EP3963690A1 - System comprising drive motors for hand-held power tools - Google Patents

Abstract

The invention relates to a system comprising a first drive motor (120) and a second drive motor (20). The drive motors (20, 120) are provided for a suction device (400) or a machine tool in the form of a hand-held power tool (200, 300) or a semi-stationary machine tool or form components of the suction device (400) or the machine tool. Each of the drive motors (20, 120) has a stator (80) with an excitation coil assembly (86) and a rotor (40, 140) with a motor shaft (30, 130) which is rotatably mounted about a rotational axis on the stator or relative to the stator (80) using a bearing assembly (24A) and which passes through a shaft through-opening (42, 142) of a laminated core (41, 141) held on a holding portion (33) of the respective motor shaft (30, 130). The holding portions (33) of the motor shafts (30, 130) of the drive motors (20, 120) have identical outer circumferential geometries in the region of the laminated cores (41, 141), wherein the laminated core (141) of the first drive motor (120) is supported directly on the outer circumference of the holding portion (33) of the motor shaft (30, 130) supporting the laminated core (141), and the laminated core (41) of the second drive motor (20) is supported on the holding portion (33) of the motor shaft (30, 130) supporting the laminated core (41) via an electrically insulating insulation element (60A).

Description

Festool GmbH, Wertstrasse 20, 73240 Wendlingen

System comprising drive motors for hand machine tools

The invention relates to a system comprising a first drive motor and a second drive motor, the drive motors each having a stator with an excitation coil arrangement and a rotor with a motor shaft which is rotatably mounted on the stator or with respect to the stator by means of a bearing arrangement about an axis of rotation and a Shaft passage opening of a Blechpa kets penetrated, which is held on a holding portion of the respective motor shaft.

The system is designed, for example, in the manner of a modular engine kit.

The drive motors are e.g. for a suction device or a machine tool in the form of a hand machine tool or a semi-stationary machine tool or form components of the suction device or the machine tool.

A respective or each drive motor is e.g. provided for a suction device or a machine tool in the form of a hand machine tool or a semi-stationary machine tool or forms a component of the suction device or the machine tool, ie the hand machine tool or the semi-stationary machine tool.

The first drive motor is arranged, for example, in a first device or intended for arrangement in a first device, while the second drive motor is arranged in a second device or is intended for arrangement in a second device, the first and second devices from one another are different. The first device or the second device is, for example, a hand machine tool or a semi-stationary machine tool or a suction device. Thus, for example, the first drive motor is for a first hand machine tool and the second drive motor is for a second

Hand machine tool or suction device provided.

In principle, however, it is possible that both drive motors or at least two drive motors according to the invention are also used in one and the same machine tool machine or the same suction device.

From JP S-59226630 A the use of an insulating sleeve in a motor shaft is known.

For different hand machine tools, for example drills, sawing machines or the like, different drive motors are typically used, the speed and power of which is optimally adapted to the respective machine type of the hand machine tool. The drive motors mentioned at the beginning are, for example, electronically commutated or brushless motors. For hand machine tools operated by means of accumulators and for mains operated hand machine tools, different drive motors are required which are suitable for different voltage classes. In practice, therefore, a variety of Antriebsmo tor variants is necessary, the production and storage is expensive.

It is therefore the object of the present invention to provide an improved system comprising at least two drive motors.

To solve the problem, it is provided in a drive motor of the type mentioned that the holding sections of the motor shafts of the drive motors in the area of the laminated core have identical outer circumferential geometries, the laminated core of the first drive motor being supported directly on the outer circumference of the holding section of the motor shaft carrying the laminated core and the Laminated core of the second drive motor via an electrically insulating insulation onskkörper is supported on the holding section of the motor shaft carrying the laminated core.

It is a basic idea that the same motor shafts can be used for different types of drive motors. In order to provide adaptation to different voltage ranges, no insulation between the motor shaft and the laminated core is necessary for one drive motor, but it is implemented using the insulation body for the other drive motor. Thus, for example, basically identical mechanical structures can also be provided in the respective stator of the drive motor, the same bearings for the drive motors and more. A kind of modular principle can therefore be implemented.

The system advantageously provides that the first drive motor is designed for a first operating voltage, in particular an operating voltage of less than 60 V, and the second drive motor for a second operating voltage, in particular an operating voltage of more than 60 V. It is particularly advantageous if the operating voltage for the first drive motor is a direct voltage, whereby it is advantageously provided that an energizing device of the machine tool or the suction device processes the operating voltage or direct voltage for the respective drive motor in order to provide currents for energizing the excitation coil arrangement . The first operating voltage is, for example, a typical voltage that is provided by battery cells or an accumulator pack. The first operating voltage is, for example, a voltage of 14 V to 36 V. The second operating voltage for the second drive motor is, for example, an AC voltage. This alternating voltage is also advantageously prepared by an energizing device for energizing the field coil arrangement of the second drive motor. The second operating voltage is, for example, greater than 110 V, in particular greater than 220-230 V. However, the isolation using the insulating body ensures that the isolation distances are sufficiently large even with such an operating voltage. It is advantageously provided that the first drive motor is configured for operation using an electrical energy storage device, in particular a battery pack, and the second drive motor is configured for network operation using an electrical alternating voltage network. The electrical energy store is, for example, a battery pack, but can also include, for example, a fuel cell or other similar energy store. The AC voltage network has, for example, a voltage of 110 V to 230 V.

It is also advantageous if the stators, in particular the laminated cores of the stators, of the first drive motor and the second drive motor are geometrically identical on the outside and / or have identical outer circumferential geometries.

It is also useful if the stators of the first drive motor and the second drive motor have identical laminated cores which are arranged on identical support bodies of the stators. The mechanical structure of the stators is therefore essentially the same or identical. In particular, it is advantageous if the laminated cores have the same geometries radially outside with respect to the axis of rotation and radially inside with respect to the axis of rotation. The carrier bodies are implemented, for example, by overmolding the respective laminated cores or molding plastic components onto the laminated cores. The carrier bodies can, for example, provide winding heads or the like other holding components for the field coil arrangement. Furthermore, the carrier bodies can be provided for the electrical insulation of the laminated core of the stator. For example, the carrier bodies can comprise walls which electrically isolate the laminated cores on the end face and / or radially inward from the rotor of the drive motor.

Even in the case of stators that are largely structurally identical, ie, mechanically identical laminated cores and support bodies, the following measure can easily be advantageously implemented. It is advantageously provided that the first drive motor and the second drive motor have different excitation coil arrangements, the excitation coils of which have different numbers of turns and / or un- different wire cross-sections, so that the first drive motor can be operated with a first operating voltage and the second drive motor with a second operating voltage different from the first operating voltage. The first operating voltage is, for example, a low voltage of less than 60 V, in particular a maximum of 36 V. The second operating voltage is, for example, a voltage of at least 110 V.

It is also advantageously provided that the stators of the first drive motor and the second drive motor have identical arrangements of support projections for receiving the excitation coils of the different excitation coil arrangements on their longitudinal end regions opposite one another with respect to the axis of rotation. The support projections include, for example, so-called winding heads or the like, around which the coil conductors of the excitation coils can be wound. It is possible that support projections or winding heads are used in one drive motor, while at least one support projection or winding head is not used in the excitation coil arrangement of the other drive motor or does not carry an electrical coil conductor of an excitation coil arrangement.

Furthermore, it is expedient if the stators of the first drive motor and the second drive motor, in particular the support body of the stators, have at least one plug-in receptacle for plugging in a connection device provided for connecting a connection line, which when in the plug-in receptacle is connected to at least one coil conductor of an excitation coil Excitation coil arrangement is electrically connected by means of the connecting line. Depending on the need for electrical connections, a connection device may or may not be arranged on the at least one plug receptacle. The connection device comprises, for example, a plug contact, a soldering lug or the like.

It is advantageously provided that the motor shafts of the drive motors are rotatably mounted on opposite longitudinal end regions of the respective stator on a first bearing and a second bearing of the bearing arrangement and the stators of the two drive motors in the region of the first bearing and of the second bearing and / or at least one bearing cover arranged on the respective stator and bearing the first or second bearing are geometrically identical. For example, the stators can be constructed identically in an assembly area where the bearing cover is to be arranged. It is also possible that one of the bearing caps or both bearing caps for the first and the second drive motor are identical.

An advantageous insulation concept, in particular for operation with mains voltage, provides that the insulation body has a wall thickness of at least 2 mm in the area of the shaft opening. Of course, the wall thickness of the insulation body can also be greater. It is also advantageous if the insulation body has the same wall thickness over its entire length, which it has within the sheet metal package.

A section of the insulation body can protrude in front of the laminated core and encase the motor shaft there. As a result, an additional insulation distance or protection against electric shock is implemented between the motor shaft on the one hand and the laminated core on the other. It is advantageously provided that the insulation body has at least one insulation section protruding in front of an end face of the laminated core.

An insulation distance of at least 5 mm, preferably at least 7 mm, in particular at least 8 mm, between tween the laminated core and the motor shaft is advantageously formed by the insulation section. Such a variant in particular enables operation with voltages of more than 60 V, in particular special AC voltages of 110 V and higher.

The isolation section can have different geometries and shapes. It can advantageously be provided that the insulation section comprises a pipe section or is formed by a pipe section which does not protrude radially outwardly with respect to the axis of rotation in front of a section of the insulation sleeve received in the shaft opening of the laminated core and which is arranged next to the insulation section with regard to the plug-in axis . Example wise, both the section received in the laminated core and the section of the insulation body protruding in front of the laminated core are each designed as a tubular body.

Furthermore, it is possible that the insulation section comprises an in particular ring-shaped flange body which protrudes radially outward in front of a tubular section of the insulation body received in the laminated core with respect to the axis of rotation. It is also possible that the flange body is not ring-shaped, but only partially ring-shaped or comprises ring segments. In this case it is advantageous to have insulation measures in the spaces between the individual

Flange sections are taken. An electrically insulating potting compound, an electrically insulating insulation element or the like is advantageously arranged in at least one intermediate space or all intermediate spaces between the individual flange sections. The flange body can have an additional function, namely that it supports the insulation body with a direction of force parallel to the axis of rotation of the drive motor on the laminated core.

In principle, it would be possible for the insulation body to be produced by a casting process. It is possible, for example, that the motor shaft is encapsulated with the material of the insulation body and / or that the motor shaft is inserted into a shaft opening of the rotor laminated core and then the laminated core and the motor shaft to form the insulation body with plastic or the like other insulating material be overmolded.

It is advantageous if the insulating body is formed by an insulating sleeve or has an insulating sleeve which is inserted into the shaft passage opening and is arranged between the motor shaft and the laminated core and a

Has plug-in receptacle with an insertion opening through which the motor shaft is inserted into the plug-in receptacle along a plug-in axis.

The plug axis preferably corresponds to the axis of rotation of the drive motor and / or a longitudinal axis of the motor shaft and / or the insulation sleeve. The quick-release axle along which the motor shaft is inserted into the connector, preferably corresponds to the plug-in axis along which the insulation sleeve is inserted into the shaft passage opening of the laminated core or runs parallel to the same.

