An integrated water treatment apparatus

This device integrates ice making, pure water, hot water, and chilled water functions. It adopts a dual heating mode and a circulating pump system, which solves the problems of low hot water production efficiency and large equipment size. It achieves efficient cooling and hot water preparation and is suitable for small apartments.

CN224461477UActive Publication Date: 2026-07-07NINGBO XIMING INTELLIGENT DRINK TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
NINGBO XIMING INTELLIGENT DRINK TECHNOLOGY CO LTD
Filing Date
2025-08-04
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing ice-making water dispensers suffer from low hot water production efficiency and large overall size, making them particularly unsuitable for small apartments.

Method used

This device integrates ice making, pure water, hot water, and chilled water functions. It adopts a dual heating mode and a circulation pump system. By combining the use of cooling and heating modules, it improves cooling efficiency and shortens the boiling time of hot water.

Benefits of technology

It achieves efficient preparation of cold and hot water, avoids freezing of the cold tank, has strong comprehensive capabilities, and is suitable for small-sized households.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224461477U_ABST
Patent Text Reader

Abstract

The utility model relates to an integrated water treatment equipment, including main part, the main part includes the shell of lower part and the pedestal of upper part, be provided with cold gallbladder water tank in the main part, refrigeration module is used for receiving the water of cold gallbladder water tank and making ice block and / or ice water, and ice block exports through ice outlet, and ice water exports through the water outlet on the pedestal, heating module is used for receiving the water of cold gallbladder water tank and making hot water, and hot water exports through the water outlet on the pedestal, pure water module is used for receiving the pure water after filtering from the output of cold gallbladder water tank, and pure water is stored in the pure water tank on the pedestal, the heating module includes quick -warming module and electric heating module, is equipped with the kettle for receiving normal temperature water or hot water from the water outlet and heating or re -heating normal temperature water or hot water in the kettle on the electric heating module.
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Description

Technical Field

[0001] This utility model relates to the field of water treatment technology, and in particular to an integrated water treatment device. Background Technology

[0002] A water dispenser is a device used to provide drinking water. It is typically designed to meet people's drinking water needs in a convenient, efficient, and hygienic way. Water dispensers can be used in various places such as homes, offices, schools, and public areas. With continuous technological advancements, more and more water dispensers are integrating smart features to enhance user experience and convenience.

[0003] With the development of water purification and ice-making technologies, various forms of ice-making water dispensers have appeared on the market. Ice-making water dispensers use internal refrigeration systems, such as compressors, evaporators, and condensers, to complete the transformation process from liquid water to solid ice.

[0004] Currently available multi-functional water dispensers can not only provide ice water or hot water, but also make ice cubes as needed. However, due to the many functions, these dispensers are quite large, making them less suitable for smaller homes.

[0005] An ice-making water dispenser is a smart small appliance that combines ice-making and water-dispensing functions. It uses an internal refrigeration system, including components such as a compressor, evaporator, and condenser, to transform liquid water into solid ice. Users can obtain not only ice water or hot water, but also make ice cubes as needed. During the ice-making process, the compressor provides high-pressure, high-temperature refrigerant, which absorbs heat in the evaporator, causing the water to freeze, and releases heat in the condenser, returning to a liquid state. This cycle repeats continuously, achieving the ice-making function. Simultaneously, the water dispenser provides hot and cold water to meet the user's drinking needs.

[0006] However, existing ice-making water dispensers have certain limitations. For example, they are inefficient at producing hot water, requiring room temperature water to be fed into a kettle before heating, or using an internal rapid heating module to heat room temperature water before outputting it, resulting in hot water that cannot reach boiling point. In addition, multi-functional water dispensers on the market (such as ice-making water dispensers) are too bulky due to their integration of ice making, hot water, and ice water functions, making them unsuitable for small apartments. Utility Model Content

[0007] In order to solve the above-mentioned problems in the prior art, this utility model provides an integrated water treatment device.

[0008] An integrated water treatment device includes a main body, which includes a lower outer shell and an upper base;

[0009] The main body is provided with

[0010] Cold tank water tank;

[0011] The refrigeration module is used to receive water from the cold tank and produce ice and / or ice water. The ice is output through the ice outlet and the ice water is output through the drain outlet on the base.

[0012] The heating module is used to receive water from the cold tank and produce hot water, which is then output through the drain on the base.

[0013] The refrigeration module includes an ice-making component and an ice-water component connected to the same condenser assembly, and the ice-making component and the ice-water component are in communication.

[0014] A circulation pump is provided between the ice-making component and the ice-water component. The circulation pump drives the ice-water produced by the ice-water component to the ice-making component. The ice-water undergoes secondary cooling in the ice-making component and then circulates back to the ice-water component.

[0015] The above technical solution is further configured as follows: the ice-making assembly includes an ice-making box with a first evaporator inside, an ice-water separation box disposed outside the ice-making box, and an ice-receiving box for discharging ice.

[0016] The ice-making box can rotate under the action of the driving component, pouring out the ice water deposited at the bottom of the ice-making box and letting it enter the ice water separation box, which is equipped with a return water port connected to the circulation pipeline.

[0017] A further provision of the above technical solution is that an ice-removing shovel is hinged to the ice-dispensing side of the ice-making box, and the outer end of the ice-removing shovel is infinitely close to the edge of the ice-water separation box, so that ice blocks cannot enter the ice-water separation box.

[0018] A further provision of the above technical solution is that the ice water assembly includes an ice water tank with a built-in second evaporator. The ice water tank is connected to the circulation pipeline and the water inlet pipe, and can receive ice water output from the ice-making assembly and water output from the cold tank, and after cooling, output it to the drain outlet and / or output it again to the ice water box.

[0019] A further provision of the above technical solution is that the heating module includes a rapid heating module and an electric heating module. The electric heating module is equipped with a kettle for receiving room temperature water or hot water output from the drain outlet, and for heating or reheating the room temperature water or hot water in the kettle.

