DE19845914C2 - Drive device - Google Patents

Description

The invention relates to an electromotive Drive device according to the preamble of claim 1.

Such an electromotive is from US 5,672,923 Known drive device having a stator, wherein several grooves are formed in the longitudinal direction, the web-shaped poles forming opposite pairs, around which energizable windings are arranged. Moreover the drive device has a rotor on the stator rolls, and an element for rotatable mounting of the rotor on.

This drive device has the advantage that a Electric motor and a transmission combined into one component are. This is with less installation space and a lower one Weight connected. The efficiency of the drive device is improved compared to a conventional electric motor, because the surface area for the magnetic flux increases and the air gap is minimized.

There are gaps in the slots of the stator. In this The rotor has no contact with the teeth of the area Stator. As a result, the concentricity of the rotor is not particularly good.

The object of the present invention is a Generic electromotive drive device so to further develop that the drive device at a compact design has a good concentricity. Is solved this task by claim 1. This is in the grooves the pole arranged a non-magnetizable material so that the stator as a whole, with the at least one rotor interacting diameter has a toothing.  

This is improved by the fact that several rotors are provided in an annulus by the stator and an element is formed, are arranged and that the Element has a toothing that with the toothed Rotors combs.

The fact that the toothing of the element, the stator and of the rotors run parallel to the stator axis and that Element protrudes from the drive device that a Torque can be tapped, can be easily realize electromotive planetary gear.

The toothing of the element, the stator and the Rotors helical to the stator axis, so corresponds this is an electromotive spindle drive, whereby for the linear movement of either the rotors or the element let use.

The teeth of the stator can be on the inside diameter or outer diameter are formed, whereby a Inner runner or an outer runner is feasible.

A particularly simple training results from the fact that a rotor is provided that the element as cranked Shaft is formed in a central longitudinal bore of the rotor is rotatably arranged that the shaft on from Protruding ends of the rotor have two parallel webs, which are arranged perpendicular to the shaft and to the central axis of the stator, and that shaft sections on the webs are formed, which in the longitudinal direction from the Drive device protrude and on the drive device are rotatably mounted.

Further advantages and advantageous further developments result itself from the subclaims and the description.

An embodiment of the invention is in the drawing shown and in the following description explained. Show it

Fig. 1 is a simplified front view of a drive device,

Fig. 2 is a detailed section of FIG. 1 with a first toothing,

Fig. 3 is a side view from the left of FIG. 1 with a second tooth and a first possibility, the storage,

Fig. 4 is a side view from the left of FIG. 1 with the gearing according to FIG. 3 and a second possibility of storage,

Fig. 5 is a simplified front view of a modified drive apparatus,

Fig. 6 is a simplified front view of another modified drive device and

Fig. 7 is a right side view of FIG. 6.

A drive device 10 is shown in FIG. 1. The drive device 10 has a stator 12 . The stator 12 is advantageously constructed as a stator laminated core. In the longitudinal direction of the drive device 10 , which corresponds to the stator axis 14 , six dovetail-shaped grooves 18 are formed on the inner diameter 16 at regular intervals, which form three diametrically opposed pairs of grooves 18 ', 18 '', 18 '''. The six grooves 18 form six bar-shaped poles 20 , which in turn form three diametrically opposite pole pairs 20 ', 20 '', 20 '''. An energizable winding 22 is arranged around each pole 20 of the pole pairs 20 ', 20 '', 20 '''. The stator 12 of the drive device 10 thus has the structure of the stator of a so-called reluctance motor. The windings 22 of the pole pairs 20 ', 20 '', 20 ''' can therefore be energized in succession in a known manner so that a rotating magnetic field can be generated.

A non-magnetizable material 24 is advantageously arranged in the grooves 18 in such a way that the stator 12 has a toothing 26 over the entire inner diameter 16 , also at the points interrupted by the grooves 20 . The material 24 can be, for example, a plastic or a resin with which the stator 12 is poured out after the windings 22 have been installed . The toothing 26 can be produced, for example, when the stator 12 is poured out using a correspondingly shaped tool which is guided into the stator 12 and has the shape of the toothing 26 . It is also possible to produce the toothing 26 after the pouring by machining.

