CN111380297B

CN111380297B - Refrigeration cycle device

Info

Publication number: CN111380297B
Application number: CN201811650343.7A
Authority: CN
Inventors: 请求不公布姓名
Original assignee: Zhejiang Sanhua Intelligent Controls Co Ltd
Current assignee: Zhejiang Sanhua Intelligent Controls Co Ltd
Priority date: 2018-12-31
Filing date: 2018-12-31
Publication date: 2023-04-07
Anticipated expiration: 2038-12-31
Also published as: CN111380297A

Abstract

The invention provides a refrigeration cycle device, which comprises a compressor, a condenser, an electric switching valve, a refrigerating area evaporator and a freezing area evaporator, wherein the electric switching valve comprises an inlet connecting pipe, a first outlet connecting pipe and a second outlet connecting pipe; its characterized in that, the electrical changeover valve still includes disk seat and valve block, the disk seat is provided with first export and second export, first export with first export takeover intercommunication, the second export with second export takeover intercommunication, the valve block includes cooperation portion, breach portion, first throttle portion, second throttle portion, the valve block can the up end laminating of disk seat rotates to form six operating position.

Description

Refrigeration cycle device

Technical Field

The invention relates to the technical field of refrigeration, in particular to a refrigeration circulating device.

Background

In a refrigeration cycle apparatus such as a refrigerator, an electrically operated switching valve is generally employed as a control member for changing a refrigerant flow path.

The electric switching valve comprises a valve seat, a shell fixedly arranged above the valve seat and a motor, wherein a coil part of the motor is sleeved outside the shell, and a rotor part is arranged in the shell.

The valve cavity is formed in the shell, the valve seat is provided with a leading-in channel and a leading-out channel, the upper end face of the valve seat is provided with a leading-out port corresponding to the leading-out channel, the valve seat is further provided with a sliding block which is in sealing fit with the upper end face of the valve seat, and the sliding block synchronously rotates under the driving of the rotor component and is matched with the leading-out port to control the opening and closing state of the leading-out port.

The end face of the valve seat is provided with a plurality of outlet ports, and the bottom end of the sliding block is provided with a sealing surface and a notch which are in sealing fit with the upper end face of the valve seat. After the sliding block is matched with the valve seat, the sliding block can rotate, when the notch of the sliding block corresponds to the position of the outlet of the valve seat, the outlet is in an open state, and when the sealing surface of the sliding block corresponds to the position of the outlet, the outlet is in a closed state.

The electric switching valve is applied to a refrigeration cycle device, and enables the corresponding outlet to be in an open or closed state according to system requirements, and adjusts refrigerants flowing to each temperature zone to enable the corresponding temperature zone to be in a refrigeration state or a heat preservation state.

Along with the requirement of further optimization of the refrigerating system, the requirement of further accurate temperature control of the temperature areas is provided so as to reduce the temperature fluctuation of each temperature area. Therefore, how to design a refrigeration cycle device to meet the above requirements is a technical problem to be solved by those skilled in the art.

Disclosure of Invention

The invention aims to provide a refrigeration circulating device which can further accurately control the temperature of temperature zones so as to reduce the temperature fluctuation of each temperature zone.

In order to solve the technical problems, the invention provides a refrigeration cycle device, which comprises a compressor, a condenser, an electric switching valve, a refrigerating area evaporator and a freezing area evaporator, wherein the electric switching valve comprises an inlet connecting pipe, a first outlet connecting pipe and a second outlet connecting pipe; its characterized in that, electric changeover valve still includes disk seat and valve piece, the disk seat is provided with first export and second export, first export with first export takeover intercommunication, the second export with second export takeover intercommunication, the valve piece includes cooperation portion, breach portion, first throttle portion, second throttle portion, the valve piece can the up end laminating of disk seat rotates to form six operating positions:

the first outlet and the second outlet are communicated with the notch part, and the refrigerating area and the freezing area are in a refrigerating state;

in the second working position, the first outlet is communicated with the gap part, the second outlet is communicated with the first throttling part, the refrigerating area is in a refrigerating state, and the freezing area is in an accurate temperature control state;

in a third working position, the first outlet is communicated with the notch part, the second outlet is blocked by the matching part, the refrigerating area is in a refrigerating state, and the freezing area is in a heat-preserving state;

in a fourth working position, the first outlet is communicated with the second throttling part, the second outlet is blocked by the matching part, the cold storage area is in an accurate temperature control state, and the freezing area is in a heat preservation state;

in the fifth working position, the first outlet and the second outlet are blocked by the matching part, and the cold storage area and the freezing area are in a heat preservation state;

and in a sixth working position, the first outlet is blocked by the matching part, the second outlet is communicated with the notch part, the cold storage area is in a heat preservation state, and the freezing area is in a refrigeration state.

