JP5888018B2 - Charger - Google Patents

Description

  The present invention relates to a charger, and more particularly to a charger for charging a battery pack used for an electric tool or the like.

  Conventionally, a battery pack is used as a power source for an electric tool or the like, and such a battery pack is charged by a dedicated charger.

  A battery pack used for such a power tool has a relatively large capacity and a high voltage. In order to rapidly charge a battery pack having a large capacity and a high voltage, it is a mainstream to use a charger having a large output.

  However, in the case of a charger having a large output, the temperature of the electric element inside the charger during charging tends to rise. As another problem, when charging a battery pack used with a high-output power tool, there is a problem that the battery pack immediately after use is at a high temperature and cannot be charged at a high temperature.

  In order to solve such problems, there is a charger in which a cooling fan is used to forcibly cool the inside of the charger and the battery pack (for example, Patent Document 1).

JP 2009-026774 A

  However, in the conventional charger described above, since the outside air is sucked from the narrow space at the bottom of the charger and used for cooling, the intake of air does not go smoothly and there is a limit to improving the cooling performance.

  Then, this invention makes it a subject to improve cooling performance in the charger provided with the cooling fan for cooling the inside of a charger and a battery pack.

  The present invention has been made to solve the above-described problems, and is characterized by the following.

(Claim 1)
The invention described in claim 1 is characterized by the following points.

That is, a charger for charging a battery pack, an attachment portion on which an upper surface of the battery pack can be attached, a cooling fan having a rotation shaft arranged in a substantially horizontal direction, and a lee of the cooling fan. A fan cover for diverting the cooling air generated by the cooling fan, and the fan cover for vertically cooling the battery pack, and a vertical air guide path for guiding the cooling air upward to cool the battery pack. A horizontal air guide path that guides the cooling air in a horizontal direction, and a surface of the region where the electronic components inside the charger are disposed is potted, and the fan cover includes a region subjected to the potting It is disposed at the boundary with the region where the cooling fan is provided, and at least a part of the side part and the bottom part is provided with a seal part for preventing the potting material from flowing out. To.

(Claim 2 )
The invention according to claim 2, characterized by the following points.

That is, a charger for charging a battery pack, an attachment portion on which an upper surface of the battery pack can be attached, a cooling fan having a rotation shaft arranged in a substantially horizontal direction, and a lee of the cooling fan. A fan cover for diverting the cooling air generated by the cooling fan, and the fan cover for vertically cooling the battery pack, and a vertical air guide path for guiding the cooling air upward to cool the battery pack. A horizontal air guide path that guides cooling air in a horizontal direction, and the fan cover includes a drainage portion for receiving water that accumulates on an upper surface of the attachment portion and enters the inside of the charger. The part is characterized in that the upper part opens at the lower part of the mounting part, and a drainage hole communicating with the outside is formed at the lower part.

(Claim 3 )
The invention according to claim 3, characterized by the following points.

That is, a charger for charging a battery pack, an attachment portion on which an upper surface of the battery pack can be attached, a cooling fan having a rotation shaft arranged in a substantially horizontal direction, and a lee of the cooling fan. A fan cover for diverting the cooling air generated by the cooling fan, and the fan cover for vertically cooling the battery pack, and a vertical air guide path for guiding the cooling air upward to cool the battery pack. A horizontal air guide path for guiding the cooling air in the horizontal direction, wherein the horizontal air guide path is inclined so that the bottom surface becomes higher as it goes downwind.

(Claim 4 )
The invention described in claim 4 is characterized by the following points in addition to the characteristics of the invention described in claim 3 described above.

  That is, the charger case is formed by joining the upper case and the lower case up and down, and the end on the leeward side of the inclined bottom surface of the horizontal air guide path is the height of the rise of the lower case. It is characterized by being at substantially the same height or higher than the rising height of the lower case.

The present invention is as described above, and includes a cooling fan having a rotating shaft arranged in a substantially horizontal direction, so that the intake port can be opened to the side of the charger, so that air can be taken in smoothly. , Cooling performance can be improved.

  A fan cover disposed downstream of the cooling fan for diverting the cooling air generated by the cooling fan, the fan cover including a vertical air guide path that guides the cooling air upward to cool the battery pack; Equipped with a horizontal air guide that guides the cooling air in the horizontal direction to cool the inside of the charger, so that the air volume of the cooling air is controlled by the slit (wall) distribution rate to make the inside of the battery pack and the charger efficient Therefore, the battery pack and the charger can be prevented from becoming hot, and the charging time can be prevented from becoming longer.

