CN114439972A - Fluid management device - Google Patents

Abstract

The invention discloses a fluid management device which comprises a first block body, a second block body and a valve core, wherein the first block body is fixedly connected or in limited connection with the second block body, the first block body is provided with a first cavity, the second block body is provided with a second cavity, at least part of first channels are formed in the second block body, the first channels are communicated with the second cavity, the valve core is positioned in the first cavity, the valve core is provided with a communicating channel, the fluid management device is provided with a throttling cavity, the second block body is provided with a first opening, the first opening faces the valve core, and the first opening is communicated with the first channel.

Description

Fluid management device

Technical Field

The invention relates to the technical field of fluid management, in particular to a fluid management device.

Background

The technical problem is to provide a fluid management device, which is beneficial to optimizing a thermal management system.

Disclosure of Invention

It is an object of the present application to provide a fluid management device to facilitate solving the above-mentioned problems.

One embodiment of the technical scheme of the invention provides a fluid management device, which comprises a first block body, a second block body and a valve core, wherein the first block body is fixedly connected or in limited connection with the second block body; the second block has a first opening facing the spool, the first opening communicating with the first passage;

in an operating state of the fluid management device, the first cavity is communicated with the first opening through the throttling cavity or the conducting channel.

The fluid management device that embodiment of this application provided includes first block and second block, first block and second block fixed connection or spacing connection, first block has first chamber, the second block has the second chamber and the first opening with second chamber intercommunication, first opening is towards the case that is located first chamber, first chamber can be through the throttle chamber of fluid management device or lead to the passageway and communicate with first opening, can reduce the tube coupling between the different parts like this relatively, the integration of fluid management device is higher relatively, also can reduce the refrigerant flow resistance.

Drawings

FIG. 1 is a schematic view of a fluid management device in a perspective view;

FIG. 2 is an exploded view of the fluid management device of FIG. 1 from one perspective;

FIG. 3 is an exploded view of another perspective of the fluid management device of FIG. 1;

FIG. 4 is a schematic bottom view of the fluid management device of FIG. 1;

FIG. 5 is a schematic cross-sectional view taken along A-A of FIG. 4;

FIG. 6 is a perspective view of the planetary assembly from a first perspective;

FIG. 7 is a perspective view of the planetary assembly from a second perspective;

FIG. 8 is a perspective view of a first valve seat;

FIG. 9 is a schematic view of the first channel, the second cavity, and the conduit in positional relationship to the first plane of projection;

FIG. 10 is a schematic diagram of a front view of the fluid management device of FIG. 1;

FIG. 11 is a schematic cross-sectional view of the first embodiment taken along B-B of FIG. 10;

FIG. 12 is a cross-sectional structural view taken along C-C of FIG. 10;

FIG. 13 is a perspective view of the combination of the duct assembly and the separation discs;

FIG. 14 is a schematic view of a second block from one perspective;

FIG. 15 is a schematic view of the first loop in positional relationship to the first wall;

FIG. 16 is a schematic cross-sectional view of the second embodiment of FIG. 10 taken along B-B;

fig. 17 is another perspective view of the catheter assembly in combination with a separation disc.

Detailed Description

The fluid management device according to the technical scheme of the invention can be applied to various embodiments, at least one embodiment can be applied to a vehicle thermal management system, at least one embodiment can be applied to other thermal management systems such as a household thermal management system or a commercial thermal management system, and the following description takes a fluid management device applied to a vehicle thermal management system as an example and is combined with the accompanying drawings, wherein the fluid is a refrigerant, including R134a or CO2 or other forms of refrigerants.