The refrigeration cycle device provided by the invention can select the corresponding working positions according to the temperature change conditions of the refrigeration area and the freezing area, so that the temperatures of the refrigeration area and the freezing area are in the preset range, and once a certain temperature area reaches the preset temperature, the corresponding channel of the corresponding temperature area can be used to be in the throttling working position to accurately control the temperature so as to reduce the temperature fluctuation.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

fig. 2 is a structural schematic diagram of the valve seat in fig. 1.

FIG. 3 is an angled schematic view of the valve block shown in FIG. 1;

FIG. 4 is a schematic view of an alternate angle of the valve block shown in FIG. 1;

fig. 5 is a schematic structural view of the plate-shaped portion.

FIG. 6 isbase:Sub>A cross-sectional view taken along line A-A of FIG. 5;

FIG. 7 is a schematic view of a plate assembly;

FIG. 8 is a schematic view of the structure of the mold assembly of FIG. 8;

FIG. 9 is a schematic view of the plate assembly after it has been placed in the first mold cavity;

FIG. 10 is a schematic diagram of a refrigeration system for a dual temperature, dual control refrigerator;

fig. 11 is a schematic diagram showing the relative positions of the valve block and the valve seat when the electric switching valve is at different working positions.

Detailed Description

In order that those skilled in the art will better understand the disclosure, the invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1 and fig. 2, fig. 1 is a schematic structural diagram of an embodiment of an electric switching valve provided in the present invention, and fig. 2 is a schematic structural diagram of a valve seat in fig. 1.

As shown in the drawing, the electric switching valve includes a valve seat 11 and a housing 12 fixed to the valve seat 11 to form a sealed valve chamber.

The valve seat 11 is fixedly connected with an inlet connecting pipe 13, a first outlet connecting pipe 14 and a second outlet connecting pipe 15, and the inlet connecting pipe 13, the first outlet connecting pipe 14 and the second outlet connecting pipe 15 can be fixedly connected with the valve seat 11 in a welding manner. The valve seat 11 is provided with an introduction port 113 and first and

second outlet ports

111 and 112. The inlet 113 is provided on the side of the valve seat and is in communication with the inlet pipe. Thus, the refrigerant introduced from the inlet connection pipe 13 can be introduced into the valve chamber through the introduction port 113. Of course, it will be understood by those skilled in the art that the introduction port 113 provided on the valve seat 11 is used to communicate the inlet connection pipe 13 with the valve cavity, therefore, the introduction port 113 may not be provided on the valve seat 11, such as directly providing an opening on the side of the outer shell 12 and fixedly connecting the inlet connection pipe 13, and it is also possible to communicate the inlet connection pipe 13 with the inside of the valve cavity.

The first lead-out port 111 and the second lead-out port 112 are provided on the upper end surface of the valve seat 11, and in the present embodiment, the first lead-out port 111 and the second lead-out port 112 are opened on circumferences having different lengths as radii and centered on the central axis of the valve seat 11, and are spaced apart by a predetermined distance. The upper end surface of the valve seat 11 is a flat mating surface, the valve block 30 can be engaged with the upper end surface of the valve seat 11 and perform a certain angle of rotation, and the valve block 30 can selectively make the first outlet port 111 or the second outlet port 112 open, close or in a throttling state. A rotor part 23 is arranged inside the valve cavity, the rotor part 23 is driven by a solenoid (not shown in the figure) to rotate, and a rotating shaft 24 fixedly connected with the rotor part 23 drives the valve block 30 to rotate on the matching surface of the valve seat 11. The opening/closing state or the throttle state of the first and

second outlet ports

111 and 112 is controlled by the rotation of the valve block 30.

The valve seat 11 includes a support base 21 and a valve seat body 22 fixed thereon, which may be separately arranged, fixed by welding, or integrally formed. In order to make the rotor component 10 rotate together with the valve block 30, the valve block 30 and the rotating shaft 24 may be fixed relatively, for example, the valve block 30 and the rotating shaft 24 are fitted in an interference fit. Of course, the valve block 30 and the rotor member 23 may be fixed to each other, for example, by providing a protruding key portion (not shown) at the lower end of the rotor member 23, providing a key groove in the valve block 30 that engages with the key portion, and engaging and fixing the key portion and the key groove to each other, thereby fixing the rotor member and the valve block 30 to each other. The advantage of this kind of setting is, the key portion inlay card of rotor part plays the effect of compressing tightly valve block 30 in valve seat 11 to a certain extent in the keyway, can ensure valve block 30 and valve seat 11 laminating, prevents that the refrigerant from flowing into from laminating department between them.

The specific structure of the valve block 30 of the present invention will be described in detail in a specific embodiment.

Referring to fig. 3 to 6 together, fig. 3 is a schematic view illustrating an angle structure of the valve block shown in fig. 1; FIG. 4 is a schematic view of an alternate angle of the valve block shown in FIG. 1; FIG. 5 is a schematic structural view of a plate-shaped portion; fig. 6 isbase:Sub>A sectional view taken along linebase:Sub>A-base:Sub>A of fig. 5.

