This application claims priority to Japanese Patent Application No. 2018-225409, filed on Nov. 30, 2018, the entire contents of which are incorporated herein by reference.
The technique disclosed herein relates to a battery pack.
US Patent Application Publication No. 2015/0079444 describes a battery pack provided with a plurality of battery cells, a cell holder holding the plurality of battery cells, and a case accommodating the cell holder. The case includes a first case and a second case fixed to the first case. The cell holder is fixed to the first case by a fastener. The fastener is exposed to outside of the case in a state where the second case is fixed to the first case.
In the battery pack of US Patent Application Publication No. 2015/0079444, the fastener which fixes the cell holder to the first case is exposed to the outside of the case. Therefore, an influence of static electricity or the like outside of the case may be exerted onto the inside of the case through the fastener. The disclosure herein provides a technique that can suppress an influence of static electricity or the like outside of a case from being exerted onto the inside of the case in a battery pack including the case that accommodates a cell holder holding a plurality of battery cells.
The disclosure herein discloses a battery pack. The battery pack may comprise a plurality of battery cells, a cell holder holding the plurality of battery cells, and a case accommodating the cell holder. The case may include a first case and a second case fixed to the first case. The cell holder may be fixed to the first case by a fastener. The fastener may be shielded from outside of the case in a state where the second case is fixed to the first case.
According to the above configuration, the fastener which fixes the cell holder to the first case is shielded from the outside of the case, therefore an influence of static electricity or the like outside of the case is not exerted onto the inside of the case. Thus, an influence of static electricity or the like outside of the case can be suppressed from being exerted onto the inside of the case in the battery pack including the case that accommodates the cell holder holding the plurality of battery cells.
Representative, non-limiting examples of the present disclosure will now be described in further detail with reference to the attached drawings. This detailed description is merely intended to teach a person of skill in the art further details for practicing aspects of the present teachings and is not intended to limit the scope of the present disclosure. Furthermore, each of the additional features and teachings disclosed below may be utilized separately or in conjunction with other features and teachings to provide improved battery packs, as well as methods for using and manufacturing the same.
Moreover, combinations of features and steps disclosed in the following detailed description may not be necessary to practice the present disclosure in the broadest sense, and are instead taught merely to particularly describe representative examples of the present disclosure. Furthermore, various features of the above-described and below-described representative examples, as well as the various independent and dependent claims, may be combined in ways that are not specifically and explicitly enumerated in order to provide additional useful embodiments of the present teachings.
All features disclosed in the description and/or the claims are intended to be disclosed separately and independently from each other for the purpose of original written disclosure, as well as for the purpose of restricting the claimed subject matter, independent of the compositions of the features in the embodiments and/or the claims. In addition, all value ranges or indications of groups of entities are intended to disclose every possible intermediate value or intermediate entity for the purpose of original written disclosure, as well as for the purpose of restricting the claimed subject matter.
In one or more embodiments, a battery pack may comprise a plurality of battery cells, a cell holder holding the plurality of battery cells, and a case accommodating the cell holder. The case may include a first case, and a second case fixed to the first case. The cell holder may be fixed to the first case by a fastener. The fastener may be shielded from outside of the case in a state where the second case is fixed to the first case.
According to the above configuration, the fastener which fixes the cell holder to the first case is shielded from the outside of the case, therefore an influence of static electricity or the like outside of the case is not exerted onto the inside of the case. Thus, an influence of static electricity or the like outside of the case can be suppressed from being exerted onto the inside of the case in the battery pack including the case that accommodates the cell holder holding the plurality of battery cells.
In one or more embodiments, the battery pack may further comprise a cushion material interposed between the first case and the cell holder.
According to the above configuration, vibrations and/or impact can be suppressed from transferring to the cell holder from the case.
In one or more embodiments, the first case may have a box shape having one side thereof open. The cell holder may be fixed to the first case by the fastener in a state where the cell holder is placed on an inner bottom surface of the first case. The fastener may be fastened at a position that is farther apart from the inner bottom surface than a center of the cell holder with respect to a direction orthogonal to the inner bottom surface.
According to the above configuration, the cell holder which holds the plurality of battery cells can be suppressed from swaying against the case.
In one or more embodiments, each of the plurality of battery cells may have a substantially cylindrical shape having a longitudinal direction in a first direction. The plurality of battery cells may be held by the cell holder in a state where the battery cells are arranged side by side in a second direction orthogonal to the first direction. The fastener may be fastened at a position that is on an inner side relative to both ends of the plurality of battery cells with respect to the first direction and is on an outer side relative to an outermost battery cell among the plurality of battery cells with respect to the second direction.
In the case where each of the plurality of battery cells has a substantially cylindrical shape having its longitudinal direction in the first direction and the plurality of battery cells is held by the cell holder in the state where the battery cells are arranged side by side in the second direction orthogonal to the first direction, components, such as lead plates, connected to electrodes of the battery cells are provided on both sides of the battery cells in the first direction. Therefore, if the fastener is fastened at a position that is on an outer side relative to both ends of the plurality of battery cells with respect to the first direction and is on an inner side relative to the outermost battery cell among the plurality of battery cells with respect to the second direction, it is required to avoid interference between the fastener and the components near the both ends of the battery cells in the first direction, which results in increase in size of the battery pack. Meanwhile, as described above, according to the configuration where the fastener is fastened at a position that is on the inner side relative to both ends of the plurality of battery cells with respect to the first direction and is on the outer side relative to the outermost battery cell among the plurality of battery cells with respect to the second direction, the cell holder can be fixed to the first case by the fastener without increase in size of the battery pack.
In one or more embodiments, the battery pack may further comprise a control substrate accommodated in the case and electrically connected to the plurality of battery cells. The control substrate may be fixed to the cell holder.
According to the above configuration, in manufacture of the battery pack, the control substrate and the cell holder can be attached to the first case in an integrated manner where the control substrate is fixed to the cell holder. Labors related to the manufacture of the battery pack can be reduced.
In one or more embodiments, in a plan view in a direction orthogonal to the control substrate, the fastener may be fastened at a position on an outer side relative to the control substrate.
According to the above configuration, when the cell holder with the control substrate fixed thereto is attached to the first case, fastening work for the fastener can be performed without interference with the control substrate. Labors related to the manufacture of the battery pack can be reduced.
