DE102017211205A1 - loader - Google Patents

Abstract

The invention relates to a charging device for charging an energy store, in particular a battery pack, a handheld power tool, with a cooling device for cooling the energy store, in particular the battery pack, with a housing which at least partially forms an outer housing and with a recording unit accommodating the energy store. which is intended to receive the energy storage and / or to hold the charger.
According to the invention, the cooling device has a first cooling element, which is provided to cool an air flow directed towards the energy store, wherein the cooling element has a cooling temperature in at least one operating state which is smaller than an ambient temperature surrounding the charging device and / or the energy store around the energy store to cool by means of the cooling temperature.

Description

The invention relates to a charging device for charging an energy store of a hand tool according to the preamble of claim 1.

State of the art

Charging stations are known, which can take a battery to read this. In this case, such charging stations may have a fan which cools the battery.

Disclosure of the invention

The invention has for its object to improve with simple constructive measures, a charging device for an energy storage device, in particular a battery.

The object is achieved with a charging device, in particular for charging an energy store, in particular a battery pack, a hand tool, with a cooling device for cooling the energy storage device, in particular the battery pack, with a housing which at least partially forms an outer housing and with an energy storage recordable Receiving unit, which is intended to receive the energy storage and / or to hold the charging device.

According to the invention, characterized in that the cooling device has a first cooling element, which is intended to cool a directed onto the energy storage air flow. In at least one operating state, the cooling element has a cooling temperature which is less than an ambient temperature surrounding the charging device and / or the energy store in order to cool the energy store by means of the cooling temperature.

It is understood that the charging device can be provided for charging more than just an energy store. It is also understood that the cooling device may have more than one cooling element.

Under an ambient temperature in particular according to DIN EN 60204-1 denotes a temperature of the ambient air or other ambient medium, in which the charging device and / or the energy storage device is used as intended. In particular, the ambient temperature can vary greatly if the charging device or the energy store is exposed to direct sunlight, for example. As a result, the energy storage device can be charged independently of an increased ambient temperature.

The charging device according to the invention can be releasably connected to an energy store. Loading device is intended to charge the energy storage. The charging device may have an electrical interface.

The energy store may have an electrical interface which can be coupled to an electrical interface of the charging device and transmits electrical energy from the charging device to the energy store. The interfaces may have metallic contact elements for conducting electrical current. The energy store can be designed as a battery pack. The energy store may comprise a plurality of battery cells. Lithium cells can be used as battery cells.

The cooling device is intended to cool the energy storage to allow for high outside temperatures such as more than 30 ° C or more than 40 ° C rapid charging of the energy storage with electrical energy. The cooling temperature of the cooling element is preferably at least 1 ° C, in particular at least 3 ° C, preferably at least 5 ° C, preferably at least 8 ° C, more preferably at least 12 ° C, more preferably at least 20 ° C, cooler than the ambient temperature.

The cooling device can be provided to cool the energy store during a charging process. Alternatively or additionally, the cooling device can be provided to cool the energy store independently of a charging process.

Also, the energy storage can be cooled after a discharge by, for example, using the energy storage in a hand tool faster to the optimum charge for charging the charger according to the invention charging temperature, so that the energy storage can be charged quickly. In this case, in particular, a charging heat generated during charging can be compensated, so that a longevity of the energy storage is ensured.

The housing surrounds the charging device. The housing forms an outer housing, which is intended to substantially surround the cooling device. The housing may have an air inlet opening and an air outlet opening. The housing may have a singular or a plurality of air inlet openings. The housing may have a singular or a plurality of air outlet openings. The openings ( Air inlet opening, air outlet) may be formed as material breakthroughs which open a housing from an outside to an inside. The material breakthrough is intended to allow an air flow of ambient air from an outside environment through the material breakthrough into the interior of the loading device. The material breakthrough is intended to allow an air flow of ambient air from an interior of the loading device through the material breakthrough to an outside environment. An air flow is intended to represent a directed flow of the air, which is intended in particular to emit a heat in the interior of the housing and to form a cooling air flow from the air outlet opening. A directed flow is to be understood as meaning, in particular, a substantially rectilinear flow. The air inlet opening may be arranged on a side of the housing opposite the air outlet openings.