Further, the invention according to claim 1 is as described above, and the surface of the region where the electronic components inside the charger are arranged is potted, and the fan cover includes the region where the potting is performed. A seal portion is provided at a boundary with the region where the cooling fan is provided, and at least a part of the side portion and the bottom portion to prevent the potting material from flowing out. For this reason, even in the structure in which the rotation axis of the cooling fan is arranged in a substantially horizontal direction and the intake port is provided on the side portion, the potting material does not flow out from the side intake port.

  Furthermore, by sealing at least a part of the side and bottom of the fan cover, it is possible to prevent the cooling air generated by the cooling fan from escaping from the gaps on the side of the fan cover and the like. Can be used for cooling efficiently. Further, the fan cover seal also prevents vibration of the cooling fan and the fan cover due to cooling air.

Further, the invention according to claim 2 is as described above, and the fan cover includes a drainage part for receiving water that has accumulated on the upper surface of the attachment part and enters the inside of the charger, and the drainage The part has an upper opening at the lower part of the mounting part, and a drainage hole communicating with the outside at the lower part. For this reason, even when water enters from the gap between the attachment portions, the water that has entered can be discharged to the outside through the drainage portion. And since this drainage part is provided in the fan cover, it is not necessary to provide the member for drainage separately, and a manufacturing cost does not increase.

Further, the invention according to claim 3 is as described above, and the horizontal air guide passage is inclined so that the bottom surface becomes higher as it goes downwind. As a result, in the structure in which the rotation axis of the cooling fan is arranged in a substantially horizontal direction and the intake port is provided on the side portion, when water enters from the intake port on the side portion (for example, rainwater has accumulated around the charger). However, this water can be made difficult to flow into the area where the electronic components inside the charger are arranged through the horizontal air duct.

The invention according to claim 4 is as described above, and the case of the charger is formed by joining the upper case and the lower case up and down, and the lee of the inclined bottom surface of the horizontal air guide path The end on the side is substantially the same height as the rising height of the lower case, or is higher than the rising height of the lower case. For this reason, even if submerged in a range not exceeding the rising height of the lower case, water does not flow into the charger through the horizontal air duct.

It is an external view of a charger. It is an external view of the charger equipped with the battery pack. It is an exploded view of a charger. It is a figure which shows the charger of the state which removed the upper case. It is the perspective view which looked at the fan cover from various directions. It is (a) top view of a fan cover, (b) front view, (c) bottom view, (d) side view. It is XX sectional drawing of a fan cover. It is a figure which shows the charger of the state which removed the upper case and the cooling fan. It is a top view of a charger. It is AA sectional drawing of a charger. It is BB sectional drawing of a charger. It is CC sectional drawing of a charger.

  Embodiments of the present invention will be described with reference to the drawings.

  The charger 10 according to the present embodiment is for charging a battery pack 100 that is used as a power source for an electric tool or the like. As shown in FIG. I have. As shown in FIG. 2, the attachment portion 10 a is configured such that the battery pack 100 can be attached to the upper portion by slidingly fitting the battery pack 100.

  As shown in FIG. 1, the connection terminal 31 protected by the terminal cover 11a is partially exposed at the center of the attachment portion 10a. When the battery pack 100 is attached to the attachment portion 10a, the connection terminal 31 is connected to the battery. The battery pack 100 is electrically connected to the terminals of the pack 100, and the battery pack 100 can be charged via the connection terminals 31.

  A plurality of slit-like air inlets 10b are opened in the side portion of the charger 10, and external air is taken in through the air inlets 10b to be attached to the inside of the charger 10 (and attached to the mounting portion 10a). The battery pack 100) can be cooled.

  As shown in FIG. 3, the charger 10 is formed by joining an upper case 11 and a lower case 12 up and down, and a terminal block 30, a substrate 35, and a cooling fan 13 are formed inside the case. The fan cover 20 is accommodated.

  The terminal block 30 is a member including the connection terminal 31 described above, and is attached to the upper case 11 on the back surface side of the mounting portion 10a. When the terminal block 30 is attached to the upper case 11, the connection terminal 31 is semi-exposed so that it can be connected to the battery pack 100 at the back of the slit of the mounting portion 10 a.