It is a basic idea that the assembly or manufacture of the drive motor is simplified. The insulation sleeve forms a simple plug-in body that is inserted into the shaft opening of the laminated core and, in turn, provides a plug-in receptacle for plugging in or pushing through the motor shaft. It is advantageous if the insulating sleeve is first inserted into the shaft opening before the motor shaft is inserted into the plug-in receptacle of the insulating sleeve. In principle, however, it is also conceivable that first the motor shaft is inserted into the plug-in receptacle of the insulation sleeve and then the insulation sleeve arranged on the motor shaft is inserted into the shaft passage opening.

The insulating sleeve preferably extends over a full length of the laminated core with respect to the plug-in axis. Thus, a holding portion of the motor shaft on which the laminated core is held is completely isolated from the laminated core by means of the insulation sleeve.

It is also possible that the laminated core is electrically isolated from the motor shaft exclusively by means of the insulating sleeve. However, it is also possible that further insulation measures have been taken, i.e. that, for example, the motor shaft itself still has an insulation layer which is arranged between the insulation sleeve and the motor shaft when the drive motor is installed. Furthermore, it is conceivable that, although the insulation sleeve is inserted into the shaft opening of the laminated core, it is also encapsulated with plastic material, for example. This provides additional insulation.

The motor shaft preferably protrudes in front of the insertion opening of the insulation sleeve and / or in front of the outlet opening of the plug-in receptacle, which is in front of a longitudinal end region of the insulation sleeve opposite to the insertion openings. is seen. For example, the motor shaft can protrude on both sides in front of the insulation sleeve in order to be rotatably mounted there with respect to the stator, for example by means of the bearing arrangement, in particular by means of ball bearings, roller bearings or similar other roller bearings. At this point, however, it should be mentioned that the insulating sleeve can also extend, for example, to one of the bearings, that is to say that, for example, the insulating sleeve can provide electrical insulation sandwiched between a bearing receptacle of the bearing and the motor shaft.

The insulating sleeve expediently has at least one longitudinal stop for stopping against the laminated core with respect to the plug-in axis. The longitudinal stop can for example comprise a radial projection which protrudes radially with respect to the axis of rotation or plug-in axis in front of a pipe section of the insulation sleeve.

The insulating sleeve expediently has a flange body protruding in front of a pipe section of the insulating sleeve for supporting on the laminated core with respect to the plug-in axis. The pipe section is, for example, wholly or substantially received in the shaft passage opening. The flange body can be an annular flange body, i. that it extends in a ring around the axis of rotation or through axis. But it is also possible that the flange body is a partial ring body, i.e. is not completely annular.

The insulation sleeve is expediently clamped between the laminated core and the motor shaft in one or more directions of force, for example a direction of force radial to the axis of rotation and / or a direction of force parallel to the axis of rotation. For example, it is provided that the insulation sleeve is clamped through the motor shaft radially outward with respect to the axis of rotation with the laminated core. The motor shaft inserted or pushed through the plug-in receptacle thus ensures that the insulating sleeve is braced between the motor shaft and the shaft opening or the laminated core. Expediently, at least one abutment projection protrudes from the laminated core into the shaft passage opening, which protrudes into the insulation sleeve. It is possible that the at least one abutment projection penetrates the insulation sleeve or its outer wall when it is braced by the motor shaft with the shaft opening and / or is displaced into the shaft opening by the motor shaft. It is therefore possible that the at least one abutment projection does not protrude into a plug-in cross section of the shaft passage opening which is provided for inserting the insulation sleeve into the shaft passage opening when no motor shaft is arranged in the insulation sleeve. However, the motor shaft inserted into the plug-in receptacle of the insulation sleeve displaces the radial outer circumference of the insulation sleeve in the direction of the at least one abutment projection so that it comes into positive engagement with the insulation sleeve and / or claws or clamps with the insulation sleeve, so to speak. It is particularly advantageous if the at least one abutment projection plastically deforms an outer surface of the insulation sleeve when the insulation sleeve is received in the shaft opening and / or is displaced by the motor shaft in the direction of the shaft opening. The at least one abutment projection forms, for example, a retaining claw for claw-like penetration into the insulation sleeve.

It is preferred if several abutment projections are provided which have angular distances and / or longitudinal distances from one another with respect to the plug-in axis or axis of rotation. In particular, it is advantageous if at least one abutment projection is provided on opposite sides of the shaft passage opening.

With regard to the plug-in axis or axis of rotation, it is advantageous if several spaced-apart abutment projections or groups of abutment projections are present so that they can penetrate the insulating sleeve at a longitudinal distance with respect to the plug-in axis or axis of rotation.

At least one form-fit part is preferably formed on the insulation sleeve, on which the insulation sleeve is inserted through the plug-in receptacle Motor shaft is displaced with respect to the axis of rotation radially outward into a positive engagement with the laminated core. This form-fit part can include, for example, one or more such parts that penetrate between two of the aforementioned abutment projections or are received between them and / or that penetrate into a form-fit receptacle of the laminated core. The at least one form-fit part of the insulation sleeve can also comprise a form-fit receptacle into which an abutment projection of the laminated core engages.

It is preferred if the at least one form-fit part comprises a step on which an end face of the laminated core is supported. The step is preferably ring-shaped or flange-like. The plug-in receptacle has, for example, immediately next to the laminated core before the motor shaft is inserted, an internal cross-section which is enlarged or widened by the insertion of the motor shaft, so that the form-fit part or the step is formed. It is also advantageous if the insulating sleeve and the motor shaft are in engagement with one another by means of form-fitting contours, for example parallel and / or secure against rotation with respect to the plug-in axis and / or a longitudinal axis of the motor shaft or the insulating sleeve. Form-fitting contours, for example corrugations, grooves, honeycomb-like structures or the like, other form-fitting contours, can be provided, for example, on the inner circumference of the insulation sleeve and / or on the outer circumference of the motor shaft, in particular on that area with which the motor shaft is received in the insulation sleeve in the assembled state . For example, one or more longitudinal grooves and / or longitudinal projections on the radial outer circumference of the motor shaft can be advantageous. It is advantageously provided that the insulation sleeve is plastically deformed when the insulation sleeve is inserted into the shaft opening and / or when the motor shaft is inserted into the insulation sleeve along the plug-in axis so that the motor shaft in the insulation sleeve and / or the insulation sleeve in the shaft opening of the laminated core is held positively, in particular non-rotatable with respect to the quick-release axle and / or non-shiftable with respect to the quick-release axle.

The plug-in receptacle expediently has a first internal cross-section which is assigned to a longitudinal end region of the laminated core facing the insertion opening. Furthermore, the plug-in receptacle has a second inner cross section which is assigned to a longitudinal end region of the laminated core facing away from the insertion opening. Sections of the insulating sleeve on which they have the first and second inner cross-sections come to rest on the laminated core in the state of the insulating sleeve mounted on the laminated core at the respective longitudinal end regions. When the motor shaft is fully inserted into the plug-in receptacle, a section of the motor shaft with a first outer cross-section rests on the plug-in receptacle in the area of the first inner cross-section and a section of the motor shaft with a second outer cross-section on the plug-in receptacle in the area of the second inner cross-section. The two following measures are advantageous individually or in combination for bracing the insulation sleeve, in particular radial bracing of the insulation sleeve, with respect to the shaft passage opening. The first internal cross-section of the plug-in receptacle is advantageously larger than the second internal cross-section. Bracing is also achieved if it is advantageously provided that the first and second outer cross-sections of the motor shaft are identical or even if the first outer cross-section of the motor shaft is larger than the second outer cross-section, but if the difference between the first outer cross-section and the second outer cross-section is smaller than the difference between the first internal cross-section and the second internal cross-section of the receptacle.

It is also advantageous if the first outer cross section of the motor shaft is smaller than the second outer cross section. It is possible that the plug-in receptacle has the same first and second internal cross-sections or even that the first internal cross-section is smaller than the second internal cross-section if the difference between these two internal cross-sections is smaller than the difference between the external cross-sections of the motor shaft. It is therefore advantageous if the first inner cross-section and the first outer cross-section and furthermore the second inner cross-section and the second outer cross-section are complementary to one another and / or match one another. The internal and external cross-sections can for example be round, in particular circular. However, it is also possible that the matching or complementary cross-sections or contours of the plug-in receptacle or outer contours of the motor shaft are not round, for example polygonal or have other contours, in order to prevent rotation between the plug-in receptacle or insulation sleeve and the motor shaft .

It is also advantageous if the second inner cross-section of the plug-in receptacle is enlarged or widened by the second outer cross-section of the motor shaft inserted into it. Of course, the first internal cross section can also be enlarged or widened by the first external cross section of the motor shaft.

It is possible that one or more steps are present between the different inner cross-sections or outer cross-sections. Furthermore, it is possible that the inner cross-sections or outer cross-sections are designed in the manner of annular collars or annular contact surfaces. However, it is preferred if the inner cross-section of the plug-in receptacle continuously decreases from the first inner cross-section to the second inner cross-section, in particular special conically or in the manner of a plug-in cone. Such a design also enables, for example, a simple demoulding of the insulation sleeve if it is manufactured as a cast part. It is also advantageous if the outer cross section of the motor shaft increases continuously from the first outer cross section to the second outer cross section. Here, too, a step or the like, other non-continuous contour would alternatively be possible.

It is preferred if the shaft passage opening has the same internal cross-section over its entire length with respect to the plug-in axis or axis of rotation of the rotor. Then, for example, the same or identical metal sheets can be used to form the laminated core. At this point it should also be mentioned that the Metal sheets can functionally differ from one another, for example in order to provide the abutment projections already mentioned. It is also possible, however, for measures to be taken in particular to facilitate the insertion of the insulation sleeve into the shaft passage opening. It is advantageous, for example, if the shaft passage opening of the laminated core has a larger internal cross-section at a longitudinal end area provided for inserting the insulation sleeve than at a longitudinal end area opposite this longitudinal end area.

It is advantageous if anti-rotation contours are provided, based on de Ren, the insulation sleeve and the laminated core are in engagement with one another so that they cannot rotate with respect to the rotation axis. The anti-rotation contours can, for example, include mutually complementary projections and receptacles, in particular longitudinal grooves and longitudinal projections or ribs. For example, a longitudinal groove or an anti-rotation mount is provided on the laminated core, while an anti-rotation projection, for example a longitudinal projection or a longitudinal rib, is provided on the insulation sleeve. The rotational projection protrudes, for example, radially with respect to the plug-in axis and / or the axis of rotation and / or the longitudinal axis of the insulating sleeve in front of its, for example, cylindrical or circular outer circumference. The anti-rotation mount, on the other hand, is designed, for example, as an anti-rotation mount or recess that extends radially into the inner circumference of the shaft passage opening. However, it is also possible, for example, in front of the inner circumference of the shaft opening, for at least one anti-rotation projection, for example a longitudinal rib or a longitudinal projection, to protrude radially inward for positive engagement in an anti-rotation seat or recess, for example a longitudinal groove, of the insulation sleeve. Thus, the at least one anti-rotation seat on the laminated core and the at least one anti-rotation projection on the insulation sleeve can be provided and / or, conversely, the at least one anti-rotation projection on the laminated core and the at least one anti-rotation seat on the insulation sleeve. The anti-rotation projection and / or the anti-rotation mount can extend over the entire longitudinal length of the shaft mount and / or the portion of the insulation sleeve that is inserted into the shaft mount in the assembled state. It is also possible, however, for the anti-rotation projection and / or the anti-rotation mount to extend only over part of the length of the shaft mount or this part of the insulating sleeve.

