阅读说明：本技术 手持式工具机和工具系统 (Hand-held power tool and power tool system ) 是由 J·布林尼恩斯图 H·勒姆 于 2016-11-07 设计创作，主要内容包括：本发明说明一种手持式工具机,该手持式工具机公开了具有把手的壳体、布置在所述壳体中的驱动马达和第一接口,其中,该接口设计为用于从至少一个外部第二接口接收和/或给至少一个外部第二接口发送信息。根据本发明设置,所述壳体具有接收开口,其中,所述第一接口可取出地布置在所述接收开口中。此外,所述接收开口通过盖可松脱地封闭,其中,所述盖使壳体向外隔闭。(The invention relates to a hand-held power tool, which comprises a housing having a handle, a drive motor arranged in the housing, and a first interface, wherein the interface is designed to receive and/or transmit information from and/or to at least one external second interface. According to the invention, the housing has a receiving opening, wherein the first interface is arranged in the receiving opening in a removable manner. Furthermore, the receiving opening is releasably closed by a cover, wherein the cover closes the housing to the outside.)

1. A hand-held power tool (300) comprising: a housing (305) having a handle (315); a drive motor (335) disposed in the housing (305); and a first interface (380), wherein the first interface (380) is designed for receiving information from at least one external second interface (980) and/or for transmitting information to at least one external second interface (980);

wherein the housing (305) has a receiving opening (307), wherein the first mouthpiece (380) is arranged in the receiving opening (307) in a removable manner; wherein the receiving opening (307) can be releasably closed by a cover (308); and wherein the cover (308) closes the housing (305) outward,

characterized in that the receiving opening (307) is arranged in a region of a rear end of the housing (305) of the hand-held power tool (300) which is located behind the drive motor (335).

2. The hand-held power tool (300) according to claim 1, characterized in that an interface housing (389) for receiving the first interface (380) is arranged in the receiving opening (307).

3. The hand-held power tool (300) as claimed in claim 2, characterized in that the interface housing (389) is formed in one piece with a housing (305) of the hand-held power tool (300).

4. The hand-held power tool (300) as claimed in claim 2, characterized in that the interface housing (389) is formed in two parts from a housing (305) of the hand-held power tool (300).

5. The hand-held power tool (300) as claimed in claim 2, characterized in that the interface housing (389) forms a module with the first interface (380) and the cover (308), which module can be releasably mounted in the region of the receiving opening (307).

6. The hand-held power tool (300) according to any one of claims 1 to 3, characterized in that the cover (308) has a slot-shaped recess (309).

7. The hand-held power tool (300) according to any one of claims 1 to 6, characterized in that the cover (308) is locked on the housing in a rotating manner, in particular by a screw, flip-lock or bayonet lock (304), or in that the cover is locked on the housing (305) by means of at least one connecting means (306), in particular by means of at least one screw.

8. The hand-held power tool (300) according to any one of claims 1 to 7, characterized in that the first interface (380) has a radio module (382).

9. The hand-held power tool (300) according to any one of claims 1 to 8, characterized in that the first interface (380) has its own energy store (384) and/or the first interface is supplied with energy by a current supply device of the hand-held power tool (300).

10. The hand-held power tool (300) as claimed in claim 9, characterized in that the energy store (384) is replaceable and/or rechargeable.

11. The hand-held power tool (300) according to any one of claims 1 to 10, characterized in that the first interface (380) has at least one contact circuit board (386).

12. The hand-held power tool (300) according to any one of claims 1 to 11, characterized in that the first interface (380) is connected to the control unit (370) and/or to a battery electronics (800) of the battery pack (100) in a wired or wireless manner for data exchange.

13. The hand-held power tool (300) according to any one of claims 1 to 12, characterized in that the first interface (380) has at least one damping element (388), in particular a visco-elastic element.

14. The hand-held power tool (300) according to claim 13, characterized in that the damping element (388) is arranged between the cover (308) and the radio module (382) and/or between the interface (380) and a bottom surface (381) of the interface housing (389).

15. The hand-held power tool (300) according to any one of claims 1 to 14, characterized in that the first interface (380) receives and/or transmits radio signals, bluetooth signals, WLAN signals, optical signals or acoustic signals, in particular bluetooth low energy signals.