  The terminal block 30 is mounted on the upper case 11 so that a gap is not generated as much as possible. However, since there is a slight gap, rainwater or the like may enter from the gap. The rainwater and the like are collected on the upper surface of the terminal block 30. Rainwater or the like collected on the upper surface of the terminal block 30 is guided to a drainage portion 24 of the fan cover 20 described later and discharged outside.

  The board 35 is provided with electronic components such as capacitors, and is fitted and fixed to the bottom of the lower case 12 as shown in FIG. The circuit formed on the substrate 35 is electrically connected to the connection terminal 31 of the terminal block 30 so that the battery pack 100 can be charged. The region D1 in which the substrate 35 is fitted is not particularly shown, but the surface is potted. That is, the entire upper surface of the substrate 35 is covered with potting in order to protect the substrate 35 from the water that has entered the charger 10.

  The cooling fan 13 is an axial fan that generates cooling air for cooling the inside of the battery pack 100 and the charger 10 and, as shown in FIG. 3, the air inlet 10b so that the rotation axis is substantially horizontal. Placed inside. As a result, the cooling fan 13 is activated at the start of charging, and when the cooling fan 13 is activated, external air is sucked into the charger 10 from the intake port 10b and used for cooling.

  The bottom portion of the lower case 12 is divided into the above-mentioned potted region D1 and a region D2 for disposing the cooling fan 13. The cooling fan 13 is for disposing the cooling fan 13. In the region D2. That is, in the bottom portion of the lower case 12, a region where the substrate 35 is not provided is a region D2 for arranging the cooling fan 13, and the cooling fan 13 is fixed to this region D2. It should be noted that both sides of the region D2 for arranging the cooling fan 13 are separated from the potted region D1 by partition walls 36 located on both sides of the cooling fan 13.

  The fan cover 20 is arranged on the lee of the cooling fan 13 to divert the cooling air generated by the cooling fan 13. As shown in FIGS. 3 and 4, the fan cover 20 is disposed at the boundary between the region D1 where the potting process is performed and the region D2 where the cooling fan 13 is provided, and near the end on the cooling fan 13 side. Are arranged so that both side portions thereof face the inner surface of the partition wall 36.

  On both sides and the bottom near the end on the cooling fan 13 side, a band-like seal portion 25 formed of urethane or the like is pasted along the outer periphery. The gap between the partition wall 36 and the gap between the bottom of the cooling fan 13 and the bottom of the lower case 12 are filled. The seal portion 25 is provided to prevent the potting material from flowing out. That is, since the potting is fluid in the initial stage of the manufacturing process, if the potting is not sealed by the seal portion 25, the potting flows into the region D2 where the cooling fan 13 is provided and flows out from the air inlet 10b to the outside. there is a possibility. By sealing the boundary between the region D1 where the potting process is performed by the seal portion 25 and the region D2 where the cooling fan 13 is provided, such outflow of potting is prevented.

  As shown in FIGS. 5 to 7, the fan cover 20 is a member having a plurality of communication paths. Specifically, the fan cover 20 has a vertical air guide path 21 that guides the cooling air upward, 1 horizontal air guide path 22 and 2nd horizontal air guide path 23, and the drainage part 24 for receiving the water which penetrates the inside of the charger 10 are provided.

  The vertical air guide path 21 guides the cooling air generated by the cooling fan 13 upward in order to cool the battery pack 100 attached to the charger 10, and the windward opening 21 a faces the cooling fan 13. The leeward opening 21b opens upward (see FIG. 8 and the like). As shown in FIG. 11, the mounting portion 10a is positioned above the leeward opening 21b, so that the cooling air generated by the cooling fan 13 passes through the vertical air guide path 21 and is guided to the mounting portion 10a. Thereby, it forms so that a cooling wind may reach | attain the battery pack 100 with which the attaching part 10a was mounted | worn.

  The first horizontal air guide path 22 and the second horizontal air guide path 23 guide the cooling air generated by the cooling fan 13 in the horizontal direction in order to cool the inside of the charger 10. The windward openings 22 a and 23 a of the first horizontal air guide path 22 and the second horizontal air guide path 23 are both opened at positions facing the cooling fan 13. Further, the leeward openings 22b and 23b of the first horizontal air guide path 22 and the second horizontal air guide path 23 are both opened in the horizontal direction, but are opened so that the directions of the openings are different from each other. Specifically, by providing the curved side wall 23 c in the vicinity of the leeward opening 23 b of the second horizontal air guide path 23, the cooling air path of the second horizontal air guide path 23 is slightly shifted from the rotation axis direction of the cooling fan 13. It has been changed to. By the first horizontal air guide path 22 and the second horizontal air guide path 23, the cooling air generated by the cooling fan 13 flows on the potted substrate 35, and the electronic devices mounted on the substrate 35 can be cooled. It is like that.