With respect to the plug-in axis, several pairs of anti-rotation projection and anti-rotation mounts on the Isolati onshülse and the shaft mount can be provided at angular intervals, for example on opposite sides or the like. It is preferred if a single pairing of anti-rotation projection and anti-rotation mount are provided on the insulation sleeve or the shaft mount or the laminated core.

The insulation sleeve can only extend within the laminated core. However, it is preferred if the insulation sleeve protrudes on one or both end sides of the laminated core in front of the laminated core and has an Isolationsab section there. The insulation section can provide an additional insulation distance of at least 5 mm, preferably at least 7 mm, even at least 8 mm between the laminated core and the motor shaft. The insulation distance corresponds, for example, to an air gap between the motor shaft on the one hand and the laminated core on the other.

The insulation section preferably comprises a pipe section or is formed by a pipe section that does not face radially outward with respect to the axis of rotation in front of a section of the insulation sleeve received in the shaft opening of the laminated core, for example also a pipe section, this section next to is arranged in particular un indirectly next to the insulation section. Thus, the isolation section can be tubular. Such an insulation section is suitable for being pushed through the shaft opening of the laminated core. Furthermore, it is also possible that the insulation section comprises a flange body, in particular an annular or partially annular flange body, which protrudes radially outward in front of a tube section of the insulation sleeve received in the laminated core with respect to the axis of rotation. The flange body can at the same time form a support stop or longitudinal stop with which the insulating sleeve strikes the end face of the laminated core.

The insulating sleeve is expediently inserted into the shaft passage opening in a state below an operating temperature of the drive motor. For example, a temperature of less than 40 ° C. is preferred. The operating temperature of the drive motor is, for example, between 90 ° C. and 120 ° C., in particular about a maximum of 100 ° C. The insulating sleeve is therefore inserted into the shaft opening in the cold state, so to speak. This prevents the insulation sleeve from starting to flow, so to speak, when the drive motor is in operation. The insulation sleeve is preferably made of plastic, in particular a glass fiber reinforced plastic. A particularly suitable plastic is polyamide. A polyamide made from PA6 and PA66 is preferred. A glass fiber reinforcement is for example 20% to 30% of the polyamide material, but can also be up to 50% of the polyamide material. The insulating sleeve preferably retains its solid structure up to a temperature of at least 120 ° C, preferably at least 130 ° C, at least 140 ° C or even at least 155 ° C, i.e. it only becomes soft when heated further.

A magnet arrangement arranged on the rotor comprises magnets, in particular permanent magnets. For example, magnetized magnet bodies or magnet bodies suitable for magnetization on the laminated core of the rotor are made of aluminum-nickel-cobalt, bismanol, i.e. an alloy of bismuth, manganese and iron, made of a ferrite, e.g. a hard-magnetic ferrite, e.g. based on barium, strontium, made of neodymium-iron-boron (NdFeB), advantageously with an addition of dysprosium Samarium cobalt (SmCo), advantageously with 20-25% iron content, for example SmCos, Srri2Coi7, Sm (Co, Cu, Fe, Zr) _z , or the like. Rare earth magnets or plastic magnets are also possible. AINiCo alloys are also suitable,

PtCo alloys, CuNiFe and CuNiCo alloys, FeCoCr alloys, martensitic steels or MnAIC alloys for the magnet bodies.

The drive motor is preferably a brushless motor or an electronically commutated motor. In particular, it is advantageous if the respective stator of the drive motor has permanent magnets or is excited by permanent magnets.

Laminated cores of the rotor and / or the stator are preferably made from historical electrical sheets or transformer sheets.

A stator of the drive motor expediently comprises a carrier body made of plastic, in particular made of polyamide. The carrier body is produced, for example, by casting and / or overmolding the laminated core of the stator. It is also possible that the carrier body comprises one or more plug-in bodies or plug-in carrier bodies which are attached to the laminated core. For example, such a can on one or both end faces of the laminated core

Be plugged in the carrier body. The carrier body covers the laminated core from preferably in the area of the rotor mount and / or in the area of one or both end faces of the laminated core. Supports, support projections, end windings and the like for receiving coil conductors of the excitation coil arrangement are preferably provided on the carrier body. Furthermore, the carrier body preferably has electrical connection contacts or connection devices for connecting a connection line with which the drive motor can be or is connected to a flow device.

The first and the second drive motor can be equipped with different excitation coil arrangements and / or interconnections of the excitation coil arrangements. For example, a drive motor can have an excitation coil arrangement in a delta connection. A drive motor can, however, also without further ado have an excitation coil arrangement in star connection. Furthermore, in the case of the delta connection and / or the star connection, several, for example two strands or coils, can be connected in parallel and / or in series.

An embodiment would therefore be conceivable, for example, in which the first drive motor has an excitation coil arrangement in a delta connection, and another or the second drive motor has an excitation coil arrangement in a star connection. But it is also possible that the first drive motor has a delta excitation coil arrangement in which the coils or strands are connected in parallel in series or in parallel, while another or the second drive motor has a delta excitation coil arrangement in which the coils or strands are not connected in parallel or in series.

In the following, exemplary embodiments of the invention are explained with reference to the drawing. Show it:

Figure 1 is a perspective oblique view of a system of two

electric drive motors and hand machine tools that have these drive motors,

FIG. 2 shows a side view of one drive motor of the system according to FIG

Figure 1, of which in

FIG. 3 shows a section along a section line A-A in FIG. 2, FIG. 4 shows a section through the other drive motor of the system according to FIG

Figure 1, approximately along the same section line A-A corresponding to Figure 2,

FIG. 5 shows an insulating sleeve of the drive motor according to FIG. 4 in a perspective illustration, FIG. 6 shows a perspective illustration of a rotor of the drive motor according to FIG. 4, 7 shows a sectional view through the rotor according to FIG. 6 in its lowering position, approximately along a section line BB in FIG. 6,

FIG. 8 shows the view roughly corresponding to FIG. 7, but with the motor shaft completely inserted into the laminated rotor core, FIG. 9 a detail D1 from FIG. 8,

FIG. 10 is a perspective oblique view of the stator according to FIG. 1, roughly corresponding to a section D2 in FIG.

Figure 1 1 shows a section along a section line C-C through the stator according to

FIG. 10 to illustrate a connection device, which is shown laterally in the open state in FIG

Figure 13 is shown laterally in the closed state,

FIG. 14 shows a perspective illustration of the connection device according to

Figure 12 and

FIG. 15 shows a perspective illustration of the connection device according to FIG

Figure 13,

Figure 16 is a perspective oblique view to illustrate a

Assembly and processing of the connection device according to FIGS. 10 to 14 in a perspective oblique view, roughly corresponding to FIG. 10 with welding tongs, FIG. 17 a section through the arrangement according to FIG. 16 roughly along a section line D-D,

FIG. 18 shows the illustration according to FIG. 17, but with movement towards one another

Welding gun arms, 19 shows a section D3 of the stator according to FIG. 1 with a slot cover which is shown in FIG

FIG. 20 is shown obliquely in perspective, FIG. 21 shows a detail D4 from FIG. 19 during assembly of the groove cover

17 in a stator slot,

FIG. 22 shows the detail D4, but with the slot cover moved further into the stator slot and

23 shows the detail D4 with the fully assembled groove cover, FIG. 23B shows alternative embodiments of a groove cover and a groove, roughly corresponding to the view according to FIG. 23,

FIG. 24 shows a schematic representation of an assembly device for producing the slot cover according to FIG. 19 and its assembly on the stator according to FIGS. 21 to 23,

FIG. 25 shows a perspective oblique view of a section of a rotor of the aforementioned motors, roughly corresponding to a section D5 in FIG. 6 and FIG

FIG. 26 shows a schematic representation of a balancing device for balancing the rotor according to the preceding figure, and FIG

FIG. 27 shows a schematic front view of the rotor according to the above

Figure with a magnetizing device.

FIG. 1 shows a system representation comprising a Fland machine tool 300, for example a sawing machine, in which a drive motor 20 drives a tool holder 301 for a work tool, for example directly or via a gear not visible in the drawing. At the tool holder 301 is a working tool 302, for example a cutting tool, sawmill or the like, can be arranged or arranged. The drive motor 20 is accommodated in a housing 303 of the machine tool 300 and can be switched on and off using a switch 304. A speed of the drive motor 20 can preferably also be set with the switch 304.

A connection cable 305 for connection to an energy supply network EV is used for the electrical power supply of the hand machine tool 300. The energy supply network EV provides a supply voltage P1, for example 110 V AC voltage, 230 V AC voltage or the like. The hand machine tool 300 can have a current supply device 306 connected between the switch 304 and the drive motor 20.

The drive motor 20 can also be provided for operating a suction device 400, in particular for driving a suction turbine of the suction device 400. The suction device 400 has the drive motor 20 and is e.g. Can be connected to the energy supply network EV using a connection cable 405.

The voltage P1 is in any case significantly greater, e.g. at least four times to five times greater than a voltage P2, which an energy store 205 a

Hand machine tool 200 provides. The voltage P2 is, for example, a DC voltage of 14 V, 18 V or the like.

The hand machine tool 200 is, for example, a screwdriver, drill or the like. In a housing 203 of

Hand machine tool 200 includes a drive motor 120 which is suitable for the lower voltage P2. The drive motor 120 is energized by an energization device 206, which is supplied with electrical energy by the energy store 205. The drive motor 120 drives a tool holder 201 for a working tool 202, for example a drilling tool or screwing tool, directly or via a gear 208. The energization device 206 can be switched on, switched off and / or configured to set a speed of the drive motor 120 by a switch 204. The drive motors 20, 120 have partially identical or similar components.

For example, in the drive motors 20, 120, optionally usable motor shafts 30 and 130 each have bearing sections 31, 32, between which a holding section 33 is provided. The bearing section 32 is located next to an output section 34 which is used to drive the tool holder 201 or 301. For example, a gear wheel can be arranged or can be arranged on the output section 34. Alternatively, as indicated for a motor shaft 130, a toothing 35 is present. The holding section 33 preferably has a form-fit contouring 36 which extends between planar sections 37, that is to say which do not have any form-fit contouring.

The form-fit contouring 36 comprises, for example, grooves and / or projections 36A extending parallel to a longitudinal axis L of the motor shaft 30. However, corrugation, honeycomb-like structure or the like can also be provided as form-fit contouring 36.

