CN218936749U - Novel energy-saving ice maker set - Google Patents

Abstract

The utility model discloses a novel energy-saving ice maker group, which comprises a shell, a control panel, a controller, a compressor, an electromagnetic valve A, a condenser, an expansion valve, an electromagnetic valve B and an ice making device, wherein the shell is arranged on the shell; the control panel is embedded on the shell, the controller is electrically connected with the control panel, the compressor is connected with the electromagnetic valve A, the electromagnetic valve A is connected with the condenser, one end of the condenser is connected with the expansion valve, the electromagnetic valve B is arranged behind the expansion valve, the electromagnetic valve B is connected with the ice making device, the ice making device is connected with the compressor through a pipeline to form a loop, and the controller is electrically connected with the electromagnetic valve A and the electromagnetic valve B; when the evaporator A is opened singly, the refrigerant returns to the compressor through the pipeline after ice is made in the evaporator A, the ice maker is in an ice melting state, the electromagnetic valve A and the electromagnetic valve B are opened to form a passage, and the high-temperature and high-pressure refrigerant generated by the compressor is directly input into the evaporator A through the pipeline for ice melting, so that the introduction of external energy during ice melting is reduced, and the energy consumption is reduced.

Description

Novel energy-saving ice maker set

Technical Field

The utility model relates to the field of ice making, in particular to a novel energy-saving ice making machine set.

Background

In hot summer, the ice cubes are usually used for removing summer heat and icing, the effect is outstanding, the application is wide, with the development of technology, the ice making machine is mainly used for making ice cubes manually, the principle that a great amount of heat is required to be absorbed when low-temperature gas is converted into high-temperature liquid is mainly applied to the ice making machine, the refrigerant flows through an ice barrel provided with a prefabricated ice grid to absorb the heat of the water in the ice barrel so as to freeze and ice the ice, the traditional ice making machine can discharge a great amount of heat when the refrigerating liquid is converted from high-temperature high-pressure liquid to low-temperature gas in ice making, and the ice cubes are required to be dragged from the ice grid by absorbing the heat in ice taking, so that the ice making machine wastes a great amount of energy, and has high energy consumption.

Disclosure of Invention

In order to solve the problems in the background technology, the utility model aims to provide a novel energy-saving ice making unit which is simple to operate, efficient and energy-saving.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a novel energy-saving ice maker group comprises a shell, a control panel, a controller, a compressor, an electromagnetic valve A, a condenser, an expansion valve, an electromagnetic valve B and an ice making device; the control panel is inlaid on the shell, the controller is electrically connected with the control panel, the compressor is connected with the electromagnetic valve A, the electromagnetic valve A is connected with the condenser, one end of the condenser is connected with the expansion valve, the electromagnetic valve B is arranged behind the expansion valve, the electromagnetic valve B is connected with the ice making device, the ice making device is connected with the compressor through a pipeline to form a loop, and the controller is electrically connected with the electromagnetic valve A and the electromagnetic valve B.

As a preferred aspect of the present utility model, the ice-making device includes a solenoid valve C, an evaporator a, a solenoid valve D, a solenoid valve E, an evaporator B, and a solenoid valve F; the front end of the evaporator A is fixedly provided with a solenoid valve C, the rear end of the evaporator A is fixedly provided with a solenoid valve D, the front end of the evaporator B is fixedly provided with a solenoid valve E, the rear end of the evaporator B is fixedly provided with a solenoid valve F, and the controller is respectively electrically connected with the solenoid valve C, the solenoid valve D, the solenoid valve E and the solenoid valve F.

Preferably, the electromagnetic valve C is connected to the electromagnetic valve F via a conduit, and the electromagnetic valve D is connected to the electromagnetic valve E via a conduit.

Preferably, the electromagnetic valve A and the electromagnetic valve B are connected through a pipeline.

As preferable aspects of the present utility model, the evaporator a includes a water filling port, a water tank, a water pump, a sprayer, an ice-making tray, a turnover partition plate, a water blocking tank and an ice storage tank; the water injection port is fixed above the water tank, one end of the water pump extends into the water tank, the other end of the water pump is connected with the sprayer, the sprayer is fixed above the ice making grid, the overturning baffle plate is arranged at the front end of the bottom of the ice making grid, the water retaining groove is fixed below the ice making grid, the water retaining groove is connected with the water tank, and the ice storage groove is arranged below the water retaining groove.

