JP5235440B2 - Battery pack with forced desorption mechanism - Google Patents

Description

  The present invention relates to an assembled battery having a forcible detaching mechanism for forcibly detaching an electronic device to be connected, and more particularly to an assembled battery optimal for a laptop microcomputer.

An assembled battery that is detachably connected to an electronic device such as a laptop microcomputer has been developed (see Patent Document 1).
JP 2001-43905 A

  The assembled battery described in Patent Document 1 is provided with a detachable claw that is connected to a laptop microcomputer. The attachment / detachment claw is guided by an attachment / detachment recess provided on the bottom surface of the laptop microcomputer, and connects the assembled battery to the microcomputer. The attachment / detachment claw is moved in the horizontal direction while being inserted into the attachment / detachment recess provided in the microcomputer to connect the assembled battery to the microcomputer. The assembled battery is provided with a lock claw that protrudes from the case so that the detachable claw locks the assembled battery in a state where it is connected to the microcomputer. The lock claw protrudes elastically from the case. The lock claw protrudes in a state where the assembled battery is mounted at a fixed position of the microcomputer and is inserted into a lock recess provided on the bottom surface of the microcomputer to prevent the assembled battery from sliding.

  The assembled battery having the above structure has a drawback that it cannot be easily separated from an electronic device such as a microcomputer. In particular, in a state in which the contacts are connected to the electronic device, the assembled battery cannot be easily detached unless the assembled battery is forcibly separated from the electronic device.

  The present invention has been developed for the purpose of solving this drawback. An important object of the present invention is to provide a battery pack having a forcible detachment mechanism that can be easily and easily attached to and detached from an electronic device, and that has a simple structure for an ejector provided for forcibly removing it from the electronic device. is there.

The assembled battery having the forced detachment mechanism of the present invention has the following configuration in order to achieve the above-described object.
The assembled battery is provided with a forced detachment mechanism 3 for forcibly detaching the electronic device 9 in a case 1 containing the battery 2. The forced detachment mechanism 3 is movable toward the electronic device 9 and is connected to the case 1 so as to be able to reciprocate between the push-out position and the connection position of the electronic device 9, and the ejector 4 toward the connection position. A coil spring 5 that is elastically pressed, and a spring guide 6 that is provided on the inner side of the coil spring 5 and that protrudes from the inner surface of the case 1, and the coil spring 5 is disposed at a fixed position of the case 1. And an extrusion mechanism 8 that is connected to a lever 7 provided in the case 1 and moves the ejector 4 from the connection position to the extrusion position. The ejector 4 is formed by integrally molding a first locking stopper 11 at an end portion on the surface side of the case 1 and a second locking stopper 12 at an end portion on the opposite side. The coil spring 5 disposed outside the spring guide 6 is disposed between the second locking stopper 12 and the inner surface of the case 1 so that the second locking stopper 12 on the rear end side is elastic. The ejector 4 is elastically pressed from the attachment / detachment position toward the connection position. When the lever 7 of the pushing mechanism 8 is operated, the forcing / removing mechanism 3 moves the ejector 4 from the connecting position to the pushing position to forcibly separate the electronic device 9 from the case 1.

  In the assembled battery according to the second aspect of the present invention, the electronic device 9 is a laptop type microcomputer, the assembled battery is connected to the bottom surface of the laptop type microcomputer, and the ejector 4 is moved from the bottom to the top. Move from position to extrusion position.

  In the assembled battery according to claim 3 of the present invention, the lever 7 of the forced detachment mechanism 3 is connected to the side surface of the case 1 so as to be able to rotate in a horizontal plane.

  The assembled battery according to claim 4 of the present invention includes a slide base 20 in which the pushing mechanism 8 is reciprocated by the lever 7, and the slide base 20 has an inclined rib 25 that is reciprocated by the lever 7 to push up the ejector 4. .