A form-fit contouring 136 of the motor shaft 130 includes, for example, form-fit projections 136A inclined at an angle to the longitudinal axis L. The locking projections 136A, however, have a slight inclination, e.g. between 5 and 15 degrees, so that the form-locking projections 136A run essentially parallel to the longitudinal axis L.

The form-fit contours 36, 136 form, for example, form-fit contours 36B, 136B.

The output section 34 can be provided for driving a fan wheel. For example, a fan wheel holder 38 is provided on the motor shaft 130, which is arranged, for example, between the toothing 35 and the bearing portion 32.

The motor shaft 30 or 130 can be connected non-rotatably to a laminated core 41 or 141 of a rotor 40, 140. The laminated cores 41, 141 are arranged in a row rdnung transversely to the longitudinal axis L side by side arranged sheets 43, for example electrical sheets or transformer sheets in a known manner.

The laminated cores 41, 141 have shaft openings 42, 142, which have un different diameters. The shaft passage opening 42 has a larger diameter than the shaft passage opening 142. The motor shaft 30 or 130 can be inserted into the shaft passage opening 42 using an insulating sleeve 60, while the motor shafts 30 or 130 can be inserted directly into the shaft passage opening 142, so no insulating sleeve o- the like of other bodies is necessary.

The insulating sleeve 60 forms an insulating body 60A, by means of which the laminated core 41 is electrically isolated from the motor shaft 30 or 130 carrying it.

Magnet assemblies 50 are arranged on the laminated cores 41 and 141. The laminated cores 41 or 141 have holding receptacles 45 for magnets 50 of the magnetic assemblies 50. For example, four holding receptacles 45 and associated magnets 51 are provided, so that the rotor 40, 140 forms a total of four magnetic poles. The magnets 51 are e.g. Permanent magnets.

The magnets 51 have a plate-like shape, for example. The magnet 51 are, for example, magnetic disks or plate bodies 56. The Halteauf recordings 45 are accordingly suitable for receiving plate-shaped, ie flat rectangular, cubic plate bodies or magnetic plates and have corresponding inner circumferential contours.

The holding receptacles 45 and the magnets 51 extend parallel to the longitudinal axis L of the motor shaft 30, 130 or parallel to the axis of rotation D of the motor 20, 120.

Furthermore, the rotor 40, in particular as a laminated core 41, 141, is penetrated by air ducts 46, which extend parallel to the longitudinal axis L of the motor shaft 30, 130. and are open at the end faces 44 of the rotor 40, 140, so that the laminated stacks 41, 141 can be flowed through by air.

Although the shaft passage opening 42, 142 has an essentially circular inner circumferential contour, it advantageously also has an anti-rotation contour 47, in particular an anti-rotation mount 47A. The anti-rotation contour 47 is, for example, a longitudinal groove 47B, which extends paral lel to the axis of rotation D or longitudinal axis L.

Both motor shafts 30, 130 can each be inserted into the laminated cores 41, 141. In the case of the laminated core 141, the shaft passage opening 142 of which is smaller

Has a diameter than the shaft passage opening 42 of the other laminated package 41, the respective motor shaft 30, 130 can be inserted directly into the shaft passage opening 142, e.g. be pressed in.

The narrow sides or front sides of the metal sheets 43, which limit the inner circumference of the shaft passage opening 42 or protrude into it, claw in front of the motor shaft 30, 130 so that it cannot be displaced in a direction of force parallel to the axis of rotation D or to its longitudinal axis L the laminated core 141 is added. An electrical conductivity of the laminated core 141 and the motor shaft 30, 130, which is preferably made of metal, is possible despite the direct contact between the laminated core 141 and the motor shaft 30, 130 because the rotor 140 can be used with the drive motor 120 and thus for the low re voltage P2 is provided.

In the case of the rotor 40, however, insulation measures are taken so that electrical safety is provided despite the electrical conductivity of the motor shaft 30, 130 and the associated laminated core 41.

The motor shaft 30, 130 is namely received in the laminated core 41 with the aid of an insulating sleeve 60. The insulating sleeve 60 forms, so to speak, a protective jacket or an outer casing of the motor shaft 30, 130 in that section which is received in the shaft passage opening 42.

The insulation sleeve 60 has between its longitudinal ends 61, 62 a Rohrab section 63, which is sandwiched between the laminated core 41 and the motor shaft 30, 130 and electrically insulates them from the laminated core 41.

The pipe section 63 has a plug-in receptacle 64 for inserting the motor shaft 30, 130, which extends from the longitudinal end 61 to the longitudinal end 62. In the area of the longitudinal end 61, the plug-in receptacle 64 has an insertion opening 64A through which the motor shaft 30 can be inserted into the plug-in receptacle 64. The motor shaft 30 emerges from the plug-in receptacle 64 at an outlet opening 64B.

In the area of the longitudinal end 61, i.e. a longitudinal end area 61 A, the plug-in receptacle 64 has a larger diameter W1 and thus a larger inner cross section WQ1 than in the area of the longitudinal end 62, i.e. a longitudinal end area 62A, where a smaller diameter W2 and thus a smaller inner cross section WQ2 is available. For example, the diameter of the motor shaft 30, 130 in the region of the longitudinal ends 61, 62 is approximately 10 mm. In contrast, the diameter W2 is about 0.2 mm to 0.3 mm smaller than the diameter W1 before the motor shaft 30, 130 is inserted into the receptacle 64. When the motor shaft 30, 130 is inserted from the longitudinal end 61 to the longitudinal end 62 into the insulating sleeve 60 along a plug-in axis S, as indicated in FIG. 7, it first penetrates slightly or with transverse play with respect to the plug-in axis S into the plug-in opening 64A at the longitudinal end 61 a, where the plug receptacle 64 has the diameter W1. The diameter W1 is advantageously somewhat larger than the diameter of the motor shaft 30, 130 at its free longitudinal end intended for insertion into the plug-in receptacle 64. The area of the insertion opening 64A forms one

Centering section in which the motor shaft 30, 130 is centered with respect to the insulating sleeve 60 or the axis of rotation D. For example, the motor shaft 30 has the same external cross-section or external diameter both in the area of the diameter W1 and in the area of the diameter W2. Alternatively or in addition, it is possible that, for example, the motor shaft 30 has a first outer cross section AQ1 and a second outer cross section AQ2, which are assigned to the longitudinal ends 61, 62 of the plug-in receptacle 64, the first outer cross section AQ1 being smaller than the second outer cross section AQ2. In this embodiment of the motor shaft 30, it is also possible for the diameters W1 and W2 and thus the inner cross-sections of the plug-in receptacle 64 in the region of the longitudinal ends 61 and 62 to be identical or approximately the same.

Between the longitudinal ends 61, 62, the plug-in receptacle 64 is preferably continuously narrower from the diameter W1 to the diameter W2. However, it would also be possible for at least one step to be present between the diameter W1 and the diameter W2. The plug-in receptacle 64 advantageously has a plug-in cone which becomes narrower from the longitudinal end 61 to the longitudinal end 62.

At the longitudinal end 61, lead-in bevels 65, for example a lead-in cone, are advantageously provided in order to facilitate the process of inserting the motor shaft 30, 130 into the plug-in receptacle 64.

When the motor shaft 30, 130 is inserted into the plug-in receptacle 64 along the plug-in axis S, it penetrates further and further in the direction of the longitudinal end 62, widening the pipe section 63, which becomes narrower towards the longitudinal end 62, so to speak.

Installation is as follows:

First, the insulating sleeve 60 is inserted into the shaft passage opening 42 of the laminated core 41.

Provision is advantageously made for the plug-in cross-section or inner cross-section of the shaft passage opening 42 to be the same or approximately the same over its entire length provided for inserting the insulating sleeve 60.

It is also possible, however, for the shaft passage opening 42 to have a large longitudinal end area 41 A on a longitudinal end region 41 A provided for inserting the insulating sleeve 60. Ren internal cross-section than at a longitudinal end area 41 B opposite this longitudinal end area.

Then the motor shaft 30, 130 is inserted into the plug-in receptacle 64. Thus, when the motor shaft 30, 130 is inserted into the plug-in receptacle 64 along the plug-in axis S, it presses the radial outer circumference of the pipe section 64 in the direction of the radial inner circumference of the shaft opening 42. The metal sheets 43 preferably penetrate with their facing the shaft opening 42 Narrow sides into the peripheral wall 66 like teeth.

The plug-in receptacle 64 has the narrower diameter W2 up to an area in front of the laminated core 41, so that the motor shaft 30, 130, when it reaches this area of the plug-in receptacle 64, the circumferential wall 66 of the pipe section

63 expands radially outward with respect to the plug-in axis S and thus, so to speak, expands the pipe or pipe section 63. As a result, a form-fitting part 75 is formed with a step 67 on the outer circumference of the peripheral wall 63, which engages directly or engages behind with the end face 44 of the laminated core 41. The step 63 thus holds the insulating sleeve 60 with a direction of force opposite to the plug-in direction in which the motor shaft 30, 130 is inserted into the plug-in receptacle

64 can be inserted on the laminated core 41.

At the other longitudinal end region, the longitudinal end 61, the insulating sleeve 63 has a flange body 68 which protrudes radially outward in front of the pipe section 63 with respect to the plug-in axis S or the longitudinal axis L.

The flange body 68 forms a longitudinal stop 68A with respect to the plug-in axis S and is supported, for example, on the end face 44 of the laminated core 41 in the region of the longitudinal end 61. The flange body 68 has, for example, reinforcement ribs 69 which extend from its radial outer circumference in the direction of the plug-in receptacle 64, that is to say radially inwardly towards the plug-in axis S. The United reinforcement ribs 69 are arranged, for example, on a face 71 of the flange body 68 facing away from the laminated core 41. A support stop 70 for the motor shaft 30, 130 is also provided at the insertion opening 64A, against which a support stop 39, for example a step, of the motor shaft 30, 130 can strike with a direction of force parallel to the plug axis S. The support stop 70 is formed, for example, by a step between the end face 71 of the insulating sleeve 60 and the plug-in receptacle.

In the area of the longitudinal end 62 or at the outlet opening 64B, the insulation sleeve 60 preferably has a smaller outer circumference or diameter than in the area of the longitudinal end 61. For example, insertion bevels 72 are provided at the longitudinal end 62, which facilitate the insertion of the insulation sleeve 60 into the shaft passage opening 42 of the laminated core 41 facilitate. The longitudinal end 62 is designed, for example, as a plug-in projection.

Preferably, the insulation sleeve 60 protrudes at the longitudinal end 62 with a pipe section 73 forming an insulation section 76 in front of the end face 44 of the sheet-metal package 41, so that there is electrical insulation between the motor shaft 30, 130 on the one hand and the metal sheets 43 on the other .