Please refer to fig. 1-14. Fluid management device 100 includes block subassembly 3000 and case 430, block subassembly 3000 includes first block 3100 and second block 3200, first block 3100 and second block 3200 fixed connection or spacing connection, herein fixed connection include first block 3100 and second block 3200 structure as an organic whole, also include first block 3100 and second block 3200 welded fastening or bonding fixation or other forms's fixed connection, spacing connection includes bolted connection or other forms's spacing connection, in this embodiment, first block and second block pass through bolted connection. The fluid management device 100 has a first channel 3202, a first cavity 3101, and a second cavity 3201, the first cavity 3101 being located on the first block 3100, the second cavity 3201 being located on the second block 3200, at least a portion of the first channel 3202 being formed in the second block 3200, the first channel 3202 being in communication with the second cavity 3201. The valve element 430 is located in the first chamber 3101, the valve element 430 is operable in the first chamber 3101, in this embodiment, the valve element 430 is of a spherical, spheroidal or cylindrical configuration, the valve element 430 is rotatable in the first chamber 3101, the valve element 430 has a communication passage 431, and in one operating state of the fluid management apparatus 100, the first chamber 3101 is in communication with the first passage 3202 via the communication passage 431, and further the first chamber 3101 is in communication with the second chamber 3201. The fluid management device 100 further includes a throttle chamber 403, in this embodiment, the valve core 430 includes a throttle groove 432, the valve core 430 cooperates with a corresponding mating surface to form the throttle chamber 403 of the fluid management device 100, the first chamber 3101 can communicate with the first passage 3202 through the throttle chamber 403, and the first chamber 3101 communicates with the second chamber 3201, and the refrigerant in the first chamber 3101 is throttled by the throttle chamber 403 and depressurized to enter the second chamber 3201. The fluid management device 100 includes a first block 3100 and a second block 3200, a first cavity 3101 is disposed in the first block 3100, a valve spool 430 is movable in the first cavity 3101, a second cavity 3201 is disposed in the second block 3200, a first passage 3202 is capable of communicating the first cavity 3101 with the second cavity 3201, the first passage 3202 is at least partially disposed in the second block 3200, and the first block 3100 and the second block 3200 are fixedly or limitedly connected, so that pipe connections between different components can be relatively reduced, the fluid management device 100 is relatively high in integration, and refrigerant flow resistance can also be reduced.

In one embodiment, referring to fig. 1 and fig. 5 to 7, the fluid management device 100 includes a control portion, a transmission device 2000, a block assembly 3000, and a valve core 430, in the technical solution of this embodiment, the block assembly 3000 includes a first block 3100 and a second block 3200, and the first block 3100 and the second block 3200 are connected in a limiting manner by bolts. The control part comprises a driving mechanism 1000, a transmission device 2000 is positioned between the driving mechanism 1000 and a first block 3100, the driving mechanism 1000 comprises a motor part 1100, a sleeve 1200 and a connecting seat 1300, one end of the connecting seat 1300 is fixedly connected with the sleeve 1200 and the connection part is relatively sealed, the motor part 1100 comprises a stator 1110, a motor shaft 1130 and a rotor 1120, the stator 1110 is sleeved outside the sleeve 1200, the rotor 1120 is connected with the motor shaft 1130, at least part of the rotor 1120 is positioned inside the sleeve 1200, the motor shaft 1130 penetrates through a through hole of the connecting seat 1300, and after electrification, the rotor 1120 rotates under the action of an excitation magnetic field generated by the stator to drive the motor shaft 1130 to rotate. The transmission 2000 includes a gear case 2100, a planetary assembly 2200, and a valve rod 2300, and one end of the gear case 2100 has a step fixedly coupled to the coupling seat 1300, the step being formed with a step hole portion to which the coupling seat 1300 is coupled, and of course, a sealing member may be provided at the coupling position when the coupling seat 1300 is coupled to the step hole portion to improve sealing performance. The other end of the gear case 2100 is fixedly connected to the first block 3100, and the gear case 2100 and the first block 3100 may be welded or screwed and a seal may be provided at the connection. The planet assembly 2200 is located in a cavity formed by the gear box 2100, or the planet assembly 2200 is located in a cavity formed by the gear box 2100, the connecting base 1300 and/or the first block 3100, the planet assembly 2200 comprises a sun gear 2210, a plurality of planet gears 2220, a gear shaft, a first ring gear 2230, a second ring gear 2240 and two mounting plates 2250, in this embodiment, the planet assembly 2200 comprises three planet gears 2220, the three planet gears 2220 are in meshing connection with the sun gear 2210, each of the first ring gear 2230 and the second ring gear 2240 has internal teeth, a part of each planet gear 2220 is in meshing connection with the internal teeth of the first ring gear 2230, another part of each planet gear 2220 is in meshing connection with the internal teeth of the second ring gear 2240, and the outer side part of the first ring gear 2230 is fixedly connected to the gear box 2100, for example, the first ring gear 2230 and the gear box 2100 are relatively fixed in an interference fit or a limit fit manner. The planet gear 2220 and the sun gear 2210 are located between two mounting plates 2250, wherein the mounting plates 2250 near the drive mechanism 1000 are provided with through holes for the passage of the motor shaft in order to facilitate the mating of the motor shaft with the sun gear 2210.

