DE102010064704B3 - Pump with an electric motor and method for switching on such a pump - Google Patents

Abstract

Method for operating a pump (10) with an electric motor (11) having a stator (12) with pole pieces (14) arranged stator windings (16) and a permanent magnetic rotor (20), wherein the rotor (20) via a Rotor shaft (22) drives a pump impeller (24), the stator windings (16) serving as a heating element and a control circuit (18) being provided via which the stator windings (16) can be switched to a heating mode, characterized in that in a first step the heating mode is switched on and in a second step after a time tw or when a temperature Tw is reached the heating mode is stopped and in a third step the commutation of the electric motor (11) is started and in a subsequent step it is detected whether the rotor (20) is rotating , wherein the commutation is continued when the rotor (20) rotates, and steps 1 - 3 are carried out when the rotor (20) is stationary.

Description

The invention relates to a method for operating a pump with an electric motor, in particular for fuel cell systems, and a method for switching on such a pump. The electric motor for such a pump has a stator with stator windings arranged on pole pieces and a permanent magnetic rotor, with the rotor driving an impeller via a rotor shaft, with the stator windings serving as a heating element and a control circuit being provided, via which the stator windings are converted into a Heating mode can be switched. Furthermore, the invention relates to such a pump.

Such pumps are used in particular in fuel cell systems. These fuel cell systems are used to convert chemical reaction energy from a continuously supplied fuel, in particular hydrogen and an oxidizing agent, mostly oxygen, into electrical energy that can be used, for example, as drive energy for vehicles. Different types of pumps can be arranged in such a fuel cell system. When switched off and at low ambient temperatures, however, it can happen that moving parts of a pump freeze up due to water freezing. Especially when pumping media with a high water content, there is a risk of the moving parts freezing, such as the bearing, rotor or impeller, and thus the risk of the motor blocking when it starts up, which can lead to failure of the motor and thus the pump.

Such problems are, for example, from the DE 10 2007 049 641 A1 known, which also discloses a pump with an electric motor. In order to solve frozen solids, the arrangement has a can, which is designed as a heating element with heating conductors, via which the electrical energy is supplied, starting from the operating voltage, for heating the can. The disadvantage of this solution is that the can has to have additional lines that have to be routed through the motor housing in order to obtain a connection to the operating voltage, which makes the assembly process more difficult and increases the manufacturing costs.

From the DE 100 45 291 A1 Although it is known that motor windings are used to heat up magnets, in principle it would also be possible to heat up ancillary units to loosen frosting, although it may happen that the heating is not sufficient to loosen the frosting and consequently damage to the pump takes place.

In addition, from the DE 10 2008 004 013 A1 and the DE 41 05 733 A1 Known method for heating electrical machines by a targeted energization of the stator winding.

It is therefore the object of the invention to provide a method and a pump produced according to this method for switching on such a pump, with which freezing of the rotating components of the pump and the electric motor connected to it can be solved without the need for additional components be, and without increased installation effort.

The object is achieved by a method in which the heating mode is switched on in a first step and the heating mode is stopped in a second step after a time tw or when a temperature Tw is reached and in a third step the commutation of the motor is started and in in a subsequent step it is detected whether the rotor is rotating, with the commutation being continued when the rotor is rotating, and steps 1-3 being carried out when the rotor is stationary. This procedure avoids overheating of the stator windings during heating. In addition, unnecessary switching to the heating mode, which involves additional energy consumption, is avoided, thus reducing the start-up time of the pump.

In the method, the heating mode is preferably implemented in such a way that voltage is applied to adjacent stator windings in alternation, thereby ensuring an even distribution of the thermal load.

In the method, the temperature T of the stator windings (16) is advantageously determined as a function of the current flow and a predetermined voltage with reference to the specific resistance of the coil material according to the equation R(T)=R(T ₀ )×(1+α× (T - T ₀ )) determined, so that no further measuring equipment is required to ensure correct functioning of the stator windings as a heater.

The object is also achieved by a pump with an electric motor in that an insulating element made of a thermally conductive plastic is arranged between the stator windings and the pole pieces, so that rapid and efficient introduction of heat into the components of the electric motor and the pump is ensured. This simplifies the assembly and reduces the switching effort, which saves costs.

The insulating element is preferably designed as a coating on the pole limbs, which can be produced in a simple injection molding process.

In an advantageous embodiment, an insert element made of an electrically insulating material is arranged between the stator and the motor housing between the stator and the motor housing, which consists of electrically conductive material, such that a safety distance is maintained.

The invention is described in more detail using a perspective sectional view of a pump according to the invention in the single figure.

1 shows the pump 10 according to the invention with an electric motor 11 which is arranged in a motor housing 26 . Furthermore, the motor housing 26 is completely enclosed by an electronics housing part 56 and a pump housing cover 50 which mesh. in the in 1 In the exemplary embodiment shown, the pump 10 is designed as a side channel blower and has a first side channel 52 and a second side channel 54, the first side channel 52 being formed in the pump housing cover 50 and the second side channel being formed in the internal motor housing 26.

The electric motor 11 located in the motor housing 26 has a stator 12 with stator windings 16 arranged on pole pieces 14 and a permanent-magnetic rotor 20 . In the exemplary embodiment shown, a containment shell 32 separates the rotor 20 from the stator 12 .