At the other longitudinal end 61, on the other hand, the flange body 68, which so to speak protrudes laterally in front of the shaft opening 42, provides electrical insulation and also forms an insulation section 76. This results in an electrical insulation gap both in the area of the flange body 68 and on the pipe section 73 from around 8 mm to 10 mm, for example, with a clearance and creepage distance that is suitable for electrical insulation with respect to the voltage P1.

An anti-rotation contour 74 for engaging in the anti-rotation contour 47 of the laminated core 41 is preferably arranged on the radial outer circumference of the insulation sleeve 60, in particular over the entire longitudinal extent of the pipe section 63. The anti-rotation contour 74 is configured, for example, as an anti-rotation projection 74A, in particular as a longitudinal projection or a longitudinal rib 74B, which extends parallel to the plug-in axis S or axis of rotation D, respectively. The insulation sleeve 60 is received in a press fit or press fit between the motor shaft 30, 130 and the laminated core 41. This creates a frictional connection.

The anti-rotation contours 47, 74 also provide a form fit, by means of which the insulation sleeve 60 is held in a form-fitting manner on the laminated core 41 with respect to and / or transversely to the axis of rotation D.

The form-fit contouring 36, 136 of the motor shafts 30, 130 engages tooth-like in the inner circumference of the pipe section 63, so that the motor shaft 30, 130 is also non-rotatable with respect to its axis of rotation D or longitudinal axis L and / or is non-shiftable with respect to the axis of rotation D or the longitudinal axis L in the insulation sleeve 60 is added. The form-fit contouring 36, 136 advantageously forms a counter-form-fit contouring on the inner circumference of the pipe section 36, that is, for example, deforms the inner circumference of the pipe section 63 plastic so that the form-fit contouring 36, 136 with this Ge

gene form-fit contouring is positively engaged. The plastic deformation or expression of the mating form-fit contouring results or forms, for example, when the motor shaft 30, 130 is inserted into the insulation sleeve 60.

The insulating sleeve 60 thus enables the motor shafts 30, 130, which can be inserted directly into the laminated core 141 without additional measures, can also be used with the laminated core 41 without further ado. There is no need to design different motor shafts. Geometrically, the motor shafts 30, 130 are identical on the holding sections 33, which are provided for connection to the laminated cores 41 or 141. For example, the length and diameter of the holding sections 33 are identical. However, it is possible for different upper surfaces and / or surface contours to be provided in the area of the holding sections 33 of the motor shafts 30 and 130 for the optimal hold of the laminated core 41 or 141. Preferably, abutment projections 43A protruding into the shaft passage opening 42 or 142 penetrate into the radial outer circumference of the pipe section 63 of the insulating sleeve 60 or the radial outer circumference of the holding section 33 of the motor shaft 30, 130. Form-fitting parts 75A, for example, form-fitting receptacles 75B, in which the abutment projections 43A engage, are schematically indicated in FIG. 5. The radial outer circumference of the pipe section 63 is, for example, by the motor shaft 30 radially outward with respect to the plug-in axis S or of the axis of rotation D, the abutment projections 43A penetrating into the pipe section 63 and preferably clawing into it.

The abutment projections 43A are provided, for example, on the end faces of the metal sheets 43 facing the shaft passage opening 42 or 142. Between tween the abutment projections 43A, in particular between groups of abutment projections 43A, there are preferably distances with respect to the axis of rotation D, for example angular distances and / or longitudinal distances. The abutment projections 43A hold the insulation sleeve 60 in the shaft opening 42 or the motor shaft 30, 130 in the shaft opening 142 parallel to the axis of rotation D and / or in the circumferential direction with respect to the axis of rotation D. Preferably, several abutment projections 43A are provided at angular intervals around the axis of rotation D. . The insulating sleeve 60 is displaced radially outward by the motor shaft 30 inserted into it, so that the abutment protrusions 43A penetrate the outer circumference or the jacket or the peripheral wall 66 of the insulating sleeve 60, in particular penetrate like a claw.

The rotors 40, 140 of the drive motors 20, 120 can be used together with a stator 80, which has an excitation coil arrangement 86. The excitation coil arrangement 86 can have differently designed excitation coils 87, for example excitation coils 87 with more or fewer turns, with different conductor cross-sections or the like, in order to do justice to the different voltages P1 and P2 and / or current strengths of currents that flow through the excitation coils 87 to become. The stator 80 has a laminated core 81 with a rotor receptacle 82 configured as a passage opening for the rotor 40, 140. In the rotor receptacle 82, the Ro tor 40, 140 is rotatably received, with a narrow air gap between the laminated core 81 and the laminated core 41, 141 in a known manner IN ANY.

The laminated core 81 has sheets 83, for example electrical sheets or Trafoble surface, the plate plane of which extends transversely to the axis of rotation D of the drive motor 20, 120. The respective motor shaft 30, 130 protrudes in front of the end faces 84, 85 of the laminated core 81, where it is rotatably mounted on bearings 24, 25 of a bearing arrangement 24A.

The bearings 24, 25 are held on bearing receptacles 23 by bearing caps 21, 22 which close the stator 80 at the end.

The bearings 24, 25 can be set, in particular pressed into the bearing receptacles 23 of the bearing caps 21, 22. However, it is also possible that the bearings 24, 25 are encapsulated or encapsulated with the material of the bearing caps 21, 22.

For example, the bearing caps 21, 22 are firmly connected to the laminated core 41 or a carrier body 90 carrying the laminated core 41, for example screwed, glued or preferably welded.

The bearing caps 21, 22 and the carrier body 90 are preferably made of plastic, in particular made of a thermoplastic. The same plastic, for example the same thermoplastic, is preferably used for the bearing caps 21, 22 and the carrier body 90.

For example, the carrier body 90 is produced in a casting process in which the laminated core 81 is cast.

The carrier body 90 has bearing cover receptacles 91 for the bearing covers 21, 22. In the bearing cover receptacles 91, for example, peripheral walls 26 of the bearing cover 21, 22 can be inserted, for example with their end faces. The bearing cover 21 is arranged closer to the output section 34 of the motor shaft 30, 130. The bearing cap 22 in the area further away from it. The bearing caps 21, 22 close the laminated core 81 opposite one another

Longitudinal end areas. The bearing cover 21 projects less far in front of the end face of the laminated core 41, 141 than the bearing cover 22. The bearing cover 21 has a receiving space 21 A for the flange body 68.

The bearing 24 is closer to the potentially current-carrying laminated cores 41, 81 than the bearing 25.

The bearing 24 and the bearing 25 are electrically conductively connected to the Lagerab section 31 and thus the motor shaft 30, 130, so that there is actually a risk that a voltage jumps from the excitation coil arrangement 86 to the motor shaft 30, 130.

Due to the electrically insulating flange body 68, however, there is a sufficient electrical insulation distance so that this risk no longer exists.

The bearing 25, on the other hand, has a larger longitudinal distance in relation to the axis of rotation D to the end face of the laminated cores 41, 81, so that here, too, there is no danger of an electrical flashover from, for example, the excitation coil arrangement 86 to the motor shaft 30, 130 in the area of the bearing 25 . In addition, the electrically insulating pipe section 73 of the insulating sleeve 60, which protrudes in front of the sheet metal packet 41 in the direction of the bearing cover 22, ensures sufficient electrical insulation.

The coil conductors 88 of the excitation coils 87 run in the laminated core 81 through grooves 89 which, for example, are arranged parallel to the axis of rotation D or at an angle thereto. The grooves 89 have insertion openings 89D which are open to an inner circumference 82A of the rotor receptacle 82. The grooves 89 extend between the end faces 84, 85. The coil conductors 88 can be introduced into the grooves 89 through the insertion openings 89D and, for example, wound around winding heads or winding hammers of the laminated core 81. Although the rotor receptacle 82 of the stator 80 facing sections of the laminated core 81, which are located between the grooves 89, covered by a Innenver cladding 92, for example encapsulated with plastic, the grooves 89 are initially open so that the coil conductor 88 is placed in them can be.

The excitation coils 87 are also wound around support projections 93 on the end face 84 of the stator 80, which form winding heads, so to speak.

On the opposite end face 85 support projections 94 are provided, which are also suitable for winding with coil conductors of excitation coils, but are not wrapped in some embodiments.

The end face 85 represents, so to speak, the connection side of the drive motor 20, 120. Electrical connection devices 100 are provided there, to which, for example, connection lines 15 for electrical connection to the flow device 206, 306 can be or are connected. The connection lines 15 have a connector for plugging into a

Current supply device 206, 306 on. The connection devices 100 can also be referred to as terminals.

The connection lines 15 can be plugged into the connection devices 100, for example, or can also be soldered directly to them. The connection devices 100 have connection contact areas 101 configured, for example, as contact projections, to which connection plugs that are connected to the connection lines can be plugged. Furthermore, holes 102 are provided in the connection contact areas 101 through which, for example, a connection conductor of the connection lines 15 can be passed and soldered to the connection device 100 or electrically connected in some other way. For example, such a connection conductor could easily be welded to the connection device 100.

The connection devices 100 can be arranged on the carrier body 90 with a plug-in assembly. The carrier body 90 has holders 95 for the connection devices 100. The holders 95 include plug-in receptacles 96 into which the connecting devices can be inserted. The plug-in receptacles 96 are between receptacles 97, which protrude in front of the end face 85 of the support body 90, vorgese hen. For example, the receiving projections 97 have mutually opposite grooves 98 into which the laterally protruding plug projections 104 in front of the connection devices 100 can be inserted, for example in the manner of a

Tongue and groove connection.

The plug-in projections 104 protrude laterally in front of a base body 103 of a respective connection device 100. The plug-in projections 103 protrude transversely to the longitudinal extension of the connection contact area 101 in front of the base body 103. The plug-in projections 104 and the connection contact area 101 form an overall approximately T-shaped configuration. For example, the base body 104 forms, so to speak, a base leg from which the plug-in projections 104 protrude laterally in the manner of side legs. However, the base planes of the plug-in projections 104 and the base body 103 are different. Between the base body 103 and the plug-in projections 104, the transition section 106 is provided with, for example, S-shaped or opposing curvatures or curved sections. The plug-in projections 104 therefore project in front of a rear side 115 of the base body 103.

At the free end regions protruding in front of the base body 103, the plug-in projections 104 have form-fitting contours 105, in particular teeth 105A, barbs or the like, with which a form-fitting hold in the plug-in receptacle 96 is possible. Preferably, the plug-in projections 104 can dig into the plug-in receptacle 96 of the carrier body 90, so to speak, on the basis of the form-fit contours 105. In particular, if the support body 90 melts in the area of the plug receptacles 96, in particular the grooves 98, when the connection device 100 is heated, which will be described below, a form-fitting connection between the plug-in projections 104 on the one hand, in particular their form-fitting contours 105, and on the other hand, the material of the carrier body 90 in the area of the plug receptacle 96, in particular in the area of the grooves 98, is made. The toothing 105A has, for example, an interlacing, that is to say that, for example, a tooth 105B protrudes transversely to the main plane of the plug-in projection 104 in front of it.

