瑞典专利SE1650215A1 An arrangement for cooling an electrical machine

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专利摘要:
13 Abstract The present invention relates to an arrangement for Cooling of an electrical machine(3). The electrical machine (3) comprises a rotor (5) rotatably arranged around arotation aXis (4a), a stator (6) including a stator Winding (6b) arranged radially outsideof the rotor (5), a housing (2) enclosing the rotor (5) and the stator (6), at least onedrain hole (ll) configured to drain a cooling ﬂuid from the housing (2), at least onespraying device (8-10) configured to spray cooling ﬂuid on the stator Winding (6b) anda pump (l4) configured to pump cooling ﬂuid to the spraying device (8-10). Thearrangement comprises a control unit (18) Which is configured, When the electricalmachine (3) is in operation, to receive information of the temperature in at least oneposition of the stator Winding (6b) and to control the pump (l4) such that it pumps aflow rate of the cooling ﬂuid to the spraying device (8-10) Which is related to the estimated temperature of the stator Winding (6b). (Pig. i)
公开号:SE1650215A1
申请号:SE1650215
申请日:2016-02-19
公开日:2017-08-20
发明作者:Engström Jörgen；Karlsson Stefan
申请人:Scania Cv Ab；
IPC主号:

专利说明:

An arrangement for cooling of an electrical machine BACKGROUND TO THE INVENTION AND PRIOR ART The present invention relates to an arrangement for Cooling of an electrical machine according to the preamble of claim 1.
A power train of a hybrid vehicle may be powered by an electrical machine and acombustion engine. The electrical machine works as an engine and provide powerduring certain Operating conditions such as during idling conditions, at low speeds andaccelerations of the vehicle. During certain Operating conditions, the electrical machineworks as a generator where it supplies electrical energy to a battery. The electricalmachine is in an operation when it works as an engine or as a generator. Thecombustion engine may power the vehicle independently during certain Operatingconditions of the vehicle at the same time as the electrical machine does not work asgenerator. During such Operating conditions, the electrical machine is Out of Operation.The electrical machine is heated when it is in operation. Conventional cooling ofelectrical machines in hybrid vehicles may be performed by air Or water led past anexternal suiface of a housing enclosing the electrical machine. A more effective cooling method is to spray Oil On the stator windings.
US 2011/0148229 shows an electrical machine including a rotor and a stator which arearranged in a housing. A number of cooling devices generates a coolant spray On thestator during Operation of the electrical machine. A sump pan receives the suppliedcoolant at a bottom portion of the housing. A coolant discharge is mounted at a lowestpoint of the sump pan. The coolant discharge directs coolant to a coolant reservoir. Acoolant pump pumps coolant from the coolant reservoir to the coolant spray device. Acoolant Overﬂow defines a highest coolant level in the sump pan. When the electrical machine is not in Operation, the pump feeds a coolant ﬂow to the coolant spray device of a small quantity such that no coolant level is created in the housing. When theelectrical machine is in operation, the pump feeds a coolant ﬂoW of a larger quantity tothe coolant spray device such that a coolant level is created in the housing, Which Wetsthe rotor. In this case, the rotor distributes the coolant in the housing Which results inan effective cooling of the electrical machine. HoWever, the electrical machinereceives relatively large drag losses during operation since the rotor rotatescontinuously in contact With the coolant in the housing during operation of the electrical machine.
SUMMARY OF THE INVENTION The object of the invention is to establish an arrangement Which provides an effective cooling of an electrical machine in a manner such that unnecessary losses are avoided.
This object is achieved With the arrangement defined in the introduction Which ischaracterized by the features defined in the characterising part of claim l. Thetemperature rise in an electrical machine is substantially confined to specificcomponents and especially to the stator Winding. Thus, it is effective to cool theelectrical machine by injecting a cooling ﬂuid on the stator Winding. The cooling ﬂuidmay be a suitable oil. The cooling demand of the stator Winding varies during differentoperation conditions. Generally, the cooling demand increases With the temperature ofthe stator. The cooling of the stator Winding depends on the ﬂoW rate of cooling ﬂuidto the stator Winding. HoWever, it requires more pump energy to supply a larger ﬂoW rate to the stator Windings than a lower ﬂoW rate.
The control unit may have access to stored information about suitable ﬂoW rates atdifferent temperatures of the stator Winding. The control unit may receive informationof the temperature of the stator Winding substantially continuously. In case the coolingﬂoW rate to the spraying device differs from a suitable ﬂoW rate at a specifictemperature of the stator Winding, the control unit controls the pump such that the ﬂoWrate is adjusts to the desired value. In this case, it is possible to provide an effectivecooling of the stator Winding When the electrical machine is high loaded and save pump energy When the electrical machine is low loaded.
According to an embodiment of the invention, the pump is configured, When the electrical machine is in operation, to provide a ﬂoW rate of the cooling ﬂuid creating a cooling ﬂuid level in the housing related to the temperature of the stator Winding. Thedrainage hole of the housing has a size Which detern1ines the ﬂoW rate of the coolantﬂuid out of the housing. Thus, in order to create a cooling ﬂuid level in the housing, itis necessary to supply a larger ﬂoW rate to the housing than the ﬂoW rate leaving thehousing via the drainage hole. The outlet ﬂoW rate through the drainage hole increasessomeWhat With an increasing cooling ﬂuid level in the housing. Due to this fact, it ispossible to detern1ine a relationship between ﬂoW rate of cooling ﬂuid pumped to the housing and cooling ﬂuid level in the housing.