16. A tool system comprising a hand-held power tool (300) according to any one of claims 1 to 15 and comprising an external unit (900), characterized in that the external unit (900) has a second interface (980) which is designed for receiving information from the first interface (380) and/or for transmitting information to the first interface (380).

17. A tool system according to claim 16, wherein said external unit (900) is a smartphone or an electronic data processing device.

Technical Field

The invention relates to a hand-held power tool and a tool system.

Background

Electric hand-held power tools are known in principle and are supplied with current via a mains connection. Alternatively, the battery device makes it possible to achieve a high degree of flexibility in operation, since the battery device is not dependent on the grid current in particular. In this way, it is possible, for example, to easily carry out outdoor work, so that the use of a battery pack is more often provided when operating the hand-held power tool.

Such battery packs are known in principle and have rechargeable batteries, usually a plurality of battery cells connected in parallel and/or in series. In the context of the present application, a battery pack is therefore to be understood as a battery pack, which is preferably formed from a plurality of battery cells electrically connected together and which can store electrical energy and provide the energy required for operating the hand-held power tool. For example, three series-connected, cylindrical lithium ion cells, each at 3.6V, may be provided, resulting in a total voltage of 10.8V.

From the prior art, hand-held power tools are known which use a communication interface in the form of an infrared transmission device, for example, for transmitting data, parameters, etc. By means of the infrared transmission device, corresponding data can be exchanged between the hand-held power tool and the external interface. In this case, it has proven to be disadvantageous that such infrared transmission devices can be used only to a limited extent, since obstacles can be arranged between the hand-held power tool and the external interface, which could impede the transmission, or the movement of the user can at least partially interrupt the respective connection. Furthermore, such an infrared connection can only be used for a limited effective range. In the case of fixedly integrated infrared transmission devices, it has proven to be disadvantageous that replacement of the infrared transmission device is often impossible and/or the replacement process is complicated and costly.

Disclosure of Invention

The object of the present invention is to improve the above-mentioned disadvantages and to provide a hand-held power tool of the type mentioned at the outset, in which data, parameters, etc., can be transmitted reliably from or to an external control unit at a simple design effort and also over a large distance, and at the same time an adaptation to other conditions in respect of the respective connection between the hand-held power tool and the external control unit can be provided quickly and easily. The object of the present invention is, furthermore, to disclose a hand-held power tool in which a communication interface for the hand-held power tool can be provided, installed and replaced with little effort, wherein the installation and/or replacement process should be able to be carried out as simply and inexpensively as possible.

This object is achieved by the hand-held power tool according to the invention. The invention also provides advantageous configurations, variants and extensions.

According to the invention, a hand-held power tool is disclosed, comprising a housing having a handle, a drive motor arranged in the housing, and a first interface, wherein the interface is designed for receiving and/or transmitting information from/to at least one external second interface. According to the invention, the housing has a receiving opening, wherein the first interface is arranged in the receiving opening in a removable manner. Furthermore, the receiving opening can be releasably closed by a cover, wherein the cover closes the housing outward. In this way, the first interface can be releasably mounted on the hand-held power tool, wherein the receiving opening enables an easy and cost-effective exchange of the interface arranged in the housing of the hand-held power tool.

Advantageously, the hand-held power tool further comprises a control unit in the housing. The control unit can be in contact with the drive motor and/or the transmission and/or the battery pack electronics of the battery pack on the one hand and can be in electrical and/or mechanical contact with the first interface on the other hand and can receive and/or transmit information from said interface.

The interface housing is formed integrally with the housing of the hand-held power tool. Advantageously, the interface housing forms a receiving opening directly in a housing wall of the hand-held power tool, wherein the receiving opening can be embodied in the form of a pot or box with a circumferential side wall and a bottom surface. In this case, it is particularly advantageous if the pot-shaped receiving opening has an almost circular opening, which additionally reinforces the housing of the hand-held power tool, which is in principle weakened by the opening. Furthermore, the bottom surface has at least one opening for the passage of a connecting element, for example at least one electrical line, in the direction of other electronic components, for example control electronics and/or battery electronics. Alternatively or additionally, it is conceivable to form such openings in the region of the side walls.