In the utility model, preferably, a copper tube A for making ice is fixed at the rear part of the ice making grid, a refrigerating groove is formed in the ice making grid, and a copper tube B for making ice is arranged in the refrigerating groove.

Compared with the prior art, the utility model has the following beneficial effects:

1. according to the utility model, the electromagnetic valve A and the electromagnetic valve B are connected through the pipeline, the on-off of the electromagnetic valve A and the electromagnetic valve B is controlled by the controller, when the evaporator A is opened singly, the refrigerant passes through the compressor, the condenser and the expansion valve, and after the ice making grid makes ice in the evaporator A, the refrigerant returns to the compressor through the pipeline, and when the ice making machine is in an ice melting state, the electromagnetic valve A and the electromagnetic valve B are opened to form a passage, and the high-temperature high-pressure refrigerant generated by the compressor is directly input into the evaporator A through the pipeline for melting ice of equipment, so that the introduction of external energy during ice melting is reduced, and the energy consumption is reduced.

2. According to the utility model, the electromagnetic valve C is connected with the electromagnetic valve F through the guide pipe, the electromagnetic valve D is connected with the electromagnetic valve E through the guide pipe, when the evaporator B is in the ice melting state, the electromagnetic valve D and the electromagnetic valve E are controlled to be communicated through the controller, so that high-temperature refrigerating fluid generated after the evaporator A is used for making ice flows to the evaporator B through the electromagnetic valve D and the electromagnetic valve E, the high-temperature refrigerating fluid generated after the evaporator A is used for providing energy required by the ice melting of the evaporator B, and meanwhile, the high-temperature refrigerating fluid generated after the evaporator B is used for providing energy required by the ice melting of the evaporator A when the evaporator A is in the ice melting state, so that the aim of reducing energy consumption is achieved.

3. According to the utility model, the ice making copper pipe A is fixed at the rear part of the ice making grid, the refrigerating groove is formed in the ice making grid, the ice making copper pipe B is arranged in the refrigerating groove, the cooling area of the ice making area in the ice making grid is increased, and the thickness required for ice making is reduced due to multi-surface cooling, so that the energy loss caused by the thickness of ice cubes is reduced, and meanwhile, the ice making time is reduced, and therefore, the energy is saved.

Drawings

FIG. 1 is a schematic diagram of the main structure of an ice maker according to the present utility model;

FIG. 2 is a schematic plan view of the main body of the ice maker according to the present utility model;

FIG. 3 is a schematic view of a single cycle planar structure of the ice maker of the present utility model;

FIG. 4 is a schematic plan view of an ice maker set according to the present utility model;

fig. 5 is a schematic diagram of the ice making tray of the present utility model.

1, a shell; 2. a control panel; 3. a controller; 4. a compressor; 5. a solenoid valve A; 6. a condenser; 7. an expansion valve; 8. a solenoid valve B; 9. an ice making device; 10. a solenoid valve C; 11. an evaporator A; 12. a solenoid valve D; 13. a solenoid valve E; 14. an evaporator B; 15. a solenoid valve F; 16. a water filling port; 17. a water tank; 18. a water pump; 19. a sprayer; 20. making ice trays; 21. turning over the partition board; 22. a water blocking groove; 23. an ice storage tank; 24. a copper matte tube A is manufactured; 25. a refrigerating tank; 26. and (5) manufacturing the matte tube B.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 5, the present utility model provides a novel energy-saving ice maker set comprising a housing 1, a control panel 2, a controller 3, a compressor 4, a solenoid valve A5, a condenser 6, an expansion valve 7, a solenoid valve B8, and an ice making device 9; the control panel 2 is inlaid on the shell 1, the controller 3 is electrically connected with the control panel 2, the compressor 4 is connected with the electromagnetic valve A5, the electromagnetic valve A5 is connected with the condenser 6, one end of the condenser 6 is connected with the expansion valve 7, the electromagnetic valve B8 is arranged behind the expansion valve 7, the electromagnetic valve B8 is connected with the ice making device 9, the ice making device 9 is connected with the compressor 4 through a pipeline to form a loop, and the controller 3 is electrically connected with the electromagnetic valve A5 and the electromagnetic valve B8.

