The invention relates to a fluid-cooled electric motor having an internal cooling circuit through flown by a rotary-motor cooling pump.
Large electric motors require cooling units for dissipating heat. Both gases and fluid media are utilized as cooling mediums. Since convection is usually not sufficient for the dissipation of power, ventilators or pumps are used for generating flow.
Often it is the electric motor that drives these components. The impeller or pump wheel is directly connected to the shaft of the motor. If rotation speeds other than the nominal shaft rotation speed are required, solutions having an intermediary transmission or clutches are used. With pumps that have to be utilized in explosive environments, these components must additionally meet the EX protection requirements (prevention of sparks). Commonly, such components are produced in small quantities only, and are very expensive. Thus, they have a substantial influence on the costs of the entire assembly. Due to the rigid coupling using the shaft of the motor, the cooling medium is circulated even if there is no need for cooling. This reduces the performance efficiency of the machine.
It is therefore an object of the invention to improve the drive of the cooling circuit of an electric motor in such a manner that a construction that is easy to make is produced, that enables easy installation, that makes it possible to adjust the cooling power so it is tailored to the individual need, and particularly that makes measures for EX protection unnecessary.
This object is attained according to the invention in that the cooling pump has a shaft separate from the electric-motor shaft and is partially or completely within the housing of the electric motor.
A wet-rotor pump, produced in large quantities, is installed into the electric motor. In this manner, significant cost reductions can be achieved, and the pump can be operated independently of the rotation speed of the shaft. This means that the medium is circulated only, if cooling is required. With the use of a pump with variable rotation speed, the cooling output can be adjusted according to need. With the installation of the pump in the motor, additional measures for EX protection are not necessary, or can be done at a significantly reduced expense as opposed to externally operated assemblies.
Advantageous embodiments of the invention are described in the dependent claims.
One embodiment of the invention is illustrated in the drawings, and is explained in further detail below. In the drawings:
The electric motor 1 of a rotary-motor pump has a motor shaft 2 carrying a rotor 3 that is surrounded by a stator winding 4. At one end of the motor shaft 2 the shaft of a rotary pump (not illustrated) is coaxially connected to this rotor, the pump housing being attached to the motor housing 6.
Inside the motor housing 6 are the passages 7 of a cooling circuit whose coolant is circulated by a separate motor\pump assembly that has a rotary pump driven by an electric motor, and is hereinafter referred to as the “cooling pump” 8. The cooling pump 8 is a wet-rotor pump with a rotor 10 mounted in a separating can 9, seated on a shaft 8a that carries the pump impeller 5 at its end. Instead of the separating can, the rotor may also be surrounded by a rotor tube.
The cooling pump 8 aspirates the coolant with its impeller 5 via a coaxial passage 7a formed in the cooling pump housing 11, and feeds it to a passage 7b that extends radially in the cooling pump housing 11 along to the motor stator.
The housing 6 of the electric motor 1 to be cooled forms an externally accessible compartment 12 that is open to the exterior around the electric motor 1 (opening 13), as long as the opening 13 is not closed. The cooling pump 8 with its housing 11 can be inserted into the compartment 12 from the exterior in a snug fit, the dimensions of a cooling pump housing 11 corresponding to the interior dimensions of the compartment 12. The electrical connections of the cooling pump 8 to the electrical connections in the compartment 12 are effected via the plug-in connectors 14 that are attached on the outside of the housing 11, and on the inside of the compartment 12 so that after inserting the cooling pump 8 the connections are closed.
Similarly to the fitting of the coolant pump 8 into the compartment 12, the passages 7, 7a, and 7b are formed in inner and outer housing walls. After installing the cooling pump 8, the compartment 12, or its opening 13, is closed by means of a cover 15 that fits on or in from the exterior.
The cooling pump 8 can be controlled with or without feedback in that it is switched off some times, and has on times of varying lengths.
As an alternative, the rotation speed of the cooling pump 8 can be controlled independently of the rotation speed of the electric motor 1. In both cases an optimum and accurate cooling can be achieved without any unnecessary cooling expenditure.
In the embodiment the compartment 12 is open laterally of the motor housing 6 when the cover 15 removed. However, the compartment 12 can also be open toward an end 16 of the motor housing 6. Furthermore, the cover may be omitted, if the compartment 12 and its opening 13 are filled by the housing 11 of the cooling pump 8 in a sealing manner. In this case, the cooling pump and its housing 11 may project over the housing 6. In the latter case a domed cover may surround the projecting housing 11.
Number | Date | Country | Kind |
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10 2005 038 209.6 | Aug 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2006/007184 | 7/21/2006 | WO | 00 | 2/13/2008 |