Taking the view of fig. 5 as an example, the valve block 30 includes a plate-shaped portion 31, an upper body portion 32 located above the plate-shaped portion 31, and a lower body portion 33 located below the plate-shaped portion 31, which are fixedly integrated. The lower body includes a fitting portion 331 formed on the surface of the lower body 33 and a notch portion 332. The engaging portion 331 is configured to slidably engage with the engaging surface of the valve seat 11, that is, the engaging portion 331 can rotate on the engaging surface of the valve seat 11 in a fitting manner, when the engaging portion 331 rotates to cover the first outlet port 111 or the second outlet port 112 of the valve seat 11, the corresponding first outlet port 111 or second outlet port 112 is in a closed state, and the refrigerant cannot flow out from the first outlet port 111 or second outlet port 112. On the contrary, when the matching portion 331 does not cover the outlet, the notch 332 corresponds to the outlet, and at this time, the outlet is in a conducting state. As for the specific shapes of the matching portion 331 and the notch portion 332, various equivalent substitutions can be made according to different use requirements to realize corresponding functions.

The plate-shaped portion 31, the upper body portion 32 and the lower body portion 33 may be made of different materials according to structural requirements, and in the present embodiment, the plate-shaped portion 31 is made of a material which is cut for convenience of machining, such as a metal material such as copper. The upper body 32 and the lower body 33 are injection molded from engineering plastic. Specifically, the upper body 32 and the lower body 33 may be formed by injection molding of engineering plastic in a mold using the plate-shaped portion 31 as an insert. For convenience of description, the plate-shaped portion 31 is used as a boundary in this specification, and the parts of the valve block 30 are named as the plate-shaped portion 31, the upper body portion 32, and the lower body portion 33, respectively. In fact, the upper body and the lower body are partially joined together and are not completely separated by the plate 31, without a strict limit.

Referring to fig. 5, fig. 5 is a schematic structural view of the plate-shaped portion 31. As shown in fig. 5, the solid line part in the figure indicates the plate-like portion, and the dotted line part indicates the valve block structure after injection molding. The plate-like portion 31 is substantially plate-like and includes a body portion 3108 and a large diameter portion 3109 integrally formed with the body portion 3108. The body 3108 has a central through hole 3103, and when the plate 31 is molded into a valve block, the central through hole 3103 and the central hole 30a of the valve block may be arranged on the same central axis, and the inner diameter of the central through hole 3103 of the body 3108 is smaller than the inner diameter of the central hole 30a of the molded valve block. Thus, the inner edge of the central through hole 3103 is completely covered by the injection molding material, as shown in fig. 6. The large diameter portion 3109 is formed by extending the body portion 3108 in the radial direction, and in this embodiment, the large diameter portion 3109 is extended from the body portion 3108 toward a certain side, and of course, the large diameter portion 3109 may be entirely extended from the body portion 3108 in the radial direction, and this embodiment has an advantage in that, since the large diameter portion 3109 is formed only on a certain side of the body portion 3108, the bonding of the injection molding material separated by the plate-shaped portion 31 is more dense at the time of injection molding, and theoretically, the smaller the area of the plate-shaped portion, the tighter the bonding between the upper body portion and the lower body portion, and the better the injection molding effect.

It should be noted that the main body portion 3108 and the large diameter portion 3109 are merely divided for convenience in describing the general shape of the plate-like portion 31, and there is no absolutely clear boundary therebetween. The large diameter portion 3109 is provided with a first orifice portion 3101 and a second orifice portion 3102 corresponding to the first orifice portion 3311a and the second orifice portion 3311b of the lower body portion 33, respectively. In the present embodiment, the first orifice portion 3101 and the second orifice portion 3102 are located in the same radial direction, that is, the centers of the first orifice portion 3101, the second orifice portion 3102, and the center through hole 3103 are located on the same straight line. The arrangement mode has the advantages that the matching relation between the throttling hole and the outlet port is convenient to arrange, and a simpler working position is easy to obtain.

In order to further improve the injection bonding strength between the upper body and the lower body, the large diameter portion 3109 is further provided with a first through portion 3104 and a second through portion 3105 on both sides of the first orifice portion 3101 and the second orifice portion 3102. The arrangement of the first through part 3104 and the second through part 3105 enables the transition section of the whole plate-shaped part and the injection molding material not to be overlong, thereby reducing the generation of air bubbles in the injection molding process and further reducing the risk of internal leakage of the valve block.

In the present embodiment, the plate-shaped portion 31 further has a first extending portion 3106 and a second extending portion 3107 extending in opposite directions along the radial direction of the body portion 3108, wherein a part of the end portions of the first extending portion 3106 and the second extending portion 3107 extend to the outside of the valve block as a whole. Of course, the valve block can also achieve the same function even if the first and second extending

portions

3106 and 3107 are not provided.

