CN113803934A

CN113803934A - Partitioned temperature control wine cabinet

Info

Publication number: CN113803934A
Application number: CN202111166521.0A
Authority: CN
Inventors: 曾伟明; 胡勇军; 李艺
Original assignee: GUANGDONG XINGXING REFRIGERATION EQUIPMENT CO LTD
Current assignee: GUANGDONG XINGXING REFRIGERATION EQUIPMENT CO LTD
Priority date: 2021-09-30
Filing date: 2021-09-30
Publication date: 2021-12-17
Anticipated expiration: 2041-09-30
Also published as: CN113803934B

Abstract

A partitioned temperature-controlled wine mixing cabinet includes a freezing chamber, a refrigerating chamber, a heat dissipation chamber, a heat dissipation assembly, a refrigeration assembly and a temperature control assembly; the refrigeration assembly includes a first condenser, a compressor, a first evaporator, and a second evaporator A compressor and a condenser are installed in the cooling chamber, the first evaporator and the second evaporator are installed in the refrigerating chamber and the freezing chamber respectively, and the first evaporator acts on the refrigerating chamber Refrigeration, the second evaporator acts on the refrigeration of the freezer compartment, and the first evaporator and the second evaporator share a condenser and a compressor, which reduces the installation of additional equipment, thereby reducing the number of bartenders size and difficulty of production.

Description

Partitioned temperature control wine cabinet

Technical Field

The invention relates to the technical field of wine cabinets, in particular to a partitioned temperature control wine cabinet.

Background

With the improvement of living standard, more and more people are pursuing the personalized demand of the substance on the basis of meeting the living demand of the substance. Beautiful wine receives people's liking from ancient times, and the kind of wine is also more and more now, along with brought the development of accent gradevin trade, and the less equipment of volume is regarded as to the accent gradevin, convenient transport and installation receive people's love and like gradually.

The functions of the existing wine mixing cabinet and the refrigerator are similar, and the existing wine mixing cabinet has the refrigeration and cold storage functions, but the size of the wine mixing cabinet is small, so that the functions of energy conservation, excellent heat preservation and temperature control of the refrigerator can not be met by installing numerous parts like the refrigerator, and the existing wine mixing cabinet which can integrate energy conservation, excellent heat preservation and temperature control is urgent to appear.

Disclosure of Invention

In view of the above-mentioned drawbacks, the present invention provides a wine cabinet with partitioned temperature control.

In order to achieve the purpose, the invention adopts the following technical scheme: a partitioned temperature control wine blending cabinet comprises a freezing chamber, a refrigerating chamber, a heat dissipation assembly, a refrigerating assembly and a temperature control assembly;

the refrigerating assembly comprises a first condenser, a compressor, a first evaporator, a second evaporator and a capillary tube, the compressor and the condenser are installed in the heat dissipation chamber, the first evaporator and the second evaporator are installed in the refrigerating chamber and the freezing chamber respectively, the first evaporator acts on refrigeration of the refrigerating chamber, and the second evaporator acts on refrigeration of the freezing chamber;

the outlet of the compressor is connected with the inlet of a condenser through a first pipeline, the outlet of the condenser is connected with the inlet of the first evaporator through a second pipeline, the outlet of the condenser is also connected with the inlet of the second evaporator through a third pipeline, and the outlet of the first evaporator and the outlet of the second evaporator are respectively connected with the inlet of the compressor through a fourth pipeline and a fifth pipeline;

the temperature control assembly is respectively arranged in the freezing chamber and the refrigerating chamber, the second pipeline is provided with a first electromagnetic valve, the third pipeline is provided with a second electromagnetic valve, and the temperature control assembly is respectively in electric signal connection with the first electromagnetic valve and the second electromagnetic valve;

the heat dissipation assembly is installed on one side of the condenser, and the condenser is fixed at the front end of the heat dissipation chamber.

Preferably, still include low pressure switch, low pressure switch set up in the entrance of compressor, low pressure switch is used for detecting the entering the atmospheric pressure of compressor, low pressure switch with the compressor electric connection.

