阅读说明：本技术 一种多通阀 (Multi-way valve ) 是由 林炳荣 许俊波 李贵宾 薛强 戴海江 于 2021-09-27 设计创作，主要内容包括：本发明涉及控制阀技术领域,尤其涉及一种多通阀。用于解决三通比例阀和两通比例阀需要两个驱动装置控制,所占空间较大,控制复杂且成本较高的问题。驱动装置与第一阀芯传动连接,第一阀芯上设置有第一配合结构,第二阀芯上设置有与第一配合结构相配合的第二配合结构,第一配合状态时,第一阀芯独立转动,第二阀芯保持不变；在第二配合状态时,第一阀芯带动第二阀芯同步转动。第一阀芯既可以独立转动,调节第一阀口的流量,也可以在转动时带动第二阀芯转动,调节第二阀口的流量,在调整完成后,第一阀芯再转动至原位,不改变第一阀口的流量。这样,只需要一个驱动装置就可以驱动控制第一阀芯和第二阀芯,控制简单、结构紧凑且成本较低。(The invention relates to the technical field of control valves, in particular to a multi-way valve. The control device is used for solving the problems that a three-way proportional valve and a two-way proportional valve need to be controlled by two driving devices, the occupied space is large, the control is complex and the cost is high. The driving device is in transmission connection with the first valve core, a first matching structure is arranged on the first valve core, a second matching structure matched with the first matching structure is arranged on the second valve core, and when the first matching structure is in a first matching state, the first valve core independently rotates and the second valve core keeps unchanged; and in the second matching state, the first valve core drives the second valve core to synchronously rotate. The first valve core can rotate independently to adjust the flow of the first valve port, and can also drive the second valve core to rotate when rotating to adjust the flow of the second valve port. Therefore, only one driving device is needed to drive and control the first valve core and the second valve core, and the valve is simple to control, compact in structure and low in cost.)

1. A multi-way valve is characterized by comprising a valve seat, a first valve core, a second valve core and a driving device;

the driving device is in transmission connection with the first valve core;

the first valve core is provided with a first matching structure, the second valve core is provided with a second matching structure matched with the first matching structure, the first matching structure and the second matching structure have a first matching state and a second matching state, the first valve core independently rotates in the first matching state, the second valve core keeps still, and the first valve core drives the second valve core to synchronously rotate in the second matching state;

the valve seat is provided with a plurality of first valve ports corresponding to the first valve core, the first valve core is provided with a first conduction structure, and the first conduction structure is used for communicating at least two first valve ports when the first valve core rotates to a first preset position;

the valve seat is provided with a plurality of second valve ports corresponding to the second valve core, the second valve core is provided with a second conducting structure, and the second conducting structure is used for communicating at least two second valve ports when the second valve core rotates to a second preset position.

2. The multi-way valve of claim 1, wherein the first mating structure comprises a raised structure disposed on a first end surface of the first valve spool, the second mating structure comprises a recessed structure disposed on a second end surface of the second valve spool, the first end surface is disposed opposite the second end surface, and at least a portion of the raised structure is disposed within the recessed structure;

the groove structure is characterized in that a first protruding portion is arranged on the side wall of the groove structure and comprises a first end face and a second end face which are arranged at intervals in the circumferential direction, the protruding structure is not in contact with the first end face and the second end face in the first matching state, and the protruding structure is abutted to the first end face or the second end face in the second matching state.

3. The multi-way valve of claim 2, wherein the sidewall of the groove arrangement includes a first cylindrical surface, the first boss being disposed on the first cylindrical surface;

the protruding structure comprises a first column body and a second protruding part formed by protruding the outer peripheral surface of the first column body to the radial outer side, the outer side surface of the first column body is positioned at the radial inner side of the first protruding part, and two end surfaces of the second protruding part in the circumferential direction respectively form a first side surface and a second side surface;

the outer peripheral surface of the second boss comprises a second cylindrical surface, and the second cylindrical surface is matched with the first cylindrical surface.

4. The multi-way valve of claim 3, wherein the first raised portion comprises a third cylindrical surface disposed radially inward, and the outer peripheral surface of the first post comprises a fourth cylindrical surface, the third cylindrical surface conforming to the fourth cylindrical surface.

5. The multi-way valve of claim 3, wherein the raised structure comprises a second post disposed on the first end surface of the first valve spool and connected to the first post.

