CN219868636U - Air-cooled water-cooled ice making system - Google Patents

Abstract

The utility model provides an air-cooling water-cooling ice making system which comprises a shell and an ice maker, wherein a compressor is fixedly arranged at the bottom of the shell through a bolt, the output end of the compressor is connected with a high-pressure copper pipe, the other end of the high-pressure copper pipe is connected with a condenser, the condenser is arranged in the shell through a bolt, the output end of the condenser is connected with a low-pressure copper pipe, the outer side of the low-pressure copper pipe is sleeved with a condenser pipe, the output end of the low-pressure copper pipe is connected with a filter, the output end of the filter is connected with a first capillary, the upper end of the first capillary is connected with the ice maker, and a return pipe is arranged at the output end of the ice maker and is connected with the compressor. When the ambient temperature rises, the pressure of the high-pressure copper pipe increases, water flows to the condensing pipe through the water inlet pipe, water cooling and cooling are carried out, and then the device achieves the effects of water cooling and air cooling simultaneously.

Description

Air-cooled water-cooled ice making system

Technical Field

The utility model belongs to the technical field of ice making systems, and particularly relates to an air-cooling water-cooling ice making system.

Background

Ice makers are widely used as a device capable of making ice cubes in various markets or individual households, for example, a large amount of ice cubes are consumed when milk tea is made in the market, and users can make ice and coffee beverages by using ice cubes in individual households to meet the daily life demands.

The refrigeration modes of the ice maker are generally classified into air-cooled condensation and water-cooled condensation, namely air-cooled condensation and water-cooled condensation. The air cooling mode is the most common, and the mode is simple and easy to implement, so most ice machines adopt the refrigerating mode, but the requirement on the environment temperature is relatively high, and if the environment temperature is too high, the refrigerating effect is obviously reduced and even refrigerating is stopped; the physical property of water is not easy to change like air, so the water temperature is relatively lower than the air temperature in summer, and the ice making machine of the water cooling mode has good refrigerating effect, but a large amount of water is required to continuously flow away, so that serious waste is caused.

Accordingly, in view of the above, research and improvement are made to the existing structure and the existing defects, and an air-cooled water-cooled ice making system is provided to achieve the purpose of having more practical value.

Disclosure of Invention

In order to solve the technical problems, the utility model provides an air-cooling water-cooling ice making system, which is realized by the following specific technical means:

the utility model provides an air-cooled water-cooling ice making system, includes casing and ice maker, the bottom of casing is through bolt fixed mounting there being the compressor, and the output of compressor is connected with high-pressure copper pipe, and the other end of high-pressure copper pipe is connected with the condenser, and the condenser passes through the bolt to be installed in the casing, and the output of condenser is connected with low-pressure copper pipe, and the outside cover of low-pressure copper pipe is equipped with the condenser pipe, and the output of low-pressure copper pipe is connected with the filter, and the output of filter is connected with first capillary, the upper end of first capillary with ice maker is connected, is provided with the back flow on the output of ice maker, and the back flow is connected with the compressor.

Further, the condenser comprises a mounting frame, fins, heat exchange tubes and a cooling fan, wherein the fins are provided with a plurality of fins, the fins are all installed in the mounting frame, the cooling fan is installed at the rear end of the mounting frame, one end of each heat exchange tube is connected with the high-pressure copper tube, the other end of each heat exchange tube is connected with the low-pressure copper tube, and the heat exchange tubes penetrate through the fins.

Further, a water stop valve is arranged in the shell, a second capillary tube is arranged on the high-pressure copper tube, and the second capillary tube is connected with the water stop valve.

Further, the input end of the water stop valve is connected with a water inlet pipe, the water inlet pipe is externally connected with a water source, the output end of the water stop valve is connected with a water outlet pipe, and the water outlet pipe is communicated with the condensing pipe.

Further, one end of the condensing tube is provided with a water inlet, the other end of the condensing tube is provided with a water outlet, the water outlet pipe is connected with the condensing tube through the water inlet, the condensing tube is connected with a water outlet pipe through the water outlet, and the water outlet pipe, the condensing tube and the water outlet pipe are communicated.

Furthermore, a temperature controller is optionally arranged on the low-pressure copper pipe.

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

when the ice-making device works, high-temperature and high-pressure gas is conveyed to the condenser through the compressor, cooled to be supercooled liquid refrigerant after being cooled by the condenser, and then the liquid refrigerant reaches the ice-making device through the low-pressure copper pipe, the filter pipe and the first capillary tube, so that the ice-making device makes ice, the ice-making device is an air-cooling method, when the ambient temperature is low, the ice-making device is used, when the ambient temperature is increased, the pressure of the high-pressure copper pipe is increased, the water stop valve is opened by pressure, the water inlet pipe starts to inlet water, then the water stop valve and the water outlet pipe reach the condenser pipe for water-cooling, and the ice-making device achieves the effects of water cooling and air cooling simultaneously.