[0020] A further provision of the above technical solution is that: a water outlet box is provided at the drain outlet on the pedestal, and the water outlet box is connected to the heating module and the cooling module through a pipeline;

[0021] The water outlet box is equipped with a baffle plate, which divides the inner cavity of the water outlet box into an inlet cavity and an outlet cavity that are connected by a lower part; the inlet pipe is connected to the inlet cavity;

[0022] The water outlet chamber is provided with a liquid inlet and a steam inlet, with the steam inlet being higher than the liquid inlet.

[0023] A further provision of the above technical solution is that the output port of the water outlet box is a mixing outlet, and the mixing outlet is configured as a liquid outlet hole communicating with the liquid inlet and a steam outlet trough communicating with the steam inlet.

[0024] The steam outlet channel is arranged around the liquid outlet hole.

[0025] The above technical solution is further configured as follows: a pure water module is used to receive pure water output from the cold tank and filtered, and the pure water is stored in the pure water tank on the pedestal;

[0026] The pure water module includes a filter assembly connected to a cold water tank, and the drain outlet of the filter assembly is connected to the pure water tank.

[0027] The filtration assembly includes a composite filter element and an RO membrane filter element. Water in the cold tank passes sequentially through the pre-filter element of the composite filter element, the RO membrane filter element, and the post-filter element of the composite filter element before being output to the pure water tank.

[0028] A further provision of the above technical solution is that both the composite filter element and the RO membrane filter element include a core and a filter base, the end of the core is provided with a mounting neck, and the mounting neck and the filter base are locked together by a locking structure.

[0029] A further provision of the above technical solution is that: the filter seat is provided with a mounting groove capable of accommodating the mounting neck, the groove wall of the mounting groove is provided with a guide groove, and the outer wall of the mounting neck is provided with a guide rib that cooperates with the guide groove.

[0030] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0031] This utility model integrates various functions such as ice making, pure water, hot water, ice water, and storage into one device, making the device more comprehensive and practical.

[0032] With a dual heating mode, the hot water output from the rapid heating module enters the kettle through the drain, and is then heated to boiling by the kettle. This setting greatly shortens the boiling time of the hot water.

[0033] When producing low-temperature ice water, the ice-making component and the ice water component can be turned on simultaneously, and the temperature of the ice-making component can be set higher than the ice-making temperature through the program. At this time, the ice-making component cannot make ice blocks, but can make low-temperature ice water. This allows the ice water output from the ice water component to be cooled again and used for secondary refrigeration. The refrigeration temperature of both the ice-making component and the ice water component can be increased, which effectively improves the efficiency of cold water preparation and avoids the freezing of liquid water inside the refrigeration module. It has the effects of high cold water preparation efficiency and effective prevention of icing in the cold tank. Attached Figure Description

[0034] Figure 1 This is a schematic diagram of the overall structure of this utility model.

[0035] Figure 2 This is a structural diagram showing the door panel in the open position.

[0036] Figure 3 This is a schematic diagram of the heating module.

[0037] Figure 4 This is a schematic diagram showing the exploded structure of the water outlet box.

[0038] Figure 5 This is a cross-sectional structural diagram of the water outlet box.

[0039] Figure 6 This is a schematic diagram of the internal structure of the box.

[0040] Figure 7 This is a schematic diagram of the water outlet of the water box.

[0041] Figure 8 This is a schematic diagram of the cooling module.

[0042] Figure 9 This is a cross-sectional structural diagram of the cooling module.

[0043] Figure 10 This is a top view of the ice-making component.

[0044] Figure 11 This is a schematic diagram of the ice-making component.

[0045] Figure 12 This is a schematic diagram of the pure water module.

[0046] Figure 13 This is a cross-sectional structural diagram of the filter element assembly.

[0047] Figure 14 This is a schematic diagram of the connection structure between the core and the filter base.

[0048] Figure 15 This is a first-view exploded structural diagram of the core and filter base.

[0049] Figure 16 This is a second-view exploded structural diagram of the core and filter base.

[0050] Figure 17 A cross-sectional structural diagram showing the connection between the mounting neck and the filter base.

[0051] Figure 18 for Figure 15 Enlarged structural diagram of part A in the middle.

[0052] The attached diagram is labeled as follows: 100, outer casing; 110, storage cabinet; 120, door panel; 200, base; 210, backrest; 220, shelf; 230, water outlet; 240, control panel; 300, water outlet box; 310, box body; 311, anti-overflow protrusion; 311.1, water-retaining arc surface; 312, vent column; 320, box cover; 321, water baffle; 301, water box inlet; 302, water box outlet; 303, water inlet chamber; 304, water outlet chamber; 305, liquid inlet; 305.1, air bubble. Dividing rib; 306, Steam inlet; 302.1, Liquid outlet; 302.2, Steam outlet trough; 330, Water outlet sleeve; 340, Light panel; 350, Mounting plate; 351, Insertion protrusion; 360, Sealing ring; 400, Ice-making assembly; 410, Ice box; 420, Ice-water separation box; 421, Water return port; 430, First evaporator; 440, Ice receiving box; 450, Drive unit; 460, Mounting housing; 470, Ice scraper; 471, Drain hole; 500, Ice-water assembly; 510, Ice-water tank; 52 0. Second evaporator; 600. Filter assembly; 610. Composite filter element; 611. Pre-filter element; 612. Post-filter element; 620. RO membrane filter element; 630. Filter base; 631. Base body; 633. Mounting sleeve; 640. Core body; 631.1. Mounting groove; 633.1. Guide groove; 641. Mounting neck; 641.1. Guide rib; 641.2. Water guide hole; 632. Water connection plate; 632.1. Connecting pipe; 631.2. Water pipe; 632.2. Annular groove; 632.3. Protrusion 631.3, Snap-fit ​​groove; 633.3, Pressing edge; 633.11, Insertion section; 633.12, Locking section; 641.11, Guide section; 631.4, Arc groove; 1, Kettle; 2, Cold water tank; 3, Pure water tank; 4, Coupler; 5, Rapid heating module; 6, Reversing valve; 7, Condenser assembly; 8, Pump assembly; 9, Circulation pipeline; 10, Elastic element; 11, Seal; a, Water guide notch; 12, First sealing ring; 13, Second sealing ring; 14, Third sealing ring; 15, Sensor. Detailed Implementation

[0053] To further illustrate the technical means and effects adopted by this utility model in order to achieve the intended utility model purpose, the following detailed description of the specific implementation methods, structure, features and effects of this utility model is provided in conjunction with the accompanying drawings and preferred embodiments.