  In the assembled battery according to claim 5 of the present invention, the spring guide 6 is constituted by a plurality of ribs 6 </ b> A protruding from the inner surface of the case 1.

  In the assembled battery according to claim 6 of the present invention, the ejector 4 is formed in a shape in which the second locking stoppers 12 protrude from both sides of the rear end.

  The assembled battery of the present invention is characterized in that the ejector provided for forcibly removing the battery from the electronic device can have a simple structure while realizing the feature that it can be easily and easily detached from the electronic device. The reason why the assembled battery of the present invention can be easily detached from the electronic device is that it can be forcibly separated from the electronic device by operating the lever to push out the ejector. In addition, the ejector can have a simple structure by integrally forming the ejector with a first locking stopper at the end on the surface side of the case and a second locking stopper at the opposite end. Furthermore, a spring guide is provided inside the coil spring that elastically presses the ejector, and the coil spring is disposed between the second locking stopper and the inner surface of the case, and is provided on the rear end side. This is because the second locking stopper is elastically pressed by the coil spring, and the ejector is elastically pressed from the detaching position to the connecting position. The ejector moves from the coupling position to the pushing position by a pushing mechanism driven by a lever, and forcibly separates the electronic device from the assembled battery.

  The assembled battery according to claim 2 of the present invention is connected to the bottom surface of the laptop type microcomputer, and the ejector is moved from the bottom to the top to move from the connection position to the extrusion position. Since this assembled battery can have a large outer shape, the capacity of the battery stored in the assembled battery can be increased.

  In the assembled battery according to claim 3 of the present invention, the lever of the forced detachment mechanism is connected to the side surface of the case so that it can be rotated in a horizontal plane. The assembled battery can be easily removed from the electronic device.

  The assembled battery according to claim 4 of the present invention includes a slide base in which the push-out mechanism is reciprocated by a lever, and the slide base has an inclined rib that is reciprocated by the lever to push up the ejector. With the simple structure, the lever can be operated to securely press the ejector against the electronic device.

  In the battery pack according to claim 5 of the present invention, the spring guide is composed of a plurality of ribs protruding from the inner surface of the case, so that the ejector can be smoothly pressed while the coil spring is disposed at a fixed position.

  In the assembled battery according to claim 6 of the present invention, since the ejector is formed in a shape in which the second locking stopper protrudes on both sides of the rear end, the coil spring is interposed between the second locking stopper and the case. Can be securely held so as not to come out.

  Embodiments of the present invention will be described below with reference to the drawings. However, the example shown below illustrates the assembled battery having a forced detachment mechanism for embodying the technical idea of the present invention, and the present invention does not specify the assembled battery as the following structure.

  Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The assembled battery having the forced detachment mechanism shown in FIG. 1 and FIG. 2 is compulsory to a laptop microcomputer that is an electronic device 9 (the outline of the outline is shown by a dotted line in FIG. 1) in a case 1 containing the battery 2. A forced detachment mechanism 3 that detaches automatically is provided. In the assembled battery shown in the figure, an output connector 35 connected to the electronic device 9 is provided on the upper surface of the case 1 so as to protrude. The assembled battery is connected to the electronic device 9 and supplies power by connecting the output connector 35 to an input connector (not shown) of the electronic device 9.

  Case 1 has upper case 1B connected to lower case 1A, and a plurality of batteries 2 and forced detachment mechanism 3 are incorporated therein. 3 shows a perspective view with the upper case 1B removed, and FIG. 4 shows a perspective exploded view with the upper case 1B removed. Further, FIGS. 5 and 6 show enlarged perspective views of a portion where the forced detachment mechanism 3 is provided.