  Further, the bottom surfaces of the first horizontal air guide path 22 and the second horizontal air guide path 23 are inclined bottom portions 26 that are inclined so as to become higher toward the leeward side. As shown in FIG. 12, the end portion on the leeward side of the inclined bottom portion 26 has substantially the same height as the rising height T of the lower case 12. For this reason, even if the charger 10 is placed in a puddle for some reason, the water that has entered from the air inlet 10b enters the area D2 of the cooling fan 13, but the first horizontal air guide path 22 and the second air guide path 22 It is difficult to enter the region D1 of the substrate 35 through the horizontal air guide path 23, and water can be prevented from entering the substrate 35 until the water depth reaches the rising height T of the lower case 12.

  The drainage part 24 is for receiving the water which accumulates on the upper surface of the mounting part 10 a described above and enters the charger 10. As shown in FIG. 10, the drainage portion 24 has a shape in which an upper opening 24 a that opens at the top and a drainage hole 24 b provided at the bottom communicate with each other vertically. As shown in FIG. 10, the upper opening 24 a is opened at the lower portion of the attachment portion 10 a, and can receive water that has accumulated on the upper surface of the attachment portion 10 a and enters the inside of the charger 10. It is like that. Further, as shown in FIG. 10, a case drain hole 12a of the lower case 12 is opened at a lower portion of the drain hole 24b, and the drain hole 24b communicates with the outside by communicating with each other. For this reason, the water that has entered from the upper opening 24a passes through the drainage part 24 and is discharged from the drainage hole 24b to the outside.

  As described above, according to this embodiment, since the rotation shaft is provided with the cooling fan 13 arranged in a substantially horizontal direction, the intake port 10b can be opened to the side portion of the charger 10. Air intake becomes smooth and cooling performance can be improved.

  The fan cover 20 is arranged on the lee of the cooling fan 13 and diverts the cooling air generated by the cooling fan 13. The fan cover 20 is a vertical guide that guides the cooling air upward to cool the battery pack 100. Since the air guide passage 21 and the horizontal air guide passages 22 and 23 for guiding the cooling air in the horizontal direction to cool the inside of the charger 10 are provided, the air volume of the cooling air is determined by the slit 27 (wall) distribution ratio. The battery pack 100 and the charger 10 can be efficiently cooled by controlling. That is, by changing the position of the slit 27 (wall), it can be configured to send more cooling air to the battery pack 100 side, or to send more cooling air to the charger 10 side. Become.

  Therefore, it is possible to prevent the inside of the battery pack 100 and the charger 10 from becoming high temperature. For example, it is possible to prevent the charging time from becoming long due to high temperature during charging and hindering charging work.

  Further, the surface of the region D1 where the electronic components inside the charger 10 are arranged is potted, and the fan cover 20 includes the region D1 where the potting is performed and the region D2 where the cooling fan 13 is provided. And a seal portion 25 for preventing the potting material from flowing out at the side and bottom. For this reason, even in a structure in which the rotation shaft of the cooling fan 13 is arranged in a substantially horizontal direction and the intake port 10b is provided on the side portion, the potting material does not flow out from the side intake port 10b.

  Furthermore, the side and bottom of the fan cover 20 are sealed, so that the cooling air generated by the cooling fan 13 can be prevented from escaping from the gap between the side and bottom of the fan cover 20. Can be efficiently used for cooling. Further, the seal portion 25 provided around the fan cover 20 also prevents vibration of the cooling fan 13 and the fan cover 20 due to cooling air.

  In addition, the fan cover 20 includes a drainage part 24 for receiving water that accumulates on the upper surface of the attachment part 10a and enters the inside of the charger 10, and the drainage part 24 has the attachment part 10a on the upper side. A drainage hole 24b is formed in the lower portion of the rim and communicated with the outside in the lower portion. For this reason, even when water enters from the gap of the mounting portion 10 a, the water that has entered can be discharged to the outside through the drainage portion 24. And since this drainage part 24 is provided in the fan cover 20, it is not necessary to provide the member for drainage separately, and a manufacturing cost does not increase.