The cooling device is provided to form an air flow from the air inlet opening to the air outlet opening in an operating state. In this case, the air flow of the air outlet opening should be colder than the air flow of the air inlet opening. The air flow of the air outlet opening can be provided to cool the energy storage means by means of an air flow directed to the energy storage and to flow around this.

The energy store can cover the air outlet opening, in particular completely, so that the air flow of the air outlet opening directly flows to the energy store.

The cooling device is to form an active cooling of the energy storage.

The cooling device should be designed to be activated during charging, so that cooling during charging is made possible.

The air flow may be intended to flow through the charger.

The dependent claims indicate expedient developments of the charging device according to the invention.

Furthermore, it may be expedient that the cooling device has a fan element, which is provided to form the directed onto the energy storage air flow. The air flow can essentially extend between the energy store and the fan element. The fan element may be provided to completely bypass and / or flow through the energy store by means of the air flow. The fan element can be designed as a fan wheel element. The cooling device may include a singular or a plurality of fan elements. The fan element may be arranged in the housing. The fan element may be surrounded by the housing. The fan element may have a plurality of circumferentially spaced apart fan blades. The cooling device can form a directed air flow such that the air inlet opening has an inlet air flow and the air outlet opening has an outlet air flow. As a result, the cooling device can be cooled in a particularly effective manner.

Further, it may be appropriate that the first cooling element is flowed around by the air flow. Preferably, the first cooling element and be arranged in the flow direction of the air flow between the energy storage and the fan element. In the flow direction follows the fan element, the first cooling element and the first cooling element is followed by the energy storage. As a result, an air flow can be cooled in a particularly reliable manner.

Furthermore, it may be expedient that the cooling device has a second cooling element, which is arranged in a flow direction of the air flow behind the first cooling element. In the flow direction follows the second cooling element, the fan element and the fan element is followed by the first cooling element and the first cooling element is followed by the energy storage. Preferably, the cooling device has a third cooling element, which is arranged in the flow direction at least substantially between the first cooling element and the second cooling element.

It is proposed that the first, in particular each, cooling element is designed as a Peltier element and / or as an evaporator. The cooling device may include a compressor and a refrigerant, in particular a climate fluid. The compressor may be adapted to move the refrigerant in the cooling device. Alternatively, the cooling device may comprise a feed pump, which is intended to move the coolant in the cooling device. The cooling device may be designed as a refrigerator. The refrigerant may be formed as a refrigerant fluid. The refrigerant may, in at least one operating state, be present at least substantially in a liquid phase and in at least one further operating state at least substantially in a gaseous phase. The refrigerant can be guided in a pipe system. The pipe system can form a cooling circuit. It is understood that the cooling circuit with an external or outside the charging device arranged cooling circuit can be coupled.

The cooling element may be formed as a convection element. The evaporator may be configured as an evaporator of a refrigeration device. As a result, the energy storage can be cooled particularly reliable.

It is also proposed that the cooling device has a heat-conducting element with a heat-conducting surface which at least partially forms the outer casing of the charging device and with which the energy store can be contacted in a charging state. The heat-conducting element can be surrounded by the outer casing in a plane of 360 °. The heat-conducting element can serve as a bearing surface or as a contact surface of the energy store during a charging process in order to contact the energy store and to allow heat conduction. As a result, heat can be transferred in a particularly simple and fast manner to cool the energy storage.

The first and / or the second cooling element may be designed as an evaporator of a refrigeration device. The first and second cooling elements may be integrally connected. The third cooling element can be designed as a Peltier element and be provided to contact the energy store during a charging process.

The cooling elements may be integrally formed and form a cooling circuit of the evaporator of a refrigerator.

It is further proposed that the heat-conducting element, in particular the heat-conducting surface, is formed integrally with the Peltier element or the evaporator. The heat-conducting element should be understood as an element with a coefficient of thermal conduction of more than 1 W / mK, in particular more than 10 W / mK, preferably more than 100 W / mK. The heat-conducting element can be provided to receive and dissipate a heat energy of the energy store in order to cool the energy store. In this way, additional cooling by means of a heat conduction surface can be made possible.

The invention further relates to a system comprising a charging device according to one of the preceding claims and an energy store, in particular a battery pack.