Preferably, the freezing chamber is provided with an ice storage tank, two sides of the top of the ice storage tank are provided with slide rails, and a heat preservation door is slidably mounted on the slide rails;

the heat preservation door comprises at least one first sliding door and at least one second sliding door;

the bottom parts of the left end and the right end of the first sliding door extend downwards to form supporting parts, and the supporting parts, the sliding rails and the lower end surface of the first sliding door form a sliding chute;

when the heat preservation door completely covers the notch of the ice storage tank, one end of the second sliding door is placed into the sliding groove, and the second sliding door can freely slide in the sliding groove.

Preferably, the supporting portion is a vertical plate extending downwards from the left end surface and the right end surface of the first sliding door, the bottom of the vertical plate abuts against the sliding rail, the vertical plate is higher than the second sliding door, and the distance between the two vertical plates is greater than the width of the second sliding door.

Preferably, the radiating component comprises an air outlet component and an air inlet component, the air outlet component and the air inlet component are fixed on one side of the condenser, and the air outlet component is located above the air inlet component.

Preferably, still include air supply assembly, air supply assembly demountable installation is in radiator unit's one side, air supply assembly's air-out direction orientation the opening of heat dissipation room.

Preferably, a partition board is horizontally and detachably mounted in the ice storage tank, a plurality of leakage holes are formed in the partition board, and a chassis is arranged below the partition board.

Preferably, the chassis is provided with a water outlet, the chassis is obliquely arranged below the partition plate, and the water outlet is positioned at the lowest level position of the chassis.

Preferably, the refrigerator comprises at least one water baffle which is vertically fixed on the edge of the top of the freezing chamber.

Preferably, the freezer still includes the show trench, the show trench is located the front end of ice-cube holding tank, the show trench is provided with the barrier strip, the both ends of barrier strip are fixed in respectively the inner wall at both ends about the show trench.

One of the above technical solutions has the following advantages or beneficial effects:

1. the first evaporator and the second evaporator share a condenser and a compressor. The installation of extra equipment is reduced, so that the volume and the manufacturing difficulty of the wine mixing cabinet can be reduced.

2. The pulling department of heat preservation door uses single slide rail structure, avoids using cascaded structure to influence the thickness on freezing room filling foaming layer, has improved the package door effect of freezing room, and first sliding door is provided with the supporting part in addition, forms the spout through supporting part and slide rail cooperation for under the condition of single slide rail, the second sliding door also can freely slide.

3. This application all sets up air inlet subassembly and air-out subassembly in the front end of heat dissipation chamber, though the user is when transferring wine cabinet the place ahead and open walk-in or freezer, can be blown by the wind of heat dissipation chamber, but this design can be solved the side and all be shielded with the back and lead to unable radiating problem, guarantees to transfer the wine cabinet and places when any place, and its thermovent can not blockked up to the heat dissipation of heat dissipation chamber has been guaranteed.

Drawings

FIG. 1 is a schematic diagram of a refrigeration system of the present application;

FIG. 2 is a schematic structural diagram of one embodiment of the present application;

FIG. 3 is a schematic view of an embodiment of the present application showing the removal of a second sliding door;

FIG. 4 is an enlarged view at A in FIG. 3;

FIG. 5 is a schematic view of the construction of a first sliding door of the present application;

FIG. 6 is a schematic structural view of an embodiment of the present application with the insulated door removed;

FIG. 7 is an enlarged view at B in FIG. 6;

FIG. 8 is a schematic view of an embodiment of the present application after removal of the partition;

FIG. 9 is a front cross-sectional view of one embodiment of the present application;

fig. 10 is a schematic structural diagram of an air supply assembly according to an embodiment of the present application.

Wherein: the refrigerator comprises a refrigerating chamber 1, a freezing chamber 2, an ice storage tank 2a, a slide rail 2b, a heat dissipation chamber 3, a condenser 4, a compressor 5, a first evaporator 6, a second evaporator 7, a capillary tube 8, a first electromagnetic valve 9, a second electromagnetic valve 10, a temperature control assembly 11, a first pipeline 12, a second pipeline 13, a third pipeline 14, a fourth pipeline 15, a fifth pipeline 16, a low-pressure switch 17, a heat preservation door 18, a first sliding door 18a, a second sliding door 18b, a supporting part 19, a sliding chute 20, a display slot position 21, a blocking strip 22, a heat dissipation assembly 23, an air inlet assembly 23a, an air outlet assembly 23b, an air supply assembly 24, a frame 24a, a fan 24b, a mounting hole 24c, a partition plate 25, a leakage hole 25a, a chassis 26, a water outlet 27, a water baffle 28 and a water pipe 29.

