CN217039716U - Water dispenser module and water dispenser - Google Patents

Abstract

The utility model discloses a water dispenser module, include: the heat exchanger is provided with a cold water channel and a hot water channel; a water pump; preheating the water tank; the instant water container is communicated with the preheating water container; the instant water heating liner comprises an instant heating liner and a boiled water storage liner, and the upper end of the instant heating liner extends into the boiled water storage liner. The water dispenser comprises a shell and the water dispenser module. The water dispenser has the advantages that the structures of the heat exchanger, the preheating water container, the water suction pump, the instant water container and the like are integrated into one water dispenser module, so that the requirements of technical personnel are reduced, the production efficiency of a water dispenser manufacturer is improved, the production cycle and the production cost of the water dispenser are reduced, and the quality of the water dispenser can be ensured. In the process of producing warm boiled water, the water pump pumps out boiled water in the instant hot water liner, the boiled water passes through the hot water channel of the heat exchanger, and the boiled water transfers the heat to the cold water channel. The cold water is preheated and then delivered to the preheating liner, and the cooled warm boiled water is delivered to the warm boiled water storage device or directly flows out from the water nozzle.

Description

Water dispenser module and water dispenser

Technical Field

The utility model relates to a water dispenser technical field, especially water dispenser module and water dispenser.

Background

In terms of drinking habits, most people prefer warm boiled water, but the warm boiled water is cooled naturally and changed in temperature, so that the people often need to wait for a long time, and much inconvenience is brought to daily life. At present, most drinking devices, such as a water purifier, a water dispenser or a water purifier, can not provide warm boiled water. A few drinking water devices for providing warm boiled water are manufactured by quickly cooling the just-boiled hot boiled water through a heat exchanger.

The traditional structure inside the water dispenser usually needs to be processed and assembled by a water dispenser manufacturer, the water dispenser manufacturer needs to employ technicians to design a water path, an inner container structure and an electric control structure inside the water dispenser, and meanwhile, the inner container of the water dispenser needs to be welded and each component in the water dispenser needs to be assembled, so that the production period of the water dispenser is long, and meanwhile, the production cost of enterprises is high.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: the water dispenser module and the water dispenser are provided to solve one or more technical problems in the prior art and provide at least one beneficial choice or creation condition.

The utility model provides a solution of its technical problem is:

a water dispenser module comprising: the heat exchanger is provided with a cold water channel and a hot water channel, two ends of the cold water channel are respectively a cold water inlet end and a cold water outlet end, two ends of the hot water channel are respectively a hot water inlet end and a hot water outlet end, and the cold water inlet end is communicated with the cold water outlet end; the water suction pump is provided with a water suction end and a water discharge end, and the water suction end is connected with the hot water outlet end; the preheating water container is communicated with the cold water outlet end; the instant hot water liner is communicated with the preheating water liner; the instant heating water container comprises an instant heating container and a boiled water storage container, wherein an instant heating pipe is installed in the instant heating container, the upper end of the instant heating container extends into the boiled water storage container, and the instant heating container is communicated with the boiled water storage container.

Through the technical scheme, the structures such as the heat exchanger, the preheating water container, the water suction pump, the instant heating water container and the like are integrated into one water dispenser module, the water dispenser module can be directly sold to each water dispenser manufacturer, the water dispenser manufacturer can directly purchase the water dispenser module, and then the water dispenser module is assembled with other parts and a self-designed shell, so that the water dispenser can be manufactured. The requirement of the number of technicians of the water dispenser manufacturer is reduced, the production efficiency of the water dispenser manufacturer is improved, the production period and the production cost of the water dispenser are reduced, and the quality of the water dispenser produced by the water dispenser manufacturer can be ensured.

During the process of producing warm boiled water, the water pump pumps out boiled water in the instant water container, the boiled water passes through a hot water channel of the heat exchanger, the boiled water transfers heat to water in a cold water channel, cold water is preheated and then conveyed to the preheating container, and the cooled warm boiled water is conveyed to a warm boiled water storage device or directly flows out of a water nozzle. This scheme carries out thermal recycle through heat exchanger, can make the drinking water module realize the effect of low carbon, energy-concerving and environment-protective.

