CN217334210U - Thermal management module and vehicle with same - Google Patents

Abstract

The utility model discloses a thermal management module and have its vehicle, wherein thermal management module includes: cylinder manifold and circulating pump are equipped with the runner that is used for circulation heat transfer medium in the cylinder manifold, are equipped with first connecting portion on the cylinder manifold. The circulating pump is equipped with the second connecting portion, and first connecting portion and second connecting portion buckle cooperation are in order to fix the circulating pump to the cylinder manifold, and the circulating pump is in order to guide heat transfer medium to flow with at least one runner cooperation. The utility model discloses thermal management module sets up a plurality of heat transfer medium's runner in the cylinder manifold, makes things convenient for the pipeline in the heat transfer circulation system to be connected with the circulating pump, and the circulating pump can be gone into heat transfer medium pump to relevant heat transfer circulation system in the during operation. The circulating pump need not to use the support, and it is fixed that the buckle cooperation is accomplished directly to realize with the cylinder manifold, need not too much space when cylinder manifold and circulating pump installation are fixed, reduces redundant design structure such as installing support, reduces the manufacturing cost of circulating pump, lightens the weight of circulating pump, integrates the degree height.

Description

Thermal management module and vehicle with same

Technical Field

The utility model belongs to the technical field of the vehicle spare part, specifically be a heat management module and have its vehicle.

Background

With the continuous deepening of the requirements of environmental protection, low carbon and sustainable development, new energy automobiles, especially electric automobiles, are popular among consumers due to the characteristics of low noise, good acceleration maneuvering performance, nearly zero carbon emission and relatively low use cost.

In order to ensure the driving mileage of the electric vehicle, enable the electric vehicle to be driven stably and reduce the performance attenuation of a battery system, a thermal management module is often required to be equipped to ensure that each energy component of the electric vehicle is at the optimal working temperature.

Among the correlation technique, often adopt the pipeline to communicate the parts in electronic water pump, a plurality of control valve and each heat transfer circulation system, the electronic water pump during operation can provide required heat transfer medium for each heat transfer circulation system, satisfies each heat transfer circulation system's demand, makes the power battery part during operation heated reliably in microthermal environment to the during operation is dispelled the heat effectively in the environment of high temperature, thereby realizes that the power battery part normally works under reasonable temperature environment.

However, the pipelines in these schemes are too numerous and complex, the operation is complicated when the pipelines of each cooling circulation system are connected with the electronic water pump, the number of control valves is large, the occupied installation volume is large, and the miniaturization design of the whole thermal management module is not facilitated. In addition, the electronic water pump serving as a heart in the thermal management system is usually fixed on a vehicle-related component through a mounting bracket and is fastened by using bolts, so that the mounting process is complex, the efficiency is low, the occupied mounting space is large, the weight of the pump body is heavy, and the cost is high.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. Therefore, the utility model provides a heat management module, heat management module integrates the degree height, each part simple to operate, occupy the installation volume few, solved among the heat management module among the prior art that each part installation is complicated, the pipeline is crisscross, the installation occupation space is big, with high costs technical problem.

The utility model discloses still aim at providing a vehicle that has above-mentioned thermal management module.

According to the utility model discloses heat management module, include: the heat exchanger comprises a collecting plate, a heat exchanger and a heat exchanger, wherein a flow channel for circulating a heat exchange medium is arranged in the collecting plate, and a first connecting part is arranged on the collecting plate; the circulating pump, the circulating pump is equipped with the second connecting portion, first connecting portion with the buckle cooperation of second connecting portion is in order to with the circulating pump is fixed to the cylinder manifold, the circulating pump with at least one the runner cooperation is in order to guide heat transfer medium flows.

According to the utility model discloses heat management module sets up a plurality of heat transfer medium's runner in the cylinder manifold, reduces and arranges the required length of pipeline, and makes things convenient for the pipeline in each heat transfer circulation system to be connected with the circulating pump, and the circulating pump can go into heat transfer medium pump to relevant heat transfer circulation system in the during operation. The circulating pump need not to use the support, and it is fixed that the buckle cooperation is accomplished directly to realize with the cylinder manifold, need not too much space when cylinder manifold and circulating pump installation are fixed, reduces redundant design structures such as installing support, reduces the manufacturing cost of circulating pump, lightens the weight of circulating pump, is favorable to realizing the miniaturization of whole thermal management module, integrates and the lightweight.