Second ring gear 2240 has spacing portion 2241, spacing portion 2241 sets up in one side of second ring gear 2240 towards first block 3100, in this embodiment, spacing portion 2241 takes shape to two arc walls, two arc walls are with the axis symmetric distribution of second ring gear 2240, correspondingly, first block 3100 is provided with the spacing post with spacing portion 2241 complex, and similarly, spacing post also is with the axis symmetric distribution of second ring gear 2240, spacing post is located the arc wall, two tip of spacing portion 2241 can restrict the rotation range of second ring gear 2240, can know, can restrict the rotation range of second ring gear 2240 through the arc angle that sets up between two tip of spacing portion, and then restrict valve rod 2300's rotation range, in this embodiment, the arc angle of spacing portion 2241 sets up to 90, according to the application environment of difference, the arc angle of spacing portion 2241 can the adaptability setting. One end of the valve rod 2300 extends into a central hole of the second gear 2240, the valve rod 2300 and the second gear 2240 can be fixedly connected in an interference fit mode or a welding mode, and the valve rod 2300 and the second gear 2240 can also be fixedly connected in an injection molding mode.

When the fluid management device 100 works, when the motor shaft 1130 rotates, the sun gear 2210 is driven by the motor shaft 1300 to rotate, due to the meshing effect, the planet gear 2220 is driven by the sun gear 2210 to rotate, the first gear ring 2230 is fixed, the planet gear 2220 rotates around the axis of the planet gear 2220, and simultaneously, the planet gear 2220 also rotates around the sun gear 2210 in the circumferential direction, so that the second gear ring 2240 is driven to rotate, meanwhile, the valve rod 2300 also rotates along with the rotation of the second gear ring 2240, and due to the mutual matching of the limiting part and the limiting column, the valve rod 2300 rotates within a certain range. The first block 3100 may include a stem aperture portion having a stem aperture, a portion of the stem 2300 being disposed in the stem aperture, the stem 2300 being in fluid communication with the stem aperture portion, and the fluid management device 100 may further include a bushing embedded in and secured to the stem aperture, the stem 2300 being received in the bushing, the stem 2300 being in fluid communication with the bushing.

Referring to fig. 5 and 8, the first block 3100 includes a first receiving portion 3120, the first receiving portion 3120 has a first receiving cavity 3121, the first receiving cavity 3121 has a cavity opening facing the second block 3200, the first cavity 3101 is a portion of the first receiving cavity 3121, and the first cavity is a valve cavity of the fluid management device. The fluid management device 100 includes a first valve seat 410 and a second valve seat 420, a portion of the actuator is located in the first receiving cavity 3121, the actuator is fixedly or captively connected to a corresponding portion of the first receiving cavity 3120, the valve stem 2300 is drivingly connected to the valve element 430, and the valve element 430 is capable of actuating within the first cavity 3101. The second valve seat 420 is located in the first receiving cavity 3121, the second valve seat 420 is fixed or limited to a corresponding portion of the first receiving portion 3120, at least a portion of the first valve seat 410 is located in the first receiving cavity 3121, in this embodiment, the first valve seat 410 is closer to the second block 3200 than the second valve seat 420, the first valve seat 410 is located at one side of the valve core 430, the second valve seat 420 is located at the opposite side of the first valve core, the first valve seat 410 has a first through hole 411, the second valve seat 420 has a second through hole 421, the first through hole 411 and the second through hole 421 may be channels of refrigerant, and an axis of the first through hole coincides with an axis of the second through hole. The first valve seat 410 and the second valve seat 420 both have a mating surface for mating with the valve element 430, the first through hole 411 and the second through hole 421 have openings at the corresponding mating surfaces, the mating surface 412 of the first valve seat and the mating surface of the second valve seat 420 contact with the valve element 430 and press the valve element 430, and the mating surface 412 of the first valve seat and the mating surface of the second valve seat 420 are in sliding fit with the valve element 430.

