The disclosure relates to an air-cooled electric motor, for example, a belt starter generator having a belt tensioner, an inverter housing, which is mounted on the electric motor or integrated into a motor housing or end plate of the electric motor, for a power, drive and control electronics system (inverter), and having a fan system which belongs to the motor.
An apparatus for tensioning a V-ribbed belt, a so-called belt tensioner, which can be mounted in a space-saving manner directly on the housing of the output side and/or on the fixed bearing side, is required for electrically operated vehicles and for partially electrically operated vehicles with a hybrid motor or when a belt starter generator is used. The technological background in this respect is known, for example, from DE 10 2011 080 886 A1, DE 10 2013 109 294 A1 and EP 1929611 B1. However, the belt tensioner can constitute a barrier to drawing in cooling air since it can close a possible coolant supply via the housing or slots in an end plate.
The disclosure provides an air-cooled electric motor that provides effective cooling of the assembly as a whole and is performed in a space-saving manner.
The air-cooled electric motor according to the disclosure includes a belt tensioner which is fitted on a fixed bearing side of the electric motor, an inverter housing which is arranged on a floating bearing side of the electric motor, and a fan system having a floating bearing-side first fan wheel or impeller and a fixed bearing-side second fan wheel.
The first fan wheel is designed to draw a cooling air volume flow radially inward from the area surrounding the electric motor via cooling ribs of a floating bearing-side end plate which is arranged axially adjacent to the inverter housing and to blow a first proportion of the drawn-in air volume flow radially outward out of the electric motor via a floating bearing-side stator end winding. The second fan wheel is designed to draw a second proportion of the radially inwardly drawn air volume flow axially into and through a rotor, for example, by means of air channels of a rotor laminated core of the rotor, and to blow it radially outward out of the electric motor via a fixed bearing-side stator end winding.
The “fixed bearing side” of the electric motor or “fixed bearing-side” relates, in this context, to that side on which a first axial end section of the electric motor is arranged, where the first end section, for example a first axial end section of a motor housing or a first end plate, accommodates an axial fixed bearing.
On the contrary, the “floating bearing side” of the electric motor or “floating bearing-side” relates to that side on which a second axial end section of the electric motor is arranged, where the second end section, for example a second axial end section of a motor housing or a second end plate, accommodates an axial floating bearing.
The air-cooled electric motor according to the disclosure therefore has a parallel circuit including two fan wheels, where the first fan wheel allows cooling air to be exclusively radially drawn in. As a result, the fact that the belt tensioner may possibly constitute a barrier to axially drawing in air via the fixed bearing side does not present an obstacle. Due to the possibility of radially drawing in air on the floating bearing side or inverter side, slots, apertures or the like for axially drawing in air in the housing or end plate can be omitted on the fixed bearing side. As a result, the mechanical stability of the housing or end plate can be increased. In other words, it is not necessary to weaken the cross section of the housing or end plate around the housing bearing seat on the fixed bearing side, this also being accompanied by higher bearing rigidity for the fixed bearing.
Since the floating bearing-side end plate is arranged axially adjacent to the inverter housing, for example, an inverter which is accommodated in the inverter housing, the floating bearing-side end winding, the rotor and the fixed bearing-side end winding can be cooled by an open, parallel cooling circuit.
In this case, an “open” cooling circuit is intended to be understood to mean that an air inlet of the cooling circuit for drawing in the cooling air volume flow from the surrounding area and an air outlet of the cooling circuit for blowing the heated air volume flow out to the surrounding area are not connected to one another. In this case, a “parallel” cooling circuit is intended to be understood to mean that the drawn-in cooling air volume flow is divided into two volume flow elements which are formed by the first and the second proportion of the air volume flow.
In other words, the open, parallel cooling circuit allows the stator end winding to be cooled on the floating bearing side in a first of the parallel circuits after cooling of the inverter or of the inverter housing during suction operation. The rotor and then the stator end winding of the fixed bearing side are cooled in a second of the parallel circuits after cooling of the inverter or of the inverter housing during suction operation.
The first fan wheel and the second fan wheel may be integrally formed on short-circuiting rings of the rotor. In this context, “integrally formed” is intended to be understood to mean that the fan wheels are each integrated into a short-circuiting ring of the rotor, that is to say the respective short-circuiting ring and the respective fan wheel are connected to one another in one piece. This allows a reduction in weight and lower expenditure on manufacture.
In some implementations, the first fan wheel and the second fan wheel are structurally identical. During parallel operation of the two structurally identical fan wheels, the needed air volume flow can be doubled. This means that double the air throughput along the cooling ribs of the end plate and along the inner side of the inverter housing may be achieved with the same air throughput for cooling for each end winding.
Furthermore, in some examples, an air guide sleeve is arranged on a rotor shaft between the cooling ribs of the floating bearing-side end plate and the first fan wheel. The guide sleeve may be designed without blades or with blades. The air guide sleeve allows particularly targeted, effective and efficient guidance of the air from the cooling ribs in the direction of the channels of the rotor and in the direction of blades of the wheels.
In some implementations, it is furthermore provided that an air guide plate which has an L-shaped cross section is arranged between the first fan wheel and the first end plate, the air guide plate guiding the first proportion of the drawn-in air volume flow particularly efficiently over the floating bearing-side stator end winding. In addition, the air guide plate serves as a stationary housing half or as a covering disk of the fan wheel and prevents a short-circuiting current through the heat sink in the interior of the electric motor.
The details of one or more implementations of the disclosure are set forth in the accompanying drawings and the description below. Other aspects, features, and advantages will be apparent from the description and drawings, and from the claims.
Like reference symbols in the various drawings indicate like elements.
The first fan wheel 6 and the second fan wheel 7 are structurally identical and are each integrally formed on a floating bearing-side short-circuiting ring 8 or a fixed bearing-side short-circuiting ring 9 of a rotor 10. The rotor 10 is mounted in a rotationally fixed manner on a rotor shaft 11 which is shown by
A stator 18 is arranged in an immobile manner between the first end plate 14 and the second end plate 15 and surrounds the rotor 10. The stator 18 includes a floating bearing-side stator end winding 19 and a fixed bearing-side stator end winding 20, where the stator end windings 19 and 20 are arranged on opposite end regions of the stator 18 and are each radially surrounded by one of the end plates 14 and, respectively, 15. Furthermore, an air guide plate 21 which has an L-shaped cross section is arranged between the first fan wheel 6 and the first end plate 14.
By means of the first fan wheel 6, a cooling air volume flow V can be drawn radially inward from the area 22 surrounding the electric motor 1 via the cooling ribs 17 of the floating bearing-side end plate 14 and the air guide sleeve 16. A first proportion V1 of the drawn-in air volume flow V can be blown radially outward out of the electric motor 1 via the floating bearing-side stator end winding 19, where the first proportion V1 of the air volume flow V is guided in a corresponding manner via the air guide plate 21. By means of the second fan wheel 7, a second proportion V2 of the radially inwardly drawn air volume flow V can be drawn axially into and through the rotor 10 and blown radially outward out of the electric motor 1 via the fixed bearing-side stator end winding 20.
A number of implementations have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the disclosure. Accordingly, other implementations are within the scope of the following claims.
Number | Date | Country | Kind |
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10 2015 215 009.7 | Aug 2015 | DE | national |
This application claims the benefit of PCT Application PCT/EP2016/067860, filed Jul. 27, 2016, which claims priority to German Application DE 10 2015 215 009.7, filed Aug. 6, 2015. The disclosures of the above applications are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/EP2016/067860 | Jul 2016 | US |
Child | 15889955 | US |