[0054] like Figure 1-18 As shown, this embodiment discloses an integrated water treatment device.

[0055] An integrated water treatment device includes a main body, which includes a lower outer shell 100 and an upper pedestal 200;

[0056] The main body is provided with

[0057] Cold tank 2;

[0058] The refrigeration module is used to receive water from the cold tank 2 and make ice and / or ice water. The ice is output through the ice outlet and the ice water is output through the drain outlet on the base 200.

[0059] The heating module is used to receive water from the cold tank 2 and produce hot water, which is then output through the drain on the base 200.

[0060] Specific reference Figure 1 As shown, in this embodiment, the main body includes a lower outer shell 100 and an upper pedestal 200. The upper part of the inner cavity of the outer shell 100 is configured as a functional chamber for setting up functional modules. The lower part of the inner cavity of the outer shell 100 is configured as a storage cabinet 110, which can be used to store tea sets, tea-making utensils, etc.

[0061] A door panel 120 is hinged to the front end of the outer casing 100. When the door panel 120 is opened, the sheet metal and storage cabinets inside the functional cavity are exposed, facilitating the use of the storage cabinets. Furthermore, an ice container 440 for holding ice is pull-out and mounted on the sheet metal of the functional cavity. Ice can be retrieved from the ice container 440 by opening the door panel 120. (See details...) Figure 2 As shown.

[0062] Based on the above settings, functions such as ice making, pure water, hot water, ice water, and storage are integrated into one device, making the device more comprehensive and practical.

[0063] In this embodiment, the specific configuration of the cooling module is as follows:

[0064] The refrigeration module includes an ice-making component 400 and an ice-water component 500 connected to the same condenser component 7, and the ice-making component 400 and the ice-water component 500 are in communication.

[0065] A circulation pump is provided between the ice-making component 400 and the ice-water component 500. The circulation pump drives the ice-water produced by the ice-water component 500 to the ice-making component 400. The ice-water undergoes secondary cooling in the ice-making component 400 before being circulated back to the ice-water component 500.

[0066] Specific reference Figure 8 As shown, the chilled water assembly 500 is located below the ice-making assembly 400. After receiving room temperature water from the cold tank 2, the chilled water assembly 500 cools the room temperature water and drives the cooled chilled water to the ice-making assembly 400 through the pump assembly 8. The ice-making assembly 400 cools the chilled water again to form ice blocks or chilled water at an even lower temperature, thereby reducing the time for making ice or chilled water and improving the cooling efficiency.

[0067] The condenser assembly 7 is connected to the ice-making assembly 400 and the chilled water assembly 500 respectively, and can provide cooling to the ice-making assembly 400 and the chilled water assembly 500 simultaneously, or provide cooling to the ice-making assembly 400 and the chilled water assembly 500 individually, to meet consumer demand.

[0068] In this embodiment, the condenser assembly 7 is a conventional condenser structure in the prior art, and will not be described in detail here.

[0069] Preferably, in this embodiment, the pump assembly 8 includes a circulation pump that connects the ice-making assembly 400 and the ice-water assembly 500, and drives the lower-temperature ice-water generated in the ice-making assembly 400 to the ice-water assembly 500 for recirculation.

[0070] When producing low-temperature ice water, the ice-making component 400 and the ice water component 500 can be turned on simultaneously, and the temperature of the ice-making component 400 can be set to a higher temperature than the ice-making temperature through the program. At this time, the ice-making component 400 cannot make ice blocks, but can make low-temperature ice water. This allows the ice water output from the ice water component 500 to be cooled again and used for secondary refrigeration. The refrigeration temperature of both the ice-making component 400 and the ice water component 500 can be increased. This effectively improves the efficiency of cold water preparation while preventing the liquid water inside the refrigeration module from freezing. It has the effects of high cold water preparation efficiency and effective prevention of icing in the refrigeration tank.

[0071] Specifically, the ice-making assembly 400 includes an ice-making box 410 with a first evaporator 430 inside, an ice-water separation box 420 disposed outside the ice-making box 410, and an ice-receiving box 440 for discharging ice.

[0072] The ice-making box 410 can rotate under the action of the driving component, pouring out the ice water deposited at the bottom of the ice-making box 410 and letting it enter the ice water separation box 420. The ice water separation box 420 is provided with a return water port 421 connected to the circulation pipe 9.

[0073] Specific reference Figure 10 and Figure 11 As shown, in this embodiment, the condenser assembly 7 cools the first evaporator 430. Water in the cold tank 2 enters the ice box 410 under the action of the pump assembly 8. Under the cooling action of the first evaporator 430, ice is made. At the same time, a small amount of residual water or water formed by melting ice in the ice box 410 is deposited at the bottom of the ice box 410. The drive device 450 drives the ice box 410 to rotate, and the water at the bottom of the ice box 410 is poured out and enters the ice-water separation box 420. After the drive device 450 drives the ice box 410 to reset, the first evaporator 430 de-ices, and the ice blocks frozen on the ice column fall into the ice box 410. The drive device 450 drives the ice box 410 to rotate again, and the fallen ice blocks are poured out into the ice receiving box 440.

[0074] The water that enters the ice-water separation box 420 enters the circulation pipe through the return water port 421, and then enters the ice-water assembly 500 for recycling.

[0075] In this embodiment, the first evaporator 430 is a device with an ice column commonly used in ice-making equipment. After the ice blocks solidify on the surface of the ice column to form ice blocks, they fall off. The specific structure and usage are the same as those of ice-making devices in the prior art, and will not be described in detail here.