Referring to fig. 5, 11 and 13, the second block 3200 includes a second accommodating portion 3210, and the second accommodating portion 3210 has a second accommodating cavity 3211, wherein the second cavity 3201 is a portion of the second accommodating cavity 3211, and the second cavity is a gas-liquid separation cavity of the fluid management device. The first passage 3202 has an outlet 3206 of the first passage at a side wall 3213 of the second housing, and the first passage 3202 is in communication with the first cavity 3101. The fluid management device 100 includes a catheter assembly 500, at least a portion of the catheter assembly 500 is located in the second accommodating cavity 3211, the catheter assembly 500 includes a connecting portion 510 and a catheter 520, the connecting portion 510 and the catheter 520 may be an integral structure, or may be a separate structure, and then connected in a limiting manner or connected in a limiting manner. The connecting portion 510 is fixedly or limitedly connected to a corresponding portion of the second accommodating portion 3210, and the connection portion 510 is screwed to the second accommodating portion 3210 in this embodiment. The conduit assembly 500 has a refrigerant passage 501, the refrigerant passage 501 including a cavity of the conduit 520, the conduit 520 having a conduit port 521, the conduit port 521 facing the side of the bottom wall 3212 of the second container, and further, the refrigerant in the second cavity 3201 can enter the refrigerant passage 501 through the conduit port 521, the conduit port 521 is closer to the bottom wall 3212 of the second container than the outlet 3206 of the first passage, or, in the axial direction of the conduit 520, the conduit port 521 is located between the outlet 3206 of the first passage and the bottom wall 3212 of the second container. The wall forming the second chamber 3201 includes a side wall 3213 of the second receiving portion, and the side wall 3210 of the second receiving portion is substantially a ring-shaped surface. The conduit 520 is located near the central axis of the second cavity 3201 and, more closely, the axis of the conduit 520 is substantially coincident with the axis of the second cavity 3201.

The fluid management device 100 includes a second channel portion 3240, the second channel portion 3240 having a second channel 3203, at least a portion of the second channel 3203 being formed in the second block 3200, the second channel 3203 having a second channel inlet 3205 in a bottom wall 3212 of the second housing. In other embodiments, the second channel portion 3240 includes a throttling portion 3241, the aperture of the throttling portion 3241 is 1.0-2.0 mm, and after a part of the refrigerant in the second cavity 3201 enters the second channel 3203, the throttling portion 3241 can throttle and depressurize the refrigerant.

A first projection plane is defined, the first projection plane is perpendicular to the axis of the conduit 520, the axis of the conduit 520 is in the up-down direction, and the conduit port 521 is located below the outlet of the first passage 3202. Referring to fig. 9, a projection of the first channel 3202 on the first projection plane has a first side line 3222 and a second side line 3221, the first side line 3222 is closer to the projection 520 ' of the conduit 520 on the first projection plane than the second side line 3221, extension lines of the first side line 3222 and the second side line 3221 are located on the same side of the projection 520 ' of the conduit, and further, the second side line 3221 is a tangent of a projection 3213 ' of a side wall of the second accommodating part 3210, such that a large amount of refrigerant in a mixed state entering the second channel 3201 from the first channel 3202 collides with the side wall of the second accommodating part, and due to the annular surface of the side wall of the second accommodating part, the refrigerant rotates in the second channel 3201, thereby accelerating separation of the refrigerant in the mixed state in the second channel 3201, a gaseous refrigerant enters the refrigerant channel 501 from the port 521, and a liquid refrigerant enters the second channel 3203 from the second channel inlet 3205.

Referring to fig. 2 and 3, the first block 3100 includes a first wall portion 3110, the second block 3200 includes a second wall portion 3250, at least a portion of the second wall portion 3250 is disposed opposite to the first wall portion 3110, and an opening of the first cavity 3121 is formed in the first wall portion 3110. The second block 3200 includes a first face 3231, the first face 3231 contacting the first valve seat 410 and pressing the first valve seat 410, and a first opening 3204 formed at the first face 3231. In this embodiment, the second block 3200 includes the first protruding portion 3230, the first protruding portion 3230 protrudes from the second wall portion 3250, at least a portion of the first protruding portion 3230 is located in the first receiving cavity 3121, the first surface 3231 of the first protruding portion 3230 contacts and presses the first valve seat 410, and further the mating surface of the first valve seat 410 contacts and presses the valve element 430, since the mating surface of the second valve seat 420 also limits the valve element 430, so that the first protruding portion 3230 contacts and presses the first valve seat 410, and the valve element 430 is limited in the first receiving cavity 3121 under the combined action of the second valve seat 420. Through the fixed or limited connection of the first block 3100 and the second block 3200, the first protruding portion 3230 of the second block 3200 enables the valve core 430 to be relatively limited in the first accommodating cavity 3121, and a component fixed or limited with the first block 3100, such as a valve cover, does not need to be separately arranged, so that the number of components is reduced, and the installation steps can also be reduced.