Drawings

FIG. 1 is a schematic diagram of the whole structure of an air-cooled water-cooled ice making system according to the present utility model;

FIG. 2 is a schematic view of the connection of the components within the housing;

FIG. 3 is a schematic structural view of a condenser;

fig. 4 is a schematic structural diagram of a radiator fan on a condenser.

In the figure, the correspondence between the component names and the drawing numbers is:

1. a housing; 2. an ice maker; 3. a compressor; 4. a high pressure copper tube; 5. a condenser; 6. a low pressure copper tube; 7. a condensing tube; 8. a filter; 9. a first capillary; 10. a return pipe; 11. a water stop valve; 12. a second capillary; 13. a water inlet pipe; 14. a water outlet pipe; 15. a drain pipe; 501. a mounting frame; 502. a fin; 503. a heat exchange tube; 504. a heat radiation fan.

Description of the embodiments

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the utility model but are not intended to limit the scope of the utility model.

In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more; the terms "upper," "lower," "left," "right," "inner," "outer," "front," "rear," "head," "tail," and the like are used as an orientation or positional relationship based on that shown in the drawings, merely to facilitate description of the utility model and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the utility model. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "connected," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

Examples

As shown in fig. 1 to 4:

the utility model provides an air-cooling water-cooling ice making system which comprises a shell 1 and an ice maker 2, wherein a compressor 3 is fixedly arranged at the bottom of the shell 1 through bolts, the output end of the compressor 3 is connected with a high-pressure copper pipe 4, the other end of the high-pressure copper pipe 4 is connected with a condenser 5, the condenser 5 is arranged in the shell 1 through bolts, the output end of the condenser 5 is connected with a low-pressure copper pipe 6, a condensing pipe 7 is sleeved outside the low-pressure copper pipe 6, the output end of the low-pressure copper pipe 6 is connected with a filter 8, the output end of the filter 8 is connected with a first capillary pipe 9, the upper end of the first capillary pipe 9 is connected with the ice maker 2, the output end of the ice maker 2 is provided with a return pipe 10, and the return pipe 10 is connected with the compressor 3.

The condenser 5 comprises a mounting frame 501, fins 502, heat exchange tubes 503 and a cooling fan 504, wherein the fins 502 are provided with a plurality of fins 502, the cooling fan 504 is arranged at the rear end of the mounting frame 501, one end of each heat exchange tube 503 is connected with the high-pressure copper tube 4, the other end of each heat exchange tube 503 is connected with the low-pressure copper tube 6, and the heat exchange tubes 503 penetrate through the fins 502. The shell 1 is provided with a radiating opening, so that the radiating fan 504 is convenient for blowing and radiating, the heat exchange tube 503 is a bent coil pipe design, the heat exchange tube 503 penetrates through the fins 502, the radiating area is increased, the radiating is accelerated, the radiating fan 504 is used for blowing and accelerating air convection, and therefore heat is taken away.

Wherein, a water stop valve 11 is arranged in the shell 1, a second capillary tube 12 is arranged on the high-pressure copper tube 4, and the second capillary tube 12 is connected with the water stop valve 11. The input end of the water stop valve 11 is connected with a water inlet pipe 13, the water inlet pipe 13 is externally connected with a water source, the output end of the water stop valve 11 is connected with a water outlet pipe 14, and the water outlet pipe 14 is communicated with the condensing pipe 7. When the ambient temperature rises, the pressure of the high-pressure copper pipe 4 increases, so that the water stop valve 11 is jacked up by the pressure, at the moment, the water inlet pipe 13 starts to enter water, and the water reaches the condensing pipe 7 through the water stop valve 11 and the water outlet pipe 14 to perform water cooling, so that the utility model realizes the effects of water cooling and air cooling simultaneously. When the water stop valve 11 is closed, the water flow does not flow to the condensation pipe 7 any more, namely, the air cooling heat dissipation is realized at the moment.

Wherein, the one end of condenser pipe 7 is provided with the water inlet, and the other end of condenser pipe 7 is provided with the delivery port, outlet pipe 14 passes through the water inlet to be connected with condenser pipe 7, and condenser pipe 7 is connected with drain pipe 15 through the delivery port, and outlet pipe 14, condenser pipe 7 and drain pipe 15 are linked together. When the water cooling is carried out, water flows to the condensing pipe 7 through the water inlet pipe 13, is discharged through the water outlet pipe 15, and can continuously supply water into the condensing pipe 7 through the design, so that the water cooling effect is ensured.