Alternatively, the interface housing may be formed integrally with the housing of the hand-held power tool and an interface housing for receiving the interface may be arranged in the receiving opening. In a particularly preferred embodiment, the interface housing forms a separate module with the interface and the cover, which module can be releasably introduced into the receiving opening. In this case, the cover and the interface housing can be designed in particular in one piece, alternatively in two pieces, wherein the module is inserted into a receiving opening of the hand-held power tool and is releasably fixed, for example by a screw connection between the receiving opening and the interface housing or by other connecting elements. In this way, the entire interface is particularly compact and can be quickly and easily installed, replaced and/or retrofitted in the hand-held power tool. In this way, replacement and/or repair can also be carried out quickly, simply and inexpensively.

The interface housing can be fixed in the housing of the hand-held power tool or alternatively can also be inserted into the receiving opening and held in the receiving opening only by means of the cover. Preferably, the interface is arranged in the receiving opening as play-free as possible, for example by means of a snap connection, so that no rattling or the like occurs and also unintentional release of the interface is prevented during operation. Furthermore, it is advantageous if the receiving opening or the interface housing is designed in such a way that the insertion of the interface can only be carried out in one way, so that incorrect installation of the contact circuit board or the interface can be reliably prevented in the receiving opening of the hand-held power tool.

Advantageously, the cover is bent in such a way that it follows the contour of the housing wall and ends flush with the housing wall. The cover can be made of different plastic materials, such as polyamide 6, polyamide 66, pc (polycarbonat), ABS (acrylonitrile-butadiene-styrene-copolymer) or a mixture of materials from different plastics, and/or reinforced with glass fibers. Preferably, the cover is made of the same material as the housing of the hand-held power tool.

In order to provide reliable but simple access to the receiving opening and the interface arranged therein, it is advantageous if the cover is releasably locked in rotation, in particular by a screw or bayonet closure. Another embodiment is a cover which is mounted so as to be pivotable about a pivot axis and which can be releasably latched to the housing by latching, screwing, clamping or tensioning on the side opposite the pivot axis. In this way, it is possible to effectively suppress the possibility of the cover falling off the housing or the loss of the cover. Furthermore, the lid may have a slot-shaped recess, whereby a simple opening of the lid by means of a coin or a screwdriver may be achieved. The bayonet closure is easy to handle and also ensures a reliable closure of the receiving opening. In addition or alternatively, the cover can also be fixed to the housing by means of at least one connecting element, in particular by means of at least one screw.

In an advantageous embodiment, the receiving opening is arranged in the region of the handle. The handle serves as a placement surface for the hand of the operator of the hand-held power tool and generally has a longitudinal axis y, a front side which points in the direction of the tool receiver along the axis x, a rear side and two lateral sides. In this case, the receiving opening is arranged in particular in a region below an operating element for opening and closing the drive motor or for controlling the drive motor. Preferably, the receiving opening is arranged in the region of one of the two side faces of the handle, which side face extends substantially parallel to the longitudinal axis of the hand-held power tool. In this way, the operation of the hand-held power tool is not disturbed by the arrangement of the receiving opening.

In an alternative embodiment, the receiving opening is arranged in the region of the rear end of the housing of the hand-held power tool, which is located behind the drive motor. This is advantageous in particular in the following cases: the hand-held power tool has a plug-in battery, which protrudes with its battery pack electronics and a battery cell arranged in the plug-in battery into the handle. In this case, the hand-held power tool has only a very limited space in the region of the handle, so that the arrangement of the receiving opening for the interface in the region of the handle can be difficult. Furthermore, the receiving opening in the region of the rear end of the housing of the hand-held power tool makes it possible to grip the hand-held power tool without being obstructed by the receiving opening, in addition to not interfering with the operation of the hand-held power tool.

Preferably, the interface has a radio module, wherein the radio module receives and/or transmits radio signals based on electromagnetic waves, such as bluetooth signals (in particular bluetooth low energy signals), WLAN signals or NFC signals. The radio module relates to an electronic component for establishing communication connections in different areas via a radio network. The radio modules are already used, for example, in the context of so-called Machine-to-Machine (M2M), for example in the field of industrial automation, in motor vehicles to assist applications in the field of remote control technology or also for remote access to consumption meters, such as electric, gas or water meters. The use of radio modules generally enables wireless data transfer via a radio network, thereby avoiding the wiring complexity otherwise required. In this way, the transmission of data, parameters, etc. from or to the external interface can be reliably implemented with simple design effort.