The second block 3200 comprises a groove portion 3232, the groove portion 3232 having a cavity 3233, the cavity 3233 having a cavity opening in a wall of the first protrusion portion 3230 facing the first valve seat 410, at least a portion of the first valve seat 410 being located in the cavity, the first valve seat 410 being relatively sealed with said groove portion 3232, when the first face 3231 is a bottom wall of the groove portion 3232 or a portion of the bottom wall of the groove portion 3232. By providing the first projection portion 3230 with the groove portion 3232, the volume of the fluid management device 100 can be reduced, and the weight of the fluid management device 100 can also be reduced.

Referring to fig. 2 and 5, the second block 3200 has a first opening 3204, the first opening 3204 is located on the first surface 3231 of the second block 3200, the first opening 3204 is communicated with the first channel 3202, and the first opening 3204 faces the valve element 430. In the present embodiment, the first opening 3204 may be an inlet of the first channel 3202, the first opening 3204 is located at a bottom wall of the groove portion 3232, and the first opening 3204 faces the first through hole 411. To facilitate the following description, a first plane is defined, the first plane is perpendicular to the axis of the first through hole 411, and when the throttling groove 432 connects the first cavity 3101 and the first opening 3204, at least a part of the projection of the throttling groove 432 on the first plane is located within the projection of the first opening 3204 on the first plane. The throttled refrigerant can enter the first passage 3202 from the first opening 3204 to the maximum, and the flow resistance of the throttled refrigerant entering the first passage 3202 can be reduced.

Please refer to fig. 12 and 14. A first direction and a second direction are defined in the first plane, wherein the first direction is parallel to the axis of the conduit 520, i.e., the first direction is parallel to the axis of the second chamber 3201, the first direction and the second direction are perpendicular, and the maximum length of the first opening 3204 in the first direction is greater than the maximum length of the first opening 3204 in the second direction. When the fluid management device 100 is in operation, when the projection of the throttle groove 432 on the first surface 3231 is maximum, the maximum length of the projection of the throttle groove 432 on the first plane in the first direction is greater than the maximum length of the projection of the throttle groove 432 on the first surface 3231 in the second direction, so that the extending direction of the throttle groove 432 is consistent with the extending direction of the first opening 3204, and during the rotation of the valve core 430, the valve core 430 can be in the throttle stroke, and the refrigerant can enter the first opening 3204 to the maximum extent. Further, the valve core 430 can rotate around the axis of the valve rod 2300, and the axis of the valve rod 2300 is parallel to the second direction, so that the extending direction of the throttling groove 432 is perpendicular to the axis of the valve rod 2300, which is beneficial to controlling the formation of the valve core 430 by controlling the rotation angle of the valve core 430, and further beneficial to controlling the throttling stroke of the valve core 430.

Referring to fig. 14, the second block 3200 includes a first channel portion 3220, the first channel portion 3220 has a first channel 3202, the first channel portion 3220 includes a second surface 3221, the second surface 3221 is inclined with respect to an axis of the first through hole 411, the second surface 3221 extends along the first direction, and the second surface 3221 is biased from the first surface 3231 to an opposite side of the second surface 3221. When the throttle groove 432 connects the first cavity 3101 with the first opening 3204, at least a partial projection of the throttle groove 432 in the first plane is located on a projection of the second surface 3221 in the first plane.