According to an embodiment of the invention, the pump is configured, at a firsttemperature of the stator Winding, to provide a ﬂoW rate creating a cooling ﬂuid levelin the housing at Which the cooling ﬂuid covers at least a part of a loWest locatedportion of the stator Winding. It is many times difficult to provide an effective coolingof the loWest located portion of the stator Winding. In this case, a very effective coolingof the loWest located portion of the stator Winding it is obtained since it has a part inconstant contact With the cooling ﬂuid. It is possible to vary the size of the part of thestator Winding covered by the cooling ﬂuid by adjustment of the cooling ﬂuid level in the housing.
According to an embodiment of the invention, the pump is configured, at a secondtemperature of the stator Winding, to provide a ﬂoW rate creating a cooling ﬂuid levelin the housing at Which the cooling ﬂuid comes in contact With the rotor. In this case,the rotor Will splash around the cooling ﬂuid in the housing such that it comes incontact With portions of the stator Winding located at a higher level than the coolingﬂuid level. In this case, substantially all portions of the stator Winding receive a veryeffective cooling by the cooling ﬂuid. When the stator Winding has a high temperature,it is suitable to create such a cooling ﬂuid level in the housing in order to increase thecooling of the stator Winding. When the temperature of the stator Winding has beenloWered to a more ordinary temperature, it is many times possible to create a coolingﬂuid level out of contact With the rotor in order to reduce drag losses of the electrical machine.
According to an embodiment of the invention, the pump is configured, at a thirdtemperature of the stator Winding, to provide a ﬂoW rate creating substantially nocooling ﬂuid level in the housing. In case the temperature of the stator Winding decreases, it is possible to reduce the ﬂoW rate pumped to the spraying device. The reduced ﬂow rate results in a lowered cooling ﬂuid level in the housing. In case theﬂow rate to the housing decreases to a level below the ﬂow rate leaving the housingvia the drainage hole there will be no cooling ﬂuid level in the housing. With such a low ﬂow rate to the housing, pump energy is saved.
According to an embodiment of the invention, said pump is able to adjust the coolingﬂuid ﬂow to the spraying device in a substantially stepless manner. In this case, it ispossible to adjust the cooling ﬂuid level in the housing with a high accuracy.Alternatively, the control unit may control the pump such that it is restricted to provide a number of ﬂow rates of predeterrnined values.
According to an embodiment of the invention, the control unit is configured to controlthe pump such that it pumps a ﬂow rate to the housing in order to maintain atemperature of the stator windings within a predeterrnined temperature range. In casethe temperature of the stator winding is higher than the highest temperature of thetemperature range, the pump may provide a high ﬂow rate to the housing creating acooling ﬂuid level in contact with the rotor. In case the temperature of the statorwinding is lower than a lowest temperature of the temperature range, the pump may provide a low ﬂow rate creating substantially no cooling ﬂuid level in the housing.
According to an embodiment of the invention, it comprises a temperature sensorconfigured to sense the temperature of stator winding in at least one position. In thiscase, the control unit receives a reliable information about the temperature in at leastone portion the stator winding. Alternatively, the control unit is configured to receiveinformation about at least one operating parameter of the electrical machine and todetermine the temperature of the stator windings by means of this operating parameter.The control unit may receive information about operating parameters of the electricalmachine such as torque and speed. By means of this information it is possible todetermine the temperature of the stator winding and the cooling demand of the stator windin g .
According to an embodiment of the invention, the spraying device is configured tospray cooling ﬂuid on a portion of the stator winding arranged at an upper half of thestator. It is many times sufficient to spray cooling ﬂuid on some upper portions of thestator winding. The injected cooling ﬂuid cools the upper portions whereupon the cooling ﬂuid ﬂows downwardly along the lower located portions of the stator winding.
In practice, a part of the Cooling ﬂuid, which hits the upper portions of the statorwinding, bounces away from the stator winding. This cooling ﬂuid may hit a wall ofthe housing where it ﬂows downwardly without taking up any heat from lower locatedportions of the stator winding. In this case, there is a risk that the lowest locatedportion of the stator winding receives an insufficient cooling. In such a case, it isespecially important to create a cooling ﬂuid level in the housing in contact with at least a part of the lower portions of the start winding.
According to an embodiment of the invention, the housing comprises at least onefurther drainage hole configured to define a maximum cooling ﬂuid level in thehousing. Such at least one further drainage is arranged at a specific level in thehousing. A surplus of cooling ﬂuid above said level is drained out from the housing viasaid at least one drainage hole. Thus, such a drainage hole defines a maximum coolingﬂuid level in the housing in a simple and reliable manner. It is possible to arrangedrainage holes at different high levels in the housing in order to accomplish furthercooling ﬂuid levels in the housing. It is possible to arrange drainage holes at an appropriate level for preventing the pump to run dry.
According to an embodiment of the invention, the control unit may be configured tocontrol the pump, when the electrical machine is not in operation, such that is pumps aﬂow rate creating substantially no cooling ﬂuid level in the housing. During timeswhen the electrical machine does not provide any torque, it is out of operation. Duringsuch times, there is no cooling demand of the stator winding and is possible to pump aminimum ﬂow rate to the housing creating substantially no cooling ﬂuid level in the housing.