A power supply system 600 shown in
As shown in
A nominal voltage of the battery pack 2 is 64 V, for example. A nominal capacity of the battery pack 2 is 5 Ah, for example. A dimension of the battery pack 2 in the front-rear direction is approximately 220 mm, for example. A dimension of the battery pack 2 in a up-down direction is approximately 130 mm, for example. A dimension of the battery pack 2 in a right-left direction is approximately 110 mm, for example. A weight of the battery pack 2 is approximately 2 kg, for example. The nominal voltage, dimensions, and weight of the battery pack 2 vary depending on the number of battery cells 40 (to be described later) and the like, and the aforementioned numerical values are merely examples.
An overall shape of the case 12 is substantially cuboid, and the case 12 is divided into an upper case 14 and a lower case 16. The upper case 14 and the lower case 16 are each constituted of an insulating material such as resin. The upper case 14 and the lower case 16 are fixed to each other by metal screws 18.
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Each of the battery cells 40 is a secondary battery cell, such as a lithium ion battery cell, that has a substantially cylindrical shape, includes a positive electrode at one end thereof, and includes a negative electrode at another end thereof. As shown in
The control substrate 44 is fixed to the cell holder 42 by metal screws 58 in a state of being placed on an upper portion of the cell holder 42. The control substrate 44 includes a pair of power terminals 60 that is used for discharge or charge, and a plurality of signal terminals 62 that is used to send and receive signals, when the battery pack 2 is attached to the electrical machine 200 or the charger 400. The pair of power terminals 60 is disposed such that the power terminals 60 are positioned on right and left sides of the plurality of signal terminals 62 respectively to interpose the signal terminals 62 therebetween.
As shown in
The lower bent portions 60b are provided at both left and right sides of the support portion 60a, respectively. Each of the lower bent portions 60b has a shape that is bent inward from an upper end of the support portion 60a. Each of the holder portions 60c has a plate shape that is bent and extends slightly outward from an upper end of its corresponding lower bent portion 60b. An inclination angle of each holder portion 60c is adjusted such that the angle achieves parallelism to a surface of the power terminal 204 of the electrical machine 200 or a surface of the power terminal 410 of the charger 400, that is, the angle achieves surface contact with a surface of the power terminal 204 or a surface of the power terminal 410, when the power terminals 60 are engaged with the power terminals 204 or the power terminals 410. Each of the upper bent portions 60d has a shape that is bent outward from an upper end of its corresponding holder portion 60c.
The power terminals 60 are each provided with a plurality of slits 60f. Each of the slits 60f has a U-shape that extends from an upper end of its corresponding upper bent portion 60d up to a lower end of the lower bent portion 60b. Hereinbelow, combinations, each including one pair of lower bent portions 60b, one pair of holder portions 60c, and one pair of upper bent portions 60d divided by the slits 60f, may be termed elastic holder piece pairs 60g of the power terminal 60. That is, the power terminal 60 includes the support portion 60a and the plurality of elastic holder piece pairs 60g extending upward from the support portion 60a.
Upon insertion of the power terminals 204 or the power terminals 410 into the power terminals 60, a front edge of each of the power terminals 204 or the power terminals 410 enters between the elastic holder piece pairs 60g of the corresponding power terminal 60, by which the elastic holder piece pairs 60g are opened outward and then the power terminal 204 or the power terminal 410 is held by the elastic holder piece pairs 60g. At this time, the holder portions 60c of the power terminal 60 are pressed against the power terminal 204 or the power terminal 410 due to elastic restoring force of the elastic holder piece pairs 60g, which allows engagement of the power terminal 60 with the power terminal 204 or the power terminal 410. That is, upon attachment of the battery pack 2 to the elastic machine 200 or the charger 400, the elastic holder piece pairs 60g receive the power terminal 204 or the power terminal 410 and hold the same from both sides thereof. On the other hand, upon removal of the power terminals 204 or the power terminals 410 from the power terminals 60, the engagement of the power terminals 60 with the power terminals 204 or the power terminals 410 is released. Then, the elastic holder piece pairs 60g are restored to their original shape due to the elastic restoring force of the elastic holder piece pairs 60g.
In each of the power terminals 60, insertion guide ribs 60h are respectively provided at rear ends of the rearmost elastic holder piece pair 60g, namely, the elastic holder piece pair 60g that is the first to receive the power terminal 204 or the power terminal 410 upon attachment of the battery pack 2 to the electrical machine 200 or the charger 400. The insertion guide ribs 60h each have a shape that extends rearward from rear ends of the holder portions 60c and is bent outward. Providing the insertion guide ribs 60h facilitates insertion of the power terminals 204 as well as the power terminals 410.
In each of the power terminals 60, insertion guide recesses 60i are provided in rear ends of the elastic holder piece pairs 60g other than the rearmost elastic holder piece pair 60g. Each of the insertion guide recesses 60i is a substantially arc notch that expands over the lower bent portion 60b, the holder portion 60c, the upper bent portion 60d from the rear edge of the elastic holder piece pairs 60g. Providing the insertion guide recesses 60i facilitates insertion of the power terminals 204 as well as the power terminals 410.
In each of the power terminals 60, removal guide ribs 60j are provided at front ends of the elastic holder piece pairs 60g other than the frontmost elastic holder piece pair 60g. The removal guide ribs 60j each have a shape that extends forward from the front ends of the holder portions 60c and is bent outward. Providing the removal guide ribs 60j facilitates removal of the power terminals 204 as well as the power terminals 410.
As shown in
The lower bent portions 62b are provided at both left and right sides of the support portion 62a, respectively. Each of the lower bent portions 62b has a shape that is bent inward from an upper end of the support portion 62a. Each of the holder portions 62c has a plate shape that extends and is bent slightly outward from an upper end of its corresponding lower bent portion 62b. An inclination angle of each holder portion 62c is adjusted such that the angle achieves parallelism to a surface of the signal terminal 206 of the electrical machine 200 or a surface of the signal terminal 412 of the charger 400, that is, the angle achieves surface contact with a surface of the signal terminal 206 or a surface of the signal terminal 412, upon engagement of the signal terminals 62 with the signal terminals 206 or the signal terminals 412. Each of the upper bent portions 62d has a shape that is bent outward from an upper end of its corresponding holder portion 62c. Hereinbelow, combinations, each including one pair of lower bent portions 62b, one pair of holder portions 62c, and one pair of upper bent portions 62d, may be termed elastic holder piece pairs 62g of the signal terminals 62. That is, each of the signal terminals 62 includes the support portion 62a and the elastic holder piece pair 62g extending upward from the support portion 62a.