Detailed Description

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

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1-10, a sectional temperature-controlled wine blending cabinet comprises a freezing chamber (2), a refrigerating chamber (1), a heat dissipation chamber (3), a heat dissipation assembly (23), a refrigeration assembly and a temperature control assembly (11);

the refrigeration assembly comprises a first condenser (4), a compressor (5), a first evaporator (6), a second evaporator (7) and a capillary tube (8), the compressor (5) and the condenser (4) are installed in the heat dissipation chamber (3), the first evaporator (6) and the second evaporator (7) are installed in the refrigerating chamber (1) and the freezing chamber (2) respectively, the first evaporator (6) acts on refrigeration of the refrigerating chamber (1), and the second evaporator (7) acts on refrigeration of the freezing chamber (2);

the outlet of the compressor (5) is connected with the inlet of a condenser (4) through a first pipeline (12), the outlet of the condenser (4) is connected with the inlet of the first evaporator (6) through a second pipeline (13), the outlet of the condenser (4) is also connected with the inlet of the second evaporator (7) through a third pipeline (14), and the outlet of the first evaporator (6) and the outlet of the second evaporator (7) are respectively connected with the inlet of the compressor (5) through a fourth pipeline (15) and a fifth pipeline (16);

the temperature control assembly (11) is respectively installed in the freezing chamber (2) and the refrigerating chamber (1), the second pipeline (13) is provided with a first electromagnetic valve (9), the third pipeline (14) is provided with a second electromagnetic valve (10), and the temperature control assembly (11) is respectively in electric signal connection with the first electromagnetic valve (9) and the second electromagnetic valve (10);

the heat dissipation assembly (23) is installed on one side of the condenser (4), and the condenser (4) is fixed to the front end of the heat dissipation chamber (3).

In the technical scheme of the application, centralized processing is performed on components except for refrigeration parts in the refrigeration system, namely the first evaporator (6) and the second evaporator (7) share one condenser (4) and one compressor (5). The installation of extra equipment is reduced, so that the volume and the manufacturing difficulty of the wine mixing cabinet can be reduced.

During refrigeration, the compressor (5) starts to suck refrigerant steam from the first evaporator (6) and the second evaporator (7) to enable new refrigerant to evaporate and absorb heat, so that the temperatures of the refrigerating chamber (1) and the freezing chamber (2) are reduced, the compressor (5) compresses the refrigerant steam into high-pressure high-temperature refrigerant steam, the compressed refrigerant steam enters the condenser (4) to release heat to ambient air and is subjected to liquefaction cooling under the same pressure, the flow of the cooled liquid refrigerant is controlled through the capillary tube (8) and enters the first evaporator (6) and the second evaporator (7), and the refrigeration and heat preservation of the refrigerating chamber (1) and the freezing chamber (2) are realized in a circulating mode.