[Forced desorption mechanism]
FIGS. 1 and 5 show a state where the forced detachment mechanism 3 connects the assembled battery to the electronic device 9. The lever 7 is housed on the side surface of the case 1 when the assembled battery is connected. The state where the assembled battery is removed from the electronic device 9 is shown in FIGS. In this state, the lever 7 is rotated so as to be pulled out from the case 1. The lever 7 to be rotated causes the ejector 4 to protrude from the case 1 as indicated by an arrow A in FIG. The protruding ejector 4 pushes the bottom surface of the electronic device 9 to forcibly separate the assembled battery from the electronic device 9. Furthermore, the forcible detachment mechanism 3 shown in the figure is provided with a locking hook 30 for connecting the assembled battery to the electronic device 9 in the connected state. The locking hook 30 protrudes from the case 1 toward the electronic device 9 and is locked by a locking portion (not shown) provided on the bottom surface of the electronic device 9 in the connected state. 9 is connected. When the lever 7 is rotated, the locking hook 30 moves as indicated by an arrow B in FIG. 2 and the locked state with the locking portion of the electronic device 9 is released. This assembled battery can be reliably connected to the electronic device 9 by the locking hook 30.

  The forced detachment mechanism 3 for forcibly detaching the assembled battery from the electronic device 9 by performing the above operation can move toward the electronic device 9 and can reciprocate between the pushing position and the connecting position of the electronic device 9. Are connected to the ejector 4, the coil spring 5 is elastically pressing the ejector 4 toward the connection position, and is provided inside the coil spring 5 so as to protrude from the inner surface of the case 1. A spring guide 6 in which the coil spring 5 is disposed at a fixed position of the case 1 and a push-out mechanism 8 which is connected to a lever 7 provided in the case 1 and moves the ejector 4 from the connected position to the push-out position. .

[Ejector]
A state in which the ejector 4 is connected to the case 1 is shown in FIGS. However, these drawings are shown upside down from the actual use state in order to facilitate understanding of the structure of the ejector 4. The ejector 4 shown in these figures is connected to the upper case 1B so as to be able to reciprocate in the vertical direction, that is, between the connecting position and the detaching position. Further, the ejector 4 is provided with a first locking stopper 11 and a second locking stopper 12 at both ends of the columnar portion 10 in order to limit the reciprocating range. The ejector 4 is provided with a first locking stopper 11 and a second locking stopper 12 which are integrally molded in a plastic molding step. The first locking stopper 11 is provided at an end portion on the surface side of the upper case 1B, and the second locking stopper 12 is provided at an end portion on the inner surface side. In the illustrated ejector 4, the first locking stopper 11 is formed into a plate shape having a rectangular outer shape, and the second locking stopper 12 is molded into a shape in which a rod protrudes on both sides of the end portion. .

  The first locking stopper 11 is fitted into a fitting recess 13 provided in the upper case 1B, and is disposed on the same surface as the surface of the upper case 1B at the connection position. The upper case 1 </ b> B is provided with a through hole 14 on the bottom surface of the fitting recess 13 that can move the columnar portion 10 of the ejector 4 up and down. The through-hole 14 has a shape that allows the columnar portion 10 of the ejector 4 to pass therethrough and does not allow the first locking stopper 11 to pass through, ie, the outer shape of the first locking stopper 11. In a state where the assembled battery is connected to the electronic device 9, the ejector 4 is urged by the coil spring 5 to place the first locking stopper 11 in the fitting recess 13.

  The second locking stopper 12 locks the coil spring 5 so as not to come out, and the ejector 4 is arranged at the coupling position with the coil spring 5. Therefore, the second locking stopper 12 is a rod that protrudes to a length that can lock the coil spring 5.

[coil spring]
The coil spring 5 is a push spring and elastically presses the ejector 4 via the second locking stopper 12 and is arranged at the connection position. That is, the coil spring 5 arranges the ejector 4 that is not pushed by the pushing mechanism 8 at the connection position. The coil spring 5 is between the inner surface of the upper case 1B and the second locking stopper 12 and elastically presses the second locking stopper 12. The coil spring 5 elastically pushes down the second locking stopper 12 to place the ejector 4 at the connection position.