According to an embodiment of the present invention, the arrangement may becomprised in an electrical machine in a power train of a vehicle. In this case, theelectrical machine may work as a motor as well as a generator. The electrical machineis in operation when it provides a torque. The vehicle may be a hybrid vehicle powered by the electrical machine and a combustion engine.
BRIEF DESCRIPTION OF THE DRAWINGS A preferred embodiment of the invention is described below by way of an example with reference to the attached drawings, on which: Fig. 1 shows an arrangement for Cooling of an electrical machine and Fig. 2 shows a cross sectional view in the plane A-A in Fig. 1.
DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT OF THEINVENTION Fig. 1 shows a schematically indicated hybrid vehicle 1 and a housing 2 enclosing anelectrical machine 3. A rotatable shaft 4 eXtends through a first side wall 2a of thehousing 2 and a second side wall 2b of the housing 2. A periphery wall 2c connects theside walls 2a, 2b of the housing 2. The shaft 4 is rotatably arranged in relation to theside 2a, 2b by means of bearings 2d. The electrical machine 3 comprises in aconventional way a rotor 5 and a stator 6. The rotor 5 comprises a rotor core 5asupported by a rotor hub 5b. The rotor hub 5b is fastened on the rotatable shaft 4 bymeans of a splined connection. Alternatively, it may be arranged on a ring wheel of aplanetary gear. The rotor 5 and the shaft 4 rotates around a common rotation aXis 4a.The stator 6 comprises a stator core 6a, a stator winding 6b which is arranged on aninside of the periphery wall 2c of the housing 2 and a mantle 6c. A schematicallyindicated combustion engine 7 is also connected to the shaft 4. A cooling ﬂuid, whichis eXemplified as a suitable oil, is supplied to the housing 2. The oil cools andlubricates the components in the housing 1. An oil channel 8 is arranged in a radialspace between the periphery wall 2c and a mantle 6c in the housing 2. Oil is suppliedwith a positive pressure, via an inlet hole 10 in the housing 2, to the oil channel 8. Theoil channel 8 comprises a number of outlet ducts 9 in the mantle 6c. Oil is sprayed, viathe outlet ducts 9, towards a number of portions of the stator winding 6b located at an upper half of the stator 6.
The housing 2 comprises a drainage hole 11 located at a lowerrnost position of thehousing 2. The drainage hole 11 is, via a drain line 12, connected to an oil receiver 13.A pump 14 pumps oil from the oil receiver 13, via an oil line 15, to the oil channel 8 inthe housing 2. The oil line 15 comprises a thermostat 16. ln case the oil has a lowertemperature than a regulating temperature of the thermostat 16, the thermostat 16directs the oil to the housing 2 without cooling. ln case the oil has a higher temperaturethan the regulating temperature of the therrnostat 16, the thermostat 16 directs the oil toa cooler 17 before it is directed to the housing 2. A control unit 18 is configured to control the speed of the pump 14 and the flow rate of the oil pumped to the housing 2.
A temperature sensor 19 is configured to sense the temperature in at least one portionof the stator winding 6b. The control unit 18 receives information from the temperaturesensor 19 about the temperature of the stator winding 6b. Furthermore, the control unit18 receives information 20 about the torque. The information 20 may also includeother operating parameters such as the speed of the electrical machine 3. The controlunit 18 is able to determine the temperature of the stator winding 6b by means of suchoperating parameters. The control unit may also receive information from a second temperature sensor 2l about the temperature of the oil pumped to the housing 2.
Fig. 2 shows a cross sectional view in a plane A-A in Fig. l. lt is here visible that thehousing 2 comprises a number of outlet ducts 9 arranged in different positions in anupper part of the housing 2. Two further drainage holes 22a, 22b defines a maximumoil level Lmax in the housing 2. The maximum oil level Lmax is located at a higher levelthan a lowest position of the rotor 5. Thus, the rotor Scomes in contact with the oilwhen there is a maximum oil level Lmax in the housing 2. The oil level L in the housingcan be adjusted between a minimum oil level Lmin when there is substantially no oillevel in the housing 2 and up to the maximum oil level Lmax. A further oil level L isindicated in the figures in which the oil is in contact with a lower portion of the stator winding 6b but out of contact with the rotor 5.
The electrical machine 3 is in operation when it works as a motor and powers thehybrid vehicle l. The electrical machine 3 is also in an operation when it works as agenerator and charges a battery in the hybrid vehicle l. The electrical machine 3 isheated when it is in operation and needs to be cooled. During conditions when thehybrid vehicle l is running and the electrical machine 3 does not work as motor or asgenerator, it is out of operation. ln this case, the cooling demand of the electricalmachine is substantially negligible. ln a hybrid vehicle l, an electrical machine may beout of operation relatively frequently during conditions when the combustion engine 7powers the hybrid vehicle l independently at the same time as the battery is not charged.