According to the utility model discloses heat management module of some embodiments, be equipped with the holding tank on the cylinder manifold, at least a part of circulating pump is located in the holding tank, first connecting portion are located on the inner wall of holding tank.

Optionally, the first connecting portion is a matching groove, the second connecting portion is a protruding portion, and the protruding portion is in clamping fit with the matching groove.

Optionally, the inner wall of holding tank be equipped with the protruding groove of cooperation groove intercommunication in the circumference of holding tank, the stretching into of protruding groove with cooperation groove dislocation set, the bellying stretches into it is rotatory behind the protruding groove the circulating pump and/or the cylinder manifold so that the bellying remove to with cooperation groove cooperation.

According to the utility model discloses further embodiment, the stretching into the groove includes first spout and the second spout that becomes the angle and link to each other, the entry end of first spout is located the axial border of holding tank, the second spout communicates respectively the cooperation groove with first spout.

Advantageously, an end of the second sliding groove, which is far away from the first sliding groove, is connected with an anti-falling protrusion, and the protrusion crosses the anti-falling protrusion to be matched with the matching groove.

According to the utility model discloses further embodiment, be equipped with the spigot surface on the anticreep arch, the spigot surface is followed the second spout towards the direction slope setting in cooperation groove.

Optionally, a connecting cylinder protruding outwards is arranged on the bus board, and the accommodating groove is formed in the connecting cylinder; the first sliding groove extends along the axial direction of the connecting cylinder, and the second sliding groove extends along the circumferential direction of the connecting cylinder.

According to the utility model discloses heat management module of some embodiments, the bellying with the cooperation groove sets up in pairs and is equipped with many right, and is a plurality of the bellying is followed the pump case circumference interval of circulating pump sets up, and is a plurality of the cooperation groove is in the inner wall interval arrangement of holding tank.

Optionally, the circulation pump is fixedly connected with the holding tank.

According to the utility model discloses heat management module of some embodiments, be equipped with a plurality ofly on the cylinder manifold first connecting portion, it is a plurality of the circulating pump is with a plurality of first connecting portion one-to-one assembles.

According to the utility model discloses vehicle, including the thermal management module in aforementioned each example.

According to the utility model discloses vehicle, through setting up aforementioned heat management module, mounting structure is simple, the degree of integrating is high, occupy that installation space is few, installation convenient operation is swift.

Additional aspects and advantages of the invention will be set forth in the description which follows, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic view of a split structure of a bus plate and a circulation pump in a thermal management module according to some embodiments of the present invention.

Fig. 2 is a schematic view of a partially enlarged structure of a region I in fig. 1.

Fig. 3 is a schematic view of a split structure of the cylinder manifold and the circulation pump with connecting cylinders in the thermal management module according to some embodiments of the present invention.

Fig. 4 is a partially enlarged structural view of a region ii in fig. 3.

Fig. 5 is a schematic perspective view of a circulation pump according to some embodiments of the present invention.

Fig. 6 is a schematic perspective view of a connector according to some embodiments of the present invention.

Fig. 7 is a cross-sectional view of a bus plate according to some embodiments of the present invention.

Reference numerals:

1000. a thermal management module;

100. a bus bar; 101. a flow channel;

110. a first connection portion; 111. a mating groove;

120. accommodating grooves;

130. extending into the groove;

131. a first chute; 1311. an inlet end;

132. a second chute; 1321. the anti-drop bulge; 1322. a guide surface;

133. an inlet extension port;

140. a connecting cylinder;

200. a circulation pump; 210. a second connecting portion; 211. a boss portion; 212. and (7) surrounding edges.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are exemplary only for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "length", "upper", "lower", "front", "rear", "top", "bottom", "inner", "outer", "axial", "circumferential", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

The thermal management module 1000 according to the embodiment of the present invention is described below with reference to the drawings, and the thermal management module 1000 of the present invention is convenient to install, high in integration level, and low in production cost.

