DE102023104911A1 - Electric machine - Google Patents

Abstract

Electric machine (10), comprising: a stator unit (14) with
a ferromagnetic stator body (18), a plastic holding body (24) which surrounds the stator body (18), at least one stator winding (22) which is arranged on the plastic holding body (24),
a rotor unit (16) with
a rotor shaft (40) which is rotatably mounted on the plastic holding body (24) via a shaft radial bearing (25), and
a rotor body (42) which is fastened to the rotor shaft (40) and is arranged within the stator body (18), wherein the plastic holding body (24) has two axially adjacent plastic holding elements (241, 242), wherein the shaft radial bearing (25) is detachably fastened to one of the plastic holding elements (241, 242) via a locking connection.

Description

The present invention relates to an electrical machine with a stator unit which comprises a ferromagnetic stator body, a plastic holding body surrounding the stator body and at least one stator winding arranged on the plastic holding body, and a rotor unit which comprises a rotor shaft rotatably mounted on the plastic holding body via a shaft radial bearing and a rotor body fastened to the rotor shaft and arranged within the stator body.

Such electrical machines are generally known from the prior art. For example, the stator body can be overmolded by the plastic holding body. The radial shaft bearing is arranged on a separate bearing plate, with the radial shaft bearing being glued or caulked to the bearing plate. The disadvantage of such designs is that the manufacture of the plastic holding body and the inclusion of the shaft radial bearing is complex and costly. When producing the stator unit, the plastic holding body must be inserted into the injection mold so that it can be overmolded. This significantly increases the complexity of the injection mold. In addition, a separate bearing plate must be manufactured and mounted, which increases the assembly effort.

The present invention is based on the object of creating a relatively inexpensive and easily assembled electrical machine.

This object is achieved by an electrical machine having the features of main claim 1.

The electrical machine according to the invention comprises a fixed stator unit and a rotatable rotor unit.

The stator unit comprises a ferromagnetic stator body and a multi-part plastic holding body which surrounds the stator body. Typically, the stator body defines a plurality of stator poles distributed along a circumference of the rotor unit. The stator body can be designed as a solid body. Preferably, however, the stator body consists of a large number of sheet metal parts. A stator body constructed in this way is also referred to as a laminated stator body or a sheet metal stator body and has particularly low eddy currents when the electrical machine is in operation. The stator body is generally made of a ferromagnetic metal. The stator body comprises at least one, typically several winding support sections on which an electromagnetic stator winding is arranged.

The plastic holding body is preferably produced by an injection molding process and serves, among other things, for the electrical insulation between the stator body and the stator windings, which is why at least a main section of the plastic holding body surrounding the stator body preferably consists of a plastic material with good electrical insulation properties, i.e. with a high specific electrical resistance, typically at least 10 ¹⁰ Ωcm, and a high dielectric strength.

The rotor unit comprises a rotor shaft, which is supported in the plastic holding body via a shaft radial bearing, and a rotor body, which is attached to the rotor shaft and is arranged within the stator body. The shaft radial bearing can be designed for exclusively radial support, or can be designed for radial and axial support of the rotor shaft. Typically, the rotor shaft is supported in a housing part of the electrical machine via a further shaft radial bearing, which is arranged on a side of the rotor body opposite the shaft radial bearing arranged on the plastic holding body.

The rotor body may be designed as a solid, permanent magnetic body, may be configured to carry at least one permanent magnet, or may be configured to carry at least one electromagnetic rotor winding. In the last two cases, the rotor body is generally made of a ferromagnetic metal and may either be designed as a solid body or consist of several interconnected individual parts, typically sheet metal parts.

According to the invention, the plastic holding body has two axially adjacent plastic holding elements, wherein the shaft radial bearing is detachably attached to one of the plastic holding elements via a locking connection. By dividing the plastic holding body into two plastic holding elements, the manufacture of the stator unit can be simplified, wherein the plastic holding elements can be manufactured using relatively simple injection molds and can then be attached to the stator body in a simple assembly step, namely by pushing the plastic holding elements onto the stator body. In addition, the manufacture of the stator unit is simplified by mounting the shaft radial bearing on the plastic holding body via a locking connection. In this case, the shaft radial bearing simply be inserted into an opening provided on the plastic holding element, whereby the inserted shaft radial bearing on the one hand abuts axially against an inwardly projecting radial projection and on the other hand is held axially by a locking element, preferably in the form of a locking lug. The shaft radial bearing is thus secured in both axial directions.