[Spring guide]
The spring guide 6 is integrally formed on the plastic upper case 1B. The spring guide 6 is disposed inside the coil spring 5 and outside the columnar portion 10 of the ejector 4. That is, the spring guide 6 is disposed between the coil spring 5 and the columnar portion 10 of the ejector 4. The spring guide 6 is located inside the coil spring 5 and is disposed at a fixed position so that the coil spring 5 can be expanded and contracted. Therefore, the outer shape of the spring guide 6 is made smaller than the inner diameter of the coil spring 5. The spring guide 6 is composed of a plurality of ribs 6A protruding from the inner surface of the lower case 1A. The spring guide 6 shown in the figure is composed of four ribs 6A that are disposed in parallel to each other at the corners of a quadrangle. The spring guide 6 guides the second locking stopper 12 between the ribs 6A, and moves the ejector 4 from the coupling position to the detaching position. Therefore, the interval between the slits 15 provided between the adjacent ribs 6 </ b> A is set to a width that can pass through the rod of the second locking stopper 12.

[lever]
The lever 7 is connected to the lower case 1A via a vertical rotation shaft 16 so as to be rotatable in a horizontal plane. The lever 7 is housed on the side surface of the lower case 1A in the connected position. Therefore, the lower case 1 </ b> A is provided with a recess on the side surface, which is a storage portion 17 that stores the lever 7. Further, the lever 7 is connected to the pressing arm 18 so as to protrude from the rotary shaft 16 to the tip. The pressing arm 18 is made of a metal plate so as to realize sufficient strength. In the lever 7, a portion excluding the pressing arm 18 is formed of plastic, and the pressing arm 18 made of a metal plate is connected to the tip.

[Extrusion mechanism]
When the pushing mechanism 18 is pushed by the pushing arm 18 of the lever 7 and is rotated so that the lever 7 is pulled out from the case 1, the ejecting mechanism 8 projects the ejector 4 from the upper surface of the upper case 1B. To forcibly separate the assembled battery from the electronic device 9. The push-out mechanism 8 shown in the figure includes a slide base 20 that is reciprocated by being pushed by the pressing arm 18 of the lever 7, and a tension spring 21 that pulls the slide base 20.

  As shown in FIGS. 3 to 6, the slide table 20 is built in so as to reciprocate on the side surface of the lower case 1 </ b> A. The lower case 1A is integrally formed with a guide rib 22 that reciprocates the slide table 20 so as to protrude from the inner surface. At one end of the slide table 20, a slit 23 for accommodating the tension spring 21 is provided. The tension spring 21 disposed in the slit 23 moves the slide base 20 in a direction in which the slide base 20 is pressed against the pressing arm 18 of the lever 7. The slide base 20 elastically presses the pressing arm 18 of the lever 7 and stores the lever 7 in the recess that is the storage portion 17 of the lower case 1A. The slide surface 24 on which the slide base 20 presses the pressing arm 18 of the lever 7 has a shape that is parallel to the pressing arm 18 in a state where the lever 7 is stored in the storage portion 17.

  As shown in a partially enlarged perspective view of FIG. 4, the slide table 20 is provided with an inclined rib 25 that pushes up the ejector 4 to the pushing position so as to protrude from the upper surface. The inclined ribs 25 are integrally formed on the plastic slide table 20. Further, the inclined rib 25 is disposed at a position where the ejector 4 can be pushed up. Since the assembled battery shown in the figure has two ejectors 4, inclined ribs 25 are provided below the respective ejectors 4. The inclined rib 25 is formed in a shape in which the upper edge is inclined so that the height changes in the reciprocating direction. The inclined rib 25 is disposed at a position (see FIG. 5) that pushes up the ejector 4 when the slide base 20 is moved to the pushing position (see FIG. 6) and does not push up the ejector 4 when the slide base 20 returns to the coupling position. The That is, the inclined rib 25 is provided so as to extend in the reciprocating direction of the slide table 20 and has a shape in which the upper edge is inclined so as to push up the ejector 4 at the pushing position and not push up the ejector 4 at the connecting position.