  Further, the horizontal air guide paths 22, 23 are inclined so that the bottom surface (inclined bottom portion 26) becomes higher as going downwind. Thus, in the structure in which the rotation axis of the cooling fan 13 is arranged in a substantially horizontal direction and the air inlet 10b is provided on the side portion, when water enters from the side air inlet 10b (for example, rainwater around the charger 10). Even in the case where the water is accumulated), it is possible to make it difficult for the water to flow into the region D1 where the electronic components inside the charger 10 are disposed through the horizontal air guide paths 22 and 23.

The case of the charger 10 is formed by joining the upper case 11 and the lower case 12 up and down, and the leeward end of the inclined bottom surfaces (inclined bottom portions 26) of the horizontal air guide paths 22 and 23. The portion is substantially the same height as the rising height T of the lower case 12. For this reason, even if the water is submerged in a range not exceeding the rising height T of the lower case 12, the water flows into the horizontal air duct 22
, 23 does not flow into the charger 10.

  In the above-described embodiment, the leeward end of the inclined bottom portion 26 has substantially the same height as the rising height T of the lower case 12, but is not limited thereto, and the rising height of the lower case 12 is not limited thereto. The position may be higher than T.

  In the above-described embodiment, two air guide paths are provided as horizontal air guide paths. However, the present invention is not limited to this, and one air guide path may be provided, or three or more air guide paths may be provided. Good.

DESCRIPTION OF SYMBOLS 10 Charger 10a Mounting part 10b Air inlet 11 Upper case 11a Terminal cover 12 Lower case 12a Case drainage hole 13 Cooling fan 20 Fan cover 21 Vertical air duct 21a Upwind opening 21b Downward opening 22 1st horizontal airflow path 22a Upwind Opening 22b Downward opening 23 Second horizontal air guide path 23a Upwind opening 23b Downward opening 23c Curved side wall part 24 Drainage part 24a Upper opening 24b Drainage hole 25 Sealing part 26 Inclined bottom part 27 Slit (wall)
30 Terminal block 31 Connection terminal 35 Substrate 36 Bulkhead 100 Battery pack D1 Potting area D2 Cooling fan arrangement area T Height of rising

Claims (4)

A charger for charging a battery pack,
A mounting portion on which the battery pack can be mounted on the upper surface;
A cooling fan having a rotating shaft arranged substantially horizontally;
A fan cover that is arranged leeward of the cooling fan and diverts the cooling air generated by the cooling fan;
With
The fan cover includes a vertical air guide passage that guides cooling air upward to cool the battery pack, and a horizontal air guide passage that guides cooling air horizontally to cool the inside of the charger.
The surface where the electronic parts inside the charger are placed is potted.
The fan cover is disposed at a boundary between the region where the potting process is performed and the region where the cooling fan is provided, and at least a part of the side portion and the bottom portion to prevent the potting material from flowing out. wherein the parts are provided, charger. A charger for charging a battery pack,
A mounting portion on which the battery pack can be mounted on the upper surface;
A cooling fan having a rotating shaft arranged substantially horizontally;
A fan cover that is arranged leeward of the cooling fan and diverts the cooling air generated by the cooling fan;
With
The fan cover includes a vertical air guide passage that guides cooling air upward to cool the battery pack, and a horizontal air guide passage that guides cooling air horizontally to cool the inside of the charger.
The fan cover includes a drainage portion for receiving water that accumulates on the upper surface of the attachment portion and enters the inside of the charger,
The drainage unit, together with the upper is open at the bottom of the mounting portion, characterized in that the drainage hole communicating outside the bottom is formed, charger. A charger for charging a battery pack,
A mounting portion on which the battery pack can be mounted on the upper surface;
A cooling fan having a rotating shaft arranged substantially horizontally;
A fan cover that is arranged leeward of the cooling fan and diverts the cooling air generated by the cooling fan;
With
The fan cover includes a vertical air guide passage that guides cooling air upward to cool the battery pack, and a horizontal air guide passage that guides cooling air horizontally to cool the inside of the charger.
The horizontal air guide path, characterized in that inclined to become higher as the bottom is going to leeward, charger. The charger case is formed by joining the upper case and the lower case up and down,
The leeward end of the inclined bottom surface of the horizontal air guide path is substantially the same height as the rising height of the lower case or higher than the rising height of the lower case, The charger according to claim 3 .

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