As a preferred embodiment of such a radio module, for example, a WLAN module, for example an 868MHz module or a 915MHz module, or also a bluetooth module, can be used. Other kinds of radio modules may be used as well. The radio Network can be a communication Network of any Wireless communication standard, for example WLAN ((Wireless local area Network), bluetooth, gsm (global System for Mobile communications), gprs (global System for Mobile communications) or umts (universal Mobile Telecommunications System), furthermore, Wireless communication networks which are specifically adapted to the respective requirements and have a shorter effective range, also referred to as "Wireless Personal Area Networks (WPANs)", are increasingly used in particular in the field of industrial automation, as an example radio networks according to one of the IEEE 802.15.4 or Wireless-HART standards.

Advantageously, the activated radio module emits a signal every 8 seconds. Alternatively and depending on the energy supply, the signal can also be emitted at shorter or longer intervals. In particular, in the case of energy supply by means of the second energy store, a radio signal can be emitted, for example, every 10, 20 or 30 seconds, in contrast to which, in the case of energy supply by means of the first energy store, a radio module emits, for example, a signal every four seconds or even every second. The respective radio modules of the transmission device can be connected in series, in particular, to the drive control device, to the measuring device for measuring various tool variables, etc. Such tool variables are, for example, the motor speed, torque, direction of rotation of the drive motor.

In order to be able to supply the interface with sufficient power in a simple manner, according to a preferred embodiment of the invention: the radio module, in particular the interface, is supplied with energy by a current supply device of the hand-held power tool. This is ensured by means of the releasable attachment of the interface to the current supply and/or the energy store of the hand-held power tool.

Alternatively, it is conceivable for the radio module to have its own energy store, which is arranged in the interface housing, wherein the radio module is connected to the current supply of the hand-held power tool and/or to its own energy store. According to the invention, it is provided that, in the presence of a current supply device of the hand-held power tool and with sufficient energy, the radio module is supplied with energy by the current supply device of the hand-held power tool; and in any other case by its own energy store. In this way, the energy supply of the radio module can be ensured at any time.

It is also advantageous if the energy store is connected to the radio module by means of plug contacts or contact contacts and the interface also has a spring-loaded device in the form of a spring element, thereby ensuring a reliable electrical contact. In principle, it can be provided that a spring element, for example a spring element, is arranged between the cover and the energy store or between the bottom of the interface opening and the energy store in order to press the energy store against the contacts provided in the interface when the cover is closed. Advantageously, such an energy store, for example a button cell, can be exchanged. According to the invention, this can be achieved by opening the cover, so that a user can remove the energy store from the receiving opening through the opening and replace it by a charged energy store. Advantageously, the energy store is arranged between the radio module and the cover and is arranged parallel to the longitudinal axis y of the hand-held power tool with respect to its main plane of extension. By reclosing the cover, the energy store is reliably stored in the receiving opening. In this way, the replacement of the entire interface together with the radio module is avoided and a reliable operation of the interface is ensured in a simple manner over a long period of time.

Alternatively, the energy store itself can also be embodied in a rechargeable manner, wherein the energy store is or can be electrically connected to an energy supply device of the hand-held power tool in order to ensure the charging of the energy store. If the hand-held power tool has its own energy store in the form of a battery pack or a mains connection plug, the interface's own energy store can be recharged by energy supplied by the mains or the battery pack of the hand-held power tool. In this case, a control unit is advantageously provided in the interface, which, depending on the energy supply of the hand-held power tool, charges its own energy store of the interface and/or enables the energy supply of the interface to be realized only by the energy supply device of the hand-held power tool, as a result of which a continuous operation of the interface can be ensured in a simple manner.

It is also advantageous if the interface has at least one contact circuit board, wherein the contact circuit board electrically connects the radio module and the control unit of the hand-held power tool to one another and enables wired or wireless data exchange. Furthermore, the contact circuit board may provide additional space for receiving additional electronic units, for example for the above-mentioned control unit. In this connection, the contact circuit board has at least one, preferably two, connection elements, for example plug connection devices for plug contacts, wherein at least one connection element ensures data exchange and/or energy supply by means of or via a control unit of the hand-held power tool and/or a further connection element ensures data exchange and/or energy supply from the contact circuit board to the radio module via a contact, for example a SIM card contact.