[0076] Preferably, in this embodiment, the driving device 450 is a drive motor disposed on the side of the ice maker 410. The drive motor can drive the ice maker 410 to rotate to one side, thereby pouring out the ice water or ice cubes inside the ice maker 410.

[0077] Preferably, in this embodiment, the bottom of the ice-water separation box 420 is set as an arc-shaped bottom surface, which is conducive to the accumulation of water in the ice-water separation box 420. The return water port 421 is set at the lowest point of the bottom of the ice-water separation box 420 to ensure that the water accumulated in the ice-water separation box 420 can be completely drained through the return water port 421 and the circulation pipe.

[0078] Specifically, the ice-making assembly 400 also includes a mounting housing 460, which has a accommodating space for accommodating the ice-making assembly 400. Furthermore, an opening slot for accommodating the ice-receiving box 440 is provided below the ice-making assembly 400 within the mounting housing 460. The ice-receiving box 440 can be pulled out from the opening of the mounting housing 460 to retrieve ice, and then pushed into the opening slot to collect ice.

[0079] In this embodiment, a sensor is installed inside the housing 460 to sense the amount of ice in the ice box 440 and remind the user to take out the ice in time.

[0080] Meanwhile, the mounting housing 460 is positioned above the chilled water assembly 500, which helps to shorten the distance between the chilled water separator 420 and the chilled water assembly 500, reducing the loss of cooling energy during the process of water accumulating at the bottom of the chilled water separator 420 flowing back to the chilled water assembly 500, thereby achieving the purpose of saving electricity.

[0081] In addition, in order to ensure that the ice cubes can smoothly enter the ice receiving box 440, an ice-removing shovel 470 is hinged to the ice outlet side of the ice making box 410. The outer end of the ice-removing shovel 470 is very close to the edge of the ice-water separation box 420, so that the ice cubes cannot enter the ice-water separation box 420.

[0082] Preferably, the distance between the outer end of the ice scraper 470 and the edge of the ice-water separation box 420 is smaller than the size of the ice block, so as to prevent the ice block from falling into the ice-water separation box 420 through the gap.

[0083] Preferably, the ice scraper 470 has a drainage hole 471. When the ice is poured out, a small amount of liquid water generated by the melting of the ice surface can enter the ice-water separation box 420 through the drainage hole 471, further ensuring the effect of ice-water separation.

[0084] The ice water assembly 500 includes an ice water tank 510 with a built-in second evaporator 520. The ice water tank 510 is connected to the circulation pipe 9 and the water inlet pipe, and can receive ice water output from the ice making assembly 400 and water output from the cold tank 2, and after cooling, output to the drain and / or output to the ice water box again.

[0085] Specific reference Figure 9 As shown, the circulation pipe 9 is connected between the return water port 421 and the ice water box, and is used to output the water accumulated in the ice water separation box 420 downward to the ice water box for reuse; in addition, the ice water tank 510 is provided with a water outlet pipe, preferably two water outlet pipes, one connected to the water outlet box 300 of the water outlet section 230, and the other connected to the ice box 410 to supply water to the ice box 410.

[0086] During the antifreeze stage, ice water is produced by simultaneously activating the first evaporator 430 and the second evaporator 520. The refrigerant generated by the condenser assembly 7 is simultaneously supplied to the first evaporator 430 and the second evaporator 520. The second evaporator 520 is used to cool the water in the ice water tank 510. The cold water produced in the ice water tank 510 is transported to the ice maker 410 by a circulation pump. At this time, the first evaporator 430 in the ice maker 410 cools the cold water in the ice maker 410 a second time. The cold water that has been cooled a second time in the ice maker 410 gradually fills the ice maker 410 and falls into the ice water separator 420. The cold water in the ice water separator 420 flows back to the ice water tank 510 through the return water port 421. This cycle forms a dynamic water circulation between the ice water tank 510, the ice maker 410, and the ice water separator 420, which can prevent ice from forming at the outlet of the ice water tank 510.

[0087] In this embodiment, the specific implementation of the heating module is as follows:

[0088] The heating module includes a rapid heating module 5 and an electric heating module. The electric heating module is equipped with a kettle 1 for receiving room temperature water or hot water output from the drain outlet, and for heating or reheating the room temperature water or hot water in the kettle 1.

[0089] In this embodiment, the base 200 includes a backrest 210 and a shelf 220. The cold water tank 2 is located at the back of the backrest 210. A water outlet 230 with a control panel 240 is provided on the side of the backrest 210 facing the shelf 220. The drain outlet is located at the bottom of the water outlet 230. The water receiving device and the kettle 1 are located on the shelf 220 below the water outlet 230. At the same time, the electric heating module is located inside the kettle 1, and a coupler 4 for energizing the electric heating module is provided on the shelf 220. It is connected to the internal circuit system of the main body. When the kettle 1 is coupled to the coupler 4, the electric heating module can be controlled by the control panel 240 to heat the room temperature water in the kettle 1.

[0090] In this embodiment, the structure and usage of the connection between the electric heating module and the coupler 4, as well as the heating of the electric kettle, are consistent with the structure in the prior art, and will not be described in detail here.

[0091] In addition, in this embodiment, a sensor 15 is provided on the front surface of the base 200, and two placement positions are provided on the shelf 220. One position is provided with a coupler for heating the electric kettle, and the other position is used to place a cup to receive room temperature water or ice water. The sensor 15 is used to sense whether a cup is placed to prevent water from being dispensed when there is no cup to receive it.

[0092] Meanwhile, the rapid heating module 5 is located inside the back panel and is connected to the drain outlet via a pipe. When the rapid heating module 5 is powered on, it heats the room-temperature water passing through it and then outputs the hot water from the drain outlet. See details... Figure 3 As shown.

[0093] Due to the inherent limitations of the rapid heating module 5, the water temperature at the front end is relatively low during the water output process because the heating element inside the rapid heating module 5 has not reached its maximum temperature. Although the water temperature at the rear is high, the contact time between the water and the heating element is too short due to the instantaneous water output, and it usually cannot reach boiling point. As a result, the hot water output by the rapid heating module 5 is not hot enough. In this embodiment, a dual heating mode is set. The hot water output by the rapid heating module 5 enters the kettle 1 through the drain outlet, and is then heated to boiling point by the kettle 1. This setting greatly shortens the boiling time of the hot water.