The plate-shaped part 31 can be made of brass, aluminum or other metal materials, and both are cutting materials which are convenient to process, and the processing manufacturability of the plate-shaped part 31 is improved. Of course, in practice, the plate-shaped portion 31 may be made of other cutting materials for easy machining, and it is understood that a free-cutting material is preferable to improve the machining manufacturability. The upper body 32 and the lower body 33 may be PPS engineering plastic or PEEK engineering plastic, which can ensure a low coefficient of friction and low wear of the valve block 30.

The valve block 30 further includes a first throttling portion 3311a and a second throttling portion 3311b, and more specifically, the first throttling portion 3311a and the second throttling portion 3311b are disposed on the lower body 33 and penetrate the lower body 33, so that openings of the first throttling portion 3311a and the second throttling portion 3311b are located on a surface of the fitting portion 331. The distance from the first throttle part 3311a to the central axis of the valve block is adapted to the distance from the second outlet 112 provided in the valve seat 11 to the central axis of the valve seat 11 (the valve seat 11 and the valve block 30 may be coaxially provided); the distance of the second throttle portion 3311b from the center axis of the valve block 30 corresponds to the distance of the first outlet port 111 provided in the valve seat 11 from the center axis of the valve seat 11. In this way, the first throttling part 3311a and the second outlet port 112 are located on the same circumference with the center axis of the valve seat 11 as the center, and the second throttling part 3311b and the first outlet port 111 are located on another circumference with the center axis of the valve seat 11 as the center.

In the present embodiment, the first and

second chokes

3311a and 3311b are located on the same line as the center point of the valve block 30. Of course, the first and

second chokes

3311a and 3311b may be staggered according to actual needs.

Thus, when the valve block 30 is rotated by a certain angle, the first throttling part 3311a can correspond to the position of the second lead-out port 112; when the valve block 30 continues to rotate by a certain angle, the second throttling part 3311b can correspond to the position of the first lead-out port 111.

The first and

second chokes

3311a and 3311b are blocked by the plate-like portion 31 in the extending direction (i.e., along the valve block center axis direction), and the plate-like portion 31 is provided with the first choked hole portion 3101 and the second choked hole portion 3102, respectively, as described above. The filter chamber 35 is disposed above the plate portion 31, and in this embodiment, the valve device further includes a filter member 40 for filtering the refrigerant flowing through the orifice 311 of the valve block 30, so as to prevent the first orifice portion 3101 or the second orifice portion 3102 from being blocked by foreign objects and affecting the usability of the product. The filtering capacity of the filtering component 40 may be determined according to the aperture of the first throttling hole portion 3101 or the second throttling hole portion 3102, in combination with other requirements, for example, if the aperture of the throttling hole is in the range of 0.1mm to 0.3mm, the filtering component 40 can filter out at least impurities and foreign substances larger than 0.1mm when applied. In a specific arrangement, the mesh number of the filtering component 40 can be set to be larger than 100 meshes so as to meet the basic use requirement. Specifically, the filter element 40 may be formed by sintering tin bronze balls or stainless steel balls, or may be made of a multi-layer stainless steel mesh.

When the filter member 40 is fitted to the filter chamber section 35, an accommodation chamber R is formed between the filter member and the plate-like section 31, and the accommodation chamber R is located above the first throttle hole section 3101 and the second throttle section 3102. At this time, the valve block structure is configured to: the filter chamber portion 35 is partitioned from the first throttle portion 3311a and the second throttle portion 3311b by the plate portion 31, the first throttle portion 3311a communicates with the accommodating chamber R only through the first throttle hole portion 311a formed in the plate portion 31, and the second throttle portion 3311b communicates with the accommodating chamber R only through the second throttle hole portion 311b formed in the plate portion 31. Thus, when the first throttling part 3311a is rotated to a position corresponding to the second outlet port 112, the refrigerant flows into the accommodating chamber R after being filtered by the filter member 40 from above the valve block, and then only passes through the first throttling hole 3101 provided in the plate-shaped part 31, passes through the first throttling part 3311a, and then enters the second outlet port 112 and the corresponding second outlet connection pipe 15, thereby performing a throttling function on the corresponding outlet connection pipe. When the second throttling part 3311b rotates to a position corresponding to the first outlet pipe 111, the refrigerant flows into the accommodating chamber R after being filtered by the filter component 40 from above the valve block, and then only passes through the second throttling hole 3102 formed in the plate-shaped part 31, passes through the first throttling part 3311a, and then enters the first outlet pipe 111 and the corresponding first outlet connecting pipe 14, thereby throttling the refrigerant flow of the first outlet connecting pipe. In practice, the predetermined distance between the filter member 40 and the top surface of the plate-shaped portion 31 may be set as desired.

The valve block 30 in this embodiment can be made by: the body of the plate-shaped part 31 is manufactured by machining, and in order to avoid the influence on the first throttling hole part 3101 and the second throttling hole part 3102 during subsequent injection molding, the first throttling hole part 3101 and the second throttling hole part 3102 are not formed when the plate-shaped part 31 is used as an insert; the upper body 32 and the lower body 33 are integrally formed on the plate 31 by injection molding, and then the first throttle hole portion 3101 and the second throttle hole portion 3102 are formed at corresponding positions of the large diameter portion 3109 of the plate 31.