In the existing refrigerator, a refrigerating chamber (1) and a freezing chamber (2) adopt independent refrigerating systems and use a variable-frequency compressor (5) to adjust the temperature of the freezing chamber (2) or the refrigerating chamber (1) so that the freezing chamber (2) and the refrigerating chamber (1) meet respective temperature requirements. However, in the technical solution of the present application, the first evaporator (6) and the second evaporator (7) share one set of the compressor (5) and the condenser (4), that is, when the first evaporator (6) and the second evaporator (7) are in operation, the amounts of the received liquid refrigerants are consistent, which results in that the temperatures of the refrigerating chamber (1) and the freezing chamber (2) are the same, and the refrigerating requirement cannot be met. In order to solve the problems, the first electromagnetic valve (9) and the second electromagnetic valve (10) are respectively arranged on the second pipeline (13) and the third pipeline (14), and the amount of liquid refrigerant flowing into the first evaporator (6) or the second evaporator (7) is controlled through the first electromagnetic valve (9) and the second electromagnetic valve (10), so that the working frequency of the first evaporator (6) and the second evaporator (7) is adjusted, and the refrigerating requirements of the refrigerating chamber (1) and the freezing chamber (2) are met. The first temperature measurement component is arranged in the refrigerating chamber (1) and can acquire the temperature of the refrigerating chamber (1), and when the temperature of the refrigerating chamber (1) meets the refrigerating requirement, the first temperature measurement component sends a closing instruction to the first electromagnetic valve (9), so that the first electromagnetic valve (9) is closed, the liquid refrigerant conveying of the first evaporator (6) is stopped, and the first evaporator (6) is prevented from continuously working and cooling. The action principle of the second temperature measurement component and the second electromagnetic valve (10) is the same as the working principle of the first temperature measurement component and the first electromagnetic valve (9). Accuse temperature subassembly (11) can be for the controller that the integration has the thermocouple, accuse temperature subassembly (11) sets up respectively in freezer (2) and walk-in (1) and detect the temperature of freezer (2) and walk-in (1) when the indoor temperature reachs the threshold value, first solenoid valve (9) or second solenoid valve (10) will be controlled to the controller, stops the transport to first evaporimeter (6) or second evaporimeter (7) refrigeration liquid to realize the temperature control of freezer (2) and walk-in (1), in addition this design can effectively improve the energy-conserving efficiency of accent wine cabinet, avoid unnecessary work.

Because the volume of adjusting the cabinet is less, many people user likes to place the wine mixing cabinet on the wall or a plurality of wine mixing cabinets are put side by side, but the user all can influence the heat dissipation of wine mixing cabinet implementing these mode of putting. As shown in fig. 2, in the configuration of the cocktail cabinet, the freezing chamber (2) is provided above the heat radiation chamber (3), and therefore heat cannot be radiated from above the heat radiation chamber (3). In order to solve the problem of prior art, this application sets up radiator unit (23) in the front end of radiating chamber (3), radiator unit (23) include air inlet subassembly (23a) and air-out subassembly (23b), when placing air inlet subassembly (23a) and air-out subassembly (23b), should move towards the air inlet direction of air inlet subassembly (23a) inside radiating chamber (3), the air-out direction orientation of air-out subassembly (23b) the place ahead of radiating chamber (3) for wind-force can carry out a set of circulation in radiating chamber (3) and take away the heat in radiating chamber (3). Thereby reduce the temperature in radiating chamber (3), wherein air inlet subassembly (23a) and air-out subassembly (23b) can be for conventional radiator fan or radiator fan (24b) that uses, when installation air inlet subassembly (23a) and air-out subassembly (23b), only need to separate certain distance with both and can avoid both to produce the phenomenon of air current disorder at the during operation. Although the user can be blown by the wind of the heat dissipation chamber (3) when opening the refrigerating chamber (1) or the freezing chamber (2) in front of the wine blending cabinet, the design can solve the problem that the side face and the back face are blocked to cause heat dissipation incapability, and the heat dissipation port of the wine blending cabinet cannot be blocked when the wine blending cabinet is placed at any place, so that the heat dissipation of the heat dissipation chamber (3) is ensured, and the integral heat dissipation of the wine blending cabinet is ensured.

Preferably, the air conditioner further comprises a low-voltage switch (17), wherein the low-voltage switch (17) is arranged at an inlet of the compressor (5), the low-voltage switch (17) is used for detecting air pressure entering the compressor (5), and the low-voltage switch (17) is electrically connected with the compressor (5).