[0094] In addition, in this embodiment, a water outlet box 300 is provided at the drain outlet on the base 200, and the water outlet box 300 is connected to the heating module and the cooling module through pipelines;

[0095] The water outlet box 300 is provided with a baffle plate 321, which divides the inner cavity of the water outlet box 300 into an inlet cavity 303 and an outlet cavity 304 that are connected at the bottom; the inlet pipe is connected to the inlet cavity 303; the outlet cavity 304 is provided with a liquid inlet 305 and a steam inlet 306, and the steam inlet 306 is higher than the liquid inlet 305.

[0096] Specific reference Figure 4 As shown, the water outlet box 300 includes a box body 310 with an opening at the top and a box cover 320 welded by ultrasonic welding. The water inlet 301 is located on the rear end face of the water outlet box 300 or on the box cover 320. Two water inlets 301 can be provided on the water outlet box 300 at the same time, which are used to input room temperature water and hot water respectively.

[0097] The baffle plate 321 is formed on the lower end face of the cover 320. When the cover 320 is welded to the water outlet box 300, the baffle plate 321 separates the upper part of the inner cavity of the water outlet box 300, forming an inlet cavity 303 and an outlet cavity 304 that are only connected at the bottom. The water inlet 301 of the water box is connected to one side of the inlet cavity 303, and the water outlet 302 of the water box is connected to one side of the outlet cavity 304.

[0098] Based on the above settings, when the hot water heated by the rapid heating module 5 enters the outlet box 300 through the inlet pipe, the steam of the hot water is located above the liquid. Due to the setting of the baffle plate 321, the steam cannot move from the inlet chamber 303 to the outlet chamber 304, thus separating the water vapor from the hot water.

[0099] Regarding the water outlet structure of the water outlet box 300, please refer to the following for details. Figure 5 As shown, in this embodiment, an overflow prevention protrusion 311 and an exhaust column 312 extend upward from the bottom in the water outlet cavity 304. The steam inlet 306 is located on the exhaust column 312, and the steam inlet 306 is higher than the liquid inlet 305. The purpose of this arrangement is to work with the special structure where steam is above and liquid is below in hot water, so that steam enters the steam inlet 306 and liquid enters the liquid inlet 305, thus avoiding the unstable situation of intermittent water output caused by the mixing of liquid and gas entering from the same outlet during the water output process.

[0100] Furthermore, in this embodiment, to ensure the effectiveness of water vapor separation, specific details should be referred to... Figure 5 As shown, the lower end of the baffle plate 321 is lower than the height of the liquid inlet 305. With this setting, when the liquid in the water inlet chamber 303 enters the water outlet chamber 304 and reaches a certain liquid level, it can be output from the liquid inlet 305, so as to avoid steam from entering the water box outlet 302 from the liquid inlet 305 when the amount of steam is too large.

[0101] In this embodiment, the inner wall of the liquid inlet 305 is also provided with bubble dividing ribs 305.1. When hot water passes through the liquid inlet 305, it passes through the bubble dividing ribs 305.1, which defoams a small amount of bubbles mixed in the liquid, further reducing the amount of bubbles in the liquid.

[0102] When there is too much steam, the steam rises and fills the upper part of the liquid outlet chamber. At this time, the steam continues to enter the water outlet chamber 304 from the water inlet chamber 303 and moves upward in the water outlet chamber 304. The excess steam in the water outlet chamber 304 will first enter the water outlet 302 of the water box from the steam inlet 306 to prevent the steam from entering the liquid inlet chamber and occupying the liquid output space of the liquid inlet chamber.

[0103] Preferably, the anti-overflow protrusion 311 is connected to the vent column 312, the vent column 312 is provided at both ends of the anti-overflow protrusion 311, and the anti-overflow protrusion 311 is arc-shaped and forms a water-blocking arc surface 311.1, which is arranged around the outer periphery of the liquid inlet 305.

[0104] The water-blocking arc surface 311.1 and the water-blocking plate 321 are staggered vertically, and the water-blocking arc surface 311.1 and the water-blocking plate 321 form a water-guiding arc surface. The water-blocking arc surface 311.1 forms an opening for connecting the liquid inlet 305. After water enters the water inlet cavity 303, it is first buffered by the water-blocking plate, and then moves towards the liquid outlet under the guidance of the water-guiding arc surface. Finally, under the action of the water-blocking arc surface 311.1, the water is discharged from the liquid inlet 305.

[0105] When steam and liquid separate and enter the liquid inlet 305 and steam inlet 306, the outlet of the water outlet box 300 is a mixed outlet when it is output. The mixed outlet is configured as a liquid outlet hole 302.1 connected to the liquid inlet 305 and a steam outlet groove 302.2 connected to the steam inlet 306.

[0106] The steam outlet channel 302.2 is arranged around the liquid outlet hole 302.1.

[0107] Specific reference Figure 7 As shown, the water outlet 302 of the water box is configured as a mixing port, with its structure having a center for liquid discharge and an outer perimeter for steam output. Therefore, in this embodiment, the steam outlet 302.2 is configured as an annular structure, surrounding the liquid outlet 302.1. When hot water is output, liquid and steam are simultaneously output from the water outlet 302 of the water box. The outer steam has a heat-insulating effect on the liquid in the center, thereby enabling the hot water to remain at the heating temperature when it is output.

[0108] Preferably, in this embodiment, the lower end of the liquid outlet is lower than the lower end of the steam outlet 302.2 to ensure that the liquid output is consistent, while the steam located around the liquid overflows in advance to avoid impacting the liquid in the cup and causing hot water to splash and scald the user.