6. The multi-way valve of claim 5, wherein the secondary post is cylindrical and has a diameter that is the same as the diameter of the secondary cylindrical surface.

7. The multi-way valve of any one of claims 1 to 6, wherein the first communication structure comprises a first groove disposed on an outer peripheral surface of the first valve spool and extending circumferentially;

the second conduction structure comprises a second groove which is arranged on the outer peripheral surface of the second valve core and extends along the circumferential direction.

8. The multi-way valve according to claim 7, wherein the valve seat is provided with three first valve ports, and the angle occupied by the three first valve ports is smaller than or equal to the angle occupied by the first groove in the circumferential direction; and/or the presence of a gas in the gas,

the valve seat is provided with two second valve ports, and the angle occupied by the two second valve ports is smaller than or equal to the angle occupied by the second groove in the circumferential direction.

9. The multi-way valve of claim 8, wherein each of the first ports is connected to the first valve element through a first passage, and each of the second ports is connected to the second valve element through a second passage, and the first port and the second port are disposed on the same side of the valve seat.

10. The multi-way valve according to any one of claims 1 to 6, wherein the drive means comprises an electric motor and a gear train in driving connection with the electric motor, the gear train being in driving connection with the first valve spool.

Technical Field

The invention relates to the technical field of control valves, in particular to a multi-way valve.

Background

In order to increase the driving range of the electric vehicle, various modes such as heating the battery by the coolant electric heater, dissipating heat of the battery and the driving system through the radiator, and heating the battery by using waste heat of the driving system need to be realized.

In the existing cooling liquid loop of the thermal management system, a single proportional valve cannot realize the multiple modes, but a combination of multiple proportional valves such as a three-way proportional valve, a two-way proportional valve and the like is needed to realize the multiple modes.

In the prior art, the three-way proportional valve and the two-way proportional valve need to be controlled by two driving devices, so that the occupied space is large, the control is complex and the cost is high.

Disclosure of Invention

In view of the above problems, embodiments of the present invention provide a multi-way valve, which is simple to control, compact in structure, and low in cost.

In order to achieve the above object, the embodiments of the present invention provide the following technical solutions: the embodiment of the invention provides a multi-way valve which comprises a valve seat, a first valve core, a second valve core and a driving device, wherein the first valve core is arranged on the valve seat; the driving device is in transmission connection with the first valve core; the first valve core is provided with a first matching structure, the second valve core is provided with a second matching structure matched with the first matching structure, the first matching structure and the second matching structure have a first matching state and a second matching state, the first valve core independently rotates in the first matching state, the second valve core keeps still, and the first valve core drives the second valve core to synchronously rotate in the second matching state; the valve seat is provided with a plurality of first valve ports corresponding to the first valve core, the first valve core is provided with a first conduction structure, and the first conduction structure is used for communicating at least two first valve ports when the first valve core rotates to a first preset position. The valve seat is provided with a plurality of second valve ports corresponding to the second valve core, the second valve core is provided with a second conducting structure, and the second conducting structure is used for communicating at least two second valve ports when the second valve core rotates to a second preset position.

Compared with the prior art, the multi-way valve provided by the embodiment of the invention has the following advantages:

the driving device is in transmission connection with the first valve core, a first matching structure is arranged on the first valve core, a second matching structure matched with the first matching structure is arranged on the second valve core, the first matching structure and the second matching structure have a first matching state and a second matching state, when in the first matching state, the first valve core independently rotates, and the second valve core is kept unchanged; and in the second matching state, the first valve core drives the second valve core to synchronously rotate. Therefore, the first valve core can rotate independently, and the flow of the first valve port is adjusted by changing the relative angle between the first valve port and the first conduction structure. The first valve core drives the second valve core to rotate when rotating, the flow of the second valve port is adjusted by changing the relative angle between the second valve port and the second conduction structure, and after the adjustment is completed, the first valve core rotates to the original position again without changing the flow of the first valve port. Therefore, only one driving device is needed to drive and control the first valve core and the second valve core, and the valve is simple to control, compact in structure and low in cost.