During operation of the hybrid vehicle l, the control unit l8 may receive informationfrom the temperature sensor l9 about the temperature of the stator winding 6b.Thecontrol unit l8 has access to stored information l8a which defines a predeterrnined oilflow to the housing 2 as a function of the temperature of the stator winding 6b. The temperature of the stator winding 6b is strongly related to the cooling demand of the stator winding 6b. A suitable temperature of the stator winding 6b is within a specifictemperature range which, for example, may be 90° - 110°. The control unit 18 isconfigured to substantially continuously receive information 20 about the torque of theelectrical machine 3. The information 20 may also include other operating parameterssuch as the speed of the electrical machine 3. The control unit 18 may also determinethe temperature of the stator winding 6b by means of the information 20 about saidoperating parameters. The control unit 18 may also receive substantially continuouslyinformation from the second temperature sensor 21 about the temperature of the oildirected to the housing 2. The cooling capacity of the electrical machine 2 is alsorelated to the temperature of the oil. The control unit 18 receives substantiallycontinuously information 20 about the torque of the electrical machine 3. In case thetorque of the electrical machine 3 differs from zero, the control unit 18 notes that theelectrical machine 3 is in operation. In case the electric machine 3 is zero the control unit 18 notes that the electrical machine is out of operation.
In case the electrical machine 3 is in operation and the temperature of the statorwinding 6b is lower than the lowest temperature in the above exemplified temperaturerange, there is a low cooling demand of the electrical machine 3. The control unit 18controls the pump 14 such that it provides a relatively low ﬂow rate of oil, via the oilline 15, to the housing 2. The low ﬂow rate of oil enters, via the inlet hole 10, the oilchannel 8. The oil is sprayed, by the outlet duct 9, on a number of portions of the statorwinding 6b located at an upper half of the stator 6. The oil hits and cools said upperportions of the stator winding 6b. Preferably, a relatively large part of the oil will beremain on the stator winding 6b. This part of the oil flows downwardly along the statorwinding 6b and cools lower portions of the stator winding 6b. The oil is collected on abottom portion of the housing 2. The oil leaves the housing via the drainage hole 11. Inthis case, the ﬂow rate of oil to the housing 2 is lower than the ﬂow rate capacity of thedrainage hole 11. As a consequence, there will be substantially no oil level Lmin in thehousing 2. The oil ﬂows from the housing 2, via the drain line 12, to the oil receiver13. Since the cooling demand is low, it is possible to direct a low ﬂow rate of oil to the housing 2 and save pump energy.
In case the electrical machine 3 is in operation and that the temperature of the statorwinding 6b is within the above mentioned specific temperature range, there is amedium cooling demand of the electrical machine 3. The control unit 18 controls the pump 14 such that it pumps a medium ﬂow rate of oil, via the oil line 15, to the housing 2. In this case, a higher cooling of the stator winding 6b is received due to thehigher ﬂow rate of oil sprayed on the stator winding 6b. Also within this temperaturerange, the cooling demand and the ﬂow rate to the housing may vary with thetemperature of the stator winding 6b. Under all circumstances, the medium ﬂow rate ofoil to the housing 2 is to be somewhat higher than the ﬂow rate of oil through thedrainage hole ll. However, the outlet ﬂow rate of oil through the drainage hole llincreases somewhat with the oil level L in the housing 2. Due to this fact, it is possibleto determine a relationship between ﬂow rate of oil to the housing 2 and the oil level Lin the housing 2. In this case, a medium oil level L is supplied to the housing 2 whichcreates an oil level L at which the oil covers at least a part of a lowest located portionof the stator winding 6b. When oil is sprayed on portions of the stator winding 6blocated at an upper half of the stator 6, there is a risk that portions of the stator winding6b located at a lower half of the stator winding and especially the lowest locatedportion of the stator winding 6b receives a poor cooling. In this case, the cooling of thelowest located portion of the stator winding 6b will be considerably increased since itis more or less covered by oil. It is possible to adjust the ﬂow rate of the oil and the oillevel L in the housing 2 substantially continuously in order to provide a desired cooling of the stator winding 6b with a high accuracy.
In case the electrical machine 3 is in operation and the temperature of the statorwinding 6b is higher than the highest temperature in the above exemplifiedtemperature range, there is a high cooling demand of the electrical machine 3. Thecontrol unit 18 controls the pump l4 such that it pumps a high ﬂow rate of oil, via theoil line l5, to the housing 2. The high ﬂow rate of oil provides an effective cooling ofstator winding 6b. The high ﬂow rate of oil to the housing 2 is considerably higherthan the oil ﬂow rate through the drainage hole ll. As a consequence, a maximum oillevel Lmax is created in the housing 2. The maximum oil level Lmax is defined by twofurther drainages holes 22a, 22b. The total ﬂow rate capacity of the further drainageholes 22a, 22b and the ordinary drainage hole ll is larger the high ﬂow rate pumped tothe housing 2. Consequently, the oil level in the hosing 2 will not be higher than themaximum oil level Lmax. The maximum oil level Lmax is located at a higher level thanthe lowest portion of the rotor 5. Thus, the rotor 5 splashes the oil around in the housing thus further increasing the cooling of the stator winding 6b.
The above mentioned cooling arrangement results in a more uniform temperature in the stator winding 6b over time and driving modes that allow to better optimize the electrical machine 3 and give better vehicles characteristics. Improved coolingperformance at high cooling demand. Since the control unit 18 controls the speed ofthe pump l4, the cooling performance is not affected by the speed of the vehicle l. Avery effective cooling of the loWest located portion of the stator Winding 6b is obtained. No drag losses in the oil When there is a low or medium cooling demand.
The invention is in no Way limited to the embodiment to Which the draWing refers butmay be varied freely Within the scopes of the claims. lt is possible to vary the ﬂoW rateof oil to the housing in substantially arbitrary manner in relation to the temperature ofthe stator Winding for accomplish an effective cooling of the stator Winding 6b. Theelectric machine may be connected to an electric poWertrain in a purely electrically powered vehicle.