The connection devices 100 have conductor receptacles 107 for receiving the respective section of a coil conductor 88 to be connected. The conductor receptacles 107 are formed between on the one hand the front side 114 of the base body 103 and on the other hand a receiving arm 108 of the connecting device 100, which is connected to the base body 103 by means of a connecting section 109. It when the base body 103, the connec tion section 109 and the receiving arm 108 are in one piece is particularly advantageous. The side legs or plug-in projections 104 of the base body 103 are preferably integral with this. An inside of the connecting section 109 facing the conductor receptacle 107 forms a receptacle section or a receptacle hollow de 1 16A of the conductor receptacle 107.

The conductor receptacle 107 has a support surface 107A and a narrow side 107B angled thereto in the region of the receptacle trough 116A. Between the narrow side 107B and the large contact surface 107A there is arranged an inclined surface 107C, which is inclined towards the contact surface 107A and the narrow side 107B, for supporting the at least one coil conductor 88. The inclined surface 107C can be, for example, a chamfer, a curved or arcuate surface or the like. In any case, the inclined surface 107C prevents the coil conductor 88 from resting on a sharp edge.

The connection device 100 is advantageously designed as a stamped and bent part, which is first stamped out of a base material and then brought into the shape described above by appropriate shaping.

The assembly and / or fastening and / or electrical contacting of the coil conductor 88 in the conductor receptacle 107 is as follows:

First of all, the conductor receptacle 107 is open, namely in that the receptacle arm 108 still protrudes far from the base body 103, see, for example, FIGS Coil conductor 88 can reach the bottom 116, ie the inner circumference of the connecting section 109, of the conductor receptacle 107, see, for example, FIG. 12. However, this configuration is rather undesirable, so that additional support measures, for example a support 251 of an assembly device 250, the coil conductor 88 is held in a position away from the bottom 116 of the conductor receptacle 107.

However, the configuration is preferably made such that the carrier body 90 has a support contour 99 on which the coil conductor 88 is supported during assembly or when the connection device 100 is closed, see FIGS. 10 and 11. The coil conductor 88 therefore lies on the support contour 99 so that it does not touch the floor 116. The support contour 99 is provided, for example, on an outside of the receiving projections 97 facing away from the grooves 98. For example, the support contour 99 is designed as a step between the respective receiving projection 97 and the portion of the support body 90 from which the receiving projection 97 protrudes.

The raised position of the coil conductor 88 from the floor 116 is advantageous for the subsequent closing and welding operation. It is particularly advantageous when coil conductors with a small cross-section are used, e.g. a coil conductor 88B (Figure 11). This coil conductor 88B can even then stand at a distance from the bottom 116, which heats up significantly during the welding process described below, when the receiving arm 108 is moved towards the base body 103 so that its free end 113 rests on the front side 114 of the base body 103 .

The coil conductor 88B forms e.g. a component of an excitation coil 87B of an excitation coil arrangement 86B.

The receiving arm 108 has at its end region facing away from the connecting portion 109 th a closing leg 111 which protrudes angularly from a central arm portion 110 of the receiving arm 108. For example, a curve portion or connecting portion 112 is between the middle arm portion 110 and the closing leg 111 are provided. The closing leg 111 protrudes from the middle arm section 110 in the direction of the front side 114 of the base body 103, so that its free end 113 touches the front side 114 in the closed state of the conductor receptacle 107, while between the middle arm section 110 and the front side 114 of the base body 103 a distance is present which defines the conductor receptacle 107.

Welding tongs 252 of the assembly device 250 are used to close the connecting devices 100 and welding. The welding tongs 252 have tong arms 253, 255, on the free end regions of which are provided for contact with the connecting device 100, support surfaces 254, 256 are provided. The free end regions of the tong arms 253, 255, which are provided for engagement with the connection device 100, taper to a point, that is to say form points 257. In particular in the case of the tong arm 253, which acts in a supporting manner on the rear side 115 of the connection device 100 with its support surface 254, this pointed, slim design of the tong arm 253 is advantageous.

The tong arms 253, 254 are arranged in a V-shape, so that the tips 257 attack the connecting device 100 from opposite sides (see FIG. 16), close it and then weld it.

The longitudinal axes L1, L2 of the tong arms 253, 255 preferably run at an angle W, in particular approximately 20 ° to 40 °. As a result, in particular the tip 257 of the tong arm 253 can get into the space between the bearing cover 22 and the rear side 115 of the connection device 100 and support the base body 103 there with its support surface 254.

The tong arm 254 acts in the sense of closing the conductor receptacle 107 on the receiving arm 108. For example, the curved section 112 rests against the support surface 256 of the tong arm 255. The support surfaces 254, 256 are oriented parallel or essentially parallel to one another when the support surface 254 is moved towards the support surface 256, which is shown as a feed movement VS in the drawing. The tong arm 253 therefore remains stationary and supports the connection device 100 from the rear, while the pliers arm 255 displaces the receiving arm 108 in the direction of the base body 103. Then its free end 113 of its closing leg 111 comes into contact with the front side 114 of the base body 103 of the connection device 100. Thus the conductor receptacle 107 is then closed and a receiving eye 119A is formed.

It is also possible that a welding tongs or similar other milling device transforms the receiving arm 108 from an initially elongated, straight shape, in which the closing leg 111 is not yet formed, for example, to a receiving arm 108 with closing leg 111, for example using a schematic indicated deformation contour 259 on tong arm 255.

The tong arms 253, 255 are then energized by an energizing device 258 in that the tong arms 253, 255 have different potentials and thus generate a current flow through the connection device 100.

The welding current IS flows through the so-to-speak ring-shaped closed connection device 100, ie through those parts of the connection device 100 which close the conductor receptacle 107, namely the base body 103 in the area of the conductor receptacle 107 and the receptacle arm 108. The welding current IS flows via connection areas 118 and 119, namely on the one hand via the connecting section 109, but on the other hand also via a contact area 117 between the free end 113 of the closing leg 111 and the front side 114 of the base body 103. Both in the contact area 117 and in the area of the base 116, great heat occurs which, however, does not damage the coil conductors 88 or 88B, because they are at a distance from the floor 116, but also from the upper contact area 117. At the same time, the connection device 100 becomes so hot in the area of the conductor receptacle 107 that a lacquer or similar other insulation of the coil conductors 88 melts and these come into electrical contact with the surfaces of the connection device 100. The connection device 100 is therefore mechanically closed, so to speak, and then welded to those coil conductors 88 that are received in the conductor receptacle 107. On the one hand, the assembly is gentle on the coil conductors 88, but on the other hand it is also reliable and permanently resilient, because the coil conductors 88 can indeed be changed somewhat mechanically by the aforementioned pressing process and the welding process, but are not weakened or changed in their cross-sectional geometry in such a way that they break, for example, during the operation of the drive motor 20, 120.

When the excitation coils 87 are inserted into the slots 89, they are covered by slot covers 180 closed.

The groove covers 180 have a profile body 181. The slot covers 180 are preferably made of plastic and / or an electrically insulating material. The profile body 181 is designed, for example, as a plastic part or a plastic wall body.

The profile body 181 forms a wall body 182 which, so to speak, represents a closing wall for a respective groove 89.

The groove cover 180 or the profile body 181 has a longitudinal shape and extends along a longitudinal axis L8 which runs parallel to a longitudinal axis L9 of the groove 89 when the groove cover 180 is mounted in the groove 89.

Longitudinal narrow sides or longitudinal sides 195 of the groove cover 180 extend along the longitudinal axis L8. The longitudinal sides 195 have a transverse spacing Q transversely to the longitudinal axis L8.

Longitudinal end regions 183 of the slot cover 180 preferably protrude up to the carrier body 90 in front of the laminated core 81, so that electrical insulation is provided over the entire length of a slot 89. There, for example, bonding, welding or the like other fastening to one or both of the bearing caps 21 or 22 is advantageous. The groove cover 181 has a wall section 184 which completely covers the groove 88 transversely to the longitudinal axis L8. The wall section 184 is roughly U-shaped or arched in cross section, i.e. transverse to the longitudinal axis L8, and forms form-locking projections 186 on its transverse end regions, i.e. transverse to the longitudinal axis L8, which are intended to engage in the form-fit receptacles 89B of the grooves 89. At right angles to the longitudinal axis L8, the groove cover 180 has two form-locking receptacles 186 which form the most protruding sections of the groove cover 180 transversely to the longitudinal axis L8 and / or are opposite one another. The interlocking projections 186 and the interlocking receptacle 89B form interlocking contours 185, 89A, which hold the groove cover 180 in the groove 89 transversely to the longitudinal axis L8, which at the same time represents the longitudinal axis of the groove 89.

The wall section 184 forms a trough-like shape between the form-fitting contours 185, that is to say has a bottom 187. The bottom 187 is, for example, arched into the respective groove 89, that is to say extends into it. Of course, a reverse configuration would also be possible, in which the wall section 184 does not protrude radially outward with respect to the axis of rotation D, but radially inward. There, however, it would possibly be in the way of the rotor 40, 140.

Side legs 188 extend away from wall section 184. The side legs 188 are inclined towards one another, i.e. their free end regions remote from the wall section 184 are inclined towards one another. Thus, the side legs 188 and the wall section 184 in the transition area to the side legs 188 form the form-locking contour 185, which is V-shaped in a side view, that is to say a form-locking projection 186. The assembly of the slot cover 180 is as follows:

In itself it would be possible to insert the slot cover 180, for example from one of the end faces 84 or 85, into a respective slot 89 here, that is to say along a plug-in axis which runs parallel to the axis of rotation D. However, the interlocking contours 185 can be moved towards one another transversely to the longitudinal axis L8, so that a transverse distance Q between the form-fit contours 185 can be reduced so that the groove cover 180 can be shifted past a side edge 89C of the groove 89 into the groove 89, see FIGS. 21 to 23. The wall section 184 slides with its rounded outer side 189, that is, on its side opposite the bottom 187, which in this respect forms a displacement contour 189A, past the side edge 89C, the wall section 184 yielding in a flexurally flexible manner, thus forming a flexurally flexible section 194. The side legs 188 and the form-fit contours 185 are moved towards one another in the sense of narrowing the transverse distance Q and finally, at the end of this plug-in movement SB, the slot cover 180 engages in the groove 89, ie the form-fit contours 185 engage with the form-fit contours 89A .

The groove cover 180 is then positively received in the groove 89, namely in two mutually orthogonal directions transverse to the longitudinal axis L8.

A surface of the form-fit receptacle 89B facing away from the rotor receptacle 82 forms a grip-behind contour 89E. One of the rotor receptacle 82 facing

The surface of the form-fit receptacle 89B forms a support contour 89F.

The engagement contour 89E and / or the support contour 89F are preferably flat.

The engagement contour 89E and / or the support contour 89F preferably support the groove cover 180 over its entire longitudinal axis L8.