In this way, the electrical machine according to the invention can be assembled relatively easily and manufactured relatively inexpensively.

The shaft radial bearing is preferably a rolling bearing, preferably a ball bearing. The rolling bearing has an inner ring, an outer ring and a plurality of rolling elements arranged between the inner ring and the outer ring. For example, the inner ring is attached to the rotor shaft of the rotor unit with an inner circumferential surface. The outer ring is axially locked to the plastic holding element with an outer circumferential surface and is supported radially on a bearing surface with an outer circumferential surface.

The plastic holding body preferably has at least two axially spaced-apart separation planes, with both plastic holding elements each having at least one first, short axial section and at least one second, long axial section, with the first axial section of the first plastic holding element and the second axial section of the second plastic holding element defining a first separation plane and the first axial section of the second plastic holding element and the second axial section of the first plastic holding element defining a second separation plane. This ensures that when the stator unit is subjected to torsion, there is no transverse plane on which the two plastic holding elements only slide in the circumferential direction. At the first separation plane, the two plastic holding elements would slide against each other in the circumferential direction, but the two axial sections that define the second separation plane support the area of the first separation plane in the direction of rotation. Likewise, the two plastic elements support each other on the second separation plane through the axial sections that define the first separation plane in the direction of rotation.

Preferably, the stator body has a plurality of radial projections distributed over the circumference and the plastic holding body has a radial opening for each radial projection, such that the plastic holding elements are connected to the stator body in a form-fitting manner in the circumferential direction by the engagement of the radial projections in the radial openings. This allows the plastic holding body to be easily fastened to the stator body in a form-fitting manner in the circumferential direction.

In a preferred embodiment, the first axial section is arranged in the circumferential direction on a first side of a radial projection and the second axial section is arranged on a second side of the radial projection. In this way, the plastic holding body is divided in both parting planes at each radial projection of the stator body, so that there is increased rigidity of the stator unit at each radial projection. Preferably, the same axial section of a plastic holding element is arranged in the circumferential direction on the two mutually facing sides of the mutually adjacent radial projections.

Preferably, one plastic holding element has a section in the circumferential direction between two axial sections, which has a recess into which a projection of a section of the other plastic holding element arranged in the circumferential direction between two axial projections engages. This creates an additional positive connection between the two plastic holding elements, whereby the torsional rigidity, i.e. the rigidity in the circumferential direction, of the stator unit is increased even further.

Preferably, the plastic holding elements are each made in one piece. This allows the plastic holding elements to be manufactured easily and inexpensively. Preferably, the plastic holding elements are manufactured using an injection molding process.

In a preferred embodiment, the plastic holding elements are axially fastened to one another by the stator winding wound onto the plastic holding body. The coil winding is wound around the sections of the plastic holding elements in the area of the radial projections, whereby the plastic holding elements are axially fixed to one another. This allows the plastic holding elements to be axially connected to one another easily and inexpensively, with no additional, cost-intensive joining elements being required.

Preferably, the plastic holding elements are each pot-shaped, with the plastic elements each having a front side section and a covering section surrounding the base body. At least one of the plastic holding elements has an opening on the front side section through which the rotor unit can be pushed when the stator unit is finally assembled. Alternatively, the rotor unit could first be inserted into the through-opening of the stator unit and then at least one of the two plastic material holding elements. In this case, an opening for pushing the rotor unit through on one of the plastic holding elements would not be necessary.

• 1 eine Explosionsdarstellung einer erfindungsgemäßen elektrischen Maschine,
• 2 eine perspektivische Darstellung einer endmontierten Statoreinheit einer elektrischen Maschine aus 1, und
• 3 eine Schnittdarstellung der elektrischen Maschine aus 1.

An embodiment of the present invention is described below with reference to the accompanying figures.