Upon insertion of the signal terminals 206 or the signal terminals 412 into the signal terminals 62, a front edge of each of the signal terminals 206 or the signal terminals 412 enters between the elastic holder piece pair 62g of the corresponding signal terminal 62, by which the elastic holder piece pair 62g is opened outward and then the signal terminal 206 or the signal terminal 412 is held by the elastic holder piece pair 62g. At this time, the holder portions 62c of the signal terminal 62 are pressed against the signal terminal 206 or the signal terminal 412 due to elastic restoring force of the elastic holder piece pair 62g, which allows engagement of the signal terminal 62 with the signal terminal 206 or the signal terminal 412. That is, upon attachment of the battery pack 2 to the elastic machine 200 or the charger 400, the elastic holder piece pairs 62g receive the signal terminals 206 or the signal terminals 412 and hold the same from both sides thereof. On the other hand, upon removal of the signal terminals 206 or the signal terminals 412 from the signal terminals 62, the engagement of the signal terminals 62 with the signal terminals 206 or the signal terminals 412 is released. Then, the elastic holder piece pairs 62g are restored to their original shape due to the elastic restoring force of the elastic holder piece pairs 62g.
In each of the signal terminal 62, insertion guide ribs 62h are provided at rear ends of the elastic holder piece pair 62g. Each of the insertion guide ribs 62h has a shape that extends rearward from a rear end of its corresponding holder portion 62c and is bent outward. Providing the insertion guide ribs 62h facilitates insertion of the signal terminals 206 as well as the signal terminals 412.
In each of the signal terminals 62, removal guide ribs 62i are provided at front ends of the elastic holder piece pair 62g. Each of the removal guide ribs 62i has a shape that extends frontward from a front end of its corresponding holder portion 62c and is bent outward. Providing the removal guide ribs 62i facilitates removal of the signal terminals 206 as well as the signal terminals 412.
As shown in
A front portion of the right cell holder 48 is provided with a screw receiver 48a. A front portion of the left cell holder 50 is provided with a screw receiver 50a. The screw receivers 48a, 50a are disposed above a center of the cell holder 42 in the up-down direction. As shown in
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At the terminal receiver 22 of the battery pack 2, the upper case 14 is provided with recessed grooves 76 that are disposed on both left and right sides of each power terminal opening 72 and are disposed on both left and right sides of each signal terminal opening 74. Positions and a shape of the recessed grooves 76 are determined such that the recessed grooves 76 can receive the side plates 208a of the protective rib 208 of the electrical machine 200. Therefore, lower ends of the recessed grooves 76 are located below lower ends of the power terminal openings 72 and the signal terminal openings 74, and front ends of the recessed grooves 76 are located forward relative to front ends of the power terminal openings 72 and the signal terminal openings 74. Further, each of the recessed grooves 76 is opened in two directions, namely, in the up direction and in the rear direction.
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When the blower fan 418 of the charger 400 is driven with the battery pack 2 attached to the charger 400, the blower fan 418 takes in air from the battery pack mount 404. When this happens, air flows into the inside of the battery pack 2 from the outside through the air supply holes 84. The air, which has entered inside of the battery pack 2, flows through spaces between the battery cells 40 toward the openings 82 of the cell holder 42. During this, the battery cells 40 are cooled by the air flowing around them. Most part of the air having reached the openings 82 of the cell holder 42 flows through the slits 80 of the control substrate 44, flows through the vent holes 78 of the upper case 14, and then flows into the recessed grooves 76 of the terminal receiver 22. The air, which has entered the recessed grooves 76, flows through the battery pack mount 404 of the charger 400 and then reaches the blower fan 418. Further, a part of the air having reached the openings 82 of the cell holder 42 flows through the slit 81 of the control substrate 44, flows through the vent hole 79 of the upper case 14, and then reaches the blower fan 418 of the charger 400. Further, another part of the air having reached the openings 82 of the cell holder 42 flows through the notches 44a, 44b of the control substrate 44, further flows through the vent holes 78, 79 of the upper case 14, and then reaches the blower fan 418 of the charger 400. As shown in
In the battery pack 2, the vent holes 78, 79 of the upper case 14 are disposed to face the slits 80, 81 of the control substrate 44. Such a configuration allows air under the control substrate 44 to be taken in through the slits 80, 81 as air flows out from the vent holes 78, 79. Therefore, a part of the plurality of battery cells 40 that is located right under the control substrate 44 can be cooled sufficiently.
Further, in the battery pack 2, the openings 82 of the cell holder 42 are disposed to face the slits 80, 81 of the control substrate 44. Such a configuration allows air to flow toward the openings 82 of the cell holder 42 from the spaces between the battery cells 40 as air is taken in through the slits 80, 81. Therefore, a part of the plurality of battery cells 40 that is located near the center can be cooled sufficiently.
The control substrate 44 may not be provided with the slit 81, and may be provided with the slits 80 only. Corresponding to this, the case 14 may not be provided with the vent hole 79, and may be provided with the vent holes 78 only.
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Generally, among the battery cells 40 arranged in the up-down direction and in the front-rear direction, the battery cells 40 that are located near the center tend to have a high temperature because it is difficult for them to dissipate their heat, while the battery cells 40 located near the outer edge tend to have a low temperature because it is easy for them to dissipate their heat. Further, in a configuration where the battery cells 40 are cooled by air that flows in through the air supply holes 84 and flows out through the vent holes 78, air flowing in through the air supply holes 84 has a low temperature and the air flowing out through the vent holes 78 has a high temperature, thus the battery cells 40 located close to the air supply holes 84 tend to have a low temperature, and the battery cells 40 located close to the vent holes 78 tend to have a high temperature. Therefore, in a state where the first thermistor 90 and the second thermistor 92 are disposed as described above, the battery cell 40a whose temperature is detected by the first thermistor 90 has the highest temperature during charge among the battery cells 40, while the battery cell 40b whose temperature is detected by the second thermistor 92 has the lowest temperature during charge among the battery cells 40. As such, by using the first thermistor 90 and the second thermistor 92, the temperature of the battery cell 40a, which is the highest among the battery cells 40 during charge of the battery pack 2, and the temperature of the battery cell 40b, which is the lowest among the battery cells 40 during the charge, can be obtained.
The charger 400 charges the battery pack 2 when receiving a charging start instruction from the battery pack 2 while the battery pack 2 is attached to one of or each of the battery pack mounts 404. During the charge to the battery pack 2, the charger 400 receives from the battery pack 2 an allowable charging voltage, an allowable charging current, a charging-current-reduction start voltage, and a cut-off current as charging parameters. Then, the charger 400 charges the battery pack 2 at a charging voltage that is equal to or lower than the allowable charging voltage and a charging current that is equal to or lower than the allowable charging current. When the charging voltage reaches the charging-current-reduction start voltage during the charge to the battery pack 2, the charger 400 gradually reduces the charging current. When the charging current is reduced to the cut-off current during the charge to the battery pack 2, the charger 400 terminates the charge to the battery pack 2. When receiving a charging termination instruction from the battery pack 2 during the charge to the battery pack 2, the charger 400 terminates the charge to the battery pack 2 at that time.