It may be expedient that the energy store has at least one rechargeable battery heat element with a rechargeable battery heat conduction surface. The battery heat-conducting surface can at least partially form a battery outer housing of the energy store. The battery heat-conducting surface can contact the heat-conducting element, in particular the heat-conducting surface, of the cooling device in a charging state.

Furthermore, it may be expedient that the energy store has at least one cooling recess which is provided to receive an air flow and to deliver heat to the air flow. The cooling recess may be arranged between at least two, in particular three adjacent battery cells and, if appropriate, run therebetween. The cooling recess may be formed as a cooling channel. The cooling channel may extend in a gap between adjacent battery cells. The cooling channel may extend along an entire extension of the battery cells. The cooling channel may be arranged in a plane of 360 ° from the battery outer housing. The cooling channel may be formed as a substantially closed channel. The cooling channel may have a channel inlet, which in a state of charge, in which the energy store is connected to the charging device, cover the air outlet opening of the charging unit.

list of figures

• 1 eine perspektivische Ansicht einer Handwerkzeugmaschine mit einem Energiespeicher,
• 2 eine perspektivische Ansicht auf eine Ladevorrichtung gemäß Stand der Technik,
• 3 eine schematische Ansicht einer ersten Ausführungsform einer Ladevorrichtung und
• 4 eine schematische Ansicht einer zweiten Ausführungsform einer Ladevorrichtung.

Further advantages emerge from the following description of the drawing. In the drawings, embodiments of the invention are shown. The drawings, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations. Hereby shows:

• 1 a perspective view of a power tool with an energy storage,
• 2 a perspective view of a loading device according to the prior art,
• 3 a schematic view of a first embodiment of a charging device and
• 4 a schematic view of a second embodiment of a charging device.

In the following figures, the same components are provided with the same reference numerals.

The figures each relate to a loading device 11 for one as a battery pack 13 trained energy storage 13 , The battery pack 13 is intended a hand tool 15 to supply with electrical energy. The hand tool machine 15 is for example as a rotary impact wrench or as a drill ( 1 ) educated. In an alternative embodiment, the hand tool 15 as another hand tool that seems sensible to a person skilled in the art 15 , such as an angle grinder, be formed.

The hand tool machine 15 has one with a tool receiving unit 17 to Receiving insert tools (not shown) such as screwdriver bits for screwing screws or drills for drilling holes in a workpiece. The tool holder unit 17 has a clamping device known to a person skilled in the art 19 which is intended, an insertion tool in the power tool 15 to keep. The hand tool machine 15 has a battery receiving unit 21 with a holding unit 23 for releasably receiving a battery pack 13 on. The holding unit 23 is intended to use the battery pack 13 in one with the hand tool 15 to keep connected attachment state. The hand tool machine 15 is as a battery-operated hand tool 15 educated.

1 shows the hand tool 15 with a drive unit (not shown) for transmitting a working movement to an insert tool. The hand tool machine 15 has a handle housing 25 trained housing 25 on which an outer casing 27 the hand tool machine 15 forms and is provided by a hand of an operator of the power tool 15 to be embraced. The hand tool machine 15 has an actuator 29 for switching on and off the drive unit (not shown) by means of an on / off switch (not shown) and designed as a planetary gear unit (not shown) on.

2 shows a charging device 11 according to the prior art. In this case, the loading device 11 a cooling unit designed as air cooling 31 which is intended for the battery pack 13 to cool.

3 and 4 show a first embodiment of the charging device according to the invention 11 ( 3 ) and a second embodiment of the charging device according to the invention 11 ( 4 ). The loading device 11 is for charging one as a battery pack 13 trained energy storage 13 a hand tool 15 educated. The battery pack 13 has several battery cells (not shown). Furthermore, lithium cells can be used as battery cells, in particular, since it is possible, in particular in the case of lithium cells, to combine a plurality of battery cells into battery cell blocks in which a plurality of battery cells are connected in a parallel circuit. The battery cells can have different diameters and lengths.

The loading device 11 may be at least partially as an outer housing 33 trained housing 33 with one the battery pack 13 Recordable recording unit 35 have, which is intended to the battery pack 13 pick up and on the loader 11 to keep. The battery pack 13 is detachable with the receiving unit 35 connectable. The loading device 11 is intended to use the battery pack 13 charge. The loading device 11 has an electrical interface 37 on.