The first and

second orifice portions

3311a and 3311b provided in the lower body portion 33 corresponding to the first and

second orifice portions

3101 and 3102 are designed to allow the first and

second orifice portions

3101 and 3102 to communicate with the respective lead-out ports, respectively, and to allow the first and second orifice portions 3311 and 3311b to have a size larger than that of the respective first and

second orifice portions

3101 and 3102, respectively, thereby improving the manufacturability of the injection molding process and preventing the first and

second orifice portions

3101 and 3102 from being worn or contaminated by friction with the valve seat 11 during rotation of the valve block 30 to ensure reliability of the flow rate control.

With the electric switching valve according to the present embodiment, the rotor member drives the valve block 30 to rotate on the upper surface of the valve seat 11, so that the engagement portion 331 of the valve block 30 is engaged with the upper surface of the valve seat 11, and the notch portion 332 of the valve block 30 is selectively communicated with the first outlet port 111 and the second outlet port 112, thereby switching the refrigerant flow path. Meanwhile, since the valve block 30 is further provided with the first and

second throttling parts

3311a and 3311b and the first and second throttling

hole parts

3101 and 3102 provided on the plate-shaped part 31 of the valve block 30, the valve block 30 performs a throttling function for the respective lead-out ports at a certain specific rotational position.

Most of the plate-shaped part 31 inside the valve block 30 is located inside the injection molding material, only a small part of the first extension part 3106 and the second extension part 3107 is exposed out of the outer surface of the injection molding material, and the plate-shaped part avoids the part of the valve block inside which the sealing requirement is required, so that the sealing performance of the valve block is better.

The method for manufacturing the valve block will be described in detail with reference to fig. 7.

Referring to fig. 7, fig. 7 is a schematic structural diagram of the plate-shaped component assembly. The plate-shaped component is composed of a plurality of plate-shaped parts, and in the present embodiment, 4 plate-shaped parts are connected in series, and a first positioning part 31e is connected to one end of the first plate-shaped part 31a, and a second positioning part 31f is connected to one end of the fourth plate-shaped part 31 d. Taking the first plate-shaped part 31a as an example, the first extending part 3106a of the first plate-shaped part 31a is connected to the first positioning part 31e, the second extending part 3107a thereof is connected to the second plate-shaped part 31b, and so on, the second plate-shaped part 31b, the third plate-shaped part 31c, and the fourth plate-shaped part 31d are connected in sequence, and finally the fourth plate-shaped part is connected to the second positioning part 31f. It should be noted that the present embodiment is described by taking 4 plate-shaped portions as an example, and similarly, the mold is also taken 4 plate-shaped portions as an example, and it should be understood by those skilled in the art that the number of plate-shaped portions is not limited to 4, and only not less than 2 may be required in actual processing. If the number of the plate-like portions is less than 2, it is difficult to satisfy the mass production demand, and if the number of the plate-like portions is too large, the volume of the entire mold becomes large.

The first positioning portion 31e is provided with a first positioning hole 31e1, and is used for being matched with a positioning column on the mold for positioning; similarly, the second positioning portion 31f is provided with a second positioning hole 31f1 for matching and positioning with a corresponding positioning post on the mold. In order to prevent the plate-shaped portion from being misplaced on the front and back sides during operation, a gap portion 31f2 may be further provided in the second positioning portion 31f. In this way, if the front and back surfaces of the plate-like component are erroneously placed, the first positioning portion 31e cannot be attached to the mold because it is not provided with a missing portion.

Referring to fig. 8, fig. 8 is a schematic structural diagram of a mold assembly. The mold assembly comprises a first mold 100 and a second mold 200, the first mold 100 comprising a first mold cavity 105, the first mold cavity 105 having an overall shape corresponding to the shape of the plate shaped assembly and an overall edge dimension larger than the plate shaped assembly such that the overall contour of the plate shaped assembly is completely located within the first mold cavity 105 when the plate shaped assembly is placed into the first mold cavity 105. At the same time, the first mold cavity has a depth that can be matched to the thickness of the valve block. The first cavity 105 is provided with a first positioning post 101 at a position matching with the first positioning portion 31e of the plate-shaped component, and a second positioning post 102 at a position matching with the second positioning portion 31f, wherein the position of the first positioning post 101 is matched with the position of the first positioning hole 31e1, and the position of the second positioning post 102 is matched with the position of the second positioning hole 31f 1. Thus, when the plate-shaped component is placed in the first mold cavity 105, the first positioning column 101 passes through the first positioning hole 31e1, and the second positioning column 102 passes through the second positioning hole 31f1, so that the plate-shaped component is positioned in the first mold cavity 105. Since the overall contour of the first cavity 105 is adapted to the overall contour of the plate-like portion assembly, if the plate-like portion assembly is inadvertently mounted upside down during operation, the plate-like portion assembly cannot be smoothly placed into the first cavity 105 as a whole due to the presence of the cutout 31f2 and the portion of the first cavity 105 that matches the cutout 31f2. In order to further prevent operation errors, the outer diameter of the first positioning column 101 may be different from the outer diameter of the second positioning column 102; and the inner diameters of the first positioning hole 31e1 and the second positioning hole 31f1 are set to be different. Therefore, under the condition that the plate-shaped component is reversely installed, at least one positioning column cannot penetrate through one positioning hole.