Various processes executed by the control substrate 44 in connection with the charge to the battery pack 2 will be described hereinbelow. The control substrate 44 of the battery pack 2 executes a charging-start determination process shown in
In S2, the control substrate 44 obtains a temperature detected by the first thermistor 90 as a first temperature as well as a temperature detected by the second thermistor 92 as a second temperature.
In S4, the control substrate 44 determines a first charging-start voltage threshold. The control substrate 44 stores in advance a correspondence relationship between battery cell temperature and charging-start voltage threshold, which is shown in
In S6, the control substrate 44 determines a second charging-start voltage threshold. The control substrate 44 determines the second charging-start voltage threshold by using the second temperature and the correspondence relationship of
In S8, the control substrate 44 determines a charging-start voltage threshold. In the present embodiment, the control substrate 44 determines lower one of the first and second charging-start voltage thresholds as the charging-start voltage threshold.
In S10, the control substrate 44 determines whether voltages of all the battery cells 40 are lower than the charging-start voltage threshold. In a case where at least one battery cell 40 has a voltage that is equal to or higher than the charging-start voltage threshold (in case of NO), the process returns to S2. In a case where all the battery cells 40 have voltages that are lower than the charging-start voltage threshold (in case of YES), the process proceeds to S12.
In S12, the control substrate 44 obtains a temperature detected by the first thermistor 90 as a first temperature as well as a temperature detected by the second thermistor 92 as a second temperature.
In S14, the control substrate 44 determines whether both the first temperature and the second temperature are lower than a predetermined charging-start upper limit temperature (e.g., 55° C.). In a case where at least one of the first temperature and the second temperature is equal to or higher than the charging-start upper limit temperature (in case of NO), the process returns to S12. In a case where both the first temperature and the second temperature are lower than the charging-start upper limit temperature (in case of YES), the process proceeds to S16.
In S16, the control substrate 44 determines whether both the first temperature and the second temperature are higher than a predetermined charging-start lower limit temperature (e.g., 2° C.). In a case where at least one of the first temperature and the second temperature is equal to or lower than the charging-start lower limit temperature (in case of NO), the process returns to S12. In a case where both the first temperature and the second temperature are higher than the charging-start lower limit temperature (in case of YES), the process proceeds to S18.
In S18, the control substrate 44 outputs the charging start instruction to the charger 400. The charger 400 thereby starts charging the battery pack 2. After S18, the process of
The control substrate 44 of the battery pack 2 simultaneously executes a charging parameter creation process shown in
The charging parameter creation process shown in
In S24, the control substrate 44 determines a first allowable charging voltage, a first allowable charging current, a first charging-current-reduction start voltage, and a first cut-off current. The control substrate 44 stores in advance a correspondence relationship between battery cell temperature and allowable charging voltage, which is shown in
In S26, the control substrate 44 determines a second allowable charging voltage, a second allowable charging current, a second charging-current-reduction start voltage, and a second cut-off current. The control substrate 44 determines the second allowable charging voltage, the second allowable charging current, the second charging-current-reduction start voltage, and the second cut-off current by using the second temperature and the correspondence relationships of
In S28, the control substrate 44 determines an allowable charging voltage, an allowable charging current, a charging-current-reduction start voltage, and a cut-off current. In the present embodiment, the control substrate 44 determines lower one of the first and second allowable charging voltages as the allowable charging voltage. Similarly, the control substrate 44 determines lower one of the first and second allowable charging currents as the allowable charging current, determines lower one of the first and second charging-current-reduction start voltages as the charging-current-reduction start voltage, and determines lower one of the first and second cut-off currents as the cut-off current.
In S30, the control substrate 44 outputs the allowable charging voltage, the allowable charging current, the charging-current-reduction start voltage, and the cut-off current to the charger 400. The charger 400 chargers the battery pack 2 based on the allowable charging voltage, the allowable charging current, the charging-current-reduction start voltage, and the cut-off current that were outputted from the battery pack 2.
In S32, the control substrate 44 determines whether the charging by the charger 400 has been terminated. In a case where the charging has not been terminated yet (in case of NO), the process returns to S22. In a case where the charging has been terminated (in case of YES), the process of
The charging abnormality determination process shown in
In S44, the control substrate 44 determines whether both the first temperature and the second temperature are lower than a predetermined charging upper limit temperature (e.g., 60° C.). In a case where at least one of the first temperature and the second temperature is equal to or higher than the charging upper limit temperature (in case of NO), the process proceeds to S46. In S46, the control substrate 44 sends a charging termination instruction due to abnormally high temperature to the charger 400, and the process of
In S48, the control substrate 44 determines whether both the first temperature and the second temperature are higher than a predetermined charging lower limit temperature (e.g., 0° C.). In a case where at least one of the first temperature and the second temperature is lower than the charging lower limit temperature (in case of NO), the process proceeds to S50. In S50, the control substrate 44 sends a charging termination instruction due to abnormally low temperature to the charger 400, and the process of
In S52, the control substrate 44 determines a first abnormal voltage threshold. The control substrate 44 stores in advance a correspondence relationship between battery cell temperature and abnormal voltage threshold, which is shown in
In S54, the control substrate 44 determines a second abnormal voltage threshold. The control substrate 44 determines the second abnormal voltage threshold by using the second temperature and the correspondence relationship of
In S56, the control substrate 44 determines an abnormal voltage threshold. In the present embodiment, the control substrate 44 determines lower one of the first and second abnormal voltage thresholds as the abnormal voltage threshold.
In S58, the control substrate 44 determines whether voltages of all the battery cells 40 are lower than the abnormal voltage threshold. In a case where at least one battery cell 40 has a voltage that is equal to or higher than the abnormal voltage threshold (in case of NO), the process proceeds to S60. In S60, the control substrate 44 sends a charging termination instruction due to abnormally high voltage to the charger 400, and the process of
In S62, the control substrate 44 determines whether the charging by the charger 400 has been terminated. In a case where the charging has not been terminated yet (in case of NO), the process returns to S42. In a case where the charging has been terminated (in case of YES), the process of
During the charging to the battery pack 2 by the charger 400, the control substrate 408 of the charger 400 obtains the temperature detected by the first thermistor 90 and the temperature detected by the second thermistor 92 from the battery pack 2, and controls operation of the blower fan 418. When the charger 400 starts charging the battery pack 2, the control substrate 408 executes a blow control process shown in
In S72, the control substrate 408 drives the blower fan 418.