In an alternative embodiment, the interface does not have its own contact circuit board, in which case the radio module and/or its own energy store are electrically connected, wirelessly or by wire, directly to the tool-side contact elements. In a further embodiment, the arrangement of the interface in the receiving opening can also be realized without a contact to the hand-held power tool, so that the hand-held power tool can be positioned at least by means of the radio module.

Preferably, the interface also has at least one damping element, in particular a viscoelastic element, which is advantageously embodied in a ring shape, for example as an O-ring or an O-web, and is elastically deformable. The damping element can be formed integrally with the interface housing, the receiving opening, the cover and/or the contact circuit board or as a separate component. Preferably, the damping element is arranged between the cover and the contact circuit board or the radio module. Alternatively or additionally, the damping element can also be arranged between the contact circuit board or the radio module and the bottom surface or the side wall of the receiving opening. This ensures that the interface is reliably protected from external influences within the receiving opening and/or within the interface housing.

Advantageously, the contact circuit board is fixed in the receiving opening or in the interface housing by means of a latching device, wherein the holding force can be ensured by the damping element. Accordingly, the receiving opening and/or the interface housing can have a plurality of different latching elements, by means of which the interface or parts thereof can be latched in the interface housing or in the receiving opening and can be secured to the greatest possible extent without play.

Furthermore, orientation elements, such as ribs and webs, can be arranged in the receiving opening and/or on the mouthpiece or the mouthpiece housing, with which ribs and webs a univocal arrangement or orientation of the mouthpiece or the mouthpiece housing in the receiving opening can be achieved. Therefore, erroneous mounting can be prevented in a simple manner.

The hand-held power tool according to the invention can also be arranged in a power tool system. Accordingly, the hand-held power tool forms a further subject matter of the invention together with an external unit, which has a second interface, which is in turn designed for receiving information from the first interface and/or for transmitting information to the first interface. According to the invention, it can be provided that the external unit is a smartphone, an electronic data processing device, an electronic technical product, such as a hand-held lighting device, a radio broadcast on a construction site, a hand-held power tool, and/or a charger.

The tool system allows data, parameters, etc. to be reliably exchanged between the hand-held power tool and the external unit at a simple design effort and over a large distance, so that control or switching between different operating modes of the hand-held power tool can be facilitated.

A hand-held power tool is generally understood to be any hand-held power tool having a tool carrier that can be set in motion, for example in rotation and/or in vibration, for example a pole driver, a battery drill, a hammer drill, a multifunction tool and/or a drill driver, which can be driven by a drive motor. The transmission of electrical energy is to be understood in this context to mean, in particular, that the hand-held power tool is supplied with energy via a battery and/or a cable connection.

In principle, in particular, lithium ion batteries can be used as battery cells for a battery pack, since, in particular in the case of lithium ion batteries, a plurality of battery cells can be combined into a battery cell block in which a plurality of battery cells are connected in parallel. In this case, it is particularly advantageous if the cell holder can receive battery cells of different diameters and lengths, so that the cell holder or the cell carrier can be used in different battery packs.

The electric motor is an EC motor (electronically commutated motor). On the one hand, such brushless EC motors are particularly efficient because they are almost maintenance-free and, due to their high efficiency during operation of the battery, allow the battery to operate for a relatively long time after each charging. Furthermore, the hand-held power tool with the EC motor can be constructed very compactly and in a lightweight manner, wherein it is particularly advantageous if the heat losses are also low, so that the appliance is not as hot as a comparable appliance and therefore has a longer service life.

Further features, application possibilities, advantages and configurations of the invention result from the following description of exemplary embodiments of the invention, which are illustrated in the drawing. The description, drawings contain several combined features. The person skilled in the art can also consider the features described, in particular the features of the different embodiments, individually and summarize them into meaningful further combinations. It should be noted here that the features shown have merely an illustrative character and can also be used in combination with other extensions described above and should not be considered to limit the invention in any way.