Referring to fig. 2, solenoid valve A5 is connected to solenoid valve B8 by a pipe.

Through connecting the electromagnetic valve A5 with the electromagnetic valve B8 through a pipeline, the controller 3 controls the on-off of the electromagnetic valve A5 and the electromagnetic valve B8, when the evaporator A11 is opened singly, the refrigerant passes through the compressor 4, the condenser 6 and the expansion valve 7, the refrigerant is cooled in the evaporator A11 to make ice of the ice making grid 20 and then returns to the compressor 4 through the pipeline, the electromagnetic valve A5 and the electromagnetic valve B8 are opened to form a passage under the ice melting state of the ice making machine, and the high-temperature and high-pressure refrigerant generated by the compressor 4 is directly input into the evaporator A11 through the pipeline for equipment ice melting, so that the introduction of external energy during ice melting is reduced, and the energy consumption is reduced.

Referring to fig. 1, solenoid valve C10 is connected to solenoid valve F15 via a conduit, and solenoid valve D12 is connected to solenoid valve E13 via a conduit.

Through connecting the electromagnetic valve C10 with the electromagnetic valve F15 through a conduit, the electromagnetic valve D12 is connected with the electromagnetic valve E13 through a conduit, when the evaporator B14 is in an ice melting state, the electromagnetic valve D12 and the electromagnetic valve E13 are controlled by the controller 3 to be communicated, so that high-temperature refrigerating fluid generated after the evaporator A11 is made into ice flows to the evaporator B14 through the electromagnetic valve D12 and the electromagnetic valve E13, the high-temperature refrigerating fluid generated after the evaporator A11 is made into ice is used for providing the energy required by the ice melting of the evaporator B14, and meanwhile, the high-temperature refrigerating fluid generated after the evaporator B14 is made into ice when the evaporator A11 is in the ice melting state is used for providing the energy required by the ice melting of the evaporator A11, so that the aim of reducing energy consumption is achieved.

Referring to fig. 5, an ice making copper pipe a24 is fixed at the rear of the ice making tray 20, a refrigerating tank 25 is provided in the ice making tray 20, and an ice making copper pipe B26 is provided in the refrigerating tank 25.

Through the fixed ice making copper pipe A24 in ice making grid 20 rear portion, the inside refrigeration groove 25 that sets up of ice making grid 20 sets up ice making copper pipe B26 in the refrigeration groove 25, increases the ice making district cooling area in the ice making grid 20, because the multiaspect cooling, makes the required thickness of ice making reduce, reduces the energy loss because of ice-cube thickness brings and has reduced the time of ice making simultaneously to the energy has been practiced thrift.