In S74, the control substrate 408 determines whether the charging to the battery pack 2 has been terminated. In a case where the charging has been terminated (in case of YES), the process proceeds to S76. In S76, the control substrate 408 stops the blower fan 418, and the process of
In S78, the control substrate 408 obtains a temperature detected by the first thermistor 90 as a first temperature as well as a temperature detected by the second thermistor 92 as a second temperature.
In S80, the control substrate 408 determines whether both the first temperature and the second temperature are lower than a predetermined blow stop temperature (e.g., 15° C.). In a case where at least one of the first temperature and the second temperature is equal to or higher than the blow stop temperature (in case of NO), the process returns to S74. In case where both the first temperature and the second temperature are lower than the blow stop temperature (in case of YES), the process proceeds to S82.
In S82, the control substrate 408 stops the blower fan 418.
In S84, the control substrate 408 determines whether the charging to the battery pack 2 has been terminated. In a case where the charging has been terminated (in case of YES), the process of
In S86, the control substrate 408 obtains a temperature detected by the first thermistor 90 as a first temperature as well as a temperature detected by the second thermistor 92 as a second temperature.
In S88, the control substrate 408 determines whether both the first temperature and the second temperature are higher than a predetermined blow start temperature (e.g., 17° C.). In a case where at least one of the first temperature and the second temperature is equal to or lower than the blow start temperature (in case of NO), the process returns to S84. In a case where both the first temperature and the second temperature are higher than the blow start temperature (in case of YES), the process returns to S72.
A process executed by the control substrate 44 in connection with discharge of the battery pack 2 will be described hereinbelow. The control substrate 44 of the battery pack 2 executes a discharge-abnormality determination process shown in
In S92, the control substrate 44 obtains a temperature detected by the first thermistor 90 as a first temperature as well as a temperature detected by the second thermistor 92 as a second temperature.
In S94, the control substrate 44 determines whether both the first temperature and the second temperature are lower than a predetermined discharging upper limit temperature (e.g., 85° C.). In a case where at least one of the first temperature and the second temperature is equal to or higher than the discharging upper limit temperature (in case of NO), the process proceeds to S96. In S96, the control substrate 44 sends a discharging termination instruction due to abnormally high temperature to the electrical machine 200, and the process of
In S98, the control substrate 44 determines whether the discharging to the electrical machine 200 has been terminated. In a case where the discharging has not been terminated yet (in case of NO), the process returns to S92. In a case where the discharging has been terminated (in case of YES), the process of
In the above-described embodiment, the side plates 208a of the protective rib 208 of the electrical machine 200 may be disposed only on both sides of each power terminal 204 and may not be disposed on both sides of each signal terminal 206. Corresponding to this, the recessed grooves 76 of the battery pack 2 may be provided only on both sides of each power terminal 60 and may not be provided on both sides of each signal terminal 62.
In the above-described embodiment, the power terminals 60 of the battery pack 2 are disposed such that they interpose the signal terminals 62 therebetween from both sides in the right-left direction. However, another arrangement may be employed for the power terminals 60 and the signal terminals 62. Corresponding to this, the arrangement for the power terminals 204 and the signal terminals 206 of the electrical machine 200 and the arrangement for the power terminals 410 and the signal terminals 412 of the charger 400 may be different from the arrangements described in the embodiment, as long as these arrangements correspond to the arrangement for the power terminals 60 and the signal terminals 62 of the battery pack 2.
In the above-described embodiment, the power terminals 60 and the signal terminals 62 of the battery pack 2 are installed on the control substrate 44. However, the power terminals 60 and the signal terminals 62 may be installed on another terminal substrate (not shown) that is separated from the control substrate 44 and is electrically connected to the control substrate 44.
In the above-described embodiment, the blower fan 418 of the charger 400 is configured to take in air from the battery pack mounts 404. Unlike this, the blower fans 418 may be configured to discharge air toward the battery pack mounts 404. In this case, as shown in
The above-described embodiment describes an example where the battery pack 2 includes thirty-two battery cells 40, the nominal voltage of the battery pack 2 is 64 V, and the nominal capacity of the battery pack 2 is 5 Ah. Unlike this, the battery pack 2 may include sixteen battery cells 40, the nominal voltage of the battery pack 2 may be 64 V, and the nominal capacity of the battery pack 2 may be 2.5 Ah. In this case, as shown in
As described above, in one or more embodiments, the battery pack 2 includes the plurality of battery cells 40, the cell holder 42 holding the plurality of battery cells 40, and the case 12 accommodating the cell holder 42 therein. The case 12 includes the lower case 16 (an example of first case) and the upper case 14 (an example of second case) fixed to the lower case 16. The cell holder 42 is fixed to the lower case 16 by the screws 70 (an example of fastener). The screws 70 are shielded from the outside of the case 12 in a state where the lower case 16 is fixed to the upper case 14.
According to the above configuration, the screws 70 fixing the cell holder 42 to the lower case 16 are shielded from the outside of the case 12, thus an influence of static electricity or the like outside the case 12 is not exerted onto the inside of the case 12 through the screws 70. In the battery pack 2 which includes the case 12 accommodating the cell holder 42 holding the plurality of battery cells 40, an influence of static electricity or the like outside the case 12 can be suppressed from being exerted onto the inside of the case 12.
In one or more embodiments, the battery pack 2 further comprises the cushion material 68 interposed between the lower case 16 and the cell holder 42.
According to the above configuration, vibration and/or impact can be suppressed from transferring to the cell holder 42 from the case 12.
In one or more embodiments, the lower case 16 has a box shape having its upper surface (an example of one side thereof) opened. The cell holder 42 is fixed to the lower case 16 by the screws 70 in a state where the cell holder 42 is placed on the inner bottom surface of the lower case 16. The screws 70 are fastened at positions that are farther apart from the inner bottom surface of the lower case 16 than the center of the cell holder 42 with respect to a direction orthogonal to the inner bottom surface of the lower case 16, namely with respect to the up-down direction.
According to the above configuration, the cell holder 42 which holds the plurality of battery cells 40 can be suppressed from swaying against the case 12.
In one or more embodiments, each of the plurality of battery cells 40 has the substantially cylindrical shape having the longitudinal direction in the right-left direction (an example of first direction). The plurality of battery cells 40 is held by the cell holder 42 in a state where the battery cells 40 are arranged side by side in the front-rear direction (an example of second direction orthogonal to the first direction). The screws 70 are fastened at positions that are on an inner side relative to both ends of the plurality of battery cells 40 with respect to the right-left direction and are on an outer side relative to the outermost battery cell 40 among the plurality of battery cells 40 with respect to the front-rear direction.