As a further improvement of the technical scheme, the instant heating water container is connected with a steam pipe, the steam pipe is communicated with the boiled water storage container, two ends of the steam pipe are respectively provided with a steam inlet and a steam outlet, the steam inlet is arranged above the instant heating water container, and the steam pipe penetrates through the preheating water container.

Through above-mentioned technical scheme, the steam pipe discharges the vapor that produces when boiling to the water in the hot water courage promptly, avoids the too high hot water courage of leading to of the pressure in the hot water courage promptly to break. Because the steam pipe passes through the preheating water container, steam in the steam pipe and water in the preheating water container generate heat exchange while the steam is discharged through the steam pipe, so that the temperature of the water in the preheating water container is increased, a preheating effect is achieved, energy can be more effectively utilized, and the energy utilization rate is improved.

As a further improvement of the technical scheme, the boiled water storage liner is provided with a first water-stop piece, and the first water-stop piece is arranged above the instant heating liner.

Through above-mentioned technical scheme, first water-stop piece can separate vapor and boiling water, and vapor discharges from the bottom of preheating the water courage after the steam pipe condensation from the instant heating water courage top, and the boiling water is then blockked by first water-stop piece and can't get into the steam pipe, can only save in boiling water storage courage.

As a further improvement of the technical scheme, the boiled water storage liner is provided with a first water level monitoring device.

As a further improvement of the technical scheme, the boiled water storage liner is provided with a second water-stop piece, and the second water-stop piece is arranged on one side, close to the instant heating liner, of the first water level monitoring device.

Through above-mentioned technical scheme, the water that the second water proof piece can prevent the boiling splashes to first water level monitoring devices, can avoid the water of boiling to cause the influence to first water level monitoring devices.

As a further improvement of the technical scheme, the heat exchanger further comprises a cold water inlet pipeline assembly, wherein the cold water inlet pipeline assembly comprises a water inlet electromagnetic valve, a one-way valve, a flow stabilizing valve and a cold water inlet pipe body, one end of the cold water inlet pipe body is connected with the cold water inlet end, the water inlet electromagnetic valve, the flow stabilizing valve and the one-way valve are sequentially arranged along the extending direction of the cold water inlet pipe body, and the one-way valve is arranged on one side, close to the heat exchanger, of the flow stabilizing valve.

Through the technical scheme, the water dispenser module further comprises the cold water inlet pipeline assembly, so that the integration degree of the water dispenser module can be improved, and the production and assembly steps of downstream manufacturers can be further reduced.

As a further improvement of the technical scheme, the device further comprises a warm boiled water storage assembly, wherein the warm boiled water storage assembly comprises a warm boiled water liner and a warm boiled water connecting pipe body, and two ends of the warm boiled water connecting pipe body are respectively connected with the warm boiled water liner and the water outlet end of the pump.

Through the technical scheme, the warm boiled water storage component can be used for storing warm boiled water, so that the water yield of the warm boiled water can be guaranteed.

As a further improvement of the technical scheme, a heating and heat-preserving pipe is arranged in the warm boiled water liner.

Through the technical scheme, the heating insulation pipe can insulate warm boiled water in the warm boiled water liner.

As a further improvement of the above technical solution, a high water level detection device and a low water level detection device are arranged in the preheating water tank, the low water level detection device is lower than the high water level detection device, and the high water level detection device is lower than the upper end of the instant heating tank.

According to the technical scheme, the instant water heating liner is communicated with the preheating water liner, so that the water levels in the instant water heating liner and the preheating water liner are approximately the same according to the principle of a communicating vessel, the water level of the instant water heating liner is controlled by a water level electrode of the preheating liner, and the water level is between the high water level detection device and the low water level detection device and has a certain distance with the upper part of the heating pipe under the condition that water is not boiled, so that the water cannot overflow; however, when the water is heated to boiling, the boiled water overflows from the heating pipe and flows into the boiled water storage liner due to the volume expansion and boiling of the water.

The water dispenser comprises a shell and the water dispenser module, wherein the water dispenser module is arranged in the shell, and the water dispenser module is relatively fixed with the shell.