In the longitudinal direction of the drive device 10 or centrally to the stator 12 and aligned with the stator axis 14 , the drive device 10 has an element 28 rotatably mounted on the drive device 10 , the outer diameter 30 of which has a toothing 32 . The element 28 has the function of an output element. The element 28 protrudes from the drive device 10 and has the shape of an output shaft outside the drive device 10 , as a result of which a torque can be tapped off from the element 28 . The storage takes place in a known manner on housing parts of the drive device 10 , not shown, for example a front and rear flange. The element 28 and the inner diameter 16 of the stator 12 form an annular space 34 . In the annular space 34 , four planet gears designed as rotors 36 are arranged, a different number also being possible. The four rotors 36 form two pairs of rotors 36 ', 36 '', which are diametrically opposed. The toothing 32 of the element 28 meshes with an external toothing 37 of the rotors 36 and thus also serves for the rotatable mounting of the rotors 36 . This also shows that it is advantageous to provide the non-magnetizable material 24 in the grooves 18 , since the stator 12 thus has a toothing 26 on the entire inner diameter 16 interacting with the rotors 36 , as a result of which the concentricity of the drive device 10 is improved. The rotors 36 can be connected to their end faces 38 each with a ring 40 - indicated by dashed lines.

As can be seen from FIG. 2, the toothing 26 of the stator 12 , the toothing 32 of the element 28 and the outer toothing 37 of the rotors 32 run parallel to the longitudinal direction of the drive device 10 or to the stator axis 14 .

If the windings 22 of the pole pairs 20 ', 20 '', 20 ''' are energized, a magnetic field is built up which exerts a force on parts which consist of a material which reacts to a magnetic field. By appropriately energizing the windings 22 , as is customary, for example, in a reluctance motor, a magnetic rotating field is generated, as a result of which the rotor pairs 36 ′, 36 ″ rotate.

If a planet wheel designed as a rotor 36 moves, its outer toothing 37 rolls counterclockwise along the toothing 26 formed on the inner diameter 16 of the stator 12 and towards a pole 20 . Due to the rotary movement of a rotor 36 , which is exerted by the magnetic attraction force of a pole 20 , the element 28 inevitably rotates, as in the case of a planetary gear. If a rotor 36 rolls along the toothing 26 of the stator 12 in a clockwise direction, a rotor 36 rotates counterclockwise about its own longitudinal axis. As a result, the element 28 is rotated clockwise. The rotational movement of the element 28 and the transmissible torque can be tapped in a known manner at an end of the element 28 which protrudes from the drive device 10 and is designed as a shaft end.

The drive device 10 from FIGS. 1 and 2 represents the combination of a planetary gear train in the form of a planetary gear and an electric motor, in particular a reluctance motor. In this way, it is thus possible to use only one component instead of an electric motor and a flanged gear , which saves space, weight and costs. The interlocking toothings 37 , 26 of the stator 12 and the rotors 36 increase the surface area between them, which increases the efficiency and thus the performance. The required transmission ratio can be achieved in a simple manner, as in the case of a planetary gear train, by the choice of the diameter of the stator 12 , the element 28 and the rotors 36 .

In FIG. 3, a driving device 10 is shown a, wherein the toothing, the teeth 32 a of the member 28 a and the toothing or run 26 a of the stator 12 a 37 a of the rotors 36 a helically to the longitudinal direction of the drive device 10 to the stator 14 . In this case, the element 28 a is fixed axially, for example — depending on the load case — by one or two ball bearings 42 , one of which is symbolically represented in FIG. 3. In this case, the element 28 a serves solely to support the rotors 36 a. The rotors 36 a are axially movable. They are rotatably mounted on rods 44 which protrude beyond the drive device 10 a. At the ends of the rods 44 lying outside the drive device 10 a, a plate 46 is attached. Such a plate 46 can also be attached to both ends of the rods 44 when they protrude from the drive device 10 a. The rods 44 are axially displaceable. When the rotors 36 a rotate about their own axis, which corresponds to a rod 44 , the rods 44 are axially displaced. A tensile or compressive force can be removed via the plate 46 . In this way, the drive device 10 a acts as an actuator that can be used like a spindle drive. For the required stroke, the lengths of the stator 12 a, the element 28 a and the rotors 36 must be coordinated. The usable stroke corresponds approximately to the length of the housing of the drive device 10 a minus the length of the rotors 36 a.

In Fig. 4, a drive device 10 b is shown, which is similar to the drive device 10 a. It differs in that the element 28 b is axially movable and that the rotors 36 b are axially fixed. The rotors are advantageously fixed axially via ball bearings 48 , although another bearing can also be suitable. As a result, the rotors 36 b can rotate about their own axis and can also run along the toothing 26 b of the stator 12 b.

The element 28 b protrudes from the drive device 10 b. The usable stroke corresponds approximately to the length of the element 28 b minus the length of the housing of the drive device 10 b. In this case, the element 28 b serves to support the rotors 36 b and to transmit a tensile or compressive force to the outside. For this transmission, it is advantageous to design one or both ends of the element 28 b similar to the shaft of a spindle drive known per se.