• 1 an exploded view of an electrical machine according to the invention,
• 2 a perspective view of a fully assembled stator unit of an electrical machine from 1 , and
• 3 a sectional view of the electrical machine from 1 .

The 1 and 3 show an electrical machine 10 with a also in the 2 shown stator unit 14 and a rotatable rotor unit 16.

The stator unit 14 comprises a stator body 18, which consists of a plurality of ferromagnetic sheet metal parts 181, which are stacked in the axial direction to form a laminated core 182. The stator body 18 comprises six radial projections 20, which are distributed over the circumference and extend axially from a first end face to the second end face of the laminated core 182. Each radial projection 20 forms a winding support section 183, on which a stator winding 22 is arranged.

The stator unit 14 further comprises a plastic holding body 24, which is composed of a first plastic holding element 241 and a second plastic holding element 242. The plastic holding elements 241, 242 are each pot-shaped and have an end face section 26 and a covering section 28. Both plastic holding elements 241, 242 have six radially projecting sections 29 distributed over the circumference on the covering section 28, each of which includes an open radial opening 30. In the final assembled state, radial projections 20 of the stator body 18 are arranged within the radial openings 30 of the plastic holding elements 241, 242.

When assembling the stator unit 14, the pot-shaped first plastic holding element 241 is pushed over the first end face of the stator body 18 with the covering section 28 onto the laminated core. The pot-shaped second plastic holding element 242 is also pushed over the second end face of the stator body 18 with the covering section 28 onto the laminated core 182. In the final assembled state, the two plastic holding elements 241, 242 are adjacent or in contact with one another with the axial end facing away from the end face section 26 and are axially connected to one another by the wound stator winding 22.

The plastic holding body 24 has two axially spaced-apart separation planes E1, E2, on which the two plastic holding elements 241, 242 axially adjoin one another or bear against one another. For this purpose, the two plastic holding elements 241, 242 each have six first, short axial sections 321, 341 and six second, long axial sections 322, 342, wherein the first axial sections 321, 341 all have the same length and the second axial sections 322, 342 also all have the same length. The first axial sections 321 of the first plastic holding element 241 and the second axial sections 342 of the second plastic holding element 242 define the first separation plane E1. The first axial sections 341 of the second plastic holding element 242 and the second axial sections 322 of the first plastic holding element 241 define a second separation plane E2. The total length of the two axial sections 321, 342 or 322, 341 of the two plastic holding elements 241, 242 that are axially adjacent to one another, i.e. arranged in alignment with one another, always remains the same.

The axial sections 321, 322, 341, 342 are arranged in the circumferential direction on the radial projections 20 of the stator body 18 such that the first axial section 321, 341 is arranged on a first side of a radial projection 20 and the second axial section 322, 342 is arranged on a second side of the radial projection 20, wherein the same axial section 321, 322, 341, 342 is arranged on the sides of the adjacent radial projections 20 facing each other in the circumferential direction.

In addition, both plastic holding elements 241, 242 have a plurality of sections 36 in the circumferential direction between the two axial sections 321, 322, 341, 342, which each have a recess 361 or a projection 362, wherein each projection 362 of a plastic holding element 241, 242 engages in a recess 361 of the other plastic holding element 241, 242.

The plastic holding elements 241, 242 each consist of a single plastic material which has relatively good electrical insulation properties.

The rotor unit 16 comprises a rotor shaft 40 and a rotor body 42 fastened to the rotor shaft 40. The rotor shaft 40 is secured on a first axial side of the rotor body 42 via the shaft radial bearing 25, which is designed as a rolling bearing, in particular as a ball bearing, to the plastic holding body 24, in particular to the first plastic holding element 241, rotatably mounted. The shaft radial bearing 25 is arranged in an opening 260. The shaft radial bearing 25 is fastened to the rotor shaft 40 on the one hand with an inner peripheral surface of an inner ring. On the other hand, the shaft radial bearing 25 is firmly connected to the first plastic holding element 241 with an outer peripheral surface of an outer ring. The shaft radial bearing 25 is supported radially with the outer peripheral surface on a bearing receiving surface 261 provided by the opening 260. In the axial direction, the shaft radial bearing 25 is held on the one hand by several radial projections 262 provided on the end face section 26 and extending radially inwards and on the other hand by several locking elements 263 distributed over the circumference. The shaft radial bearing 25 rests with a first end face on the radial projections 262 and with a second end face on the locking elements 263. As a result, the shaft radial bearing is held axially on the first plastic holding element 241 in a simple manner.