The battery pack 13 has an electrical interface 39 on which with an electrical interface 37 the loader 11 can be coupled to an electrical energy from the charging device 11 on the battery pack 13 transferred to. The interfaces 37 . 39 have metallic contact elements (not shown) for conducting electrical power.

The loading device 11 can be a cooler 41 for cooling the battery pack 13 exhibit. The cooling device 41 has a first cooling element 43 on, which is intended, one on the battery pack 13 directed airflow KS to cool. The first cooling element 41 has in at least one operating state to a cooling temperature which is smaller by at least 3 ° C than a charging device 11 and the battery pack 13 surrounding ambient temperature to the battery pack 13 to cool by means of the cooling temperature.

The cooling device 41 is intended to use the battery pack 13 to cool during a charge. In this case, electrical energy required for charging and the battery pack 13 be compensated heated.

The loading device 11 is mains operated and has for this purpose a power cable (not shown), which the charging device 11 with, for example, a power outlet (not shown) connects.

The outer housing 33 surrounds the charger 11 , The outer housing 33 essentially surrounds the cooling device 41 , The outer housing 33 has an air inlet opening 43 and an air outlet opening 45 on. The openings (air inlet opening 43 , Air outlet 45 ) are here as material breakthroughs 43 . 45 formed, which an outer housing 33 open from an outside to an inside. The material breakthrough 43 . 45 is intended to provide a flow of air KS an ambient air from an outside environment through the material breakdown 43 . 45 into the interior of the loader 11 to enable. The material breakthrough 43 . 45 is intended to provide a flow of air KS an ambient air from an interior of the charging device 11 through the material breakthrough 43 . 45 to allow for an outdoor environment. The airflow KS is designed as a directed flow of air, which is intended to heat inside the outer casing 33 and a cooling air flow from the air outlet opening 45 to build.

The cooling device 41 is intended, in an operating condition, an air flow KS of the Air inlet opening 43 to the air outlet 45 to build. Here is the airflow KS the air outlet opening 45 colder than the airflow KS the air inlet opening 43 , The airflow KS the air outlet opening 45 is intended to use the battery pack 13 by means of one on the battery pack 13 directed airflow KS to cool and to flow around this.

The battery pack 13 covers the air outlet opening 45 the loader 11 completely in a state of charge, so the airflow KS the air outlet opening 45 the battery pack 13 flows directly to.

The cooling device 41 has a fan element 47 , which is intended, the on the battery pack 13 directed airflow KS to build. The airflow KS essentially extends between the battery pack 13 and the fan element 47 , The fan element 47 is intended to use the battery pack 13 by means of the airflow KS completely to flow around. The fan element 47 is designed as a fan element. In an alternative embodiment, the cooling device 41 several fan elements 47 exhibit. The fan element 47 is in the outer casing 33 arranged. The fan element 47 is from the outer casing 33 surround. The fan element 47 has a plurality of circumferentially spaced fan blades. The cooling device 41 forms a directed airflow KS such that the air inlet opening 43 has an input air flow and the air outlet opening has an output air flow.

The first cooling element 43 is from the airflow KS flows around. The first cooling element 43 is in the flow direction SR of the airflow KS between the battery pack 13 and the fan element 47 arranged. In the flow direction SR follows the fan element 47 the first cooling element and the first cooling element is followed by the battery pack 13 ( 3 . 4 ).

The cooling device 41 has a second cooling element 51 on, which in a flow direction SR of the airflow KS behind the first cooling element 43 is arranged. In the flow direction SR follows the second cooling element 51 the fan element 47 and on the fan element 47 follows the first cooling element 43 and on the first cooling element 43 follows the battery pack 13 ,

The cooling device 41 has a third cooling element 53 on, which in the flow direction SR at least substantially between the first cooling element 43 and the second cooling element 51 is arranged. The third cooling element 53 is designed as a Peltier element. The third cooling element 53 is as a heat conducting element 55 with a heat conduction surface 57 educated. The heat-conducting element 55 forms at least partially the outer housing 33 the loader 11 and contacts the battery pack 13 in a state of charge. The heat-conducting element 55 can in a plane of 360 ° from the outer casing 33 be surrounded. The heat-conducting element 55 is on a side surface 59 of the outer casing 33 be arranged and serves as a contact surface 59 of the battery pack 13 during a charging process. The contact surface contacts 59 the battery pack 13 and allows heat conduction. In an alternative embodiment, the heat conducting element can 55 through the outer casing 33 extend around from the airflow KS to be cooled inside the housing.