  Further, as shown in the partially enlarged perspective view of FIG. 4, the slide table 20 is integrally formed with a slide rib 26 that moves the locking hook 30 to the locking position and the detaching position. The slide rib 26 is a rib provided so as to protrude from the upper surface of the slide table 20, and is inclined so as to reciprocate and move the locking hook 30 in the direction indicated by the arrow B in FIG. The locking hook 30 is connected to the inner surface of the lower case 1A through the cover plate 27 shown in FIG. 3 so as to reciprocate in the direction indicated by the arrow B in FIG. The cover plate 27 opens a slit 28 that penetrates the locking hook 30, and has a guide groove 29 for reciprocating the locking hook 30 on the inner surface as shown in FIG. 11. Thus, the locking hook 30 is reciprocated.

  The locking hook 30 is formed in a shape that connects the hook portion 32 to the base plate 31 that reciprocates along the guide groove 29 of the cover plate 27. The hook portion 32 is integrally formed with plastic as a shape protruding vertically from the base plate 31. As shown in the bottom perspective view of FIG. 11, the base plate 31 is provided with a drive portion 33 that protrudes from the lower surface so as to contact the slide rib 26 (shown by a chain line in the drawing) of the slide table 20. Further, the base plate 31 of the locking hook 30 is connected to the cover plate 27 via a pressing spring 34. When the slide base 20 is moved to the pushing position, the above-described locking hook 30 moves in the direction indicated by the arrow A in FIG. 11 while the slide rib 26 slides on the surface of the drive unit 33 of the base plate 31. At this time, the drive unit 33 of the base plate 31 is pressed by the slide rib 26 and moves in the direction indicated by the arrow B in the figure. In this state, the locking hook 30 moves as indicated by an arrow B in FIG. 2, and the locked state with the locking portion of the electronic device is released. When the slide table 20 returns to the coupling position, the slide rib 26 moves in the direction opposite to the arrow A in FIG. 11, the base plate 31 is pressed by the pressing spring 34, and the locking hook 30 is opposite to the arrow B in the figure. Move in the direction. In this state, the locking hook 30 returns to the connection position, and the locking portion of the electronic device can be locked.

  In the above assembled battery, when the lever 7 is disposed at the connecting position in FIG. 1, the slide base 20 is not moved by the pressing arm 18 as shown in FIG. 5. The slide table 20 in this position does not push up the ejector 4 with the inclined rib 25, and the slide rib 26 of the slide table 20 does not press the drive portion 33 of the lock hook 30, so that the lock hook 30 is moved to the electronic device. 9 is disposed at the locking position. As shown in FIG. 2, when the lever 7 is rotated to a position where it is pulled out from the side surface of the case 1, as shown in FIG. 6, the pressing arm 18 of the lever 7 pushes the slide base 20 to move to the detaching position. In the slide table 20 that moves to the detaching position, the inclined rib 25 pushes up the ejector 4 and moves the ejector 4 to the pushing position. The ejector 4 pushed out to the pushing position pushes up the electronic device 9 from the bottom surface and forcibly separates it from the assembled battery. Further, the slide rib 26 of the slide base 20 moves the driving portion 33 of the locking hook 30 to release the locking state of the locking hook 30. Therefore, when the lever 7 is pulled out from the case 1, the assembled battery is forcibly separated from the electronic device 9.

It is a perspective view of the assembled battery which has the forced detachment mechanism concerning one Example of this invention. It is a perspective view which shows the state which removes the assembled battery shown in FIG. 1 from an electronic device. It is the perspective view which removed the upper case of the assembled battery shown in FIG. FIG. 4 is a partially enlarged exploded perspective view of the assembled battery shown in FIG. 3. It is an expansion perspective view which shows the forced desorption mechanism of the state which connects an assembled battery with an electronic device. It is an expansion perspective view which shows the forced desorption mechanism of the state which removes an assembled battery from an electronic device. It is a partially expanded perspective view of an upper case. It is a disassembled perspective view which shows the connection structure of the ejector of the upper case shown in FIG. It is an expansion disassembled perspective view which shows the connection structure of an upper case and an ejector. It is an expansion perspective view which shows the connection structure of an upper case and an ejector. It is a bottom perspective view of a locking hook.

