CN217377607U - Instant cooling type ice water system - Google Patents

Abstract

The utility model discloses an instant-cooling type ice water system, which is used for rapidly providing refrigerated ice water and comprises an RO reverse osmosis water purifier, a water cooler and a water tap, wherein a water inlet pipe of the osmosis machine of the RO reverse osmosis water purifier and a water inlet pipe of the water cooler are respectively communicated with a drinking water inlet pipeline through a tee joint, a drinking water interface connected with a water inlet pipe of the water cooler and a cold tank water outlet interface communicated with the water tap through a pipeline are respectively arranged on the water cooler, RO concentrated water prepared by the RO reverse osmosis water purifier is communicated with a water cooling water inlet interface arranged on the water cooler through a wastewater outlet pipe; a bypass water-cooling pipe communicated with a wastewater outlet pipe is also connected to the water inlet pipe of the water cooler in a bypass manner; the refrigerating speed is high, the double-mode frequency conversion cooling is 20 times of the traditional air cooling effect, the refrigerating capacity is 1: 8, the quenching effect can be achieved within 30 seconds, and cold water can be continuously supplied and is not influenced by the environment temperature.

Description

Instant cooling type ice water system

[ technical field ] A method for producing a semiconductor device

The utility model relates to a supply with cold water technique fast, especially relate to an instant cold type frozen water system.

[ background of the invention ]

With the improvement of the living standard of people, ice water is often used in the daily production and living process, for example, a large amount of ice water is often used for drinking water, wine blending, cooking, beautifying and the like.

However, no matter the normal temperature water is placed in the refrigerator for cooling or the ice blocks are directly taken out from the refrigerator for mixing water at present, the normal temperature water needs very long time of water cooling, and the normal temperature water is placed in the refrigerator for a long time, so that bacteria are easy to breed, and the normal temperature water is not suitable for direct drinking and cooking; if a household water dispenser is adopted, the ice water is refrigerated through an electronic ice container or a compressor, the time of the generated ice water is long, the refrigerating capacity is small, the ice water storage capacity can only obtain about 0.8 liter of ice water with the temperature of below 15 ℃ in one hour, and the requirement of the existing fast-paced life is difficult to meet.

[ Utility model ] content

The utility model provides a whole small, control is convenient, and the internals arranges rationally, simple structure, and convenient to use just provides the cold type frozen water system promptly of capacity frozen water fast.

In order to achieve the above object, the utility model provides a following technical scheme:

the system is characterized by comprising an RO reverse osmosis water purifier for supplying pure water, a water cooler for preparing required ice water and a water tap for directly supplying water outwards, wherein a water inlet pipe of the RO reverse osmosis water purifier and a water inlet pipe of the water cooler are respectively communicated with a drinking water inlet pipeline through a tee joint, and a drinking water interface connected with a water inlet pipe of the water cooler and a cold tank water outlet interface communicated with the water tap through a pipeline are respectively arranged on the water cooler;

RO concentrated water prepared by the RO reverse osmosis water purifier is communicated with a water-cooling water inlet interface arranged on the water chiller through a wastewater outlet pipe, and the water-cooling water outlet interface on the water chiller is directly drained into a sewer pipeline through a drainage pipeline to be drained away or is connected with a water-cooling circulation heat sink and the wastewater outlet pipe through the drainage pipeline for circulation water cooling;

a bypass water-cooling pipe which is communicated with the wastewater outlet pipe and supplies water-cooling tap water for circulating water to a water-cooling water inlet interface on the water chiller is also connected to the water inlet pipe of the water chiller in a bypass mode, a first water inlet valve for controlling the on-off of a pipeline is arranged on the bypass water-cooling pipe, and a check valve for preventing wastewater from flowing backwards is arranged on the wastewater outlet pipe between the corresponding bypass water-cooling pipe and the RO concentrated water outlet of the RO reverse osmosis water purifier;

the water chiller comprises a power control panel, a compressor, an evaporator, a drying filter, a water-cooled condenser and a refrigerant storage pipe, wherein the compressor, the evaporator, the drying filter, the water-cooled condenser and the refrigerant storage pipe are sequentially connected through a refrigerant pipeline to form a closed-loop circulating system;

the evaporator is arranged in a water storage tank, and the water storage tank is respectively communicated with a drinking water interface and a cooling tank water outlet interface on the water chiller through pipelines;

the water-cooled condenser is arranged in a cooling tank, and the cooling tank is respectively communicated with a water-cooled water inlet interface and a water-cooled water outlet interface on the water chiller through pipelines.