In the case where each of the plurality of battery cells 40 has the substantially cylindrical shape having its longitudinal direction in the right-left direction and the plurality of battery cells 40 is held by the cell holder 42 in the state where the battery cells 40 are arranged side by side in the front-rear direction, components, such as the lead plates 54, 56, connected to the electrodes of the battery cells 40 are provided on both sides of the battery cells 40 in the right-left direction. Therefore, if the screws 70 are fastened at positions that are on an outer side relative to both ends of the plurality of battery cells 40 with respect to the right-left direction and are on an inner side relative to the outermost battery cell 40 among the plurality of battery cells 40 with respect to the front-rear direction, it is required to avoid interference between the screws 70 and the components near the both ends of the battery cells 40 in the right-left direction, which results in increase in size of the battery pack 2. Meanwhile, as described above, according to the configuration where the screws 70 are fastened at positions that are on the inner side relative to both ends of the plurality of battery cells 40 with respect to the right-left direction and are on the outer sides relative to the outermost battery cells 40 among the plurality of battery cells 40 with respect to the front-rear direction, the cell holder 42 can be fixed to the lower case 16 by the screws 70 without increase in size of the battery pack 2.
In one or more embodiments, the battery pack 2 further comprises the control substrate 44 accommodated in the case 12 and electrically connected to the plurality of battery cells 40. The control substrate 44 is fixed to the cell holder 42.
According to the above configuration, in manufacturing the battery pack 2, the control substrate 44 and the cell holder 42 can be attached to the lower case 16 in an integrated manner where the control substrate 44 is fixed to the cell holder 42. Labors related to manufacture of the battery pack 2 can be reduced.
In one or more embodiments, in a plan view in a direction orthogonal to the control substrate 44, namely from above, the screws 70 are fastened at positions on an outer side relative to the control substrate 44.
According to the above configuration, when the cell holder 42 with the control substrate 44 is fixed thereto is attached to the lower case 16, fastening work for the screws 70 can be performed without interference with the control substrate 44. Labors related to the manufacture of the battery pack 2 can be reduced.
In one or more embodiments, the battery pack 2 comprises the battery cell 40, the control substrate 44 (an example of substrate) including the power terminal 60 and the signal terminal 62 (an example of a plurality of terminals), and the case 12 accommodating the battery cell 40 and the control substrate 44 therein. The control substrate 44 includes the slit 80 (an example of through hole) disposed between the power terminal 60 and the signal terminal 62. The case 12 includes the vent hole 78 disposed at a position facing the slit 80 of the control substrate 44.
According to the above configuration, the vent hole 78 provided in the case 12 is disposed at a position facing the slit 80 provided in the control substrate 44, therefore air flowing in or flowing out through the vent hole 78 of the case 12 passes through the slit 80 of the control substrate 44. As such, even when the battery cell 40 and the control substrate 44 are disposed close to each other within the case 12, sufficient air can flow through between the battery cell 40 and the control substrate 44 and thus the battery cell 40 located close to the control substrate 44 can be sufficiently cooled. Further, according to the above configuration, the slit 80 provided in the control substrate 44 is disposed between the power terminal 60 and the signal terminal 62. Therefore, even if a conductive substance, such as water, enters inside of the case 12 and adheres to the control substrate 44, short circuit can be suppressed from occurring between the power terminal 60 and the signal terminal 62.
In one or more embodiments, the power terminal 60 and the signal terminal 62 include a first terminal (e.g., the power terminal 60) and a second terminal (e.g., the signal terminal 62 adjacent to the power terminal 60). The vent hole 78 includes a plurality of holes 78a disposed between a region of the upper case 14 facing the first terminal (e.g., the power terminal 60) and a region of the upper case 14 facing the second terminal (e.g., the signal terminal 62 adjacent to the power terminal 60).
If a size of the vent hole 78 provided in the case 12 is large, an amount of air passing through the vent hole 78 is increased, however, foreign matter may easily enter inside of the battery pack 2 through the vent hole 78. According to the above configuration, the vent hole 78 includes the plurality of holes 78a, therefore a size of individual holes 78a can be reduced without reduction in air amount passing through the vent hole 78, and foreign matter can be suppressed from entering inside of the battery pack 2 through the vent hole 78.
In one or more embodiments, the battery pack 2 further comprises the cell holder 42 accommodated in the case 12 and holding the battery cell 40. The cell holder 42 includes an opening 82 disposed at a position facing the slit 80 of the control substrate 44.
In the configuration where the battery cell 40 is held by the cell holder 42, if the cell holder 42 shields a space between the slit 80 of the control substrate 44 and the battery cell 40, air passing through the slit 80 flows in the space between the control substrate 44 and the cell holder 42, which results in insufficient cooling for the battery cell 40 close to the slit 80. According to the above configuration, the cell holder 42 includes the opening 82 disposed at a position facing the slit 80 of the control substrate 44, therefore air passing through the slit 80 flows through the opening 82 of the cell holder 42. As such, the battery cell 40 close to the slit 80 can be sufficiently cooled.
In one or more embodiment, the case 12 includes the recessed groove 76 disposed between the power terminal 60 and the signal terminal 62 and opened in two directions. The vent hole 78 is disposed in a bottom surface of the recessed groove 76.
According to the above configuration, an inner space of the recessed groove 76 of the case 12 functions as a flow passage for air passing through the vent hole 78. Further, according to the above configuration, either of the two directions in which the recessed groove 76 is opened can be used as a direction in which air passing through the vent hole 78 flows into the case 12 or as a direction the air flows out from the case 12, as desired. The above configuration can improve a degree of freedom in designing a mechanism through which cooling air flows into the battery pack 2 or flows out therefrom.
In one or more embodiments, the battery pack 2 further comprises at least one lead plate 54, 56 connecting the battery cell 40 to the control substrate 44. The control substrate 44 further includes the slit 85 (an example of second through hole) disposed between the power terminal 60 and the at least one lead plate 54, 56. The case 12 further includes the vent hole 83 (an example of second vent hole) disposed at a position facing the slit 85 of the control substrate 44.
According to the above configuration, the vent hole 83 provided in the case 12 is disposed at a position facing the slit 85 of the control substrate 44, therefore air flowing into the case 12 or flowing out therefrom through the vent hole 83 passes through the slit 85 of the control substrate 44. As such, even when the battery cell 40 and the control substrate 44 are disposed close to each other with in the case 12, sufficient air can flow between the battery cell 40 and the control substrate 44, and the battery cell 40 close to the control substrate 44 can be sufficiently cooled. Further, according to the above configuration, the slit 85 provided in the control substrate 44 is disposed between the power terminal 60 and the at least one lead plate 54, 56. Therefore, even if a conductive substance, such as water, enters inside of the case 12 and adheres to the control substrate 44, short circuit can be suppressed from occurring between the power terminal 60 and the at least one lead plate 54, 56.