The first and the second cooling element 43 . 51 are formed as a Peltier element.

In an alternative embodiment, at least the first and / or the second cooling element may be formed as an evaporator of a refrigerating machine device. The first and second cooling elements may be integrally connected.

The cooling elements 43 . 51 . 53 are preferably supplied by electrical conductors with electrical energy, which is preferably obtained from the mains socket.

The battery pack 13 has at least one battery heat element 61 with a battery thermal interface 63 on ( 4 ). The battery thermal interface 63 forms at least partially a battery outer housing 65 of the battery pack 13 , The battery thermal interface 63 contacts the heat conduction surface 57 the Wärmeleitelements 55 the cooling device 41 in a state of charge.

The battery pack 13 has at least one cooling recess 67 which is intended to receive an air flow KS and heat to the air flow KS to give up ( 3 ). The cooling recess 67 is arranged between at least two, in particular three adjacent battery cells and extends between them. The cooling recess 67 is designed as a cooling channel. The cooling channel extends in a gap between adjacent battery cells. The cooling channel extends along an entire extension of the battery cells and in particular substantially of the battery pack 13 , The cooling channel is in a plane of 360 ° from the outer casing 33 the loader 11 arranged. The cooling channel is designed as a substantially closed channel. The cooling channel has a channel entrance 69 on, which in a state of charge, in which the battery pack 13 with the charger 11 connected to the air outlet 45 covered the charging unit.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• DIN EN 60204-1 [0007]

Claims (10)

Charging device for charging an energy store (13), in particular a battery pack (13), a hand tool (15), with a cooling device (41) for cooling the energy store (15), in particular the battery pack (13), with a housing, which at least in sections forms an outer housing (33) and with the energy storage device (13) accommodating receiving unit (35), which is intended to receive the energy storage device (13) and / or to the charging device (11), characterized in that the cooling device (41) has a cooling element (43, 51, 53) which is provided to cool an air flow (KS) directed onto the energy store (13), the cooling element (43, 51, 53) having a cooling temperature in at least one operating state which is smaller than an ambient temperature surrounding the charging device (11) and / or the energy store (13) in order to cool the energy store (13) by means of the cooling temperature. loader Claim 1 , characterized in that the cooling device (41) has a fan element (47) which is provided to form the directed to the energy storage (13) air flow (KS), which is substantially between the energy storage (13) and the fan element (47). Charging device according to one of the preceding claims, characterized in that the first cooling element (43) is flowed around by the air flow (KS) and in the flow direction (SR) of the air flow (KS) between the energy store (13) and the fan element (47) is arranged , Loading device according to one of the preceding claims, characterized in that the cooling device (41) has a second cooling element (51) which is arranged in a flow direction (SR) of the air flow (KS) behind the first cooling element (43). Loading device according to one of the preceding claims, characterized in that the first, in particular each, cooling element (43, 51, 53) is designed as a Peltier element and / or as an evaporator. Loading device according to one of the preceding claims, characterized in that the cooling device (41) has a heat-conducting element (55) with a heat-conducting surface (57) which at least partially forms the outer housing (33) of the charging device (11) and with which the energy store (13 ) is contactable in a state of charge. Charging device according to one of the preceding claims, characterized in that the heat-conducting element (55), in particular the heat-conducting surface (57), is formed integrally with the Peltier element or the evaporator. System comprising a charging device (11) according to one of the preceding claims and an energy store (13), in particular a battery pack (13). System after Claim 9 , characterized in that the energy store has at least one rechargeable battery heat element (61) with a rechargeable battery heat-conducting surface (63) which at least partially forms a rechargeable battery outer housing (65) of the energy store (13) and in particular which the heat-conducting element (55), in particular the heat-conducting surface (67) of the cooling device (41) contacted in a state of charge. System according to one of Claims 8 or 9 , characterized in that the energy store (13) has at least one cooling recess (67) which is provided to receive an air flow (KS) and to deliver heat to the air flow (KS).

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