In the first cavity 105, a plurality of third positioning posts 103 and fourth positioning posts 104 are further provided, and the number thereof is the same as that of the plate-shaped portions. Specifically, the third positioning column 103 passes through the central through hole 3103 of the plate-shaped portion, and limits the horizontal direction of the plate-shaped portion, taking the direction shown in fig. 8 as an example; the fourth positioning column 104 is abutted against the plate-shaped component, so that the plate-shaped component is limited in the vertical direction, and meanwhile, the part of the plate-shaped component, which is in contact with the fourth positioning column 104, cannot be filled with injection molding materials. Fig. 9 is a schematic view of the plate shaped component after it has been placed in the first mold cavity, as shown in fig. 9.

It should be noted that, in fig. 8, a total of two first mold cavities are provided, and the description is given above for one first mold cavity 105, and those skilled in the art can understand that the other mold cavity may also be provided in the same manner as the first mold cavity 105, and thus, the description is not repeated here.

The mold assembly further comprises a second mold 200 corresponding to the first cavity 105 of the first mold 100, the second mold 200 being provided with a second cavity 205, the second cavity 205 comprising a first socket portion 201 and a

second socket portion

202 and 4 separate valve block cavity portions 204, an end portion of the first positioning post 101 being inserted into the first socket portion 201 and an end portion of the second positioning post 102 being inserted into the second socket portion 202 when the first mold 100 is engaged with the second mold 200. The second boss portion 203 provided in each valve block cavity portion 204 is formed such that a first throttle portion 3311a and a second throttle portion 3311b are formed in the valve block at the time of injection molding, and the position of the second boss portion 203 is substantially located between a first through portion 3104 and a second through portion 3105 provided in the plate-shaped portion when the second mold 200 is engaged with the first mold 100.

In order to precisely fasten the first mold 100 and the second mold 200 together, a first stopper 107 may be provided on an outer circumferential portion of the first mold 100, and a second stopper 207 may be provided on an outer circumferential portion of the second mold 200, so that a relatively precise position may be ensured after the first mold 100 and the second mold are fastened together.

A first filling portion 106 is provided in the center of the first mold, the first filling portion 106 has 8 first runner portions 106a extending to the areas of the respective first mold cavities 105 where the valve blocks are located, and correspondingly, a second filling portion 206 is provided in the center of the second mold 200, the second filling portion 206 has 8 second runner portions 206a extending to the respective valve block cavity portions 204, and liquid inlets 206b are provided between the end portions of the second runner portions 206a and the respective valve block cavity portions 204 for communication. Thus, when the first mold 100 is engaged with the second mold 200, the first runner section 106a and the second runner section 206a form a channel for the flow of the injection molding material, and the feed port may be disposed outside the second mold 200 (not shown) and communicate with the second filling portion 206.

According to the die structure, the valve block is processed as follows:

1) A plate-shaped assembly was prepared.

The plate-shaped component may be formed by stamping a metal plate, for example, by directly forming the plate-shaped component by using a stamping die.

2) The plate-shaped component is placed in the first cavity 105 of the first mold 100, such that the first positioning hole 31e1 is matched with the first positioning post 101, the second positioning hole 31f1 is matched with the second positioning post 102, and the third positioning post 103 is matched with the central through hole of each plate-shaped component.

3) The second mold 200 is snapped onto the first mold 100 such that the first mold cavity 105 and the second mold cavity 205 combine to form relatively independent filling chambers.

4) Filling material is injected from the feed inlet, and the filling material enters the filling cavity through a liquid inlet arranged on the die cavity part of each valve block to form each valve block assembly.

5) And after the mould is opened, cutting the extension part of the plate-shaped component along the edge of the valve block by the injection-molded plate-shaped component to form an independent valve block component.

6) The first orifice portion 3101 and the second orifice portion 3102 are machined in the plate-like portion of the valve block to form a complete valve block.

By adopting the die structure and the processing method, 8 valve blocks can be formed at one time, injection molding operation is not required to be carried out on each valve block independently, and the processing efficiency can be greatly improved.

The electric switching valve with the valve block can be applied to a refrigeration cycle device. A refrigeration system for a refrigerator will be described as an example.