As an improvement of the multi-way valve according to the embodiment of the present invention, the first mating structure includes a protrusion structure disposed on a first end surface of the first valve core, the second mating structure includes a groove structure disposed on a second end surface of the second valve core, the first end surface and the second end surface are disposed opposite to each other, and at least a part of the protrusion structure is located in the groove structure; the groove structure is characterized in that a first protruding portion is arranged on the side wall of the groove structure and comprises a first end face and a second end face which are arranged at intervals in the circumferential direction, the protruding structure is not in contact with the first end face and the second end face in the first matching state, and the protruding structure is abutted to the first end face or the second end face in the second matching state.

As a further improvement of the multi-way valve according to the embodiment of the present invention, the sidewall of the groove structure includes a first cylindrical surface, and the first protruding portion is disposed on the first cylindrical surface; the protruding structure comprises a first column body and a second protruding part formed by protruding the outer peripheral surface of the first column body to the radial outer side, the outer side surface of the first column body is positioned at the radial inner side of the first protruding part, and two end surfaces of the second protruding part in the circumferential direction respectively form a first side surface and a second side surface; the outer peripheral surface of the second boss comprises a second cylindrical surface, and the second cylindrical surface is matched with the first cylindrical surface.

As a further improvement of the multi-way valve according to the embodiment of the present invention, the first protruding portion includes a third cylindrical surface disposed on a radially inner side, an outer circumferential surface of the first cylinder includes a fourth cylindrical surface, and the third cylindrical surface is fitted with the fourth cylindrical surface.

As a further improvement of the multi-way valve according to the embodiment of the present invention, the protrusion structure includes a second cylinder disposed on the first end surface of the first valve core and connected to the first cylinder.

As a further improvement of the multi-way valve in the embodiment of the invention, the second cylinder is a cylinder, and the diameter of the second cylinder is the same as that of the second cylindrical surface.

As a further improvement of the multi-way valve according to the embodiment of the present invention, the first conducting structure includes a first groove that is provided on an outer peripheral surface of the first valve element and extends in a circumferential direction. The second conduction structure comprises a second groove which is arranged on the outer peripheral surface of the second valve core and extends along the circumferential direction.

As a further improvement of the multi-way valve in the embodiment of the invention, the valve seat is provided with three first valve ports, and in the circumferential direction, the angle occupied by the three first valve ports is smaller than or equal to the angle occupied by the first groove; and/or the valve seat is provided with two second valve ports, and the angle occupied by the two second valve ports is smaller than or equal to the angle occupied by the second groove in the circumferential direction.

As a further improvement of the multi-way valve according to the embodiment of the invention, each first valve port is connected to the first valve core through a first passage, each second valve port is connected to the second valve core through a second passage, and the first valve port and the second valve port are disposed on the same side of the valve seat.

As a further improvement of the multi-way valve according to the embodiment of the present invention, the driving device includes a motor and a gear set in transmission connection with the motor, and the gear set is in transmission connection with the first valve core.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and those skilled in the art can also obtain other drawings according to the drawings without creative efforts.

FIG. 1 is a schematic diagram of a multi-way valve according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a first valve cartridge provided in an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a second valve cartridge provided in an embodiment of the present invention;

FIG. 4 is a schematic diagram of the flow path of a second valve spool according to an embodiment of the present invention;

fig. 5 is a schematic view of a flow path of the first valve element according to an embodiment of the present invention.

Description of reference numerals:

100: a multi-way valve; 10: a first valve spool; 11: a raised structure; 111: a first side surface; 112: a second side surface; 113: a second cylindrical surface; 114: a fourth cylindrical surface; 12: a first column; 13: a second cylinder; 14: a spline shaft; 15: a first groove; 20: a second valve core; 21: a groove structure; 211: a first cylindrical surface; 212: a first end face; 213: a second end face; 214: a third cylindrical surface; 22: a second groove; 30: a motor; 31: a worm; 32: a first turbine; 33: a second turbine; 34: a third turbine; 35: a first gear; 36: a second gear.

Detailed Description

In order to increase the driving range of the electric vehicle, various modes such as heating the battery by the coolant electric heater, dissipating heat of the battery and the driving system through the radiator, and heating the battery by using waste heat of the driving system need to be realized. In order to improve the endurance mileage of an electric vehicle, a single proportional valve cannot realize the multiple modes, but a combination of multiple proportional valves such as a three-way proportional valve and a two-way proportional valve is required to realize the multiple modes. In the prior art, the three-way proportional valve and the two-way proportional valve need to be controlled by two driving devices, so that the occupied space is large, the control is complex and the cost is high.