Whether the liquid refrigerant controlled by the first electromagnetic valve (9) and the second electromagnetic valve (10) can enter the first evaporator (6) and the second evaporator (7) to meet the refrigeration requirement or not is adopted in the application, but when the refrigerating chamber (1) and the freezing chamber (2) meet the requirement of refrigeration temperature at the same time, the first electromagnetic valve (9) and the second electromagnetic valve (10) can be closed at the same time, but at the moment, the compressor (5) can still continue to work to output high-temperature and high-pressure gas. Therefore, high-temperature and high-pressure gas is blocked in the first pipeline (12) between the condenser (4) and the compressor (5), and when the pressure in the first pipeline (12) reaches a certain degree, the first pipeline (12) is broken, so that the normal operation of the refrigerating system is influenced. For this purpose, a low-pressure switch (17) is provided at the inlet of the compressor (5), the low-pressure switch (17) is capable of detecting the air pressure input to the compressor (5), because the first electromagnetic valve (9) and the second electromagnetic valve (10) are closed, no liquid refrigerant enters the first evaporator (6) and the second evaporator (7), gas generated by the work of the first evaporator (6) and the second evaporator (7) is reduced at the moment, the current refrigerating chamber (1) and the refrigerating chamber (2) can be judged to meet the refrigerating temperature requirement only by detecting that the air pressure input to the compressor (5) is reduced to a certain degree, the compressor (5) is not required to be continuously compressed, the low-pressure switch (17) controls the compressor (5) to be closed at the moment, the air pressure in the first pipeline (12) is ensured to be stable, and meanwhile, the compressor (5) is prevented from being damaged due to idling. In addition, when the first electromagnetic valve (9) or the second electromagnetic valve (10) is opened, liquid refrigerant enters the first evaporator (6) or the second evaporator (7) to work, gas is generated, and the compressor (5) is restarted when the low-pressure switch (17) detects that certain air pressure is met.

Preferably, the freezing chamber (2) is provided with an ice storage tank (2a), two sides of the top of the ice storage tank (2a) are provided with slide rails (2b), and a heat preservation door (18) is slidably mounted on the slide rails (2 b);

the thermal door (18) comprises at least one first sliding door (18a) and at least one second sliding door (18 b);

supporting parts (19) extend downwards from the bottoms of the left end and the right end of the first sliding door (18a), and the supporting parts (19), the sliding rails (2b) and the lower end surface of the first sliding door (18a) form a sliding chute (20);

when the thermal insulation door (18) completely covers the notch of the ice storage groove (2a), one end of the second sliding door (18b) is placed into the chute (20), and the second sliding door (18b) can freely slide in the chute (20).

In the technical scheme of this application, the top both sides of ice-cube holding tank (2a) are provided with only a slide rail (2b), and when production, the producer of being convenient for makes, has reduced the production degree of difficulty of producer. Meanwhile, the influence of one sliding rail (2b) on the thickness of the foaming layer of the ice storage tank (2a) is smaller than that of the existing wine mixing cabinet, so that the heat preservation effect of the ice storage tank (2a) is improved.

However, since only one slide rail (2b) is provided, the first sliding door (18a) and the second sliding door (18b) can only slide on the one slide rail (2b), and when the first sliding door (18a) and the second sliding door (18b) completely cover the notch of the ice storage tank (2a), there is no slidable space between the first sliding door (18a) and the second sliding door (18b), and a user can only lift one of them to get stuck on the ice storage tank (2 a). In order to solve the problem, in the technical scheme of the application, support portions (19) extend downwards from the bottoms of the two ends of the first sliding door (18a), when the first sliding door (18a) is placed on the sliding rail (2b), the support portions (19) lift the first sliding door (18a), at the moment, only the support portions (19) slide on the sliding rail (2b) when the first sliding door (18a) slides, the contact area between the first sliding door (18a) and the sliding rail (2b) when the first sliding door (18a) slides is greatly reduced, at the moment, the support portions (19), the sliding rail (2b) and the lower end face of the first sliding door (18a) form a sliding groove (20), and the second sliding door (18b) can freely slide in the sliding groove (20). The problem that the first sliding door (18a) or the second sliding door (18b) cannot slide due to a single sliding rail (2b) is solved. Also in the present application, when the first sliding door (18a) and the second sliding door (18b) completely cover the notch of the ice storage tank (2a), the second sliding door (18b) is also partially put into the chute (20) so that the second sliding door (18b) can always slide in the chute (20). The second sliding door (18b) is prevented from sliding to the extreme end to escape from the chute (20) when the ice storage tank (2a) is completely sealed. So that the user needs to realign the second sliding door (18b) with the chute (20) when the first sliding door (18a) or the second sliding door (18b) is slid again, which seriously affects the user experience.

In addition, in another technical scheme of the application, a plurality of first sliding doors (18a) and one second sliding door (18b) can be combined, so that the degree of freedom of the whole assembly of the wine blending cabinet is improved, and more personalized choices are provided for users.