According to the utility model discloses thermal management module 1000, mainly used carries out fluid distribution or changes in the scene of liquid flow direction, for example can be used to the thermal management cooling circulation system of hydraulic system, air conditioning system and water circulating system, car in distribute and flow direction control the heat transfer medium. The energy management system is used for a vehicle and mainly used for distributing heat exchange energy among a battery, a motor, a power device and a passenger compartment.

As shown in fig. 1 and 3, the thermal management module 1000 includes: a manifold plate 100 and a circulation pump 200.

A flow channel 101 for circulating a heat exchange medium is arranged in the bus board 100 (the structure of the flow channel 101 can be shown in fig. 1, 3 and 7), and the heat exchange medium can be a heat exchange medium with a higher temperature and used for warming and keeping warm for a component to be temperature-regulated; the heat exchange medium with lower temperature can also be used for cooling and radiating the temperature of the part to be regulated. It should be further noted that the bus bar 100 is a plate body with various flow channels 101 formed therein, and is used as a middle bus, flow dividing and transition part; the length of the pipeline of the heat exchange circulation system which needs to be arranged can be saved, and the parts of the pipelines of the plurality of heat exchange circulation systems can be integrally arranged in the confluence plate 100 in the form of the flow channel 101. In addition, a plurality of flow channels 101 are provided in the manifold plate 100 and a plurality of joints are provided in the manifold plate 100. The flow channel 101 may be a single layer or a plurality of layers, and the bus plate 100 may be stacked in a plurality of layers. Manifold board 100 may enable the integration of the pipes and connections within thermal management system 1000 into one board.

Further, the circulation pump 200 cooperates with at least one flow channel 101 to guide the heat exchange medium to flow, that is, when the circulation pump 200 works, the heat exchange medium can be driven to move along the flow channel 101 and be conveyed to a specific heat exchange circulation system to participate in heat exchange.

As shown in fig. 2 and 4, the bus bar 100 is provided with the first connecting portion 110, the circulating pump 200 is provided with the second connecting portion 210, and the first connecting portion 110 and the second connecting portion 210 are in snap fit to fix the circulating pump 200 to the bus bar 100, and herein, the first connecting portion 110 and the second connecting portion 210 form a snap connection when the finally installing and fixing of the circulating pump 200 and the bus bar 100 are completed, so that the assembling and disassembling are convenient.

According to the above structure, the utility model discloses thermal management module 1000 sets up a plurality of heat transfer medium's runner 101 in cylinder manifold 100, reduces and arranges the required length of pipeline, and in pipeline and circulating pump 200's intersection, each pipeline can not crisscross winding, makes things convenient for the pipeline in each heat transfer circulation system to be connected with the circulating pump 200 that corresponds.

The utility model provides a circulating pump 200 need not to use the support, also need not to fasten through the bolt. When first connecting portion 110 and second connecting portion 210 joint target in place, circulating pump 200 then directly accomplishes fixedly with the buckle cooperation of cylinder manifold 100, need not too much space when cylinder manifold 100 is fixed with the installation of circulating pump 200, reduces redundant design structures such as installing support, therefore weight when lightening circulating pump 200 and installing is favorable to realizing the miniaturization of whole thermal management module 1000, integrate and the lightweight.

It can be understood that, compare in the electronic water pump among the prior art and pass through the support mounting fixed, and need adopt fasteners such as bolt to fasten the scheme during the installation, the utility model discloses thermal management module 1000 directly sets up circulating pump 200 on cylinder manifold 100 through the mode integration that the buckle is connected to simplified the structure, reduced the required installation volume of installation fixed circulating pump 200, thereby reduced the installation cost and the installation degree of difficulty, simplified mounting process, improved the installation effectiveness.

Compare in prior art each heat transfer circulation system's pipeline respectively with respective electronic water pump individual adoption pipeline be connected and the pipeline that causes is complicated, the fixed difficulty of electronic water pump, the utility model discloses an integrated runner 101 in the cylinder manifold 100 directly communicate with circulating pump 200, need not to use solitary pipeline to be connected with circulating pump 200, complexity when having simplified circulating pump 200 and tube coupling has promoted assembly efficiency, has promoted thermal management module 1000's miniaturization and integration.

In the description of the present invention, the features defined as "first" and "second" may explicitly or implicitly include one or more of the features for distinguishing between descriptive features, non-sequential, non-trivial and non-trivial.