A pump impeller 24 with blades is connected to a rotor shaft 22 and is rotatably mounted in the part of the motor housing 26 opposite the electronics housing part 56, the rotor shaft 22 being mounted in the motor housing 26 and electronics housing part 56 via ball bearings 40 or other bearings.

An insert element 28 made of an electrically insulating plastic prevents an electrically conductive contact between the housing 26 and the stator winding 16. Furthermore, the material of the insert element 28 has good heat-conducting properties, so that in the heating mode, which is described below, a thermal insulation effect is significantly reduced becomes.

Each pole piece 14 of the stator 12 also has a coating that is designed as an insulating member 30 and separates the pole piece 14 from the stator windings 16 . The insulating element 30 consists of an electrically insulating, thermally conductive plastic and enables heat to be released quickly to the surrounding components to be heated.

The use of thermally conductive material also prevents the electric motor 11 from overheating in the heating mode, since the heat can be quickly dissipated from the windings 16 to the surrounding housing 26, 56.

Furthermore, the pump 10 with the electric motor 11 has a control circuit 18 which is arranged within the electronics housing part 56 . An electronics circuit board 60 divides the electronics housing part 56 into two areas, the control circuit 18 being arranged in a first area and the electric motor 11 of the pump 10 being arranged in a second area. The first area of the electronics housing part 56, which contains the control circuit 18, is closed by an electronics housing cover 58. In order to enable a signal connection between the control circuit 18 and the stator 12, the electronics circuit board 60 of the electronics housing part 56 has an opening 64 through which corresponding lines 62 are routed. Such a control unit 18 can put the electric motor 11 into different operating states and also detect the rotational position of the electric motor 11 .

Since water deposits and freezing can occur when pumps are switched off and at outside temperatures below freezing, especially on the moving parts such as the ball bearings 40, the rotor 20 or the impeller 24, there is a risk of the motor blocking when starting, which can lead to Damage to the motor and failure of the pump can result. In order to solve such water deposits or freezing, the stator windings 16 of the electric motor 11 can be used as a heating element before the motor starts, in which a heating mode can be switched on via the control circuit 18 . The heating mode is designed in such a way that adjacent stator windings 16 are alternately energized. In a first step, the heating mode is switched on, which leads to the stator windings 16 being heated up. The heat generated at the stator windings 16 is passed on via the heat-conducting insulating elements 30 directly to the pole pieces 14 and to the can 32 resting thereon. By heating the can 32 and thus its interior, the rotor 20, the rotor shaft 22 and the ball bearings 40 are released from possible freezing due to thawing of the ice. Since the insert element 28 is also made of a thermally conductive plastic, the motor housing 26 heated, whereby the impeller 24 and the side channels 52, 54 are heated more easily. In a second step, the heating mode is stopped after a time tw or when the heating mode reaches a temperature Tw. This avoids overheating of the stator windings 16 and establishes a point in time by which the ice must have melted. After switching off the heating mode, the commutation of the electric motor 11 is started in a known manner in a third step.

Of course, the scope of protection of the application is not limited to the exemplary embodiment described. The control circuit can thus be designed in such a way that a jamming is first detected before the heating mode is switched on. Of course, structural changes to the pump can also be carried out without departing from the scope of protection of the main claim.

Claims (6)

Method for operating a pump (10) with an electric motor (11) having a stator (12) with pole pieces (14) arranged stator windings (16) and a permanent magnetic rotor (20), wherein the rotor (20) via a Rotor shaft (22) drives a pump impeller (24), the stator windings (16) serving as a heating element and a control circuit (18) being provided, via which the stator windings (16) can be switched to a heating mode, characterized in that in a first step the heating mode is switched on and in a second step after a time tw or when a temperature Tw is reached the heating mode is stopped and in a third step the commutation of the electric motor (11) is started and in a subsequent step it is detected whether the rotor (20 ) rotates, with the commutation being continued when the rotor (20) rotates, and steps 1 - 3 being carried out when the rotor (20) is stationary. Method of operating a pump (10) according to any one of the preceding claim 1 , characterized in that the heating mode is designed such that adjacent stator windings (16) are alternately charged with voltage. Procedure for operating a pump claim 1 or 2 , characterized in that the temperature T of the stator windings (16) as a function of the current flow and predetermined voltage with reference to the specific resistance of the coil material according to R(T) = R(T ₀ ) × (1 + α × (T - T ₀ )) is determined. Pump (10) with an electric motor (11) which has a stator (12) with stator windings (16) arranged on pole pieces (14) and a permanent magnetic rotor (20), the rotor (20) being connected via a rotor shaft (22) a pump impeller (24) drives according to one of Claims 1 - 3 , characterized in that between the stator windings (16) and the pole pieces (14) an insulating member (30) is arranged that consists of a thermally conductive plastic. Pump (10) after claim 4 , characterized in that the insulating member (30) is a coating of the pole piece (14) made of a thermally conductive plastic. Pump (10) after claim 4 or 5 , characterized in that an insert element (28) made of electrically insulating material is arranged between the stator (12) and the motor housing (26).

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