Furthermore, a pure water pipeline for supplying pure water to the water chiller is further arranged between the pure water outlet of the RO reverse osmosis water purifier and the water chiller water inlet pipe of the water chiller, and a second water inlet valve for controlling the on-off of the pure water is arranged on the pure water pipeline.

Further, still be provided with in the cold water machine and be used for carrying on the automatically controlled adjustment converter that the function switches into the state of heating by the refrigeration state between evaporimeter and the water-cooled condenser, work as the evaporimeter is right when water heating in the water storage tank, it is corresponding the water storage tank with still be provided with on the pipeline between the tap right supply out hot water and then secondary rapid heating's instant heating module in the water storage tank. When a water faucet is connected, a water path of ice water in a water storage tank is utilized, when boiled water is prepared, function switching is carried out between an original evaporator and a water-cooled condenser through an electric control adjusting converter, the evaporator is changed from a refrigerating state to a heating state, a water inlet water path is unchanged, heat released by the water-cooled condenser is directly absorbed by the water storage tank and converted into the evaporator, the temperature is increased to 60 ℃, then the water enters an instant heating module, drinking water is heated in a stepped mode through the heat of the condenser, the heating efficiency is improved by more than one time, the problem that the water yield of the instant heating module in the existing water heater is small is solved, and energy is saved by more than 70%.

Furthermore, the water chiller also comprises a square shell and a side sealing plate which is positioned on the side surface of the square shell and used for sealing the shell.

Furthermore, a water-cooling water inlet interface, a water-cooling water outlet interface, a drinking water interface and a cold tank water outlet interface on the water chiller are sequentially arranged on the top side of the square shell from left to right.

Furthermore, a compressor in the water chiller is installed at a corner on the bottom side of the square shell, a water-cooled condenser in the water chiller located in the cooling tank is arranged in the square shell on the upper side of the compressor, and evaporators in the water storage tank in the water chiller are arranged in the square shell beside the compressor and the cooling tank in parallel.

The beneficial effects are that:

the utility model discloses a compressor refrigeration heat transfer utilizes contrary carnot principle, and it is fast to have a refrigeration, and bimodulus frequency conversion cooling is traditional air-cooled 20 times cooling effect, and 1 is than 8 refrigerating capacity, can reach the rapid cooling effect in 30 seconds, and cold water can be incessant constantly, does not receive ambient temperature to influence. The working principle is that a set of water-cooling compressor circulation system is adopted in the water chiller, and the main components comprise a compressor, a heat-absorbing evaporator, a heat-dissipating water-cooling condenser, a refrigerant storage pipe for refrigerant expansion, a capillary tube, a drying filter, a power control panel, an electric control adjustment converter and other connecting pipelines; and because the water-cooled condenser is soaked in the cooling tank communicated with the wastewater discharged by the RO reverse osmosis water purifier or external tap water, the water circulating in the cooling tank is used for heat dissipation of the water-cooled condenser, when refrigeration is started, refrigerant Freon is pressurized by the compressor to become high-temperature high-pressure gas and enter the water-cooled condenser, and at the moment, the refrigerant Freon is condensed and liquefied to release heat to become liquid, and simultaneously, the heat is released to the water in the cooling tank. Meanwhile, the liquid Freon is decompressed by a throttling device (such as a capillary tube) and enters an evaporator arranged in the water storage tank, refrigerant Freon is evaporated, gasified and absorbs heat to become gas, and heat of drinking water or other water in the water storage tank is absorbed at the same time, so that the purpose of reducing the temperature of water in the water storage tank is achieved, and the Freon which becomes gas enters the compressor again to start the next cycle. On the contrary, when the electric control adjustment converter controls the functions of the evaporator and the water-cooled condenser to be exchanged, the water storage tank is switched from the refrigeration mode to the heating mode.