In some embodiments of the present invention, as shown in fig. 2 and 4, the collecting plate 100 is provided with a holding groove 120, at least a portion of the circulating pump 200 is located in the holding groove 120, and the first connecting portion 110 is located on an inner wall of the holding groove 120. In these examples, the circulation pump 200 is stably mounted in the housing groove 120 by forming the hollow groove on the bus bar 100, and the circulation pump 200 is not easily shaken or skewed with respect to the bus bar 100. And the first connecting part 110 and the second connecting part 210 form a final clamping connection, so that the circulating pump 200 can be stably assembled in the accommodating groove 120.

Alternatively, as shown in fig. 2 and 4, the first connecting portion 110 is a fitting groove 111, the second connecting portion 210 is a protrusion 211, and the protrusion 211 is snap-fitted into the fitting groove 111. In these examples, when the protrusion 211 extends into the fitting groove 111, the protrusion and the groove form a relatively stable snap fit, thereby stabilizing the relative positions of the circulation pump 200 and the groove wall of the receiving groove 120. Then, the circulation pump 200 is not easy to move in multiple directions relative to the manifold plate 100, so that the circulation pump 200 assembled in place is not easy to change positions relative to the manifold plate 100 in the bumping or transportation process, and therefore the circulation pump 200 works stably, and the circulation pump 200 can stably drive the heat exchange medium in the flow channel 101 to flow in a specific direction in work.

Of course, in other examples, the structures of the first connection portion 110 and the second connection portion 210 may not be limited to the structures in the above examples, for example, the first connection portion 110 may be the protrusion 211 and the second connection portion 210 may be the fitting groove 111, and there is no particular limitation. For another example, one of the first connection portion 110 and the second connection portion 210 is a bayonet, and the other is a buckle, and when the buckle is fitted in the bayonet, the buckle forms a snap fit.

Advantageously, as shown in fig. 2 and 4, in order to further improve the efficiency of the engagement between the circulation pump 200 and the holding tank 120, the inner wall of the holding tank 120 is provided with the protrusion groove 130 communicating with the engagement groove 111. The protrusion groove 130 serves to guide the circulation pump 200 to be assembled with the bus bar 100.

Further, in the circumferential direction of the receiving groove 120, the protrusion opening 133 of the protrusion groove 130 is disposed to be offset from the fitting groove 111, so that when the circulation pump 200 enters the fitting groove 111 along the protrusion groove 130, a specific force is applied to smoothly enter the protrusion 211 into the fitting groove 111; the protrusion 211 will not easily reverse from the mating groove 111 back into the protruding groove 130, so that the protrusion 211 can be reliably mated with the mating groove 111.

Specifically, the utility model provides a boss 211 stretches into and stretches into arbitrary one in rotatory circulating pump 200 and the cylinder manifold 100 behind the groove 130 or rotate circulating pump 200 and cylinder manifold 100 in opposite directions simultaneously to make boss 211 move to cooperate with cooperation groove 111, so in these examples, stretch into the mouth 133 and cooperate groove 111 dislocation set to greatly promote the spacing performance of circulating pump 200 and cylinder manifold 100 rotation direction with cooperating groove 111.

Advantageously, the protrusion opening 133 is higher than the bottom of the fitting groove 111 in the height direction of the receiving groove 120, so that when the protrusion 211 falls along the protrusion opening 133 to the bottom of the fitting groove 111, it will not be easy to reversely enter the protrusion groove 130 from the protrusion opening 133 against the gravity of the circulation pump 200 itself only by the vibration force, and the circulation pump 200 can be kept stable even when it vibrates with respect to the bus bar 100.

Alternatively, as shown in fig. 2 and 4, the protrusion groove 130 includes a first slide groove 131 and a second slide groove 132 which are connected at an angle, that is, the protrusion 211 performs a certain direction change while moving in the protrusion groove 130.

Further, the inlet end 1311 of the first sliding groove 131 is located at the axial edge of the accommodating groove 120, and the inlet end 1311 can facilitate a worker to quickly align the protrusion 211 when assembling the circulation pump 200, thereby facilitating the circulation pump 200 to quickly enter the protrusion groove 130 and slide along the protrusion groove 130.

Further, the second slide groove 132 is communicated with the engaging groove 111 and the first slide groove 131, respectively, and the end of the second slide groove 132 forms an extending opening 133 communicated with the engaging groove 111.