In one or more embodiments, the control substrate 44 includes a notch 44a (or a notch 44b) provided between adjacent lead plates 54 (or lead plates 56).
According to the above configuration, air can also flow through the notch 44a (or the notch 44b) of the control substrate 44, therefore sufficient air can flow through between the battery cell 40 and the control substrate 44, and the battery cell 40 close to the control substrate 44 can be sufficiently cooled. Further, according to the above configuration, the notch 44a (or the notch 44b) provided in the control substrate 44 is disposed between the adjacent lead plates 54 (or lead plates 56). Therefore, even if a conductive substance, such as water, enters inside of the case 12 and adheres to the control substrate 44, short circuit can be suppressed from occurring between the adjacent lead plates 54 (or lead plates 56).
In one or more embodiments, the battery pack 2 is configured to be detachably attached to the charger 400 by sliding the battery pack 2 in the front-rear direction (an example of predetermined sliding direction). The control substrate 44 further includes the slit 81 (an example of third through hole) disposed at a position offset from the signal terminal 62 in the rear direction. The case 12 further includes the vent hole 79 (an example of third vent hole) disposed at a position facing the slit 81 of the control substrate 44.
According to the above configuration, the vent hole 79 provided in the case 12 is disposed at a position facing the slit 81 provided in the control substrate 44, therefore air flowing in or flowing out through the vent hole 79 of the case 12 passes through the slit 81 of the control substrate 44. As such, even when the battery cell 40 and the control substrate 44 are disposed close to each other within the case 12, sufficient air can flow through between the battery cell 40 and the control substrate 44, and the battery cell 40 close to the control substrate 44 can be sufficiently cooled.
In one or more embodiments, the battery pack 2 comprises the plurality of battery cells 40 including the battery cell 40a (an example of first battery cell) and the battery cell 40b (an example of second battery cell), the first thermistor 90, and the second thermistor 92. The first thermistor 90 is disposed at a position that is close to the battery cell 40a and is surrounded by the other battery cells 40. The second thermistor 92 is disposed at a position that is close to the battery cell 40b and is not surrounded by the other battery cells 40.
According to the configuration, the first thermistor 90 is disposed at a position that is close to the battery cell 40a and is surrounded by the other battery cells 40, namely at a position where heat dissipation is difficult and a temperature tends to become high, therefore the first thermistor 90 can obtain a temperature of the battery cell 40a having a high temperature. Further, according to the configuration, the second thermistor 92 is disposed at a position that is close to the battery cell 40b and is not surrounded by the other battery cells 40, namely at a position where heat dissipation is easy and a temperature tends to become low, therefore the second thermistor 92 can obtain a temperature of the battery cell 40b having a low temperature. According to the above configuration, in the battery pack 2 including the plurality of battery cells 40, the temperature of the battery cell 40a having a high temperature as well as the temperature of the battery cell 40b having a low temperature can be obtained.
In one or more embodiments, the battery pack 2 further comprises the case 12 that accommodates the plurality of battery cells 40, the first thermistor 90, and the second thermistor 92. The case 12 includes the air supply holes 84 (an example of air supply hole) through which air is introduced and the vent holes 78 (an example of air discharge hole) through which air is discharged.
According to the above configuration, in the battery pack 2 where the plurality of battery cells 40 is cooled by air flowing inside the case 12 from the air supply holes 84 to the vent holes 78, the temperature of the battery cell 40a having a high temperature as well as the temperature of the battery cell 40b having a low temperature can be obtained.
In one or more embodiments, the second thermistor 92 is disposed at a position where a distance from the position to the air supply holes 84 is smaller than a distance from the position to the vent holes 78.
In the battery pack 2 where the plurality of battery cells 40 is cooled by air flowing inside the case 12 from the air supply holes 84 to the vent holes 78, the air has the lowest temperature immediately after having flowed in through the air supply holes 84 and has the highest temperature immediately before flowing out through the vent holes 78. Therefore, the battery cell(s) 40 disposed near the air supply holes 84 tend to have a low temperature, while the battery cell(s) 40 disposed near the vent holes 78 tend to have a high temperature. According to the above configuration, the second thermistor 92 can obtain the temperature of the battery cell 40b having a lower temperature.
In one or more embodiments, the first thermistor 90 is disposed at a position where a distance from the position to the vent holes 78 is smaller than a distance from the position to the air supply holes 84.
In the battery pack 2 where the plurality of battery cells 40 is cooled by air flowing inside the case 12 from the air supply holes 84 to the vent holes 78, the battery cell(s) 40 disposed near the air supply holes 84 tend to have a low temperature, while the battery cell(s) 40 disposed near the vent holes 78 tend to have a high temperature. According to the above configuration, the first thermistor 90 can obtain the temperature of the battery cell 40a having a higher temperature.
In one or more embodiments, the battery pack 2 further comprises the control substrate 44 (an example of substrate) accommodated in the case 12 and disposed between the vent holes 78 and the plurality of battery cells 40. Each of the first thermistor 90 and the second thermistor 92 is connected to the control substrate 44. The first thermistor 90 includes a film thermistor. The second thermistor 92 includes a dip thermistor.
According to the above configuration, the control substrate 44 is disposed between the vent holes 78 and the plurality of battery cells 40, therefore the temperature of the battery cell 40a having a high temperature can be obtained with high accuracy by obtaining the temperature of the battery cell 40a disposed near the vent holes 78, namely the temperature of the battery cell 40a which tends to have a high temperature, by the first thermistor 90 including the film thermistor. Further, according to the above configuration, even when the control substrate 44 is disposed between the vent holes 78 and the plurality of battery cells 40, the temperature of the battery cell 40b disposed near the air supply holes 84, namely the temperature of the battery cell 40b which tends to have a low temperature, can be obtained by the second thermistor 92 including the dip thermistor.
In one or more embodiments, the battery cell 40b is disposed at a position where no other battery cells 40 are interposed between the position and a wall surface of the case 12.
Generally, in the battery pack 2 where the plurality of battery cells 40 is accommodated in the case 12, heat is dissipated from an outer surface of the case 12 to air outside the case 12, therefore the battery cell(s) 40 located near the wall surface of the case 12 tend to have a low temperature, while the battery cell(s) 40 located farther from the wall surface of the case 12 tend to have a high temperature. According to the above configuration, the battery cell 40b whose temperature is obtained by the second thermistor 92 is disposed at a position near the wall surface of the case 12. Therefore, the second thermistor 92 can obtain the temperature of the battery cell 40b having a lower temperature.