Referring to fig. 1-3 and 5, the fluid management device 100 has a first inlet 103, a first outlet 101, and a second outlet 102, wherein the first inlet 103 is formed in the first block 3100, and the first inlet 103 is in communication with the first cavity 3101. In this embodiment, the valve core 430 is located between at least a portion of the valve rod 2300 and the first inlet 103 along the axial direction of the valve rod 2300, and since the refrigerant entering the first cavity 3101 from the first inlet 103 may impact the valve core 430, and the first inlet 103 is located at the opposite side of the valve rod 2300, the shaking of the valve core 430 caused by the impact of the refrigerant may be reduced, which is beneficial to maintaining the stability of the valve core 430. The first outlet 101 is located at the duct assembly 500, and particularly, the first outlet 101 is located at the connection part 510 of the duct assembly 500, and the first outlet 101 communicates with the refrigerant passage 501 of the duct assembly 500. The second outlet 102 is formed in the first block 3100, and in an operating state of the fluid management device 100, the first chamber 3101 can be communicated with the second chamber 3201 through the throttling chamber 403 or the communication channel, and a portion of the fluid in the second chamber 3201 can be discharged through the second outlet 102. To facilitate gaseous refrigeration exiting the fluid management device 100, the second outlet 102 may be located on an upper wall of the duct assembly 500.

Referring to fig. 5 and 12, the fluid management device 100 further includes a third channel 3102 and a fourth channel 3103, the third channel 3102 and the fourth channel 3103 being formed on the first block 3100. The third passage 3102 communicates with the second outlet 102, and the third passage 3102 communicates with the second passage 3203. The fourth channel 3103 is adjacent to the second valve seat 420, the fourth channel 3103 communicates with the second through hole 421, the fourth channel 3103 has a port in the wall forming the third channel 3102, and the fourth channel 3103 communicates with the third channel 3102. In another operating state of the fluid management device 100, that is, when the throttling chamber 403 or the conducting channel 431 communicates the first chamber 3101 with the second through hole 421, the first chamber 3101 communicates with the fourth channel 3103, or the refrigerant in the first chamber 3101 can enter the fourth channel 3103 and the third channel 3102 through the throttling chamber 403 or the conducting channel 431 and then exit the fluid management device 100 through the second outlet 102.

The fluid management device 100 includes a check valve member 800, the check valve member 800 is located in the third channel 3102, the second channel 3203 can be communicated with the second outlet 102 in a single direction through the check valve member 800, and the communication position between the third channel 3102 and the fourth channel 3103 is close to the second outlet 102 relative to the check valve member 800, so that the refrigerant entering the third channel 3102 from the fourth channel 3103 can only be discharged from the second outlet 102, but can not enter the second channel 3203. Further, the third passageway 3102 includes a first sub-portion 3104 and a second sub-portion 3105, wherein the first sub-portion 3104 is positioned below the first chamber 3101, the first sub-portion 3104 is in communication with the second passageway 3203, and the one-way valve member 800 is positioned in the first sub-portion 3104; the second sub-portion 3105 communicates with the second outlet 102 and the fourth channel 3103, the second sub-portion 3105 is parallel to the axis of the second chamber 3201, and the second sub-portion 3105 is further from the second chamber 3201 than the first chamber 3101. The first sub-portion 3104 and the second sub-portion 3105 are disposed on the first block 3100 to facilitate forming the third channel.

In other embodiments, the second channel 3203 may not be communicated with the third channel 3102, or the third channel 3102 does not include the first sub-portion, and the second channel 3203 has a third outlet on the second block 3200, which may reduce the difficulty in processing and may also be beneficial to reducing the risk of leakage caused by the communication between the second channel 3203 and the third channel 3102. In other embodiments, the third outlet may also be located in the first block.

Referring to fig. 11 and 13, the fluid management device 100 includes the separation disc 600, the conduit port 521 faces the upper wall of the separation disc 600, the separation disc 600 is located between the second channel inlet port 3205 and the conduit port 521 along the axis of the conduit 520, a gap for the refrigerant to flow is formed between the sidewall of the separation disc 600 and the sidewall 3213 of the second receiving portion, in this embodiment, the fluid management device 100 further includes at least two brackets 610, one end of each bracket 610 is fixedly or limitedly connected to the separation disc 600, the other end of each bracket 610 is fixedly or limitedly connected to the conduit 520, a channel for the refrigerant to flow is formed between the adjacent brackets 610, and in this embodiment, the conduit 520, the connecting portion 510 and the separation disc 600 are integrally formed.