[0109] In addition, in this embodiment, a water outlet sleeve 330 is provided at the water outlet position of the water outlet section 230. The water outlet sleeve 330 is provided with a clearance hole that can accommodate the water outlet 302 of the water box to extend out. At the same time, a light plate 340 is provided inside the water outlet sleeve 330. The center of the light plate 340 is hollowed out and fitted on the water outlet 302 of the water box, and is far away from the lower end of the steam outlet 302.2. It can accurately indicate the position of the water outlet, making it easier for users to collect water. In addition, different lights are provided for different water temperatures to improve the user experience and enhance the safety during use.

[0110] To ensure light transmittance, the water outlet sleeve 330 can be made of a light-transmitting material.

[0111] To facilitate the installation of the lamp panel 340, in this embodiment, the water outlet sleeve 330 is provided with a mounting plate 350. The lamp panel 340 is embedded in the mounting plate 350 and the mounting plate 350 is snapped into the water outlet sleeve 330. The lamp panel 340 emits light, and the light passes through the mounting plate 350 and the water outlet sleeve 330 in sequence to radiate outward, so as to accurately indicate the position of the water outlet.

[0112] In addition, the mounting plate 350 has a plug-in protrusion 351, and the bottom of the water outlet box 300 has a plug-in groove for the plug-in protrusion 351 to be inserted. The plug-in protrusion 351 and the plug-in groove cooperate to further ensure the reliability of the connection between the water outlet box 300 and the water outlet sleeve 330.

[0113] Preferably, a sealing groove is formed on the water outlet sleeve 330, and a sealing ring 360 is provided in the sealing groove. The sealing ring 360 abuts against the water outlet panel 300, further improving the stability of the mounting base installation.

[0114] As a preferred option, the water outlet sleeve 330 is filled with glue, which not only improves the waterproof performance but also increases the heat dissipation effect.

[0115] In this embodiment, multiple water outlet boxes 300 can be provided in the water outlet section 230, and a reversing valve 6 is connected to the water outlet end of the rapid heating module 5 to communicate with the multiple water outlet boxes 300 respectively. The water outlet is switched by controlling the reversing valve 6.

[0116] Coupler 4 is only located below one of the water outlets, so that hot water at the required temperature can be obtained according to the consumer's needs.

[0117] In this embodiment, the specific implementation method for the pure water module is as follows:

[0118] The pure water module is used to receive and filter pure water output from the cold tank 2, and the pure water is stored in the pure water tank 3 on the pedestal 200.

[0119] The pure water module includes a filter assembly 600 connected to the cold water tank 2, and the drain of the filter assembly 600 is connected to the pure water tank 3.

[0120] The filtration assembly 600 includes a composite filter element 610 and an RO membrane filter element 620. The water in the cold tank 2 passes sequentially through the pre-filter element 611 of the composite filter element 610, the RO membrane filter element 620, and the post-filter element 612 of the composite filter element 610, and then the pure water is output to the pure water tank 3.

[0121] Specific reference Figure 12 As shown, the water in the cold water tank 2 is filtered sequentially through the filter element in the filter assembly 600, and then the pure water is output to the pure water tank 3 for storage and use.

[0122] Preferably, in this embodiment, the outlet of the filter component 600 can be simultaneously connected to the ice-making component 400 and the ice-water component 500 for making ice cubes and ice-water.

[0123] Specific reference Figure 13As shown, the pre-filter 611 and post-filter 612 are arranged vertically to form a composite filter 610. The composite filter 610 is provided with a pre-inlet, a pre-outlet, a post-inlet, and a post-outlet respectively connected to the pre-filter 611. The RO membrane filter 620 is provided with a filter outlet and a filter inlet. The water in the cold tank 2 enters the pre-filter 611 through the pre-inlet for the first filtration, then exits through the pre-outlet, enters the RO membrane filter 620 through the filter inlet for the second filtration, exits through the filter outlet, enters the post-filter 612 through the post-inlet for the third filtration, and after filtration, exits through the filter outlet to the post-filter 612 for the third filtration. After filtration, it is output from the post-outlet to the pure water tank 3, the ice-making unit 400, or the ice-water unit 500 for use.

[0124] Specifically, both the composite filter element 610 and the RO membrane filter element 620 include a core 640 and a filter base 630. The end of the core 640 is provided with a mounting neck 641, and the mounting neck 641 and the filter base 630 are locked together by a locking structure.

[0125] The core 640 is disposed inside the core shell. Inside the core 640 are the pre-filter 611 and post-filter 612 of the composite filter 610 and the RO membrane structure of the RO membrane filter 620. Each core 640 is provided with a corresponding filter seat 630, and the two filter seats 630 have the same structure.

[0126] Reference Figure 14 and Figure 15 As shown, the filter base 630 is provided with a mounting groove 631.1 that can accommodate the mounting neck 641. The groove wall of the mounting groove 631.1 is provided with a guide groove 633.1, and the outer wall of the mounting neck 641 is provided with a guide rib 641.1 that cooperates with the guide groove 633.1.

[0127] Align the guide rib 641.1 at the lower end of the core 640 with the opening of the guide groove 633.1 of the filter seat 630, and then rotate the core 640 or the filter seat 630 so that the guide rib 641.1 rotates relative to the guide groove 633.1, thereby sliding the guide rib 641.1 into the guide groove 633.1, thus completing the installation of the core 640 and the filter seat 630.

[0128] Specifically, refer to Figure 15 and 16 As shown, the bottom of the mounting neck 641 has several water guide holes 641.2 that communicate with the inner cavity of the core 640. A locking structure is provided between the mounting neck 641 and the filter seat 630. The core 640 can rotate and switch between locked and unlocked states relative to the filter seat 630 through the locking structure.