Application method

The working principle and the using flow of the utility model are as follows: the ice maker is started, an ice making instruction is input on a control panel, a water pump is started, water in a water tank is pumped out and is input into a sprayer, the sprayer sprays evenly to an ice making grid, redundant water drops flow back to the water tank, ice making gas enters a copper making pipe A and a copper making pipe B to absorb heat in the ice making grid, water in the ice making grid is condensed into ice, the ice making gas in the copper making pipe A and the copper making pipe B is replaced by high-temperature liquid during ice melting, the temperature of the inner wall of the ice making grid is increased, the surface of ice cubes is melted into water, the ice cubes slide downwards under the action of gravity, and a turnover baffle plate is pushed to block the water blocking groove, so that the ice cubes fall into an ice storage groove; when one evaporator is started singly, the compressor compresses the refrigerating fluid into high-temperature high-pressure fluid, the temperature is reduced through the condenser, the expansion valve expands into low-temperature gas to enter the evaporator A, the low-temperature gas is converted into high-temperature fluid to flow back to the compressor after heat is absorbed, the controller controls the electromagnetic valve A and the electromagnetic valve B to be opened during ice melting, the condenser and the expansion valve stop working, and the high-temperature high-pressure refrigerant generated by the compressor is directly input into the evaporator A for ice melting through a pipeline; when the two evaporators are started, the controller controls the evaporator A to be started first, the compressor compresses the refrigerating fluid into high-temperature high-pressure fluid, the temperature of the refrigerating fluid is reduced through the condenser, the expansion valve expands into low-temperature gas to enter the evaporator A and the evaporator B, the low-temperature gas is converted into high-temperature fluid to flow back to the compressor after absorbing heat, the evaporator A is started first, the evaporator B is still in an ice-making state when the evaporator A enters an ice-melting state, the controller controls the electromagnetic valve C and the electromagnetic valve F to be started, the high-temperature refrigerating fluid generated by ice making of the evaporator B flows into the evaporator A through the electromagnetic valve C and the electromagnetic valve F, ice-melting operation is carried out in the evaporator A by utilizing heat of the high-temperature refrigerating fluid generated by ice making of the evaporator B, the evaporator A enters the ice-melting state after a period of time, the evaporator A is in the ice-making state at the moment, the controller controls the electromagnetic valve D and the electromagnetic valve E to be started, and the high-temperature refrigerating fluid generated by ice making of the evaporator A flows into the evaporator B through the electromagnetic valve D and the electromagnetic valve E, and ice-melting operation is carried out in the evaporator B in the reciprocating mode alternately.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a novel energy-conserving ice maker group which characterized in that: comprises a shell (1), a control panel (2), a controller (3), a compressor (4), an electromagnetic valve A (5), a condenser (6), an expansion valve (7), an electromagnetic valve B (8) and an ice making device (9); control panel (2) are inlayed on casing (1), controller (3) are connected with control panel (2) electricity, compressor (4) are connected with solenoid valve A (5), solenoid valve A (5) are connected with condenser (6), condenser (6) one end is connected with expansion valve (7), be provided with solenoid valve B (8) behind expansion valve (7), solenoid valve B (8) are connected with ice making device (9), ice making device (9) are connected with compressor (4) through the pipeline and are formed the return circuit, controller (3) are connected with solenoid valve A (5), solenoid valve B (8) electricity.

2. The novel energy-saving ice-making unit as set forth in claim 1, wherein: the ice making device (9) comprises an electromagnetic valve C (10), an evaporator A (11), an electromagnetic valve D (12), an electromagnetic valve E (13), an evaporator B (14) and an electromagnetic valve F (15); the front end of the evaporator A (11) is fixedly provided with a solenoid valve C (10), the rear end of the evaporator A is fixedly provided with a solenoid valve D (12), the front end of the evaporator B (14) is fixedly provided with a solenoid valve E (13) and the rear end of the evaporator B is fixedly provided with a solenoid valve F (15), and the controller (3) is electrically connected with the solenoid valve C (10), the solenoid valve D (12), the solenoid valve E (13) and the solenoid valve F (15) respectively.

3. The novel energy-saving ice-making unit as set forth in claim 2, wherein: the electromagnetic valve C (10) is connected with the electromagnetic valve F (15) through a conduit, and the electromagnetic valve D (12) is connected with the electromagnetic valve E (13) through a conduit.

4. The novel energy-saving ice-making unit as set forth in claim 1, wherein: the electromagnetic valve A (5) is connected with the electromagnetic valve B (8) through a pipeline.

5. The novel energy-saving ice-making unit as set forth in claim 2, wherein: the evaporator A (11) comprises a water filling port (16), a water tank (17), a water pump (18), a sprayer (19), an ice making grid (20), a turnover baffle plate (21), a water retaining groove (22) and an ice storage groove (23); the water injection port (16) is fixed above the water tank (17), one end of the water pump (18) stretches into the water tank (17), the other end of the water pump is connected with the sprayer (19), the sprayer (19) is fixed above the ice making grid (20), the overturning baffle plate (21) is arranged at the front end of the bottom of the ice making grid (20), the water retaining groove (22) is fixed below the ice making grid (20), the water retaining groove (22) is connected with the water tank (17), and the ice storage groove (23) is arranged below the water retaining groove (22).

6. The novel energy-saving ice-making unit as set forth in claim 5, wherein: the ice making device is characterized in that an ice making copper pipe A (24) is fixed at the rear part of the ice making grid (20), a refrigerating groove (25) is formed in the ice making grid (20), and an ice making copper pipe B (26) is arranged in the refrigerating groove (25).

Images