In order to solve the above problems, the present invention provides a multi-way valve, wherein a driving device is in transmission connection with a first valve core, the first valve core is provided with a first matching structure, a second valve core is provided with a second matching structure matched with the first matching structure, and the first matching structure and the second matching structure are designed such that the first valve core can adjust the flow rate of a first valve port by changing the relative angle between the first valve port and a first conduction structure when the first valve core rotates alone. The first valve core drives the second valve core to rotate when rotating, the flow of the second valve port is adjusted by changing the relative angle between the second valve port and the second conduction structure, and after the adjustment is completed, the first valve core rotates to the original position again without changing the flow of the first valve port. Therefore, only one driving device is needed to drive and control the first valve core and the second valve core, and the valve is simple to control, compact in structure and low in cost.

In order to make the aforementioned objects, features and advantages of the embodiments of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. It is to be understood that the described embodiments are merely a few embodiments of the invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

A multi-way valve according to an embodiment of the invention is described below with reference to the accompanying drawings.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a multi-way valve according to an embodiment of the present invention. The multi-way valve 100 comprises a valve seat, a first valve core 10, a second valve core 20 and a driving device. The driving device is in transmission connection with the first valve core 10; the first valve core 10 is provided with a first matching structure, the second valve core 20 is provided with a second matching structure matched with the first matching structure, the first matching structure and the second matching structure have a first matching state and a second matching state, the first valve core 10 independently rotates in the first matching state, the second valve core 20 keeps still, and in the second matching state, the first valve core 10 drives the second valve core 20 to synchronously rotate.

A plurality of first valve ports corresponding to the first valve core 10 are arranged on the valve seat, a first conduction structure is arranged on the first valve core 10, and the first conduction structure is used for communicating at least two first valve ports when the first valve core 10 rotates to a first preset position; the valve seat is provided with a plurality of second valve ports corresponding to the second valve core 20, and the second valve core is provided with a second conducting structure which is used for communicating at least two second valve ports when the second valve core 20 rotates to a second preset position.

The driving device is in transmission connection with the first valve core 10, and when the first valve core 10 rotates, the first matching structure on the first valve core 10 can drive the second valve core 20 to rotate through the second matching structure. Thus, the first valve core 10 can rotate independently, and the flow rate of the first valve core 10 can be adjusted by changing the corresponding angle between the first valve port and the first conducting structure. When the first valve core 10 rotates, the second valve core 20 is driven to rotate, the flow rate of the second valve core 20 is adjusted by changing the corresponding angle between the second valve port and the second conduction structure, and the first valve core 10 rotates to the original position again without changing the flow rate of the first valve core 10. The first valve core 10 and the second valve core 20 can be driven and controlled by only one driving device, and the control is simple, compact and low in cost.

The first matching structure and the second matching structure can be set to be any structures meeting the requirements, in an alternative embodiment, referring to fig. 2 and 3, fig. 2 is a structural schematic diagram of a first valve core provided by an embodiment of the invention; fig. 3 is a schematic structural diagram of a second valve core according to an embodiment of the present invention. The first matching structure comprises a protruding structure 11 arranged on the first end surface 212 of the first valve core 10, the second matching structure comprises a groove structure 21 arranged on the second end surface 213 of the second valve core 20, the first end surface 212 and the second end surface 213 of the first valve core 10 are arranged oppositely, and at least part of the protruding structure 11 is positioned in the groove structure 21.

In an alternative embodiment, the side wall of the groove structure 21 is provided with a first protrusion, the first protrusion includes a first end surface 212 and a second end surface 213 that are circumferentially spaced, in the first mating state, the protrusion 11 does not contact with the first end surface 212 and the second end surface 213, and the first valve core 10 can rotate independently in the groove structure. In the second matching state, the protrusion 11 abuts against the first end surface 212 or the second end surface 213, so that the first valve core 10 drives the second valve core 20 to rotate synchronously, and the first end surface 212 and the second end surface 213 are arranged, thereby better realizing the first matching state and the second matching state.