Drawings

The invention is explained in detail below on the basis of preferred embodiments. The figures show schematically:

fig. 1 is a side view of a hand-held power tool according to the invention, with a first embodiment of an interface inserted into a receiving opening;

fig. 2 is a perspective view of the hand-held power tool according to the invention from fig. 1, with an exploded view of the inserted interface;

FIG. 3 is a detailed view of the interface of FIG. 2;

FIG. 4 is a cross-sectional view of the receiving opening along axis y of FIG. 1 with a second embodiment of the interface built into it;

FIG. 5 is a cross-sectional view of the receiving opening along line A-A of FIG. 1 with the first embodiment of the interface built into it;

FIG. 6 is a cross-sectional view of the receiving opening taken along line A-A of FIG. 1, with a third embodiment of the interface built into it;

FIG. 7 is a perspective view of a contact circuit board of the interface;

fig. 8 is a side view of a hand-held power tool according to the invention, with a fourth embodiment of the inserted interface; and

fig. 9 is a perspective view of the hand-held power tool according to the invention from fig. 8 with the cover removed.

Detailed Description

Fig. 1 shows an electronic device in the form of a hand-held power tool 300, which is in the form of a battery-operated drill driver, for example. Accordingly, in the embodiment shown, hand-held power tool 300 is mechanically and electrically connected to battery pack 100 for a network-independent current supply. It should be noted, however, that the invention is not limited to battery-operated drill drivers, but can be used in different hand-held power tools 300 operated with a battery pack 100. The hand-held power tool 300 has a not shown gear 330, which is arranged in the housing 305 and serves to transmit a torque generated by a likewise not shown drive motor 335 to a drive shaft rotating about the axis of rotation x, on which drive shaft the tool receiver 320 is fastened, and a handle 315. The hand-held power tool 300 has a control unit 370 in the housing 305, which is in electrical and/or mechanical contact with the drive motor 335 and/or the gear 330. The handle 315 serves as a placement surface for the hand of the operator of the hand-held power tool 300 and generally has a longitudinal axis y, a front side 317, a rear side 316 and two side sides 318, the front side pointing in the direction of the tool receiver 320 along the axis x. Battery pack 100 shown in fig. 1 is implemented as a push-on battery pack. When battery pack 100 is mounted on hand-held power tool 300, receiving means, such as guide grooves and guide ribs, provided on hand-held power tool 300 form a fit with corresponding guide elements 110 of battery pack 100, battery pack 100 being guided along the receiving means of handle 315 in the insertion direction, and battery pack 100 being inserted into the battery pack receiving means of hand-held power tool 300 along the lower outer surface of handle 315 oriented substantially perpendicularly to the longitudinal direction y of handle 315. In the position shown in fig. 1, battery pack 100 is fixed and locked on handle 315 of hand-held power tool 300 by means of a locking device. The locking means comprise, inter alia, a locking element and an actuating element 220. By actuating the actuating element 220, the battery pack 100 can be released from the handle 315 of the portable handheld power tool 300.

In addition, the handle 315 has a receiving opening 307 for receiving the interface 380. The interface 380 is designed for receiving and transmitting information to a control unit 370 arranged within the housing 305 and/or to an external second interface, not shown. The receiving opening 307 is arranged on one of the two side faces 318 in a region below the operating element 310 for opening and closing or for controlling the drive motor 335. In this way, the arrangement of the receiving opening 307 does not interfere with the operation of the hand-held power tool 300. In the embodiment shown, the receiving opening 307 is implemented pot-shaped. Alternatively, the receiving opening 307 can also have other embodiments, for example a box-shaped embodiment.

The can-shaped receiving opening 307 is shown with a surrounding side wall 385 and with a bottom surface 381. This has the following advantages, among others: the almost circular receiving opening 307 additionally reinforces the housing 305 of the hand-held power tool 300, which is in principle weakened by the receiving opening 307. The receiving opening 307 can be closed by means of a cover 308. The cover 308 is curved in such a way that it follows the contour of the housing 350 and terminates flush with said contour. Accordingly, the cover 308 can be made of a different plastic material, such as PA6(Gebamid B), PA6.6(Gebamid a), pc (polycarbonat), ABS (acrylonitrile-butadiene-styrene-copolymer) or a mixture of different plastic materials, and/or reinforced with glass fibers, wherein the cover 308 advantageously comprises the same material as the housing 305 and the handle 315 of the hand-held power tool 300.