Referring to another embodiment illustrated in fig. 15-17, the fluid management device 100 includes at least one blocking portion 700, the blocking portion 700 being located between the conduit port 521 and the bottom wall 3212 of the second receptacle along the axial direction of the conduit 520, and the blocking portion 700 being located between the second channel inlet 3205 and the side wall 3213 of the second receptacle along the radial direction of the first cavity 3101. The barrier 700 may be a sheet or column or other form of structure. Due to the rotating flow of the refrigerant in the second chamber 3201, a relatively liquid refrigerant may be distributed in a large amount near the bottom wall of the second receiving portion, and a situation that the refrigerant near the side wall 3213 of the second receiving portion is relatively much and the refrigerant near the center of the second chamber 3201 is relatively less is present, so that the refrigerant between the second channel inlet 3205 and the conduit port 521 forms a vortex, if the vortex is formed, a low pressure may occur at the center of the second chamber 3201 and relatively near the bottom wall 3212 of the second receiving portion, such that a refrigerant flash evaporation phenomenon may occur, the blocking portion 700 is disposed in the fluid management device 100, which is beneficial for preventing the flash evaporation phenomenon, and can improve the performance of the refrigerant, and simultaneously can reduce the pressure loss of the refrigerant.

The blocking portion 700 includes a first wall 710, the first wall 710 may be arc-shaped or plane or approximately plane, in this embodiment, the blocking portion is plate-shaped, the first wall 710 is plane or approximately plane, and a projection of the outlet 3202 of the first channel on the first projection plane faces a projection of the first wall on the first projection plane, so that the first wall can block the refrigerant flow. A first loop is defined, the center of which is located at the axis of the first cavity 3101, and the first wall can intersect the first loop, and the tangent of the first loop at the intersection point forms an angle of greater than or equal to 45 ° and less than or equal to 135 ° with the first wall, so that the first wall can effectively block the refrigerant from swirling between the second channel inlet 3205 and the conduit port 521. In this embodiment, the tangent to the first loop at the point of intersection makes an angle of 90 ° with the first wall.

The fluid management device 100 may further include a separation disc 600, and as such, the conduit port 521 faces the upper wall of the separation disc 600, and the separation disc 600 is located between the inlet of the second passage 3203 and the conduit port 3205 along the axis of the conduit 520, and the separation disc 600 can prevent the relatively liquid refrigerant from being sucked into the refrigerant passage 501 of the conduit assembly 500. The side walls of the separation disc 600 and the side walls 3213 of the second receiving portion have gaps therebetween, and the separation disc 600 and the bottom wall 3212 of the second receiving portion have gaps therebetween, which are passages through which the refrigerant enters the second passage inlets. Separation disc 600 is fixedly or captively attached to barrier 700, where a fixed attachment includes the case where separation disc 600 is integral with barrier 700. In a specific embodiment, the separation discs 600 are closer to the first passage outlet 3206 than the barriers 700 along the axial direction of the conduit 520, and the gaps between the barriers 700 and the side walls 3213 of the second receiving portion are smaller than the gaps between the separation discs 600 and the side walls 3213 of the second receiving portion along the radial direction of the second chamber, which can reduce the obstruction of the refrigerant flow by the separation discs 600 before the refrigerant enters the space where the barriers 700 are located. In this embodiment, the blocking portion is fixed or connected to the bottom wall 3212 of the second accommodating portion in a limited manner.

The quantity of separation portion 700 is one at least, and when the quantity of separation portion was for being more than or equal to 3 and being less than or equal to 10 between, can further improve the effect of hindering to the refrigerant, in this embodiment, the quantity of separation portion is eight, along the circumference of second chamber, and the clearance sets up between the adjacent separation portion, and the clearance between the adjacent separation portion is the passageway that the refrigerant got into the second passageway entry.

In another specific embodiment, the side wall of the separation disc 600 is fixedly or limitedly connected to one end of the blocking portion 700, the other end of the blocking portion 700 is fixedly or limitedly connected to the side wall 3213 of the second accommodating portion, a gap is formed between adjacent blocking portions 700, and the gap between adjacent blocking portions 700 is a circulation channel of the refrigerant.

It should be noted that: although the present invention has been described in detail with reference to the above-mentioned embodiments, it should be understood by those skilled in the art that the present invention may be modified and equivalents may be substituted for those skilled in the art, and all technical solutions and modifications that do not depart from the spirit and scope of the present invention should be covered by the claims of the present invention.

