfaces of the first case <NUM> and the second case <NUM> of the pack housing <NUM> so that at least a part of the connection portion <NUM> and the sensing portion <NUM> of the bus bar plate <NUM> is inserted and fixed.

Specifically, the inlet groove <NUM> formed on the outer surface of the pack housing <NUM> may have an inner surface having a size corresponding to the outer shape of the bus bar plate <NUM>. For example, as shown in <FIG>, the inlet groove <NUM> into which the connection portion <NUM> of the bus bar plate <NUM> may be inserted and embedded may be formed in the outer surface of the front of the first case <NUM>.

In addition, the inlet groove <NUM> into which a part of the sensing portion <NUM> of the bus bar plate <NUM> may be inserted and fixed may be formed in an upper outer surface of the first case <NUM>. Similarly, the inlet groove <NUM> may also be formed in a rear outer surface and an upper outer surface of each of the second case <NUM> of the pack housing <NUM> so that a part of the connection portion <NUM> and the sensing portion <NUM> of the bus bar plate <NUM> may be inserted and fixed.

Accordingly, according to this configuration of the present disclosure, the inlet grooves <NUM> may be formed in the outer surface of the pack housing <NUM> so that at least a part of the connection portion <NUM> and the sensing portion <NUM> of the bus bar plate <NUM> is inserted and fixed, and thus the busbar plate <NUM> may stably establish an electrical connection between the plurality of battery cells <NUM>, and prevent the busbar plate <NUM> from being damaged from external substances. In addition, since the sensing portion <NUM> of the bus bar plate <NUM> may be prevented from flowing due to an external impact, the electrical connection between the battery management unit <NUM> and the plurality of battery cells <NUM> may be stably maintained. Accordingly, durability of the battery pack <NUM> may be improved.

In addition, the printed circuit board <NUM> on which the plurality of connectors <NUM> are mounted may be mounted to the upper portion of the pack housing <NUM>.

Meanwhile, in the present specification, although the terms indicating directions such as up, down, left, right, front, and back are used, it is apparent to those skilled in the art that these terms are for convenience of explanation only and vary depending on the position of a target object or the position of an observer.

Claim 1:
A connector (<NUM>) comprising:
a mounting portion (<NUM>) electrically connected to a printed circuit board of a battery management unit (<NUM>) configured to manage voltages of a plurality of battery cells; and
a connection portion (<NUM>) comprising two or more connection terminals (<NUM>) configured to contact a counterpart connection terminal (<NUM>) and comprising a concave-convex structure (<NUM>) formed on an outer surface of the connection terminal (<NUM>),
wherein the concave-convex structure (<NUM>) comprises a plurality of protrusions (134p, 134p1, 134p2) respectively formed in the two or more connection terminals (<NUM>),
characterised in that the plurality of protrusions (134p, 134p1, 134p2) are formed on an inner side surface (132a) of the two or more connection terminals (<NUM>) facing each other and an outer side surface (132b) that is an opposite surface to the inner side surface (132a).