Fig. 10 is a schematic diagram of a refrigeration system of a dual temperature dual control refrigerator. As shown in fig. 10, the refrigeration system includes a compressor S1, a condenser S2 connected to an exhaust port of the compressor S1, the condenser S2 is connected to an inlet connection pipe 13 of an electric switching valve S3, a refrigerant enters the electric switching valve through the inlet connection pipe 13, and may respectively flow out from a first outlet connection pipe 14 and a second outlet connection pipe 15 according to different working positions, wherein the refrigerant flowing out from the first outlet connection pipe 14 enters a cold storage area evaporator S4 through a cold storage capillary tube S6; the refrigerant flowing out of the second outlet connection pipe 15 enters the freezing area evaporator S3 through the freezing capillary tube S7 and then returns to the compressor S1, forming a complete refrigeration cycle.

Referring to fig. 11, fig. 11 is a schematic diagram illustrating relative positions of a valve block and a valve seat when the electric switching valve is at different working positions. As shown in the figure, when the electric switching valve is in the first working position, the first outlet port 111 and the second outlet port both correspond to the notch portion 332 of the valve block, the first throttling hole portion 3101 and the second throttling hole portion 3102 both correspond to the matching portion 331 of the valve block, the first outlet port 112 and the second outlet port 112 are both communicated with the notch portion 332 and are in a fully open state, the refrigerant enters the refrigerating area from the first outlet connecting pipe 14, enters the freezing area from the second outlet connecting pipe 15, and both the freezing area and the refrigerating area are in a full-speed refrigerating state.

In the second operating position, the first outlet port 111 corresponds to the notch portion 332 of the valve block, and the second outlet port 112 corresponds to the first orifice portion 3101 of the valve block. At this time, the first lead-out port 111 is in a fully opened state in conduction with the notch portion 332, and the second lead-out port 112 is in a throttled state in conduction with the first throttle portion 3311 a. The refrigerant enters the refrigeration area from the first outlet connecting pipe 14, and the refrigeration area is in a refrigeration state; the refrigerant enters the freezing region after being throttled by the first throttle hole portion 3101, and the throttle flow rate may be set to be smaller than the flow rate of the freezing capillary tube S7. At the moment, the freezing area of the refrigerator reaches the set temperature, and the temperature can be accurately controlled by utilizing the throttling working position so as to reduce the temperature fluctuation.

In the third operating position, the first lead-out port 111 corresponds to the cut-out portion 332 of the valve block, and the second lead-out port 112 corresponds to the engagement portion 331 of the valve block. At this time, the first lead-out opening 111 is in conduction with the notch portion 332 to be in a fully opened state, and the second lead-out opening 112 is closed by the engaging portion 331 to be in a closed state. The refrigerant enters the refrigeration area from the first outlet connecting pipe, and the refrigeration area is in a refrigeration state; the freezing area is in a heat preservation state.

In the fourth operating position, the first lead-out port 111 corresponds to the second orifice portion 3102 of the valve block, and the second lead-out port 112 corresponds to the engagement portion 331 of the valve block. At this time, the first lead-out port 111 and the second throttle portion 3311b are in a throttled state by being communicated with each other, and the second lead-out port 112 is closed by the fitting portion 331 and is in a closed state. The refrigerant enters the cooling region after being throttled by the second throttle hole portion 3102, and the throttle flow rate may be set to be smaller than the flow rate of the refrigerating capillary tube S6. At the moment, the refrigerator cold storage area reaches the set temperature, and the throttle working position can be utilized to accurately control the temperature so as to reduce the temperature fluctuation.

In the fifth working position, the first and

second outlet ports

111 and 112 each correspond to the fitting portion 331 of the valve block. At this time, the first lead-out port 111 and the second lead-out port 112 are both closed by the fitting portion 331 and are in a closed state, and the refrigerating area and the freezing area are both in a heat-retaining state.

In the sixth operating position, the first outlet port 111 corresponds to the engagement portion 331 of the valve block, and the second outlet port 112 corresponds to the notch portion 332 of the valve block. At this time, the first outlet port 111 is closed by the engaging portion 331 and is in a closed state, and the second outlet port 112 is in a fully open state by being in communication with the notch portion 332. The refrigerant enters the freezing area from the second outlet connecting pipe 15, and the freezing area is in a refrigerating state; the cold storage area is in a heat preservation state.

It should be noted that the six working positions may be continuously or discontinuously arranged, and the corresponding working positions may be selected according to the temperature change conditions of the cooling area and the freezing area, so that the temperatures of the cooling area and the freezing area are in a predetermined range, and once a certain temperature area reaches a preset temperature, the corresponding channel of the corresponding temperature area may be used to be in a throttling working position to perform accurate temperature control, so as to reduce the temperature fluctuation. In addition, the above description is only given by taking a dual-temperature dual-control refrigerator as an example, and those skilled in the art can apply the electric switching valve to various types of refrigeration systems according to the teaching of the present invention.

It should be noted that the terms of orientation, upper, lower, top, bottom, etc. used herein are defined by the components shown in fig. 1 and the positional relationship between the components, and are only used for the sake of clarity and convenience of the technical solution, and it should be understood that the terms of orientation used herein should not limit the scope of protection of this patent.