Preferably, the supporting portion (19) is a vertical plate extending downwards from the left end surface and the right end surface of the first sliding door (18a), the bottom of the vertical plate abuts against the sliding rail (2b), the height of the vertical plate is higher than that of the second sliding door (18b), and the distance between the two vertical plates is greater than the width of the second sliding door (18 b).

The normal sliding of the first sliding door (18a) and the second sliding door (18b) can not be influenced only when the height of the vertical plates is higher than that of the second sliding door (18b) and the distance between the two vertical plates is larger than the width of the second sliding door (18 b). In addition, the first sliding door (18a) and the second sliding door (18b) are used for sealing the ice storage tank (2a) and preserving heat, if the height of the supporting part (19) is too high, the distance between the first sliding door (18a) and the second sliding door (18b) is too large, so that the sealing performance of the ice storage tank (2a) is affected, the height of the supporting part (19) only needs to be 0.5 CM-1 CM higher than the height of the second sliding door (18b) in production, the sliding between the first sliding door and the second sliding door is not affected at the distance, and meanwhile, the sealing performance of the ice storage tank (2a) can be guaranteed.

Preferably, radiating component (23) is including air-out subassembly (23b) and air inlet subassembly (23a), air-out subassembly (23b) is fixed in with air inlet subassembly (23a) one side of condenser (4), air-out subassembly (23b) is located the top of air inlet subassembly (23 a).

As is well known, when the gas temperature rises, the gas rises, the air outlet assembly (23b) is arranged above the air inlet assembly (23a), the air heated in the heat dissipation chamber (3) rises, and then the air is extracted and taken out of the heat dissipation chamber (3) by the air outlet assembly (23b), so that the amount of hot air extracted in the heat dissipation chamber (3) can be increased, and the heat dissipation performance is improved.

Preferably, the cooling device further comprises an air supply assembly (24), the air supply assembly (24) is detachably mounted beside the heat dissipation assembly (23), and the air outlet direction of the air supply assembly (24) faces to the opening of the heat dissipation chamber (3).

Because air-out subassembly (23b) goes out the radiating chamber (3) with the hot-air in radiating chamber (3) after, still have a hot-air because the gas flow velocity is not enough by air inlet subassembly (23a) inhales in radiating chamber (3) to reduce heat dispersion, for this reason, this application still is provided with air supply subassembly (24), the air-out direction of air supply subassembly (24) with air-out subassembly (23b) is the same, can improve the velocity of flow that sends out the hot-air and increase the extraction volume of hot-air, guarantees that the hot-air blows off the one moment of radiating chamber (3) can have sufficient velocity of flow not by air inlet subassembly (23a) extraction, thereby improves heat dispersion. The air supply assembly (24) comprises a frame (24a) and at least one fan (24b), the fan (24b) is fixed in the frame (24a), and a mounting hole (24c) is formed in the edge of the frame (24 a).

In actual installation, the frame (24a) is optimally fixed above the heat dissipation assembly (23) and can extract hot air together with the air outlet assembly (23b), the number of the fans (24b) is determined according to the volume of the heat dissipation chamber (3), and when the volume of the heat dissipation chamber (3) is larger, the number of the fans (24b) should be correspondingly increased.

When the frame (24a) is installed, the installation hole (24c) on the frame (24a) can be aligned with the hole in the heat dissipation chamber (3), and then a screw is screwed into the installation hole (24c) to complete the installation and fixation of the air supply assembly (24).

Preferably, a partition plate (25) is horizontally and detachably mounted in the ice storage tank (2a), a plurality of leakage holes (25a) are formed in the partition plate (25), and a chassis (26) is arranged below the partition plate (25).

In order to improve the energy-saving effect, the refrigeration effect of the refrigerating chamber (1) and the freezing chamber (2) is controlled by the first electromagnetic valve (9) and the second electromagnetic valve (10). Because the volume size of the wine mixing cabinet is small, redundant parts cannot be installed to increase the temperature control precision in the refrigerating chamber (1) and the freezing chamber (2). Be provided with the ice-cube storage in freezer (2) and just deposit the ice-cube, when refrigeration effect reduces, the ice-cube can melt, causes the inside ponding of freezer (2), and the ice-cube surface has moisture in addition, when people take out the ice-cube from freezer (2), the moisture on ice-cube surface splashes easily, and the use of giving people brings a great deal of inconvenience.