Therefore, in the above example, the protrusion 211 can enter the first sliding groove 131 from the edge of the receiving groove 120 along the axial direction of the receiving groove 120 and enter the second sliding groove 132 under the guidance of the first sliding groove 131, and the protrusion 211 changes the moving track in the second sliding groove 132, so that the protrusion 211 can further move into the mating groove 111 along the second sliding groove 132. Because first spout 131 and second spout 132 extend along equidirectional not, so the utility model discloses a position that sets up of cooperation groove 111 will be more nimble, and the removal route of bellying 211 in stretching into groove 130 is longer, makes bellying 211 more difficult follow cooperation groove 111 and reverse enter into and stretch into groove 130 and deviate from holding tank 120, makes bellying 211 form circumference spacing and axial spacing for cooperation groove 111.

Alternatively, the angle between the first and second slide grooves 131 and 132 may be an acute angle, a right angle, or an obtuse angle. For example, in the specific example, the receiving groove 120 is a concave cylindrical groove body, the first slide groove 131 extends in the axial direction of the receiving groove 120, the second slide groove 132 extends in the circumferential direction of the receiving groove 120, and the engaging groove 111 is disposed at the circumferential end of the second slide groove 132 in a staggered manner, while the first slide groove 131 and the second slide groove 132 are disposed at 90 degrees. When the circulation pump 200 is assembled, the circulation pump 200 slides inward along the axial direction of the accommodating groove 120, and then enters the fitting groove 111 along the circumferential rotation of the accommodating groove 120, so that the circulation pump 200 can extend into the accommodating groove 120 to a certain depth, and the circulation pump 200 can be guided to the fitting groove 111 on the inner wall of the accommodating groove 120 more quickly.

Alternatively, as shown in fig. 2 and 4, an anti-slip projection 1321 is connected to an end of the second chute 132 away from the first chute 131, and the protrusion 211 is engaged with the engagement groove 111 over the anti-slip projection 1321. The retaining protrusion 1321 here blocks the path of the fitting groove 111 to the projecting groove 130, and makes it difficult for the protrusion 211 entering into the fitting groove 111 to return to the second chute 132 across the retaining protrusion 1321, so that the protrusion 211 can be stably fitted into the fitting groove 111.

Advantageously, as shown in fig. 2 and 4, the retaining projection 1321 is provided with a guide surface 1322, the guide surface 1322 is inclined from the second slide groove 132 toward the fitting groove 111, and the guide surface 1322 facilitates smooth entry of the protruding portion 211 into the fitting groove 111, and the protruding portion 211 is not jammed during the assembling process.

The utility model discloses in the setting of the protruding 1321 of above-mentioned anticreep and spigot surface 1322 also makes the utility model provides an it further forms dislocation set with cooperation groove 111 to stretch into mouthful 133, and the cross-sectional width size that just stretches into mouthful 133 is less than the cross-sectional width size of second spout 132, stretches into mouthful 133 department and forms the neck throat.

In some embodiments of the present invention, as shown in fig. 3 and 4, the bus board 100 is provided with a connecting cylinder 140 protruding outward, and the receiving groove 120 is formed in the connecting cylinder 140. The connecting cylinder 140 has a certain axial height, which is more suitable for the installation of a large-sized circulating pump 200, so that the space in the bus board 100 where the flow channel 101 can be arranged is more sufficient. The connecting cylinder 140 of the present invention can also protect the circulating pump 200, and effectively prevent the circulating pump 200 from being impacted. The connection cylinder 140 also ensures the sealing property of the connection between the circulation pump 200 and the bus bar 100.

Further, as shown in fig. 4 and 6, the first slide groove 131 extends in the axial direction of the connecting cylinder 140, and the second slide groove 132 extends in the circumferential direction of the connecting cylinder 140, so that the circulation pump 200 can move in the circumferential direction after moving in the axial direction relative to the manifold plate 100 to complete the engagement.

Optionally, the utility model discloses a connecting cylinder 140 and cylinder manifold 100 integrated into one piece to expanded the space of cylinder manifold 100, promoted the convenience of cylinder manifold 100 with the assembly of circulating pump 200.