Wherein, the low-pressure copper pipe 6 is optionally provided with a temperature controller. The temperature controller is controlled by a circuit board, when the temperature controller reaches a preset value, a water inlet valve on the water inlet pipe 13 is opened, so that water flows through the water inlet pipe 13 and the water outlet pipe 14 to reach the condensing pipe 7, and then water cooling is performed. When the thermostat is installed, the water flow can be controlled by the thermostat without installing the second capillary tube 12 and the water stop valve 11.

The working principle of the embodiment is as follows: when the ice maker is used, water is added into the ice maker 2 from an external water source, the ice maker is used for making ice cubes, the compressor 3 is started, high-temperature and high-pressure gas reaches the condenser 5 through the high-pressure copper pipe 4, the temperature is reduced by the acceleration of the fins 502, then the air is blown through the cooling fan 504, the air convection is accelerated, heat is taken away, the high-temperature and high-pressure gas is cooled into supercooled liquid refrigerant through the condenser 5, the liquid refrigerant reaches the ice maker 2 through the condenser pipe 7, the filter pipe 8 and the first capillary pipe 9, so that the ice maker 2 makes ice, and the method of air cooling is adopted at the moment when the ambient temperature is low; when the ambient temperature rises, the pressure of the high-pressure copper pipe 4 increases, so that the water stop valve 11 is jacked up by the pressure, the water inlet pipe 13 starts to inlet water at the moment, then the water reaches the condensation pipe 7 through the water stop valve 11 and the water outlet pipe 14, water cooling and cooling are carried out, and then the effect of water cooling and air cooling are realized at the same time, and water flow passing through the condensation pipe 7 is finally discharged through the water outlet pipe 15, so that the water flow can continuously supply water into the condensation pipe 7, the water cooling effect is ensured, the air cooling and the water cooling are carried out at the same time, the ice making process is more stable, normal production of ice cubes is ensured, when the ambient temperature is relatively low, the water stop valve 11 is closed, the water flow does not flow to the condensation pipe 7 at the moment, namely the air cooling ice making is carried out at the moment, water resources are saved, the two refrigeration methods are matched for use, the energy is also saved while the production is ensured, and the production cost is further reduced.

The embodiments of the utility model have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (6)

1. An air-cooled water-cooled ice making system, includes casing (1) and ice maker (2), its characterized in that: the bottom of casing (1) is through bolt fixed mounting has compressor (3), the output of compressor (3) is connected with high-pressure copper pipe (4), the other end of high-pressure copper pipe (4) is connected with condenser (5), condenser (5) are installed in casing (1) through the bolt, the output of condenser (5) is connected with low-pressure copper pipe (6), the outside cover of low-pressure copper pipe (6) is equipped with condenser pipe (7), the output of low-pressure copper pipe (6) is connected with filter (8), the output of filter (8) is connected with first capillary (9), the upper end of first capillary (9) with ice maker (2) are connected, be provided with back flow (10) on the output of ice maker (2), back flow (10) are connected with compressor (3).

2. An air-cooled water-cooled ice making system as set forth in claim 1, wherein: the condenser (5) comprises a mounting frame (501), fins (502), heat exchange tubes (503) and a cooling fan (504), wherein the fins (502) are provided with a plurality of fins (502), the fins (502) are all installed in the mounting frame, the cooling fan (504) is installed at the rear end of the mounting frame (501), one end of each heat exchange tube (503) is connected with each high-pressure copper tube (4), the other end of each heat exchange tube (503) is connected with each low-pressure copper tube (6), and each heat exchange tube (503) passes through each fin (502) to be arranged.

3. An air-cooled water-cooled ice making system as set forth in claim 1, wherein: a water stop valve (11) is arranged in the shell (1), a second capillary tube (12) is arranged on the high-pressure copper tube (4), and the second capillary tube (12) is connected with the water stop valve (11).

4. An air-cooled water-cooled ice-making system according to claim 3, wherein: the water stop valve is characterized in that the input end of the water stop valve (11) is connected with a water inlet pipe (13), the water inlet pipe (13) is externally connected with a water source, the output end of the water stop valve (11) is connected with a water outlet pipe (14), and the water outlet pipe (14) is communicated with the condensing pipe (7).

5. An air-cooled water-cooled ice-making system as set forth in claim 4, wherein: one end of the condensing pipe (7) is provided with a water inlet, the other end of the condensing pipe (7) is provided with a water outlet, the water outlet pipe (14) is connected with the condensing pipe (7) through the water inlet, the condensing pipe (7) is connected with a water outlet pipe (15) through the water outlet, and the water outlet pipe (14), the condensing pipe (7) and the water outlet pipe (15) are communicated.

6. An air-cooled water-cooled ice making system as set forth in claim 1, wherein: and a temperature controller is optionally arranged on the low-pressure copper pipe (6).