权利要求:
Claims (13)
[1] 1. l. An arrangement for Cooling of an electrical machine (3), Wherein the electricalmachine (3) comprises a rotor (5) rotatably arranged around a rotation axis (4a), astator (6) including a stator Winding (6b) arranged radially outside of the rotor (5), ahousing (2) enclosing the rotor (5) and the stator (6), at least one drain hole (ll)configured to drain a cooling ﬂuid from the housing (2), at least one spraying device(8-10) configured to spray cooling ﬂuid on the stator Winding (6b) and a pump (l4)configured to pump cooling ﬂuid to housing (2), characterized in that the arrangementcomprises a control unit (18) Which is configured, When the electrical machine (3) is inoperation, to receive information of the temperature in at least one position of thestator Winding (6b) and to control the pump (l4) such that it provides a ﬂoW rate of thecooling ﬂuid to the housing (2) as a function of the temperature of the stator Winding(6b).
[2] 2. An arrangement according to claim l, characterized in that the pump (l4) isconfigured, When the electrical machine (3) is in operation, to provide a ﬂoW ratecreating a cooling ﬂuid level (L) in the housing (2) related to the temperature of thestator Winding (6b).
[3] 3. An arrangement according to claim 2, characterized in that the pump (l4) isconfigured, at a first temperature of the stator Winding (6b), to provide a ﬂoW ratecreating a cooling ﬂuid level (L) in the housing (2) at Which the cooling ﬂuid covers at least a part of a loWest located portion of the stator Winding (6b).
[4] 4. An arrangement according to claim 2 or 3, characterized in that the pump (l4) isconfigured, at a second temperature of the stator Winding (6b) Which is higher than thefirst temperature, to provide a ﬂoW rate creating a cooling ﬂuid level (L) in the housing (2) at Which the cooling ﬂuid comes in contact With the rotor (5).
[5] 5. An arrangement according to any one the claims 2-4, characterized in that the pump(l4) is configured, at a third temperature of the stator Winding (6b) Which is lower thanthe first temperature, to provide a ﬂoW rate creating substantially no cooling ﬂuid level(L) in the housing (2). 12
[6] 6. An arrangement according to any one of the preceding claims, characterized in that said pump (14) is able to adjust the ﬂoW rate in a substantially stepless manner.
[7] 7. An arrangement according to any one of the preceding claims, characterized in thatthe control unit(18) is configured to control the pump (14) such that it pumps a ﬂoWrate to the housing (2) in order to maintain a temperature of the stator Winding (6b) Within a predetern1ined temperature range.
[8] 8. An arrangement according to any one of the preceding claims, characterized in thatit comprises a temperature sensor (15) configured to sense the temperature of the stator Windings (6b).
[9] 9. An arrangement according to any one of the preceding claims, characterized in thatthe control unit (18) is configured to receive information (20) about at least oneoperating parameter of the electrical machine (3) and to determine the temperature of the stator Winding (6b) by means of this operating parameter.
[10] 10. An arrangement according to any one of the preceding claims, characterized in thatthe spraying device (8-10) is configured to spray cooling ﬂuid on a portion of thestator Winding (6b) arranged at an upper half of the stator (6).
[11] 11. ll. An arrangement according to any one of the preceding claims, characterized in thatthe housing (2) comprises at least one further drainage hole (19a, 19b) configured to define a maximum cooling ﬂuid level (Lmax) in the housing (2).
[12] 12. An arrangement according to any one of the preceding claims, characterized in thatthe control unit (18) is configured to control the pump (14), When the electricalmachine (3) is out of operation, such that is pumps a ﬂoW rate to the housing (2) at Which substantially no cooling ﬂuid level (L) is created in the housing (2).
[13] 13. A vehicle comprising an arrangement according to any one of the preceding claims1-12.