Advantageously, the accommodating groove 120 is provided therein with a rib, the upper portion of which is provided with the fitting groove 111 and the protrusion groove 130; as shown in fig. 5, a circle of surrounding edge 212 is provided in the circumferential direction of the pump case of the circulation pump 200, the surrounding edge 212 is further provided in the circumferential direction with a protrusion 211, and when the protrusion 211 is fitted into the fitting groove 111, the surrounding edge 212 contacts the upper surface of the rib, thereby facilitating the stable arrangement of the circulation pump 200 and improving the sealing performance after the circulation pump 200 is fitted.

Alternatively, as shown in fig. 2, 4 and 5, the protrusions 211 are provided in pairs with the fitting grooves 111 and provided in a plurality of pairs, the plurality of protrusions 211 are provided at intervals in the circumferential direction of the pump housing of the circulation pump 200, and the plurality of fitting grooves 111 are arranged at intervals in the inner wall of the accommodation groove 120. Then in these examples, when circulating pump 200 assembles towards cylinder manifold 100, each bellying 211 will cooperate with the cooperation groove 111 that matches with it, make circulating pump 200 form the buckle connection in many places for holding tank 120, finally realize circulating pump 200 and relative with cylinder manifold 100 in the spacing cooperation in many places, circulating pump 200 is more stable in position after the assembly is accomplished, difficult emergence is rocked, and set up the position at cooperation groove 111 when reasonable, the holistic levelness of circulating pump 200 is high after the assembly is accomplished, difficult rocking when circulating pump 200 pump heat transfer medium.

In the description of the present invention, "a plurality" means two or more unless otherwise specified.

Advantageously, the plurality of protrusions 211 are uniformly distributed along the circumferential direction of the circulation pump 200, and accordingly, the plurality of fitting grooves 111 are uniformly distributed along the circumferential direction of the accommodation groove 120. The uniformity of the force between the circulation pump 200 and the bus plate 100 is improved.

Optionally, the circulation pump 200 is fixedly connected to the accommodating tank 120, for example, by welding or bonding, so that the circulation pump 200 and the accommodating tank 120 are tightly fitted and structurally stable. In the previous examples with the connecting cylinder 140, the circulation pump 200 is integrally connected with the connecting cylinder 140, and in these examples, after the first connecting portion 110 is snap-fitted with the second connecting portion 210, the circulation pump 200 and the connecting cylinder 140 will form a more stable structure by welding, and the circulation pump 200 and the connecting cylinder 140 are tightly fitted.

The utility model discloses an in some embodiments, as shown in fig. 1 and fig. 3, be equipped with a plurality of first connecting portion 110 on the cylinder manifold 100, a plurality of circulating pumps 200 and a plurality of first connecting portion 110 one-to-one assembly, so can integrate a plurality of circulating pumps 200 on the cylinder manifold 100 simultaneously, each circulating pump 200 can be connected to different heat transfer circulation system to make the heat management module 1000 integrate the degree height, effectively solve circulating pump 200 and the complicated, the difficult problem of installation of the wrong complicated with the pipeline on the heat transfer circulation system of difference.

Optionally, as shown in fig. 7, the flow channel 101 on the junction plate 100 may be a liquid inlet flow channel communicated with the circulation pump 200, or may be a liquid outlet flow channel communicated with the circulation pump 200, and the liquid inlet flow channel and the liquid outlet flow channel are staggered and do not interfere with each other, so that the pipeline of each heat exchange circulation system does not need to be separately connected with the circulation pump 200, and the interface connection on the junction plate 100 is favorable for the arrangement of the pipeline of each heat exchange circulation system, and the pipeline is not staggered and is convenient to install.

Advantageously, the liquid inlet and the liquid outlet of the circulation pump 200 are disposed on the same side, and the liquid inlet is located in the axial direction of the circulation pump 200, and the liquid outlet is disposed in the radial direction of the circulation pump 200, so that when the circulation pump 200 is assembled into the accommodation groove 120, the liquid inlet and the liquid outlet of the circulation pump 200 can be respectively communicated with the liquid inlet flow passage and the liquid outlet flow passage in the confluence plate 100.

The utility model discloses an in some embodiments, can also integrate on the cylinder manifold 100 and set up the valve body and distribute heat transfer medium and carry different heat transfer circulation system with heat transfer medium.