The rotor shaft 40 is rotatably mounted on a second axial side of the rotor body 42 via a further bearing element not shown in the figures on a housing that is also not shown. Alternatively, the rotor shaft 40 could also be rotatably mounted on the plastic holding body 24, in particular on the second plastic holding element 242.

In this way, the electrical machine 10 according to the invention can be assembled relatively easily and manufactured relatively inexpensively.

Claims (11)

Electrical machine (10), comprising: - a stator unit (14) with • a ferromagnetic stator body (18), • a plastic holding body (24) which surrounds the stator body (18), • at least one stator winding (22) which is arranged on the plastic holding body (24), - a rotor unit (16) with • a rotor shaft (40) which is rotatably mounted on the plastic holding body (24) via a shaft radial bearing (25), and • a rotor body (42) which is fastened to the rotor shaft (40) and is arranged within the stator body (18), characterized in that the plastic holding body (24) has two axially adjacent plastic holding elements (241, 242), wherein the shaft radial bearing (25) is detachably fastened to one of the plastic holding elements (241, 242) via a latching connection. Electrical machine (10) according to Claim 1 , wherein the shaft radial bearing (25) is a rolling bearing. Electrical machine (10) according to Claim 1 , wherein the plastic holding element (241, 242) receiving the shaft radial bearing (25) has an opening (260) in which the shaft radial bearing (25) is arranged, wherein the shaft radial bearing (25) abuts axially with a first end face against an inwardly projecting radial projection (262) of the plastic holding element (241, 242) and is held axially with a second end face by a locking element (263). Electrical machine (10) according to Claim 1 or 2 , wherein the plastic holding body (24) has at least two axially spaced-apart parting planes (E1, E2), wherein both plastic holding elements (241, 242) each have at least a first, short axial section (321, 341) and at least a second, long axial section (322, 342), wherein the first axial section (321) of the first plastic holding element (241) and the second axial section (342) of the second plastic holding element (242) define a first parting plane (E1) and the first axial section (341) of the second plastic holding element (242) and the second axial section (322) of the first plastic holding element (241) define a second parting plane (E2). Electrical machine (10) according to Claim 1 or 2 , wherein the stator body (18) has a plurality of radial projections (20) distributed over the circumference and the plastic holding body (24) has a radial opening (30) for each radial projection (20), such that the plastic holding elements (241, 242) are positively connected to the stator body (18) in the circumferential direction by the engagement of the radial projections (20) in the radial openings (30). Electrical machine (10) according to Claim 2 and 3 , wherein the first axial portion (321, 341) is arranged in the circumferential direction on a first side of a radial projection (20) and the second axial portion (322, 342) is arranged on a second side of the radial projection (20). Electrical machine (10) according to Claim 4 , wherein the same axial section of a plastic holding element (241, 242) is arranged in the circumferential direction on the two mutually facing sides of the mutually adjacent radial projections (20). Electrical machine (10) according to Claim 5 , wherein the one plastic holding element (241, 242) has a section (36) in the circumferential direction between two axial sections (321, 341, 322, 342) which has a recess (361) into which a projection (362) of a circumferentially between two axial sections (321, 341, 322, 342) arranged portion (36) of the other plastic holding element (241, 242). Electrical machine (10) according to one of the preceding claims, wherein the plastic holding elements (241, 242) are each designed in one piece. Electric machine (10) according to one of the preceding claims, wherein the plastic holding elements (241, 242) are axially fastened to one another by the stator winding (22) wound onto the plastic holding body (24). Electric machine (10) according to one of the preceding claims, wherein the plastic holding elements (241, 242) are each pot-shaped, wherein the plastic holding elements (241, 242) each have an end face section (26) and an enveloping section (28) surrounding the stator body (18), wherein the shaft radial bearing is arranged on the end face section.

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