The outer peripheral surface of the protruding structure 11 includes a first side surface 111 and a second side surface 112 arranged at intervals in the circumferential direction, the sidewall of the groove structure 21 is provided with a first protruding portion, and the first protruding portion includes a first end surface 212 and a second end surface 213 arranged at intervals in the circumferential direction; when the protruding structure 11 rotates along the first direction until the first side surface 111 abuts against the first end surface 212, the second valve core 20 can be driven to rotate along the first direction synchronously with the first valve core 10; when the protruding structure 11 rotates along the second direction until the second side surface 112 abuts against the second end surface 213, the second valve core 20 can be driven to rotate along the second direction synchronously with the first valve core 10. When the first valve core 10 drives the second valve core 20 to rotate, the protrusion structures 11 and the groove structures 21 can be better matched.

Preferably, the side wall of the groove structure 21 comprises a first cylindrical surface 211, and the first convex portion is disposed on the first cylindrical surface 211. The protruding structure 11 includes a first column 12 and a second protruding portion formed by protruding the outer peripheral surface of the first column 12 to the radial outside, the outer side surface of the first column 12 is located at the radial inside of the first protruding portion, and two end surfaces of the second protruding portion in the circumferential direction respectively form a first side surface 111 and a second side surface 112; the outer peripheral surface of the second boss includes a second cylindrical surface 113, and the second cylindrical surface 113 is fitted to the first cylindrical surface 211. The second protruding structure 11 is arranged on the protruding structure 11, so that axial force is better transmitted to the second valve core 20 when the first valve core 10 rotates, and force application is facilitated.

Further preferably, the first protruding portion includes a third cylindrical surface 214 disposed at the radially inner side, the outer peripheral surface of the first cylinder 12 includes a fourth cylindrical surface 114, and the third cylindrical surface 214 is matched with the fourth cylindrical surface 114. The design ensures the smoothness of rotation when the first valve core 10 drives the second valve core 20 to rotate.

In an alternative embodiment, the protrusion 11 includes a second cylinder 13 disposed on the first end surface 212 of the first valve core 10 and connected to the first cylinder 12. The second cylinder 13 keeps the first valve core 10 and the second valve core 20 at a certain distance, so that the contact area is reduced, and when the first valve core 10 rotates, the friction resistance is reduced, and the transmission efficiency is improved.

Preferably, in order to further improve the transmission efficiency, a first circular hole is formed in the center of the protrusion structure 11 of the first valve core 10, a second circular hole is formed in the center of the groove structure 21 of the second valve core 20, and the transmission shaft is connected with the first circular hole and the second circular hole, so that when the first valve core 10 drives the second valve core 20 to rotate, the friction resistance is reduced, and the transmission efficiency is improved.

The shape of the second cylinder 13 may be a square cylinder or a cylinder, and for convenience of processing, the second cylinder 13 is preferably a cylinder. The diameter of the second cylinder 13 is the same as that of the second cylindrical surface 113, so that the bottom surface of the second cylinder 13 is relatively prevented from contacting the second spool 20, and the frictional resistance is reduced.

The first direction is a direction in which the first side surface 111 of the first valve body 10 rotates toward the first end surface 212 of the second valve body 20; the second direction is a direction in which the second side surface 112 of the first valve spool 10 rotates toward the second end surface 213 of the second valve spool 20.

When the first valve core 10 drives the second valve core 20 to rotate synchronously, there are two situations. In the first condition, when the protrusion structure 11 of the first valve core 10 rotates along the first direction until the first side surface 111 abuts against the first end surface 212, the second valve core 20 can be driven to rotate along the first direction synchronously with the first valve core 10; in the second situation, when the protrusion 11 of the first valve core 10 rotates along the second direction until the second side surface 112 abuts against the second end surface 213, the second valve core 20 can be driven to rotate along the second direction synchronously with the first valve core 10.

When the first spool 10 is rotated alone, there are two cases. In the first case, when the projection 11 of the first valve body 10 abuts the first end surface 212 from the first side surface 111 and rotates in the second direction until the second side surface 112 abuts the second end surface 213, the first valve body 10 rotates alone, and the second valve body 20 remains as it is. In the second case, the convex structure of the first valve body 10 abuts against the second end surface 213 from the second side surface 112, and when the first side surface 111 abuts against the first end surface 212 after rotating in the first direction, the first valve body 10 is rotated alone, and the second valve body 20 is kept as it is.