Explanation of symbols

1 ... Case 1A ... Lower case
DESCRIPTION OF SYMBOLS 1B ... Upper case 2 ... Battery 3 ... Forced removal mechanism 4 ... Ejector 5 ... Coil spring 6 ... Spring guide 6A ... Rib 7 ... Lever 8 ... Extrusion mechanism 9 ... Electronic device 10 ... Columnar part 11 ... 1st latching stopper 12 ... Second locking stopper 13 ... Fitting recess 14 ... Through hole 15 ... Slit 16 ... Rotating shaft 17 ... Storage part 18 ... Pressing arm 20 ... Slide base 21 ... Tension spring 22 ... Guide rib 23 ... Slit 24 ... Slide surface 25 ... Inclined rib 26 ... Slide rib 27 ... Cover plate 28 ... Slit 29 ... Guide groove 30 ... Lock hook 31 ... Base plate 32 ... Hook part 33 ... Drive part 34 ... Pressing spring 35 ... Output connector

Claims (6)

An assembled battery in which a case (1) containing the battery (2) is provided with a forced detachment mechanism (3) for forcibly detaching the electronic device (9),
The ejector (4), wherein the forced detachment mechanism (3) is movable toward the electronic device (9) and is connected to the case (1) so as to reciprocate between the pushing position and the connecting position of the electronic device (9). A coil spring (5) that elastically presses the ejector (4) toward the coupling position, and is provided inside the coil spring (5) and protruding from the inner surface of the case (1). The coil spring (5) is connected to a spring guide (6) arranged at a fixed position of the case (1) and a lever (7) provided on the case (1) to connect the ejector (4). An extrusion mechanism (8) for moving from the coupling position to the extrusion position,
Furthermore, the ejector (4) is integrally formed with a first locking stopper (11) at the end on the surface side of the case (1) and a second locking stopper (12) at the opposite end. Molded and provided,
A coil spring (5) disposed outside the spring guide (6) is disposed between the second locking stopper (12) and the inner surface of the case (1), so that the rear end side 2 elastically pressing the locking stopper (12), and elastically pressing the ejector (4) from the attachment / detachment position toward the connection position,
When the lever (7) of the pushing mechanism (8) is operated, the pushing mechanism (8) moves the ejector (4) from the connecting position to the pushing position, and the electronic device (9) is moved from the case (1). An assembled battery having a forced desorption mechanism configured to force separation.   The electronic device (9) is a laptop-type microcomputer, and the assembled battery is connected to the bottom surface of the laptop-type microcomputer, and the ejector (4) is moved from the bottom to the top to move from the connection position to the extrusion position. An assembled battery having the forced desorption mechanism according to claim 1.   The assembled battery having a forced detachment mechanism according to claim 1, wherein the lever (7) of the forced detachment mechanism (3) is connected to a side surface of the case (1) so as to be rotatable in a horizontal plane.   The pushing mechanism (8) includes a slide base (20) reciprocated by a lever (7), and this slide base (20) is reciprocated by the lever (7) to push up the ejector (4) ( 25. A battery pack having the forced detachment mechanism according to claim 1 having 25).   The assembled battery having a forced detachment mechanism according to claim 1, wherein the spring guide (6) is composed of a plurality of ribs (6A) protruding from the inner surface of the case (1).   The assembled battery having a forced detachment mechanism (3) according to claim 1, wherein the ejector (4) is formed in a shape in which a second locking stopper (12) protrudes on both sides of a rear end.

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