In order to provide reliable but simple access to the receiving opening 307 and the interface 380 arranged therein, the cover 308 has a slot-shaped recess 309. Through the slit-shaped recess 309, the cover 308 can be opened, for example, by means of a coin or a screwdriver. In the embodiment shown in fig. 2 and 3, the cover 308 is locked in rotation, in particular releasably by a bayonet lock. As in fig. 8 and 9, the cover 308 can also be locked to the housing 305 by means of at least one connecting element 306, in particular by means of at least one screw. Another embodiment, not shown, is a flap which is mounted so as to be pivotable about a pivot axis and can be releasably latched to the housing 305 by latching, screwing, clamping or tensioning on the side opposite the pivot axis. A possible falling or loss of the cover 308 can be prevented by such a cover 308.

Fig. 2 shows a perspective view of hand-held power tool 300 from fig. 1, wherein interface 380 is shown, in particular in an exploded view, releasably inserted into receiving opening 307. In the embodiment variant shown, the interface 380 essentially has a damping element 388, its own energy store 384, a radio module 382, a contact circuit board 386 and, in the embodiment shown, also a cover 308.

As shown in fig. 3 and 5, the receiving opening 307 may be integrally constructed with the housing 305 to form an interface housing 389. Alternatively, as shown in fig. 4 and 6, the interface housing 389 may be constructed in two parts and together with the cover 308 can be releasably inserted as a module into the receiving opening 307 of the hand-held power tool. The interface housing 389 can be fixed in the housing 305 of the hand-held power tool or, alternatively, can also be inserted into the receiving opening 307 and held in the receiving opening 307 only by the cover 308. The interface 380 is arranged in the receiving opening 307 as play-free as possible, for example by means of a snap connection, as a result of which rattling or the like can be avoided and unintentional release of the interface 380 can be prevented.

Furthermore, the interface housing 389 has a bottom surface 381, which bottom surface 381 has at least one opening 390 for the passage of the connecting element 387, for example at least one electrical line or plug contact, in the direction of other electronic components, for example the control electronics 370 and/or the battery electronics 800. In principle, but not illustrated, such openings 390 may alternatively or additionally be formed in the region of the side walls 385.

The interface 380 and in particular the radio module 382 can be supplied with energy (not shown) by means of releasable attachment of the interface 380 to a current supply and/or an energy store of the hand-held power tool 300. Alternatively and as shown in the figures, the interface 380 has its own energy store 384, which in the embodiment shown is embodied as a button cell battery and is arranged within an interface housing 389 directly on the radio module 382 and between the cover 308 and the radio module 382 parallel to the longitudinal axis y of the hand-held power tool 300 with respect to its main plane of extension.

In order to latch the energy store 384, the interface 380 has at least one spring element, which can be arranged, for example, in the form of a spring element between the cover 308 and the energy store 384 and/or between the bottom 381 of the interface housing 289 and the contact circuit board 386 in order to press the energy store 384 against the contacts provided in the interface 380 when the cover 308 is closed, as a result of which a reliable electrical contact can be ensured.

The energy store 384 is replaceable, wherein this can be achieved by opening the cover 308. By closing the cover 308, the energy store 384 is securely held in the receiving opening 307. In this way, the replacement of the entire interface 380 together with the radio module 382 is avoided and a reliable operation of the interface 380 is ensured in a simple manner over a long period of time.

Alternatively, the energy store 384 itself can also be embodied in a rechargeable manner, wherein the energy store 384 is or can be electrically connected to an energy source, for example to the battery pack 100 or to a mains connection of the hand-held power tool 300, in order to ensure charging of the energy store. Depending on the energy supply of the hand-held power tool 300, the energy store 384 of the interface 380 is charged and/or the interface 380 can be supplied with energy directly by the energy supply device of the hand-held power tool 300, in which way a continuous operation of the interface 380 can be ensured in a simple manner.

The interface of fig. 2 is shown in detail in fig. 3 and from other perspectives. The radio module 382 is designed for receiving and/or transmitting radio signals, for example bluetooth signals, WLAN signals, acoustic signals. Accordingly, the radio module 382 contacts the control unit 370, the battery electronics 800 and/or various measuring devices for measuring tool variables via a wireless or wired connection. Such tool variables are, for example, the motor speed, torque, direction of rotation of the drive motor. Advantageously, the activated radio module 382 emits a signal every ten seconds. Alternatively, the signal can also be emitted at shorter intervals, for example every four seconds or longer, for example every 20 or 30 seconds.