[0129] A water connection plate 632 is rotatably mounted on the filter base 630. A water pipe 631.2 is provided on the filter base 630 corresponding to the water guide hole 641.2. A connecting pipe 632.1 is provided on the water connection plate 632. When the core 640 is installed on the filter base 630, one end of the connecting pipe 632.1 is inserted into and connected to the water guide hole 641.2 of the mounting neck 641. The core 640 can drive the water connection plate 632 to rotate relative to the filter base 630. When the core 640 rotates relative to the filter base 630 to the locked state, the water pipe 631.2 connects to the mounting neck 641 through the connecting pipe 632.1. The corresponding water guide hole 641.2 is connected; the filter seat 630 is provided with an installation groove 631.1 corresponding to the mounting neck 641, and the side wall of the water connection plate 632 is provided with an annular groove 632.2. A first sealing ring 12 is provided in the annular groove 632.2. The side wall of the water connection plate 632 is sealed with the inner wall of the installation groove 631.1 through the first sealing ring 12. The annular groove 632.2 can improve the installation firmness of the first sealing ring 12 on the side wall of the water connection plate 632, and the first sealing ring 12 can improve the water leakage prevention performance between the water connection plate 632 and the inner wall of the installation groove 631.1.

[0130] Furthermore, the water guide hole 641.2 is equipped with a valve structure. When the core 640 is installed on the filter base 630, the connecting pipe 632.1 operates the valve structure to the open state. When the core 640 is separated from the filter base 630, the water guide hole 641.2 remains sealed through the valve structure. When the core 640 is separated from the filter base 630, the core 640 can achieve self-sealing through the valve structure to prevent water leakage after the core 640 is removed.

[0131] Specific reference Figure 17 As shown, the valve structure includes an elastic element 10 and a sealing element 11 disposed in the corresponding water guide hole 641.2. The elastic element 10 has a tendency to push the sealing element 11 to block the opening end of the water guide hole 641.2. The side wall of the end of the connecting pipe 632.1 is provided with a water guide notch a. When the core 640 is installed on the filter seat 630, the connecting pipe 632.1 pushes the sealing element 11 away from the opening end of the corresponding water guide hole 641.2, so that the connecting pipe 632.1 communicates with the inner cavity of the core 640 through the water guide notch a. After the core 640 is installed on the filter seat 630, the connecting pipe 632.1 of the water circuit connecting plate 632 is inserted into the water guide hole 641.2 of the core 640. The connecting pipe 632.1 pushes the sealing element 11 to move away from the opening end of the water guide hole 641.2, so that the connecting pipe 632.1 can communicate with the inner cavity of the core 640 through the water guide notch a.

[0132] A second sealing ring 13 is provided inside the water guide hole 641.2. When the connecting pipe 632.1 is inserted into the corresponding water guide hole 641.2, the outer side of the connecting pipe 632.1 is sealed to the inner wall of the water guide hole 641.2 through the second sealing ring 13. The second sealing ring 13 can seal and wrap the outer wall of the connecting pipe 632.1 inserted into the water guide hole 641.2, thereby improving the water leakage prevention performance between the outer wall of the connecting pipe 632.1 and the inner wall of the water guide hole 641.2.

[0133] The filter base 630 includes a base body 631 and a mounting sleeve 633. A mounting groove 631.1 is formed on the base body 631, and the mounting sleeve 633 is fixedly connected in the mounting groove 631.1 to prevent the water circuit connecting plate 632 from detaching from the mounting sleeve 633. A water pipe 631.2 is provided through the base body 631. A locking structure is provided between the mounting neck 641 and the mounting sleeve 633. During assembly, the water circuit connecting plate 632 is first rotated and placed in the mounting groove 631.1, and then the mounting sleeve 633 is fixedly installed in the mounting groove 631.1, so that the lower end of the mounting sleeve 633 stops and prevents detachment from the upper end of the water circuit connecting plate 632.

[0134] The base 631 has a groove at the outlet end of the water pipe 631.2, and a third sealing ring 14 is installed in the groove. When the core 640 is in the unlocked state relative to the filter base 630, the water circuit connecting plate 632 and the base 631 are sealed together by the third sealing ring 14. When the core 640 drives the water circuit connecting plate 632 to be in the unlocked state relative to the filter base 630, the connecting pipe 632.1 of the water circuit connecting plate 632 and the water pipe 631.2 of the filter base 630 are misaligned. The third sealing ring 14 can be used to achieve a seal between the outlet end of the water pipe 631.2 and the water circuit connecting plate 632. Water seal; the side wall of the mounting sleeve 633 extends with a snap-fit ​​part, and the base body 631 has a snap-fit ​​groove 631.3 corresponding to the snap-fit ​​part, which connects to the mounting groove 631.1. The snap-fit ​​part and the snap-fit ​​groove 631.3 snap-fit ​​together, so that the mounting sleeve 633 is positioned in the mounting groove 631.1 to prevent rotation. The snap-fit ​​part is locked and fixed to the base body 631 by bolts. By using the snap-fit ​​positioning of the snap-fit ​​part and the snap-fit ​​groove 631.3, the mounting sleeve 633 can be positioned in the base body 631 to prevent rotation. Then, the mounting sleeve 633 can be firmly locked to the base body 631 by bolts to complete the assembly of the mounting sleeve 633.

[0135] The locking structure includes several guide ribs 641.1 and guide grooves 633.1. The guide ribs 641.1 are distributed in a ring around the outer periphery of the mounting neck 641 in a horizontal direction. The guide grooves 633.1 are correspondingly formed on the inner wall of the mounting sleeve 633. The guide grooves 633.1 include a connected insertion section 633.11 and a locking section 633.12. The guide ribs 641.1 are inserted into the guide grooves 633.1 through the insertion section 633.11 and rotated to lock into the corresponding locking section 633.12. By utilizing the locking cooperation of the guide ribs 641.1 and the guide grooves 633.1, the mounting neck 641 of the core 640 can be disassembled and assembled on the mounting sleeve 633, improving the ease of disassembly and assembly between the core 640 and the filter base 630. The contact surface between guide rib 633.11 and guide rib 641.1 in the insertion direction is set as an arc-shaped guide surface. When guide rib 641.1 is inserted into insertion section 633.11, guide rib 641.1 is guided into the corresponding locking section 633.12 by the arc-shaped guide surface. In addition, in this embodiment, guide portion 641.11 extends obliquely at the tail of guide rib 641.1. When core 640 rotates from locked state to unlocked state relative to filter seat 630, the guide portion 641.11 and the arc-shaped guide surface can guide guide rib 641.1 to slide more smoothly from locking section 633.12 of guide groove 633.1 to insertion section 633.11, which facilitates the separation of core 640 and filter seat 630.