Meanwhile, the water in the cooling tank is directly connected with tap water or concentrated wastewater of an RO reverse osmosis water purifier, or can be connected with a circulating cooling tower for circulating cooling water, the concentrated wastewater discharged by the RO reverse osmosis water purifier is automatically discharged in an electric control manner after reaching a certain temperature, so that the energy is saved and the environment is protected, and particularly, the secondary utilization of the environment-friendly and energy-saving wastewater is realized by using the circulating water or the wastewater of the RO reverse osmosis water purifier, in the household or commercial use, the electric charge and the water charge are greatly saved, the maximum efficiency of the device realizes the effect of water cooling of the condenser, the heat dissipation performance of water is 28 times of that of air, and the actual measurement efficiency can reach 35 times by adopting the flowing water for heat dissipation, therefore, the water-cooled condenser in the cooling tank is quickly heated by water, the refrigeration effect of the evaporator is effectively improved, and ice water can be discharged when the water faucet is opened, so that the effect of cooling when the water faucet is opened is achieved.

In addition, when boiled water is prepared, the original evaporator and the water-cooled condenser are switched in function through the electric control adjustment converter, the evaporator is changed from a refrigerating state to a heating state, a water inlet waterway is unchanged, the heat released by the evaporator and converted into the water-cooled condenser is directly absorbed by the water storage tank, the temperature is increased to 60 ℃, the water enters the instant heating module, the drinking water is subjected to stepped heating by the heat of the condenser, the heating efficiency is improved by more than one time, the problem that the water yield of the instant heating module in the existing water heater is small is solved, energy is saved by more than 70%, the water cooler can be immediately heated to be a water machine, and the water heater is dual-purpose. And the water cooler adopts a water-cooled compressor system, is not influenced by a heat dissipation environment, has no fan noise, is not influenced by the ambient temperature, can be used in places with severe environment in summer and winter, and can be used in ship aircrafts and high-speed rails besides household and commercial use.

[ description of the drawings ]

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

fig. 2 is a schematic diagram of the system of the water chiller of the present invention;

fig. 3 is an enlarged schematic view of the explosive structure of the present invention;

FIG. 4 is an enlarged schematic view of the present invention with the outer shell removed;

fig. 5 is an enlarged schematic view of the internal structure of the shell removing side sealing plate of the present invention;

the present invention will be further described with reference to the accompanying drawings and examples.

[ detailed description ] embodiments

The cold type ice water system, as shown in fig. 1 and 2, is used for rapidly providing refrigerated ice water, and comprises an RO reverse osmosis water purifier 1 for supplying pure water, a water chiller 2 for preparing the required ice water, and a water tap 3 for directly supplying water to the outside, wherein a water inlet pipe 4 of the osmosis machine of the RO reverse osmosis water purifier 1 and a water inlet pipe 5 of the water chiller 2 are respectively communicated with a drinking water inlet pipe 6 through a tee joint, and the water chiller 2 is respectively provided with a drinking water interface 7 connected with the water inlet pipe 5 of the water chiller, and a cold tank water outlet interface 8 communicated with the water tap 3 through a pipeline; the RO concentrated water prepared by the RO reverse osmosis water purifier 1 is communicated with a water-cooling water inlet interface 10 arranged on the water cooler 2 through a wastewater outlet pipe 9, and a water-cooling water outlet interface 11 on the water cooler 2 is directly discharged into a sewer pipeline 13 through a drainage pipeline 12 to be discharged away or is connected with a water-cooling circulation heat dissipation tower 120 and the wastewater outlet pipe 9 through the drainage pipeline 12 for circulation water cooling.

As shown in fig. 1 and 2, a bypass water-cooling pipe 14 which is communicated with the waste water outlet pipe 9 and supplies water-cooling tap water for circulating water to a water-cooling water inlet port 10 of the water chiller 2 is connected to the water chiller inlet pipe 5 of the water chiller 2 in a bypass manner, a first water inlet valve 15 for controlling the on-off of the pipeline is arranged on the bypass water-cooling pipe 14, and a check valve 17 for preventing the waste water from flowing backwards is arranged on the waste water outlet pipe 9 between the corresponding bypass water-cooling pipe 14 and an RO concentrated water outlet 16 of the RO reverse osmosis water purifier 1. Further, a pure water line 18 for supplying pure water to the chiller 2 is provided between the pure water outlet 160 of the RO reverse osmosis water purifier 1 and the chiller water inlet pipe 5 of the chiller 2, and a second water inlet valve 19 for controlling the opening and closing of the pure water is provided in the pure water line 18, so that pure water for cooling can be supplied to the chiller 2 as required.