For this purpose, the present application provides the partition (25) horizontally across the freezer compartment (2), and when ice cubes are placed into the freezer compartment (2), the ice cubes fall onto the partition (25). A plurality of small openings (25a) have been seted up in baffle (25), melt when the ice-cube produces the water, the drop of water can be followed small opening (25a) is dripped downwards, drops on chassis (26), keeps apart ponding and ice-cube, avoids ponding to breed the bacterial contamination ice-cube, has ensured the food safety of ice-cube.

And the downward orthographic projection of the partition plate (25) is completely projected on the chassis (26), so that the chassis (26) has enough width to catch all accumulated water, the accumulated water is prevented from dripping into parts in the wine mixing cabinet, and certain electronic parts cannot be used due to water inflow.

Baffle (25) can be fixed in through the mode of screw in freezer (2), convenient subsequent dismantlement baffle (25), it is right chassis (26) clean, keep the inside health of freezer (2).

Preferably, the chassis (26) is provided with a water outlet (27), the chassis (26) is obliquely arranged below the partition plate (25), and the water outlet (27) is positioned at the lowest level position of the chassis (26).

The chassis (26) is obliquely arranged to facilitate accumulated water to flow downwards, the water outlet (27) is arranged at the tail end of the accumulated water outflow part to facilitate accumulated water to be discharged, and accumulated water is prevented from staying at the bottom.

Because ponding all drips the storage on chassis (26), when ponding storage reachd the certain degree, can follow leak hole (25a) are gushed baffle (25), so need be in chassis (26) set up outlet (27), the export of outlet (27) has connect water pipe (29) or folding tube, through water pipe (29) or folding tube with water draw the wine mixing cabinet outside, lead water pipe (29) to near condenser (4) in an embodiment of this application, because the temperature of ponding is lower, pass through the water course ponding can absorb condenser (4) during condenser (4) the heat at the during operation to help refrigerating system heat dissipation.

Preferably, at least one water guard plate (28) is included, and the water guard plate (28) is vertically fixed to the edge of the top of the freezing chamber.

When the ice blocks are melted, the surface of the ice blocks is somewhat provided with moisture, when the ice blocks are taken up, the moisture is likely to fall on the sliding rail (2b) of the heat preservation door (18), when the heat preservation door (18) slides, water drops are splashed, and the water baffle plate (28) can block water splash and prevent the moisture from dropping on the ground or the wall.

Preferably, freezer (2) are still including show trench (21), show trench (21) are located the front end of ice-cube holding tank (2a), show trench (21) are provided with and block strip (22), the both ends that block strip (22) are fixed in respectively the inner wall at both ends about show trench (21).

Show trench (21) by the baffle on the left and right sides ice-cube holding tank (2a) with the roof of walk-in (1) constitutes, only need be in the top of walk-in (1) is attached two baffles and both can be formed, and processing is simple, moreover show trench (21) can be used for placing the beverage bottle, and the show trench (21) that increase has simultaneously increased the practicality of accent wine cabinet, convenience of customers show and prevent the beverage bottle. And the blocking strip (22) is positioned at the outer side of the wine bottle and plays a role in blocking the wine bottle from falling outwards.

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

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

Claims

1. A zone temperature-controlled wine bartending cabinet, characterized in that it comprises a freezer compartment (2), a refrigerating compartment (1), a heat dissipation chamber (3), a heat dissipation assembly (23), a refrigeration assembly and a temperature control assembly (11);

The refrigeration assembly includes a first condenser (4), a compressor (5), a first evaporator (6), a second evaporator (7) and a capillary tube (8), and the heat dissipation chamber (3) is provided with a capillary tube (8). A compressor (5) and a condenser (4), the first evaporator (6) and the second evaporator (7) are respectively installed in the refrigerating chamber (1) and the freezing chamber (2), the first evaporator (6) and the second evaporator (7) An evaporator (6) acts on the refrigeration of the refrigerating chamber (1), and the second evaporator (7) acts on the refrigeration of the freezing chamber (2);