Claims (10)

1. A fluid management device comprises a first block, a second block and a valve core, wherein the first block is fixedly connected or in limit connection with the second block, the fluid management device is provided with a first channel, a first cavity and a second cavity, the first cavity is positioned in the first block, the second cavity is positioned in the second block, at least part of the first channel is formed in the second block, the first channel is communicated with the second cavity, the valve core is positioned in the first cavity, the valve core is provided with a communication channel, and the fluid management device is provided with a throttling cavity; the second block has a first opening facing the spool, the first opening communicating with the first passage;

in an operating state of the fluid management device, the first cavity is communicated with the first opening through the throttling cavity or the conducting channel.

2. The fluid management device of claim 1 wherein the first block includes a first receptacle having a first receptacle cavity having an orifice facing the second block, the fluid management device including a first valve seat and a second valve seat, the spool and the second valve seat being located in the first receptacle cavity, at least a portion of the first valve seat being located in the first receptacle cavity, the first cavity being part of the first receptacle cavity.

3. The fluid management device of claim 2 wherein the first block comprises a first wall portion and the second block comprises a second wall portion, at least a portion of the second wall portion being disposed opposite the first wall portion, the orifice of the first receiving cavity being formed in the first wall portion;

the second block body further comprises a first protruding portion protruding relative to the second wall portion, at least part of the first protruding portion is located in the first accommodating cavity, and the first protruding portion is in contact with and presses the first valve seat.

4. The fluid management device of claim 3 wherein the second block includes a recessed portion having a cavity with a recess opening in a wall of the first boss facing the first valve seat, the first opening being located in a bottom wall of the recessed portion, at least a portion of the first valve seat being located in the cavity, the first valve seat being relatively sealed from the recessed portion.

5. The fluid management device according to any of claims 1-4, wherein the fluid management device has a first inlet, a first outlet, and a second outlet, the first inlet and the second outlet being located in the first block, the first inlet communicating with the first chamber, the first outlet communicating with the second chamber;

in another working state of the fluid management device, the first cavity is communicated with the second outlet through the throttling cavity or the conducting channel.

6. The fluid management device of claim 5 wherein the axis defining the second chamber is in an up-down direction, the first outlet is located above the second chamber, the fluid management device has a second channel, the second block includes a second receptacle, the second channel inlet is located at a bottom wall of the second receptacle, the second channel is in communication with the second chamber, the second channel is in communication with the second outlet, or the second block has a third outlet located at the second block or the first block, the second channel is in communication with the third outlet.

7. The fluid management device of claim 6 wherein the first block has a third passage in communication with the second outlet, the third passage having a passage opening in the first wall facing the second block, the second passage in communication with the third passage; the first block is provided with a fourth channel, the fourth channel is close to the second valve seat, and the fourth channel is communicated with the third channel;

the fluid management device comprises a one-way valve component, the one-way valve component is positioned in the third channel, the second channel can be communicated with the second outlet in a one-way mode through the one-way valve component, and the communication position of the third channel and the fourth channel is close to the second outlet relative to the one-way valve component.

8. The fluid management device of claim 7 wherein the third channel comprises a first subsection and a second subsection, the first subsection being located below the first cavity, the first subsection having a channel opening in the first wall facing the second block, the first subsection being in communication with the second channel, the one-way valve member being located in the first subsection;

the second sub-portion is in communication with the second outlet, the fourth passage, the second sub-portion is parallel to an axis of the second chamber, and the second sub-portion is further from the second chamber than the first chamber.

9. The fluid management device according to any one of claims 6-8, wherein the second block comprises a second channel portion having the second channel, the second channel portion comprising a restriction, the restriction having a bore diameter in a range of 1.0-2.0 mm.

10. The fluid management device of claim 9 wherein the second outlet is located in an upper wall of the first block; the valve core is positioned between at least part of the valve rod and the first inlet along the axial direction of the valve rod;

the fluid management device comprises a conduit assembly, the second containing part is provided with a second containing cavity, the second containing cavity is provided with an opening on the upper wall of a second block, at least part of the conduit assembly is positioned in the second containing cavity, the second cavity is part of the second containing cavity, and the first outlet is positioned on the upper wall of the conduit assembly;

the valve core is spherical or spheroidal or cylindrical.

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