As shown in fig. 1 to 5, the water chiller 2 includes a power control board 20, a compressor 21, an evaporator 22, a dry filter 23, a water-cooled condenser 24 and a refrigerant storage pipe 25, wherein the compressor 21, the evaporator 22, the dry filter 23, the water-cooled condenser 24 and the refrigerant storage pipe 25 are connected in sequence through refrigerant pipes to form a closed-loop circulation system; the evaporator 22 is arranged in a water storage tank 26, and the water storage tank 26 is respectively communicated with a drinking water interface 7 and a cold tank water outlet interface 8 on the water chiller 2 through pipelines; the water-cooled condenser 24 is arranged in a cooling tank 27, and the cooling tank 27 is respectively communicated with a water-cooled water inlet interface 10 and a water-cooled water outlet interface 11 on the water chiller 2 through pipelines.

Wherein, an electric control adjustment converter (not shown) for switching the function between the evaporator 22 and the water-cooled condenser 24 from the refrigeration state to the heating state is further arranged in the water chiller 2, and when the evaporator 22 heats the water in the water storage tank 26, an instant heating module 28 for supplying hot water into the water storage tank 26 and then heating the water for the second time is further arranged on the pipeline between the corresponding water storage tank 26 and the water tap 3. After the water faucet 3 is connected, the water channel of ice water in the water storage tank 26 is utilized, when boiled water is prepared, the original evaporator 22 and the water-cooled condenser 24 are switched in function through the electric control adjusting converter, the evaporator 22 is changed from a refrigerating state to a heating state, the water inlet channel is unchanged, the heat released by the water-cooled condenser 24 is directly absorbed by the water storage tank 26 and converted into the heat by the evaporator 22, the temperature is increased to 60 ℃, then the heat enters the instant heating module 28, the drinking water is subjected to step heating by the heat of the condenser, the heating efficiency is improved by more than one time, the problem that the water outlet quantity of the instant heating module 28 in the existing water heater is small is solved, more than 70% of energy is saved, and the water cooler 2 can be instantly heated and used as a water heater. Moreover, the water cooler 2 adopts a water-cooled compressor 21 system, is not influenced by heat dissipation environment, has no fan noise, is not influenced by environment temperature, can be used in places with severe environment in summer and winter, and can be used in ship aircrafts and high-speed rails except for households and businesses.

As shown in fig. 3 to 5, the water chiller 2 further includes a square housing 29 and a side sealing plate 30 located on the side of the square housing 29 for sealing the housing, the water-cooling water inlet 10, the water-cooling water outlet 11, the drinking water outlet 7 and the cold tank water outlet 8 on the water chiller 2 are sequentially disposed on the top side of the square housing 29 from left to right, the compressor 21 in the water chiller 2 is mounted on a side corner of the bottom side of the square housing 29, the water-cooling condenser 24 in the cold tank 27 in the water chiller 2 is disposed in the square housing 29 on the upper side of the compressor 21, and the evaporators 22 in the water storage tank 26 in the water chiller 2 are mounted in the square housing 29 beside the sides of the compressor 21 and the cold tank 27 in parallel.

The water cooling machine in the system adopts the compressor 21 for refrigeration and heat exchange, utilizes the inverse Carnot principle, has high refrigeration speed and dual-mode variable frequency cooling, is 20 times of the traditional air cooling effect, can achieve the quenching effect within 30 seconds due to 1 to 8 refrigeration capacity, and can continuously cool water without being influenced by the environmental temperature.

Meanwhile, the water in the cooling tank 27 is directly connected with tap water or concentrated wastewater of the RO reverse osmosis water purifier 1, or can be connected with a circulating cooling tower for circulating cooling water, the concentrated wastewater discharged by the RO reverse osmosis water purifier 1 is automatically controlled to be automatically discharged after reaching a certain temperature, so that the energy is saved and the environment is protected, and particularly, the secondary utilization of the environment-friendly and energy-saving wastewater is realized by using the circulating water or the wastewater of the RO reverse osmosis water purifier 1, in the household or commercial use, the electric charge and the water charge are greatly saved, the maximum efficiency of the device realizes the effect of water cooling of the condenser, the heat dissipation performance of water is 28 times of that of air, and the actual measurement efficiency can reach 35 times by adopting the flowing water for heat dissipation, therefore, the water-cooled condenser 24 in the cooling tank 27 is quickly heated by water, the refrigeration effect of the evaporator 22 is effectively improved, and the tap 3 is opened to discharge ice water, so that the effect of cooling when the tap is opened is achieved.