In order to realize the connection of the pipeline channel, a plurality of first valve ports corresponding to the first valve core 10 are arranged on the valve seat, a first conduction structure is arranged on the first valve core 10, and the first conduction structure is used for communicating at least two first valve ports when the first valve core 10 rotates to a first preset position; the valve seat is provided with a plurality of second valve ports corresponding to the second valve core 20, and the second valve core is provided with a second conducting structure which is used for communicating at least two second valve ports when the second valve core 20 rotates to a second preset position. The first valve spool 10 and the second valve spool 200 are respectively provided with a first conduction structure and a second conduction structure, which respectively realize the communication between the plurality of first ports and the plurality of second ports. The first and second conduction structures are provided to make the multi-way valve 100 more compact and reduce space.

The first conducting structure and the second conducting structure may be any structures capable of meeting the requirement, and for convenience of processing, in an alternative embodiment, the first conducting structure includes a first groove 15 that is disposed on the outer circumferential surface of the first valve core 10 and extends along the circumferential direction; the second communication structure includes a second groove 22 provided on an outer circumferential surface of the second spool 20 and extending in the circumferential direction.

The valve seat is provided with a plurality of first valve ports corresponding to the first valve core 10, in a specific embodiment, the valve seat is provided with three first valve ports, and in the circumferential direction, the angle occupied by the three first valve ports is smaller than or equal to the angle occupied by the first groove 15, so that the three first valve ports can be communicated and closed.

The valve seat is provided with a plurality of second valve ports corresponding to the second valve core 20, the valve seat is provided with two second valve ports, and the angle occupied by the two second valve ports is smaller than or equal to the angle occupied by the second groove 22 in the circumferential direction, so that the two second valve ports can be communicated and closed.

In an alternative embodiment, each first valve port is connected to the first valve core 10 through a first passage, and each second valve port is connected to the second valve core 20 through a second passage, and the first valve port and the second valve port are disposed on the same side of the valve seat. The first valve port and the second valve port are arranged on the same side of the valve seat in a centralized mode, so that the pipeline arrangement is facilitated, and the space is reduced.

In an alternative embodiment, the first channels are a channel, b channel and c channel, respectively, the a channel is an inlet channel, the b channel and c channel are outlet channels, and the b channel is located between the a channel and the c channel. The included angle between the first channels is not limited, and in order to avoid interference of the three first channels, the included angle between the three first channels is 90 degrees; the second channel is the e passageway and the f passageway respectively, and the contained angle between two second passageways is 90 degrees.

Referring to fig. 4 and 5, fig. 4 is a schematic view illustrating a flow path of a second valve element according to an embodiment of the present invention; fig. 5 is a schematic view of a flow path of the first valve element according to an embodiment of the present invention. The first valve core 10 is matched with a valve seat to be equivalent to a three-way proportional valve, the second valve core 20 is matched with the valve seat to be equivalent to a two-way proportional valve, and as shown in fig. 4 and 5, the first valve core 10 has the functions of a channel inlet and b channel outlet; or a channel is in, and c channel is out; the functions to be performed by the second spool 20 are e-channel in and f-channel out. The multi-way valve 100 achieves the functions of a three-way proportional valve and a two-way proportional valve, achieves the purpose of five channels through one driving device, and is highly integrated and compact in arrangement.

Preferably, the a-channel, the b-channel, and the c-channel of the first spool 10, and the e-channel and the f-channel of the second spool 20 are collectively disposed on one mounting surface of the valve seat, which is aesthetically pleasing and reduces space.

The angles occupied by the three first valve ports are smaller than or equal to the angle occupied by the first groove 15, and the angles occupied by the two second valve ports are smaller than or equal to the angle occupied by the second groove 22, preferably, the angle occupied by the first groove 15 is 180 degrees, and the angle occupied by the second groove 22 is 180 degrees.

In the initial state, the first side surface 111 of the first valve spool 10 abuts against the first end surface 212 of the second valve spool 20, the a-channel and the c-channel are located at the first groove 15, the b-channel is located on the outer peripheral surface of the first valve spool 10, the b-channel is blocked by the first valve spool 10, and the a-channel and the c-channel are communicated. The e-channel is located on the outer circumferential surface of the second spool 20, the second spool 20 blocks the e-channel, the f-channel is located at the second groove 22, and the e-channel and the f-channel are in a closed state.