In one or more embodiments, the battery cell 40a is disposed at a position where at least one other battery cell 40 is interposed between the position and the wall surface of the case 12.
Generally, in the battery pack 2 where the plurality of battery cells 40 is accommodated in the case 12, heat is dissipated from the outer surface of the case 12 to air outside the case 12, therefore the battery cell(s) 40 located near the wall surface of the case 12 tend to have a low temperature, while the battery cell(s) 40 located farther from the wall surface of the case 12 tend to have a high temperature. According to the above configuration, the battery cell 40a whose temperature is obtained by the first thermistor 90 is disposed at a position farther from the wall surface of the case 12. Therefore, the first thermistor 90 can obtain the temperature of the battery cell 40a having a higher temperature.
In one or more embodiments, the power supply system 600 comprises the electrical machine 200 and the battery pack 2 configured to be detachably attached to the electrical machine 200 by being slid in the front-rear direction (an example of sliding direction) with respect to the electrical machine 200. The electrical machine 200 includes the power terminals 204 (an example of machine-side power terminal) and the protective ribs 208 disposed on both sides of each power terminal 204 and extending beyond the power terminals 204. The battery pack 2 includes the power terminals 60 (an example of battery-side power terminal) configured to mechanically engage with and electrically connect to the power terminals 204, and the case 12 accommodating the power terminals 60. The case 12 includes the power terminal openings 72 disposed at positions facing the power terminals 60 in the front-rear direction, and the recessed grooves 76 disposed on both sides of each power terminal 60 and extending along the front-rear direction.
In one or more embodiments, the electrical machine 200 is configured to have the battery pack 2 detachably attached thereto by the battery pack 2 being slid in the front-rear direction (an example of sliding direction). The electrical machine 200 comprises the power terminals 204 (an example of machine-side power terminal) and the protective ribs 208 disposed on both sides of each power terminal 204 and extending beyond the power terminals 204.
In one or more embodiments, the battery pack 2 is configured to be detachably attached to the electrical machine 200 by being slid with respect to the electrical machine 200 in the front-rear direction (an example of sliding direction). The battery pack 2 comprises the power terminals 60 (an example of battery-side power terminal) and the case 12 accommodating the power terminals 60. The case 12 includes the power terminal openings 72 disposed at positions facing the power terminals 60 in the front-rear direction, and the recessed grooves 76 disposed on both sides of each power terminal 60 and extending along the front-rear direction.
According to the above configuration, the protective ribs 208, which extend beyond the power terminals 204, are provided on both sides of each power terminal 204 of the electrical machine 200, therefore the user can be prevented from accidentally touching the power terminals 204 even in the state where the battery pack 2 is detached from the electrical machine 200. According to the above configuration, the recessed grooves 76 of the case 12 of the battery pack 2 receive the protective ribs 208 of the electrical machine 200 upon attachment of the battery pack 2 to the electrical machine 200, which allows the battery pack 2 to be attached to the electrical machine 200 without interference between the protective ribs 208 and the case 12.
In one or more embodiments, the electrical machine 200 further comprises the signal terminals 206 (an example of machine-side signal terminal). The protective ribs 208 are also disposed on both sides of each signal terminal 206 and extend beyond the signal terminals 206. The battery pack 2 further comprises the signal terminals 62 (an example of battery-side signal terminal) which are accommodated in the case 12 and are configured to mechanically engage with and electrically connected to the signal terminals 206. The case 12 further includes the signal terminal openings 74 disposed at positions facing the signal terminals 62 in the front-rear direction. The recessed grooves 76 are also disposed on both sides of each signal terminal 62.
In one or more embodiments, the electrical machine 200 further comprises the signal terminals 206 (an example of machine-side signal terminal). The protective ribs 208 are also disposed on both sides of each signal terminal 206 and extend beyond the signal terminals 206.
In one or more embodiments, the battery pack 2 further comprises the signal terminals 62 (an example of battery-side signal terminal) accommodated in the case 12. The case 12 further includes the signal terminal openings 74 disposed at positions facing the signal terminals 62 in the front-rear direction. The recessed grooves 76 are also disposed on both sides of each signal terminal 62.
According to the above configuration, the protective ribs 208, which extend beyond the signal terminals 206, are provided on both sides of each signal terminal 206 of the electrical machine 200, therefore the user can be prevented from accidentally touching the signal terminals 206 even in the state where the battery pack 2 is detached from the electrical machine 200. According to the above configuration, the recessed grooves 76 of the case 12 of the battery pack 2 receive the protective ribs 208 of the electrical machine 200 upon attachment of the battery pack 2 to the electrical machine 200, which allows the battery pack 2 to be attached to the electrical machine 200 without interference between the protective ribs 208 and the case 12.
In one or more embodiments, the electrical machine 200 further comprises the slide rails 210 (an example of machine-side slide rail). At least one of the protective ribs 208 is disposed between the slide rail 210 and the power terminal 204. The battery pack 2 further comprises the slide rails 20 (an example of battery-side slide rail) configured to slidably engage with the slide rails 210 in the front-rear direction. At least one of the recessed grooves 76 is disposed between the slide rail 20 and the power terminal 60.
In one or more embodiments, the electrical machine 200 further comprises the slide rails 210 (an example of machine-side slide rail). At least one of the protective ribs 208 is disposed between the slide rail 210 and the power terminal 204.
In one or more embodiments, the battery pack 2 further comprises the slide rails 20 (an example of battery-side slide rail). At least one of the recessed grooves 76 is disposed between the slide rail 20 and the power terminal 60.
Spaces that receive the slide rails 20 of the battery pack 2 are often provided between each slide rail 210 of the electrical machine 200 and the power terminal 204 adjacent thereto, which allows for easy insertion of user's finger. According to the above-described configuration, the user is prevented from accidentally touching the power terminals 204 via the spaces between the slide rails 210 and the power terminals 204, even in the state where the battery pack 2 is detached from the electrical machine 200. According to the above-described configuration, the recessed grooves 76 of the case 12 of the battery pack 2 receive the protective ribs 208 of the electrical machine 200 upon attachment of the battery pack 2 to the electrical machine 200, which allows the battery pack 2 to be attached to the electrical machine 200 without interference between the protective ribs 208 and the case 12.
Number | Date | Country | Kind |
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2018-225409 | Nov 2018 | JP | national |