The above-mentioned embodiment is only the preferred embodiment of the present invention, and is not limited thereto, the scope of the present invention is not limited thereto, and all changes apparent from the shape, structure and principle of the present invention and other changes do not depart from the essence of the present invention should be covered within the protection scope of the present invention.

Claims (6)

1. The system is characterized by comprising an RO reverse osmosis water purifier for supplying pure water, a water cooler for preparing required ice water and a water tap for directly supplying water outwards, wherein a water inlet pipe of the RO reverse osmosis water purifier and a water inlet pipe of the water cooler are respectively communicated with a drinking water inlet pipeline through a tee joint, and a drinking water interface connected with a water inlet pipe of the water cooler and a cold tank water outlet interface communicated with the water tap through a pipeline are respectively arranged on the water cooler;

RO concentrated water prepared by the RO reverse osmosis water purifier is communicated with a water-cooling water inlet interface arranged on the water chiller through a wastewater outlet pipe, and the water-cooling water outlet interface on the water chiller is directly drained into a sewer pipeline through a drainage pipeline to be drained away or is connected with a water-cooling circulation heat sink and the wastewater outlet pipe through the drainage pipeline for circulation water cooling;

a bypass water-cooling pipe which is communicated with the wastewater outlet pipe and supplies circulating water-cooling tap water to a water-cooling water inlet interface on the water cooler is connected to a water inlet pipe of the water cooler in a bypass mode, a first water inlet valve for controlling the on-off of a pipeline is arranged on the bypass water-cooling pipe, and a check valve for preventing wastewater from flowing backwards is arranged on a wastewater outlet pipe between the corresponding bypass water-cooling pipe and an RO concentrated water outlet of the RO reverse osmosis water purifier;

the water chiller comprises a power supply control panel, a compressor, an evaporator, a drying filter, a water-cooling condenser and a refrigerant storage pipe, wherein the compressor, the evaporator, the drying filter, the water-cooling condenser and the refrigerant storage pipe are sequentially connected through a refrigerant pipeline to form a closed-loop circulating system;

the evaporator is arranged in a water storage tank, and the water storage tank is respectively communicated with a drinking water interface and a cooling tank water outlet interface on the water chiller through pipelines;

the water-cooled condenser is arranged in a cooling tank, and the cooling tank is respectively communicated with a water-cooled water inlet interface and a water-cooled water outlet interface on the water chiller through pipelines.

2. The instantly-cooled ice water system as claimed in claim 1, wherein a pure water line for supplying pure water to the water chiller is further provided between the pure water outlet of the RO reverse osmosis water purifier and the water chiller inlet pipe of the water chiller, and the pure water line is provided with a second water inlet valve for controlling the on/off of the pure water.

3. The ice-water cooling system as claimed in claim 1, wherein an electrically controlled adjustment converter is further provided in the water chiller for switching between the evaporator and the water-cooled condenser from a cooling state to a heating state, and when the evaporator heats the water in the water storage tank, an instant heating module is further provided on the corresponding pipe between the water storage tank and the faucet for supplying hot water to the water storage tank for secondary rapid heating.

4. The chilled ice and water system as claimed in claim 1, wherein the water chiller further comprises a square housing and side sealing plates on the sides of the square housing for housing cover.

5. The instant-cooled ice water system as claimed in claim 4, wherein the water-cooled water inlet port, the water-cooled water outlet port, the drinking water port and the cold tank water outlet port of the water chiller are sequentially disposed from left to right on the top side of the square housing.

6. The instant cold type ice water system as claimed in claim 4, wherein the compressor of the water chiller is installed at a side corner of the bottom side of the square housing, the water cooled condenser of the water chiller located in the cooling tank is installed in the square housing at the upper side of the compressor, and the evaporator of the water chiller located in the water storage tank is installed in the square housing at the side of the compressor and the cooling tank in parallel.

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