The outlet of the compressor (5) is connected to the inlet of the condenser (4) through a first pipeline (12), and the outlet of the condenser (4) is connected to the first evaporator (6) through a second pipeline (13). ), the outlet of the condenser (4) is also connected to the inlet of the second evaporator (7) through a third pipe (14), and the outlet of the first evaporator (6) is connected to the second evaporator (7). ) outlet is connected to the inlet of the compressor (5) through the fourth pipeline (15) and the fifth pipeline (16) respectively;

The temperature control assembly (11) is installed in the freezer compartment (2) and the refrigerator compartment (1) respectively, the second pipe (13) is installed with a first solenoid valve (9), and the third pipe ( 14) A second solenoid valve (10) is installed, and the temperature control assembly (11) is electrically connected to the first solenoid valve (9) and the second solenoid valve (10) by electrical signals respectively;

2. The temperature-controlled wine mixing cabinet according to claim 1, further comprising a low-pressure switch (17), wherein the low-pressure switch (17) is arranged at the inlet of the compressor (5), The low pressure switch (17) is used to detect the air pressure entering the compressor (5), and the low pressure switch (17) is electrically connected to the compressor (5).

3. The temperature-controlled bartending cabinet according to claim 1, wherein the freezing chamber (2) is provided with an ice cube storage slot (2a), and the top of the ice cube storage slot (2a) is provided with an ice cube storage slot (2a). Slide rails (2b) are provided on both sides of the slide rail (2b), and a thermal insulation door (18) is slidably installed on the slide rails (2b);

The heat preservation door (18) comprises at least one first sliding door (18a) and at least one second sliding door (18b);

The bottoms of the left and right ends of the first sliding door (18a) protrude downwardly with support parts (19). The end face constitutes a chute (20);

When the heat preservation door (18) completely covers the notch of the ice cube storage slot (2a), one end of the second sliding door (18b) is inserted into the sliding slot (20), and the second sliding door (18b) is inserted into the sliding slot (20). The door (18b) can slide freely in the chute (20).

4 . The temperature-controlled wine bartending cabinet according to claim 3 , wherein the support portion ( 19 ) is an upright extending downward from the left and right end faces of the first sliding door ( 18 a ). 5 . The bottom of the vertical plate is in contact with the sliding rail (2b), the height of the vertical plate is higher than the height of the second sliding door (18b), and the distance between the two vertical plates is greater than that of the second sliding door (18b). The width of the two sliding doors (18b).

5 . The temperature-controlled wine mixing cabinet according to claim 1 , wherein the heat dissipation assembly ( 23 ) comprises an air outlet assembly ( 23 b ) and an air intake assembly ( 23 a ), and the air outlet assembly ( 23 a ). 6 . 23b) and the air inlet assembly (23a) are fixed on one side of the condenser (4), and the air outlet assembly (23b) is located above the air inlet assembly (23a).

6. A temperature-controlled wine mixing cabinet according to claim 1, characterized in that it further comprises an air supply assembly (24), and the air supply assembly (24) is detachably installed on the side of the heat dissipation assembly (23) , the air outlet direction of the air supply assembly (24) faces the opening of the heat dissipation chamber (3).

7. A partitioned temperature-controlled wine bartender according to claim 3, characterized in that, a partition (25) is horizontally detachably installed in the ice cube storage tank (2a), and the partition (25) A plurality of leak holes (25a) are opened, and a bottom plate (26) is provided under the partition plate (25).

8 . The temperature-controlled wine bartending cabinet according to claim 3 , wherein the chassis ( 26 ) is provided with a drain port ( 27 ), and the chassis ( 26 ) is obliquely arranged on the partition plate. 9 . Below (25), the water outlet (27) is located at the lowest horizontal position of the chassis (26).

9. The temperature-controlled wine mixing cabinet according to claim 8, characterized in that it comprises at least one water baffle (28), and the water baffle (28) is vertically fixed on the top of the freezer compartment. on the edge.

10. The temperature-controlled bartending cabinet according to claim 3, characterized in that, the freezer compartment (2) further comprises a display slot (21), and the display slot (21) is located in the ice At the front end of the block storage slot (2a), the display slot (21) is provided with a blocking strip (22), and both ends of the blocking strip (22) are respectively fixed to the inner walls of the left and right ends of the display slot (21). .