The present invention has been described in detail above with reference to specific embodiments. The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims

1. A refrigeration cycle device comprises a compressor (S1), a condenser (S2), an electric switching valve (S3), a refrigerating area evaporator (S4) and a freezing area evaporator (S3), wherein the electric switching valve (S3) comprises an inlet connecting pipe (13), a first outlet connecting pipe (14) and a second outlet connecting pipe (15), an exhaust port of the compressor (S1) is connected with the condenser (S2), an outlet of the condenser (S2) is connected with the inlet connecting pipe (13), the first outlet connecting pipe (14) is connected with the refrigerating area evaporator (S4), and the second outlet connecting pipe (15) is connected with the freezing area evaporator (S3); the electric switching valve is characterized by further comprising a valve seat (11) and a valve block (30), wherein the valve seat (11) is provided with a first outlet (111) and a second outlet (112), the first outlet (111) is communicated with the first outlet connecting pipe (14), the second outlet (112) is communicated with the second outlet connecting pipe (15), the valve block (30) comprises a matching portion (331), a notch portion (332), a first throttling portion (3311 a) and a second throttling portion (3311 b), and the first outlet (111) and the second outlet (112) are arranged on circumferences which the center axis of the valve seat (11) is used as a circle center and different lengths are used as radiuses and are separated by a certain distance; the first throttling part (3311 a) and the second outlet port (112) are located on the same circumference with the central axis of the valve seat (11) as the center of the circle, and the second throttling part (3311 b) and the first outlet port (111) are located on the other circumference with the central axis of the valve seat (11) as the center of the circle; the valve block can rotate on the upper end face of the valve seat (11) in a fitting mode, and six working positions are formed:

a first operating position in which the first outlet port (111) and the second outlet port (112) are both in communication with the cutout (332), and the refrigeration area and the freezing area are both in a refrigerated state;

in the second working position, the first outlet (111) is communicated with the notch part (332), the second outlet (112) is communicated with the first throttling part (3311 b), the refrigerating area is in a refrigerating state, and the freezing area is in an accurate temperature control state;

in a third working position, the first outlet (111) is communicated with the notch part (332), the second outlet (112) is blocked by the matching part (331), the refrigerating area is in a refrigerating state, and the freezing area is in a heat preservation state;

in a fourth working position, the first outlet (111) is communicated with the second throttling part (3311 b), the second outlet (112) is blocked by the matching part (331), the cold storage area is in a precise temperature control state, and the freezing area is in a heat preservation state;

in the fifth working position, the first outlet (111) and the second outlet (112) are blocked by the matching part (331), and the cold storage area and the freezing area are in a heat preservation state;

and in a sixth working position, the first outlet (111) is blocked by the matching part (331), the second outlet (112) is communicated with the notch part (332), the refrigeration area is in a heat preservation state, and the freezing area is in a refrigeration state.

2. The refrigeration cycle apparatus according to claim 1, wherein the six operating positions are provided in series.

3. The refrigeration cycle apparatus of claim 1, wherein the six operating positions are non-consecutively disposed.

4. The refrigeration cycle apparatus according to claim 1, wherein the valve block (30) includes a plate-shaped portion (31), and an upper body portion (32) and a lower body portion (33) which are integrally injection-molded with the plate-shaped portion (31), the plate-shaped portion (31) is provided with a first orifice portion (3101) and a second orifice portion (3102), the lower body portion (33) of the valve block is penetratingly provided with a first orifice portion (3311 a) and a second orifice portion (3311 b), and openings of the first orifice portion (3311 a) and the second orifice portion (3311 b) are located on a surface of the fitting portion (331).

5. The refrigeration cycle apparatus according to claim 4, wherein the first throttle portion (3311 a) communicates with the first throttle hole portion (3101) and selectively communicates with the second lead-out port (112); the second throttle portion (3311 b) communicates with the second throttle hole portion (3102) and selectively communicates with the first outlet port (111).

6. The refrigeration cycle device according to claim 5, wherein the upper body portion (32) of the valve block (30) includes a filter chamber portion (35) and a receiving chamber (R), the filter chamber portion (35) is at least partially filled with a filter member (40), the receiving chamber (R) is located between the filter member (40) and the plate-like portion (31), the receiving chamber (R) communicates with the first throttle hole portion (3101), and the receiving chamber (R) communicates with the second throttle hole portion (3102).

7. The refrigeration cycle device according to claim 4, wherein the plate-like portion (31) includes a body portion (3108) and a large diameter portion (3109) formed integrally with the body portion (3108), the body portion (3108) has a central through hole (3103), and the first throttle hole portion (3101) and the second throttle hole portion (3102) are opened in the large diameter portion (3109).

8. The refrigeration cycle apparatus according to claim 7, wherein the first throttle hole portion (3101), the second throttle hole portion (3102) are located in the same radial direction, and the centers of the first throttle hole portion (3101), the second throttle hole portion (3102), and the center through hole (3103) are located on the same straight line on a plane defined by the surface of the plate-shaped portion (31).