The side legs 188 have rear gripping surfaces 188A which are supported on the rear gripping contour 89E. Sections of the wall section 184 adjoining the side legs 188 have support surfaces 188B or form these support surfaces which are supported on the support contours 89F. Thus, the engaging contours 89A support the groove cover 180 in the direction of the interior of the rotor mount 82 or the axis of rotation D and the support contours 89F oppose this, that is, in the radially outward direction with respect to the axis of rotation D or a base of the respective groove 89. The advantage of this construction method also results from the fact that, for example, the support body 90 can protrude slightly at the longitudinal end regions of the groove 89 in a radial inward direction towards the rotor receptacle 82 when the groove covers 180 are mounted. Their longitudinal end regions 183 can then be brought into engagement behind in the direction of the rotor receptacle 82 of the protruding section of the carrier body 90.

Furthermore, the engaging behind surfaces 188A and the engaging behind contours 89E as well as the supporting surfaces 188B and the supporting contours 89F lie flat against one another, so that a sealing seat or sealing of the groove 89 is realized and / or the groove cover 180 tightly closes the groove 89.

The groove covers 180 advantageously have a sealing function for sealing the grooves 89, but no support function for the excitation coils 87 of the excitation coil arrangement 86. The inclination of the engagement contours 89E and the engagement surfaces 188A actually act in the sense of a release bevel that occurs when force is applied to the groove cover 180 in a sense out of the groove 89 or radially inward with respect to the axis of rotation D causes a deformation or narrowing of the groove cover 180 and thus facilitates or enables it to be released from the groove 89.

An alternative exemplary embodiment according to FIG. 23B, which is only shown schematically, provides, for example, a groove 489 configured as an alternative to groove 89, into which a groove cover 480 is introduced. The groove cover 480 has form-fit receptacles 486 on its narrow longitudinal sides, which engage with form-fit projections 489B of the groove 489. The form-fit projections 489B are opposite one another. The form-fit receptacles 486 and the form-fit projections 489B are complementary to one another, for example V-shaped.

Surfaces of the form-fit projections 489B facing away from the rotor receptacle 82 form engagement contours 489E. The surfaces of the form-fit projections 489B facing the rotor receptacle 82 form support contours 489F. The rear gripping contour 489E and / or the supporting contour 489F are preferably flat. The engagement contour 489E and / or the support contour 489F preferably support the groove cover 480 over its entire longitudinal axis L8. The longitudinal sides of the groove cover 480 or the form-fit receptacles 486 have rear gripping surfaces 488A, which are supported on the rear gripping contours 489E. The form-fit receptacles 486 also have support surfaces 488B or form these support surfaces which are supported on the support contours 489F.

The mechanical structure of the stator 80 is preferably completely or partially identical for both voltage levels P1 and P2. In particular, the Rotorauf acquisition 82 for the rotor 40, 140 is identical, that is, for example, has the same diameter. The design of the grooves 89, for example de ren form-fit contours 89A and / or their width and / or depth, are also identical. It is also advantageous if the slot cover 180 on the stator 80 can be used or used regardless of whether the excitation coil arrangement 86 is designed and / or arranged for the voltage P1 or the voltage P2.

This means that a largely identical part principle can be implemented.

It is possible to provide the groove covers 180 as individual profile pieces, i. that they already have the elongated shape shown in FIG. 20 and have lengths corresponding to the length of the groove 89.

An advantageous embodiment, however, provides that the slot covers 180 are obtained from a roll material 190. The roll material 190 is available as a roll 191, for example. The roll 191 is rotatably received, for example, on a roll carrier 273, in particular a corresponding holding frame. An unwinding device 274 unwinds the roll material 190 from the reel 191. A section 192 of the roll material 190 unwound from the roll 191 runs through, for example, a roll arrangement 275 with one or more rolls, in particular deflection rolls or guide rolls.

Downstream of the roller assembly 275, a smoothing device 276 is provided in which the section 192 is smoothed so that its originally on the Wrap 191 rounded shape is converted into an elongated shape. The smoothing device 276 comprises, for example, at least one pressing member 277, in particular opposing pressing members 277, and / or a heating device 278 with heating bodies 279 in order to bring the roll material 190 of the section 192 into an elongated shape, as shown in Figure 20. Thus, the roll material 190 is brought by the Glättungseinrich device 276 in a straight, elongated shape.

The smoothing device 276 is followed by a cutting device 280, with which a length is cut from the section 192 that corresponds to a desired slot cover 180, for example the length of the laminated core 81 or the carrier body 90. The cutting device 280 has, for example, cutting elements 281, in particular Knives, blades, saw organs or the like.

At this point it should be mentioned that instead of the laminated core 181 or stator 80, other, i.e. shorter or longer stators can be provided with slot covers using the assembly device 270. If necessary, suitable slot covers 180 are produced, the length of which is adapted to the length of the stator to be fitted. The cutting member 280, for example a cutting knife, thus cuts a slot cover 180 from the section 192, which is then gripped by a holding member 271 and inserted into the stator 80.

The holding member 271, for example a gripper, comprises holding arms 272 which grip the profile body 181 or the groove cover 180 at their longitudinal end regions 183 and can insert them into the groove 89 by means of the insertion movement SB. Without further ado, it would be possible for the holding member 271 to have a suction device or a similar holding element which sucks the groove cover 180 in the area of the base 187 and inserts it into the groove 89 with a force component that generates the plugging movement SB. It can therefore be seen that by plugging, joining, pressing and the like essential components of the motor 20, 120 are to be produced, namely for example the connection devices 100, the covering of the grooves 89 using the groove covers 180. The magnetization of the magnets 51 described below also follows this assembly concept.

The magnets 51 are not initially magnetized when they are mounted on the rotor 40, 140 or laminated core 41, 141. A magnetizable material 51A of a respective magnet body 56 is therefore initially non-magnetic when the magnet body 52, which is not yet magnetic, is inserted or pressed into one of the holding receptacles 45 during a plugging or pressing process. The magnetizable material 51 A is, for example, neodymium-iron-boron (NdFeB), advantageously with an addition of dysprosium, or samarium-cobalt (SmCo). Support projections 48 are provided on the holding receptacles 45, for example, which support narrow sides 54 of a respective magnet body 52. When the magnets 50 are mounted on the rotor 40, 140, the narrow sides 54 run parallel to the axis of rotation D. The magnet bodies 52 or magnets 51 are preferably clamped between the support projections 48. Between the narrow sides 54, compared to the narrow sides 54, larger flat sides 53 extend. Normal directions of the flat sides 53 are preferably radial to the axis of rotation D.

The laminated cores 41, 141 have holding projections 49 for holding the Magnetkör by 52. The holding projections 49 protrude, for example, toward the flat sides 53 and their free end regions bear against the flat sides 53. It is preferred if the holding projections 49 claw with the magnet body 52, so to speak, and / or form abutment projections. The sheets 43 of the laminated cores 41, 141 include sheets 43 which aufwei sen in a vorbe certain angular position with respect to the axis of rotation D recesses 59A. The recesses 59A preferably extend radially with respect to the axis of rotation D away from one of the flat sides of the respective holding receptacle 45, for example radially inward toward the axis of rotation D. It is preferred if the recesses 59 A are arranged parallel to the axis of rotation D in an axis line one behind the other, that is to say are aligned with one another. Some of the metal sheets 43 have holding projections 59 protruding into the recesses. The holding projections 59 also protrude into the plug-in cross-section of a respective holding receptacle 45, so that when a magnet body 52 is inserted into a holding receptacle 45, they engage with the magnet body 52 and through the magnet body 52 an insertion direction SR, in which the magnet body 52 is inserted into the holding receptacle 45, are bent. A retaining projection 59 can be displaced into the recess 59A of one or more adjacent metal sheets 43 into whoever. An end face of a respective retaining projection 59, which has the width of a narrow side of a metal sheet 43, is then supported at an inclined angle on the flat side 53 of the magnet body 52 and prevents the magnet body 52 from being pulled out of the retaining receptacle 45 against the insertion direction SR.

The magnet bodies 52 or magnets 51 are preferably received in the holding receptacle 45 with a press fit. Of course, gluing, welding or other similar assembly would be entirely possible. The magnetizable material 51 A is thus inserted into the respective laminated core 41, 141 in the not yet magnetized state.

The rotor 40, 140 is then balanced using a balancing device 285. The motor shaft 30, 130 and possibly the insulating sleeve 60 are already mounted. The rotor 40, 140 can therefore be rotated about its axis of rotation D with the aid of a motor 286 using the motor shaft 30, 130. A measuring device 287 determines, for example, imbalances in the rotor 40, 140.

Any imbalances that still exist are then eliminated by, for example, using a material-reducing device 288, for example a grinding feinrichtung, a milling device or the like, at least one balancing section 55 can be produced. For example, where balancing is necessary, material of the laminated core 41, 141 is removed, with chips, metal dust or the like being produced. But this is not a problem, since the magnetic bodies 52 are not yet magnetized when the material of the laminated core 41, 141 is being worked. The chips, dusts or the like that arise from the removal of the metal sheets 43 do not adhere magnetically to the laminated core 41, 141, so that they can be easily removed. When the drive motor 20, 120 is subsequently operated, no metal chips or dust are then present that could damage the bearings 24 or 25, for example.

It is advantageous if the balancing parts 55 are attached to those areas of the laminated core 41, 141 where the laminated core 41, 141 has the greatest possible material thickness or thickness in the radial direction with respect to the axis of rotation D, i.e. in particular radially outside with respect to the magnets 51 If, for example, an unbalance U occurs in an area that is unfavorable for producing a balancing section, vectorial balancing is preferred, in which the unbalance U is broken down into force vectors Ux and Uy and this is accordingly carried out by the material-reducing device 288, for example, balancing sections 55x and 55y be produced radially on the outside of the laminated core 41, 141. The balancing parts 55x and 55y are located, for example, radially outside on the laminated core 41, 141 of holding receptacles 55, which are arranged at an angular distance from the unbalance U directly next to the same.

In the case of the rotor 40, 140 there are no balancing bodies or on the end faces 44

Balancing weights necessary. As a result, for example, the inflow openings and outflow openings of the air ducts 46 are not covered by balancing weights or balancing bodies. Furthermore, air can also flow laterally past the magnets 51, namely through air ducts 46A which are provided on the holding receptacles 45 or are provided by the holding receptacles 45. The inflow openings and outflow openings of the air channels 46A are not covered by balancing bodies or balancing weights A cleaning device 289, for example a blower device, a brush device and / or a vacuum cleaner or the like, can easily remove the metallic particles resulting from the material removal by the material-reducing device 288 from the rotor 40, 140, in particular the respective laminated core 41, 141 as long as the magnetic bodies 52 are not magnetic. For example, the cleaning device 289 generates an air jet LU which removes chips and the like from the area of the balancing section 55.

When the rotor 40, 140 is balanced, it is magnetized by means of a magnetizing device 290, i. E. In particular, the magnetic bodies 52 are activated magnetically. The magnetization device 290 has magnetization heads 291 A, 291 B, 291 C, 291 D, for example.

For example, the magnetization device 290 comprises a positioning device 292 which positions, in particular rotates, the motor shaft 30, 130 in such a way that the magnets 51 lie opposite the magnetization heads 291 at exactly the right angle.