[0136] The bottom of the water channel connecting plate 632 is provided with a protrusion 632.3, and the base body 631 is provided with an arc groove 631.4 corresponding to the protrusion 632.3. When the water channel connecting plate 632 rotates relative to the base body 631, the protrusion 632.3 is constrained in the arc groove 631.4 and guided and cooperates with it. The protrusion 632.3 and the arc groove 631.4 guide and limit each other, which can limit the rotation angle of the water channel connecting plate 632 on the base body 631. At the same time, since the core 640 and the water channel connecting plate 632 are relatively anti-rotating, the core 640 is limited to rotate on the base body 631.

[0137] In this embodiment, a clamping edge 633.3 is provided on the lower edge of the mounting sleeve 633 extending toward the center. The clamping edge 633.3 is used to clamp the outer edge of the water circuit connection plate 632 to ensure the stable installation of the water circuit connection plate 632 in the base 631.

[0138] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any way. Although the present utility model has been disclosed above with reference to a preferred embodiment, it is not intended to limit the present utility model. Any person skilled in the art can make some modifications or alterations to the above-disclosed technical content to create equivalent embodiments without departing from the scope of the present utility model. Any simple modifications, equivalent changes and alterations made to the above embodiments based on the technical essence of the present utility model without departing from the scope of the present utility model shall still fall within the scope of the present utility model.

Claims

1. An integrated water treatment device, comprising a main body, the main body including a lower outer shell (100) and an upper pedestal (200); characterized in that: The main body is provided with, Cold tank (2); The refrigeration module is used to receive water from the cold tank (2) and make ice and / or ice water. The ice is output through the ice outlet and the ice water is output through the drain outlet on the base (200). The heating module is used to receive water from the cold tank (2) and produce hot water, which is output through the drain on the platform (200); The refrigeration module includes an ice-making assembly (400) and an ice-water assembly (500) connected to the same condenser assembly (7), and the ice-making assembly (400) and the ice-water assembly (500) are in communication. A circulation pump is provided between the ice-making component (400) and the ice-water component (500). The circulation pump drives the ice-water generated by the ice-water component (500) to the ice-making component (400). The ice-water is cooled twice in the ice-making component (400) and then circulated back to the ice-water component (500).

2. The integrated water treatment equipment according to claim 1, characterized in that: The ice-making assembly (400) includes an ice-making box (410) with a first evaporator (430) inside, an ice-water separation box (420) located outside the ice-making box (410), and an ice-receiving box (440) for discharging ice. The ice-making box (410) can rotate under the action of the driving component, and pour out the ice water deposited at the bottom of the ice-making box (410) so that it enters the ice water separation box (420). The ice water separation box (420) is provided with a return water port (421) connected to the circulation pipe (9).

3. The integrated water treatment equipment according to claim 2, characterized in that: An ice-removing shovel (470) is hinged to the ice-dispensing side of the ice-making box (410). The outer end of the ice-removing shovel (470) is infinitely close to the edge of the ice-water separation box (420) so that ice blocks cannot enter the ice-water separation box (420).

4. The integrated water treatment equipment according to claim 2, characterized in that: The ice water assembly (500) includes an ice water tank (510) with a built-in second evaporator (520). The ice water tank (510) is connected to the circulation pipe (9) and the water inlet pipe. It can receive ice water output from the ice-making assembly (400) and water output from the cold tank (2), and output it to the drain outlet and / or output it to the ice water box after cooling.

5. The integrated water treatment equipment according to claim 1, characterized in that: The heating module includes a fast heating module (5) and an electric heating module. The electric heating module is equipped with a kettle (1) for receiving room temperature water or hot water output from the drain outlet, and for heating or reheating the room temperature water or hot water in the kettle (1).

6. The integrated water treatment equipment according to claim 5, characterized in that: The pedestal (200) is provided with a water outlet box (300) at the drain outlet, and the water outlet box (300) is connected to the heating module and the cooling module through pipelines; The water outlet box (300) is provided with a baffle plate (321), which divides the inner cavity of the water outlet box (300) into an inlet cavity (303) and an outlet cavity (304) connected by a lower part; the inlet pipe is connected to the inlet cavity (303); The water outlet cavity (304) is provided with a liquid inlet (305) and a steam inlet (306), and the steam inlet (306) is higher than the liquid inlet (305).

7. The integrated water treatment equipment according to claim 6, characterized in that: The outlet of the water outlet box (300) is a mixing outlet, which is configured as a liquid outlet hole (302.1) communicating with the liquid inlet (305) and a steam outlet groove (302.2) communicating with the steam inlet (306); The steam outlet channel (302.2) is arranged around the liquid outlet hole (302.1).

8. The integrated water treatment equipment according to claim 1, characterized in that: A pure water module is used to receive and filter pure water output from the cold tank (2), and the pure water is stored in a pure water tank (3) on the platform (200); The pure water module includes a filter assembly (600) connected to the cold tank (2), and the drain of the filter assembly (600) is connected to the pure water tank (3). The filtration assembly (600) includes a composite filter element (610) and an RO membrane filter element (620). The water in the cold tank (2) passes through the pre-filter element (611) of the composite filter element (610), the RO membrane filter element (620), and the post-filter element (612) of the composite filter element (610) in sequence, and then the pure water is output to the pure water tank (3).

9. The integrated water treatment equipment according to claim 8, characterized in that: Both the composite filter element (610) and the RO membrane filter element (620) include a core (640) and a filter base (630). The end of the core (640) is provided with a mounting neck (641), and the mounting neck (641) and the filter base (630) are locked together by a locking structure.

10. The integrated water treatment equipment according to claim 9, characterized in that: The filter base (630) is provided with a mounting groove (631.1) that can accommodate the mounting neck (641). The groove wall of the mounting groove (631.1) is provided with a guide groove (633.1). The outer wall of the mounting neck (641) is provided with a guide rib (641.1) that cooperates with the guide groove (633.1).