The vehicle of the embodiment of the present invention is described below with reference to the drawings of the specification.

According to the utility model discloses a vehicle, including the thermal management module 1000 in aforementioned each example, the structure of thermal management module 1000 is not repeated here.

According to the structure, the vehicle provided by the embodiment of the utility model has the advantages that the installation and connection are simple, the integration degree is high, the occupied installation space is small, and the installation operation is convenient and rapid by arranging the thermal management module 1000; circulating pumps 200 corresponding to a plurality of heat exchange circulating systems can be integrated on the bus board 100, and the installation and the control are convenient.

Optionally, the vehicle is mainly a new energy vehicle, and the new energy vehicle includes a pure electric vehicle, an extended range electric vehicle, a hybrid electric vehicle, and a fuel cell electric vehicle.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Three protrusions 211 and three mating grooves 111, and four circulation pumps 200 are shown in fig. 3 for illustrative purposes, but it is obvious to those skilled in the art after reading the above technical solutions that the solution can be applied to other numbers of protrusions 211 and mating grooves 111, and other numbers of circulation pumps 200, and this also falls within the protection scope of the present invention.

The cooling and heat dissipation of the various components of the heat exchange cycle system, the filled heat exchange medium, and the components to be heat exchanged in the heat management module 1000 and the vehicle having the same according to the embodiments of the present invention are known to those skilled in the art and will not be described in detail herein.

In the description herein, references to the description of the terms "embodiment," "example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (12)

1. A thermal management module, comprising:

the heat exchanger comprises a collecting plate, a heat exchanger and a heat exchanger, wherein a flow channel for circulating a heat exchange medium is arranged in the collecting plate, and a first connecting part is arranged on the collecting plate;

the circulating pump, the circulating pump is equipped with the second connecting portion, first connecting portion with the buckle cooperation of second connecting portion is in order to with the circulating pump is fixed to the cylinder manifold, the circulating pump with at least one the runner cooperation is in order to guide heat transfer medium flows.

2. The thermal management module of claim 1, wherein the manifold plate defines a receiving cavity, at least a portion of the circulating pump is positioned within the receiving cavity, and the first connecting portion is positioned on an inner wall of the receiving cavity.

3. The thermal management module of claim 2, wherein the first connection portion is a mating slot and the second connection portion is a protrusion that snap fits into the mating slot.

4. The thermal management module according to claim 3, wherein an extension groove communicated with the matching groove is formed in the inner wall of the accommodating groove, an extension opening of the extension groove is arranged in a staggered mode with the matching groove in the circumferential direction of the accommodating groove, and the protrusion portion extends into the extension groove and then rotates the circulating pump and/or the bus plate to enable the protrusion portion to move to be matched with the matching groove.

5. The thermal management module of claim 4, wherein the extended slot comprises a first runner and a second runner connected at an angle, an inlet end of the first runner being located at an axial edge of the receiving slot, the second runner communicating with the mating slot and the first runner, respectively.

6. The thermal management module of claim 5, wherein an end of the second runner remote from the first runner has an anti-slip projection attached thereto, the projection engaging the mating groove over the anti-slip projection.

7. The thermal management module of claim 6, wherein the anti-slip protrusion is provided with a guide surface, and the guide surface is inclined from the second sliding groove to the direction of the matching groove.

8. The thermal management module of claim 5, wherein the bus plate has outwardly projecting connector barrels formed therein, the receiver slots being formed in the connector barrels; the first sliding groove extends along the axial direction of the connecting cylinder, and the second sliding groove extends along the circumferential direction of the connecting cylinder.

9. The thermal management module of claim 3, wherein the protrusions and the mating grooves are provided in pairs, and a plurality of pairs are provided, the plurality of protrusions are provided at intervals along a circumferential direction of a pump casing of the circulation pump, and the plurality of mating grooves are provided at intervals on an inner wall of the receiving groove.

10. The thermal management module of claim 2, wherein the circulation pump is fixedly connected to the receiving tank.

11. The thermal management module of claim 1, wherein a plurality of the first connecting portions are provided on the manifold plate, and a plurality of the circulation pumps are assembled in one-to-one correspondence with the plurality of the first connecting portions.

12. A vehicle comprising a thermal management module according to any of claims 1-11.

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