The rotor 40, 140 is advantageously positioned on the basis of a mechanical coding 57 in relation to the magnetizing heads 291 A, 291 B, 291 C, 291 D such that one magnetizing head 291 A, 291 B, 291 C, 291 D is arranged between adjacent magnets 51 is. For example, the anti-rotation contour 74 serves as the coding 57, which strikes, for example, a stop 293, in particular a rotary stop, of the magnetization device 290, so that the rotor 40, 140 is arranged at the correct angle of rotation with respect to the magnetization heads 291. The stop 293 is shown in connection with the balancing device 285. However, other components of the rotor 40 can readily serve as coding 57, for example the air ducts 46, into which the corresponding stops of the magnetizing device 290 can engage and / or which are optically detectable. Optical detection of the angular position of the rotor 40 is also advantageous, 140 possible, for example by means of a camera or similar other optical sensor of the magnetization device 290.

The magnetizing heads 291 A, 291 B, 291 C, 291 D generate magnetic fields MFA, MFB, MFC, MFD, which penetrate the magnetic bodies 52 or magnets 51 arranged next to one another at an angular distance with respect to the axis of rotation D, so that they are permanently magnetized and magnetic poles form, which are indicated as north poles N and south poles S. The magnetic fields MFA, MFB, MFC, MFD are indicated in dashed field lines with arrows corresponding to their magnetic flow direction in the drawing. When the magnets 51 of the rotors 40, 140 are magnetized, the rotors 40, 140 are mounted on the stator 80.

It goes without saying that several magnetic bodies 52 or magnets 51 can also be arranged in the fold receptacles 45 for the magnets 51, for example a series arrangement of two or more magnetic bodies 52 or magnets 51 parallel to the axis of rotation D. In this case, too, a magnetization of the respective

Magnetic bodies 52 are easily possible if they have already been received in the fold receptacles 45.

When magnetizing by the magnetizing device 290, it is also advantageous that the metal sheets 43 of the laminated cores 41, 141 are magnetically conductive, so that they can optimally pass the magnetic fields 292 of the magnetizing device 290 through the magnetic body 52.

Claims

Expectations

1. System, in particular in the form of a modular motor kit, comprising a first drive motor (120) and a second drive motor (20), with a respective drive motor (20, 120) for a suction device (400) or a machine tool in the form of a hand - Machine tool (200, 300) or a semi-stationary machine tool is provided or forms part of the suction device (400) or the machine tool, the drive motors (20, 120) each having a stator (80) with an excitation coil arrangement (86) and a Rotor (40, 140) with a motor shaft (30, 130) which is rotatably mounted on the stator or with respect to the stator (80) by means of a bearing arrangement (24A) about an axis of rotation (D) and a shaft passage opening (42, 142 ) a laminated core (41, 141) passes through which is held on a holding section (33) of the respective motor shaft (30, 130), characterized in that the holding sections (33) of the motor shafts (30, 130) of the drive motors (20, 120 ) have identical outer circumferential geometries in the area of the laminated cores (41, 141), the laminated core (141) of the first drive motor (120) being supported directly on the outer circumference of the holding section (33) of the motor shaft (30, 130) carrying the laminated core (141) and the laminated core (41) of the second drive motor (20) is supported via an electrically insulating insulating body (60A) on the holding section (33) of the motor shaft (30, 130) carrying the laminated core (41).

2. System according to claim 1, characterized in that the first drive motor (120) for a first operating voltage (P2), in particular an operating voltage of less than 60 V, the second drive motor (20) for a second operating voltage (P1), in particular an operating voltage of more than 60 V is configured.

3. System according to claim 1 or 2, characterized in that the first

Drive motor (120) for operation on the basis of an electrical energy storage chers, in particular a battery pack, and the second drive motor (20) are designed for a network operation using an electrical AC voltage network.

4. System according to one of the preceding claims, characterized in that the stators (80), in particular the laminated cores (81) of the stators (80), the first drive motor (120) and the second drive motor (20) are geometrically identical on the outside and / or have identical outer circumferential geometries.

5. System according to any one of the preceding claims, characterized in that the stators (80) of the first drive motor (120) and the second drive motor (20) have identical laminated cores (81) which are attached to identical carrier bodies (90) of the Stators (80) are arranged.

6. System according to one of the preceding claims, characterized in that the first drive motor (120) and the second drive motor (20) have different excitation coil arrangements (86, 86B), the excitation coils (87, 87B) and different numbers of turns / or different conductor cross sections, in particular that the first drive motor (120) can be operated with a first operating voltage and the second drive motor (20) with a second operating voltage different from the first operating voltage.

7. System according to any one of the preceding claims, characterized in that the stators (80) of the first drive motor (120) and the second drive motor (20) at their with respect to the axis of rotation (D) opposite longitudinal end regions set identical arrangements of support projections for Receiving the excitation coils (87) of the different excitation coil arrangements (86).

8. System according to one of the preceding claims, characterized in that the stators (80) of the first drive motor (120) and the second drive motor (20), in particular the support body (90) of the stators (80), at least one plug-in receptacle (96 ) for plugging in a for connecting a connection line (15) provided connection device (100) which, when received in the plug-in receptacle (96), is electrically connected to at least one coil conductor (88) of an excitation coil (87) of the excitation coil arrangement (86) by means of the connection line (15).

9. System according to one of the preceding claims, characterized in that the motor shafts (30, 130) of the drive motors (20, 120) at opposite longitudinal end regions of the respective stator (80) on a first bearing (24) and a second bearing (25) of the bearing arrangement (24A) are rotatably mounted and the stators (80) of the two drive motors (20, 120) in the area of the first bearing (24) and the second bearing (25) and / or at least one on the respective stator (80) arranged and the first or second bearing (24, 25) bearing bearing cap are geometrically identical.

10. System according to one of the preceding claims, characterized in that the insulation body (60A) has a wall thickness of at least 2 mm in the region of the shaft passage opening (42, 142).

11. System according to one of the preceding claims, characterized in that the insulation body (60A) has at least one insulation section (76) protruding in front of an end face of the laminated core (41, 141).

12. System according to claim 11, characterized in that the insulation section (76) provides an insulation distance of at least 5 mm, preferably at least 7 mm, in particular at least 8 mm, between the laminated core (41, 141) and the motor shaft (30, 130) is formed.

13. System according to claim 11 or 12, characterized in that the insulation section (76) comprises a pipe section (63) or is formed by a pipe section (63) which is not radially outward with respect to the axis of rotation (D) in front of a protrudes in the shaft passage opening (42, 142) of the laminated core (41, 141) received section of the insulation sleeve (60) which is arranged with respect to the plug axis next to the insulation section (76).

14. System according to one of claims 11 to 13, characterized in that the insulation section (76) comprises a particularly annular flange body (68) which is radially outward in front of a tube section (63) of the laminated core (41, 141) Insulation body (60A) protrudes with respect to the axis of rotation (D).

15. System according to one of the preceding claims, characterized in that the insulation body (60A) is formed by an insulation sleeve (60) or has an insulation sleeve (60) which is inserted into the shaft passage opening (42,

142) and is arranged between the motor shaft (30, 130) and the laminated core (41, 141) and has a plug-in receptacle with an insertion opening (64A) through which the motor shaft (30, 130) is inserted into the plug-in receptacle along a plug-in axis .

16. System according to one of the preceding claims, characterized in that the insulating body (60A), in particular the insulating sleeve (60), extends over a full length of the laminated core (41, 141) with respect to the plug-in axis and / or the laminated core (41 , 141) is electrically isolated from the motor shaft (30, 130) exclusively by means of the Isolati onshülse (60).

17. System according to claim 15 or 16, characterized in that the motor shaft (30, 130) in front of the insertion opening (64A) of the insulating sleeve (60) and / or in front of an outlet opening (64B) of the plug-in receptacle (64) protrudes to one to the insertion opening (64A) opposite longitudinal end region of the insulation sleeve (60) is provided.

18. System according to one of the preceding claims 15 to 17, characterized in that the insulating sleeve (60) has at least a longitudinal stop for striking the laminated core (41, 141) with respect to the plug axis and / or a pipe section (63) the insulating sleeve (60) has protruding flange body (68) for support on the laminated core (41, 141) with respect to the plug-in axle.

19. System according to one of the preceding claims 15 to 18, characterized in that the insulating sleeve (60) between the laminated core (41, 141) and the motor shaft (30, 130) in a force direction radial to the axis of rotation (D) and / or a direction of force parallel to the axis of rotation (D) and / or that the insulation sleeve (60) is braced radially outward with respect to the axis of rotation (D) with the laminated core (41, 141) by the motor shaft (30, 130).

20. System according to one of the preceding claims 15 to 19, characterized in that the insulating sleeve (60) in a state below an operating temperature of the drive motor and / or with a temperature below 40 ° C in the shaft opening (42, 142) is plugged in.

21. System according to one of the preceding claims 15 to 20, characterized in that at least one form-locking part is formed on the insulating sleeve (60), on which the insulating sleeve (60) is inserted through the motor shaft (30, 30, 130) is displaced radially outward with respect to the axis of rotation (D) into positive engagement with the laminated core (41, 141)

22. System according to one of the preceding claims, characterized in that at least one abutment projection protrudes from the laminated core (41, 141) into the shaft passage opening (42, 142), which protrudes into the insulation body (60A), in particular the insulation sleeve (60), penetrates, and / or the insulation body (60A), in particular the insulation sleeve (60), made of in particular glass fiber reinforced plastic, in particular polyamide, preferably Pa6 / 66 Gf30, be and / or the insulation sleeve (60) has a solid structure up to a Maintains a temperature of at least 120 °.

23. A method for producing a first drive motor (120) and a second drive motor (20), wherein a respective drive motor (20, 120) for a suction device (400) or a machine tool in the form of a

Hand machine tool (200, 300) or a semi-stationary machine tool is provided or forms part of the suction device (400) or the machine tool, the drive motors (20, 120) each having a tor (80) with an excitation coil arrangement (86) and a rotor (40, 140) with a motor shaft (30, 130) which are attached to the stator or with respect to the stator (80) by means of a bearing arrangement (24A) about an axis of rotation (D ) is rotatably mounted and passes through a shaft passage opening (42, 142) of a laminated core (41, 141) which is held on a holding section (33) of the respective motor shaft (30, 130), characterized by the use of motor shafts (30 , 130), the holding sections (33) of which have identical outer circumferential geometries in the region of the laminated cores (41, 141), and assembly of the laminated core (141) of the first drive motor (120) on the first motor shaft (130) and the laminated core (41 ) of the second drive motor (20) on the second motor shaft (30) in such a way that the laminated core (141) of the first drive motor (120) is supported directly on the outer circumference of the holding section (33) of the motor shaft (30, 130) carrying the laminated core (141) is and the laminated core (41) of the second drive motor (20) via an electrically insulating insulating body (60A) on the holding portion (33) of the motor shaft (30, 130) carrying the laminated core (41).