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引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

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JP4441340B2|2004-06-23|2010-03-31|本田技研工業株式会社|Motor cooling system and hybrid vehicle|

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WO2015199176A1|2014-06-27|2015-12-30|本田技研工業株式会社|Rotating electric machine winding temperature estimation device and rotating electric machine winding temperature estimation method|FR3080506B1|2018-04-20|2021-03-19|Renault Sas|ELECTRIC MACHINE AND ELECTRIC MACHINE COOLING DEVICE INCLUDING SUCH A DEVICE|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

SE1650215A|SE539839C2|2016-02-19|2016-02-19|An arrangement for cooling of an electrical machine|SE1650215A| SE539839C2|2016-02-19|2016-02-19|An arrangement for cooling of an electrical machine|

BR112018014653A| BR112018014653A2|2016-02-19|2017-02-07|electrical machine cooling arrangement|

PCT/SE2017/050111| WO2017142457A1|2016-02-19|2017-02-07|An arrangement for cooling of an electrical machine|

CN201780011104.4A| CN108702063B|2016-02-19|2017-02-07|Device for cooling an electric machine|

US16/075,947| US20200389072A1|2016-02-19|2017-02-07|An arrangement for cooling of an electrical machine|

EP17753572.1A| EP3417532A4|2016-02-19|2017-02-07|An arrangement for cooling of an electrical machine|

KR1020187025923A| KR20180111960A|2016-02-19|2017-02-07|Devices for cooling of electrical machines|

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