Furthermore, the contact circuit board 386 has an electronics unit, a connection element 383, for example a SIM card contact and/or a plug connection 387, in order to ensure data exchange with the radio module 382 and/or with the control unit 370 of the hand-held power tool 300 and/or with the battery pack electronics 800 of the battery pack 100. In an alternative embodiment, which is not shown, the interface does not have its own contact circuit board 386, wherein in this case the radio module 382 and/or its own energy store 384 are directly electrically connected, wirelessly or by wire, to the tool-side contact elements.

The damping element 388 may be a viscoelastic element which is advantageously embodied annularly, for example as an O-ring or an O-web and is elastically deformable. The damping member 388 is integrally constructed with the interface housing 389, the receiving opening 307, the cover 308 and/or the contact circuit board 386, or is constructed as a separate member. In the embodiment variants shown in fig. 2 to 5, the damping element 388 is arranged between the cover 308 and the radio module 382 or the energy store 384. As shown in fig. 6 and in detail in fig. 7, the damping element 388 may additionally also be arranged between the contact circuit board 386 and the bottom surface 381 of the interface housing 389. The damping element 388 ensures that the interface 380 is reliably protected from external influences within the receiving opening 307 and/or within the interface housing 389.

Fig. 5 shows a cross-sectional view of the receiving opening 307 along line a-a of fig. 1, wherein the interface housing 389 is constructed integrally with the housing 305. The receiving opening 307 is pot-shaped and has a side wall 385 and a bottom 381. The interface 380 of fig. 3 is inserted into the receiving opening 307, wherein the interface 380 has a cover 308, a damping element 388, an energy store 384, as well as a radio module 382 and a contact circuit board 386. Furthermore, one of the plug connections 387 projects through an opening 390 in the bottom 381 in order to establish contact with a contact element, not shown, of the hand-held power tool 300. The receiving opening 307 and the mouthpiece 380 are covered by means of a releasable cover 308. The cover 308 is bent in such a way that it follows the contour of the housing wall and ends flush with this contour. The damping element 388 is arranged in the embodiment variant shown in fig. 5 between the cover 308 and the energy store 384.

In contrast to the second embodiment shown in fig. 5, the third variant shown in fig. 6 has a sectional view of the receiving opening 307 along the line AA in fig. 1, wherein the interface housing 389 is constructed in two parts and is releasably insertable together with the cover 308 as a module into the pot-shaped receiving opening 307 of the hand-held power tool 300. In the embodiment variant shown in fig. 6, the damping element 388 is arranged between the bottom surface 381 and the contact circuit board 386.

In fig. 7, the contact circuit board 386 is shown in a perspective view along with the damping element 388. The damping element 388 is integrally and annularly configured and is applied directly on the first side of the contact circuit board 386. On a second side of the contact circuit board 386 a connection element 383 is arranged.

Fig. 8 shows a side view of a hand-held power tool 300 according to the invention with a fourth embodiment of a plug-in interface 380. The receiving opening 307 is arranged in the region of the rear end of the housing 305 of the hand-held power tool 300, behind the drive motor 335. This is particularly advantageous if the hand-held power tool 300, as shown, has a plug-in battery pack 100, which, together with its battery pack electronics 800 and the battery cells arranged in the plug-in battery pack 100, projects into the handle 315. In this case, the hand-held power tool 300 has only a very limited space in the region of the handle, so that it can be difficult to arrange the receiving opening 307 for receiving the interface 380 in the region of the handle 315. In this variant, the cover 308 is releasably fastened to the housing 305 of the hand-held power tool 300 by means of screws 383. As can be seen in fig. 9, the energy store 384 is arranged on the radio module 382 directly below the cover 308. By means of this arrangement of the interface 380, gripping of the hand-held power tool 300 can also be effected without hindrance, in addition to the operation of the hand-held power tool 300 not being disturbed.

In addition to the embodiments illustrated and described, further embodiments are also conceivable, which may comprise further variants and combinations of features.