In the second state, on the basis of the initial state, when the first valve core 10 rotates 45 degrees in the second direction, the second valve core 20 is not moved, the channel a and the channel b are located at the first groove 15, the channel c is located on the outer circumferential surface of the first valve core 10, the channel c is shielded by the first valve core 10, and the channel a is communicated with the channel b. The e-channel and the f-channel of the second spool 20 remain the same and remain in the closed state.

In the third state, on the basis of the second state, when the first valve core 10 drives the second valve core 20 to synchronously rotate 45 degrees along the first direction and the first valve core 10, the e-channel and the f-channel of the second valve core 20 are located at the second groove 22, and the e-channel and the f-channel are communicated. The c channel and half of the a channel of the first valve core 10 are located at the first groove 15, the opening degree of the a channel is 50%, the b channel is located on the outer circumferential surface of the first valve core 10, and the b channel is shielded by the first valve core 10.

In the fourth state, when the first valve body 10 is rotated by 45 degrees in the second direction in addition to the third state, the state returns to the initial state, and the second valve body 20 is not moved. The channel a and the channel c of the first valve core 10 are positioned at the first groove 15, the channel b is positioned on the outer circumferential surface of the first valve core 10, the channel b is shielded by the first valve core 10, and the channel a is communicated with the channel c. The e-channel and the f-channel of the second spool 20 are unchanged, and the e-channel and the f-channel are communicated.

It should be noted that the rotation of the first valve core 10 can be adjusted to adjust the opening degrees of the channel a, the channel b and the channel c by 0-100%, and the first valve core 10 drives the second valve core 20 to rotate to adjust the opening degrees of the channel e and the channel f by 0-100%. For example, the opening degree of the a-channel is changed by adjusting the area of the a-channel corresponding to the first groove 15. When the channels a all correspond to the first grooves 15, the opening degree of the channels a is 100%; when half of the channel a corresponds to the first groove 15, the opening degree of the channel a is 50%; when all the a-channels are blocked by the first valve element 10, the opening degree of the a-channel is 0.

Preferably, the first valve core 10 and the second valve core 20 are manufactured by injection molding, and have the advantages of high production speed, high efficiency and easy forming of parts with complex shapes.

The driving device may be configured in any structure that can drive the first valve core 10 to rotate, and in an alternative embodiment, the driving device includes a motor 30 and a gear set in transmission connection with the motor 30, and the gear set is in transmission connection with the first valve core 10. The worm 31 is arranged on the shaft of the motor 30, and the gear set comprises a first worm wheel 32 matched with the worm 31, a second worm wheel 33 meshed with the first worm wheel 32, a third worm wheel 34 meshed with the second worm wheel 33, a first gear 35 connected to the bottom of the third worm wheel 34 and a second gear 36 meshed with the first gear 35. The central axes of the first worm gear 32, the second worm gear 33, the third worm gear 34, the first gear 35 and the second gear 36 in the gear set are parallel to each other and are all along the vertical direction, and the central axis of the first worm 31 is perpendicular to the central axis of the first worm gear 32. The worm 31 on the shaft of the motor 30 rotates, and drives the first valve core 10 to rotate through the transmission of the gear set, so that the transmission stability is ensured.

The type of the motor 30 is not limited, and for simplicity of control and accuracy assurance, it is preferable that the motor 30 be a stepping motor 30 or a servo motor 30.

In order to realize the connection between the first valve core 10 and the second gear 36, preferably, a first connection portion is provided on the first valve core 10, and a second connection portion is provided on the second gear 36, and the first connection portion and the second connection portion can be detachably connected.

Further preferably, the first connecting portion includes a spline shaft 14 disposed on the second end surface 213 of the first valve spool 10, and the second connecting portion includes a spline housing disposed on the second gear 36, and the spline shaft 14 and the spline housing form a detachable connection.

In an alternative embodiment, the multi-way valve 100 may be used in a thermal management system coolant circuit of an electric vehicle, providing the electric vehicle with the advantages of light weight and cost savings. Compared with an electric automobile which needs two driving devices to control a three-way proportional valve and a two-way proportional valve, the electric automobile using the multi-way valve 100 saves 100 yuan per automobile on average, and each automobile can be lightened by 100 g.

The embodiments or implementation modes in the present specification are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments may be referred to each other.

In the description of the present specification, references to "one embodiment", "some embodiments", "an illustrative embodiment", "an example", "a specific example", or "some examples", 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 present invention. In this specification, schematic representations of the above terms 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.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.