The drive device 10 c shown in FIG. 5 corresponds to an external rotor. The stator 12 c has a star shape, the six poles 20 c projecting outwards and forming three diametrically opposite pole pairs 20 c ', 20 c'', 20 c'''. The grooves 18 c between the poles 20 c are also provided with a non-magnetic material 24 c. The toothing 26 c of the stator 12 c is formed on its outer diameter 50 . Four rotors 36 are symmetrically arranged on the outer diameter 50 and form two diametrically opposed rotor pairs 36 ′, 36 ″. The rotors 36 are connected to each other at the end faces 38 via a ring 40 which serves as an element for mounting the rotors 36 and on which a torque can also be taken off.

6 and 7, 10 from FIGS. A drive device d forth, the stator 12 of the drive device 10 is used. Only one rotor 52 is provided, which has an external toothing 53 which is intended for engagement in the toothing 26 of the stator 12 . An element that serves to support the rotor 52 and to transmit a torque is designed as a cranked shaft 54 . The shaft 54 is rotatably arranged in a central longitudinal bore 56 of the rotor 52 . At the ends of the shaft 54 which protrude from the rotor 52 , the shaft 54 has two parallel webs 58 which are arranged perpendicular to the shaft 54 and extend to the stator axis 14 . Shaft sections 60 are formed on the webs 58 , which project in the longitudinal direction from the drive device 12 c. They are rotatably supported via bearings 62 of the drive device 12 d. The webs 58 can be screwed to the shaft 54 and the shaft sections 60, for example. This drive device 10 d represents a particularly simple construction.

Claims (8)

1. Electromotive drive device ( 10 , 10 a, 10 b, 10 c, 10 d) with a stator ( 12 , 12 a, 12 b, 12 c), in which a plurality of grooves ( 18 , 18 c) are formed in the longitudinal direction, the web-shaped poles ( 20 ) lying opposite one another form around which current-carrying windings ( 22 ) are arranged, with at least one rotor ( 36 , 36 a, 36 b) rolling on the stator ( 12 , 12 a, 12 b, 12 c) ), and with at least one element ( 28 , 28 a, 28 b, 40 , 54 ) at least for the rotatable mounting of the at least one rotor ( 36 , 36 a, 36 b), the rotor ( 36 , 36 a, 36 b) and the stator ( 12 , 12 a, 12 b, 12 c) interlocking toothings ( 26 , 26 a, 26 b, 26 c, 37 , 37 a, 52 ), characterized in that in the grooves ( 18 , 18 c) a non-magnetizable material ( 24 ) is arranged so that the stator ( 12 , 12 a, 12 b, 12 c) has continuous teeth ( 26 , 26 a, 26 b, 26 c) on its entire circumference. 2. Electromotive drive device ( 10 , 10 a, 10 b) according to claim 1, characterized in that a plurality of rotors ( 36 , 36 a, 36 b) are provided in an annular space ( 34 ) by the stator ( 12 , 12 a, 12 b), the toothing ( 26 , 26 a, 26 b) is formed on the inner circumference and the at least one element ( 28 , 28 a, 28 b) is formed, and that the element ( 28 , 28 a , 28 b) has a toothing ( 32 , 32 a) which meshes with the toothed rotors ( 36 , 36 a, 36 b). 3. Electromotive drive device ( 10 , 10 c) according to claim 1 or 2, characterized in that the teeth ( 26 , 37 , 53 ) run parallel to the stator axis ( 14 ) and that a torque can be tapped on the element ( 28 ). 4. Electromotive drive device ( 10 a, 10 b) according to claim 1 or 2, characterized in that the toothings ( 26 a, 26 b, 32 a) extend helically to the stator axis ( 14 ). 5. Electromotive drive device ( 10 a) according to claim 4, characterized in that the element ( 28 a) is fixed axially, and that the rotors ( 36 a) are axially movable. 6. Electromotive drive device ( 10 b) according to claim 4, characterized in that the rotors ( 36 b) are axially fixed, and that the element ( 28 b) is axially movable. 7. Electromotive drive device ( 10 c) according to claim 3 or 4, characterized in that the toothing ( 26 c) of the stator ( 12 c) is formed on its outer circumference ( 50 ) and that on the outer circumference arranged rotors ( 36 ) via a Ring-shaped element ( 40 ) are interconnected. 8. Electromotive drive device ( 10 d) according to claim 1, characterized in that only one rotor ( 52 ) is provided that the element is designed as a double cranked shaft ( 54 ) which is mounted centrally to the stator ( 12 ) and on the latter cranked shaft section of the rotor ( 52 ) is mounted.