The utility model has the advantages that: the water dispenser module can be directly sold to each water dispenser manufacturer by integrating structures such as the heat exchanger, the preheating water tank, the water suction pump, the instant heating water tank and the like into one water dispenser module, and the water dispenser manufacturer can directly purchase the water dispenser module and then assemble the water dispenser module with other parts and self-designed shells, so that the water dispenser can be manufactured. The requirement of the number of technicians of the water dispenser manufacturer is reduced, the production efficiency of the water dispenser manufacturer is improved, the production period and the production cost of the water dispenser are reduced, and the quality of the water dispenser produced by the water dispenser manufacturer can be ensured.

The utility model is used for water dispenser technical field.

Drawings

In order to more clearly illustrate the technical solution in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below. It is clear that the described figures represent only some embodiments of the invention, not all embodiments, and that a person skilled in the art, without inventive effort, can also derive other designs and figures from them.

Fig. 1 is a schematic overall structure diagram of a first embodiment of the present invention;

fig. 2 is a schematic diagram of a water path according to a first embodiment of the present invention;

fig. 3 is a schematic diagram of a waterway according to a second embodiment of the present invention.

In the figure, 100, a heat exchanger; 200. a water pump; 300. preheating the water tank; 310. a high water level electrode; 320. a low water level electrode; 400. a hot water liner; 410. heating the liner; 420. a boiled water storage container; 421. a first water-stop member; 422. a float ball water level switch; 423. a second water-stop member; 430. a steam pipe; 500. a warm boiled water liner; 610. a one-way valve; 620. a flow stabilizing valve; 630. a water inlet electromagnetic valve; 710. a boiled water outlet nozzle; 720. a warm water outlet nozzle.

Detailed Description

The conception, the specific structure, and the technical effects produced by the present invention will be clearly and completely described below in conjunction with the embodiments and the accompanying drawings to fully understand the objects, the features, and the effects of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and other embodiments obtained by those skilled in the art without inventive labor based on the embodiments of the present invention all belong to the protection scope of the present invention. In addition, all the coupling/connection relationships mentioned herein do not mean that the components are directly connected, but mean that a better coupling structure can be formed by adding or reducing coupling accessories according to specific implementation conditions. The technical characteristics in the invention can be combined interactively on the premise of not conflicting with each other.

The first embodiment is as follows:

referring to fig. 1 to 2, a water dispenser includes a housing and a water dispenser module. The shell is provided with a boiled water outlet nozzle 710 and a warm water outlet nozzle 720.

The water dispenser module comprises a heat insulation inclusion, a heat exchanger 100, a preheating water container 300, an instant hot water container 400, a warm boiled water container 500, a water pump 200 and a cold water inlet pipeline. The heat insulation inclusion, the heat exchanger 100, the preheating water container 300, the instant water container 400 and the water pump 200 are relatively fixedly arranged.

The cold water inlet pipeline comprises a one-way valve 610, a flow stabilizing valve 620, a water inlet electromagnetic valve 630 and a cold water inlet pipe body. The water inlet solenoid valve 630, the flow stabilizing valve 620 and the check valve 610 are sequentially arranged along the extension direction of the cold water inlet pipe body, and the check valve 610 is arranged on one side of the flow stabilizing valve 620 close to the heat exchanger 100.

The heat exchanger 100 is provided with a cold water passage and a hot water passage. The cold water channel and the hot water channel are arranged closely, so that the water in the cold water channel and the water in the hot water channel can perform sufficient heat exchange. Two ends of the cold water channel are respectively a cold water inlet end and a cold water outlet end, the cold water inlet end is communicated with the cold water outlet end, and the cold water inlet end is communicated with the cold water inlet pipe body. Two ends of the hot water channel are respectively a hot water inlet end and a hot water outlet end, and the hot water inlet end is communicated with the hot water outlet end.

The preheating water container 300 is communicated with a cold water outlet end, the preheating water container 300 is communicated with the cold water outlet end, the communication position of the preheating water container 300 and the cold water outlet end is arranged in the middle of the preheating water container 300 in the vertical direction, and cold water flows into the preheating water container 300 from the cold water outlet end. The preheating water tank 300 is fixedly installed with a high water level detection device and a low water level detection device, the high water level detection device is set as a high water level electrode 310, and the low water level detection device is set as a low water level electrode 320 (in other embodiments, other common water level detection devices, such as a float water level switch, etc., may also be used). The low water level electrode 320 is disposed below the high water level electrode 310, the high water level electrode 310 and the low water level electrode 320 are respectively used for detecting the water level of the preheating water tank 300, when the water level reaches the height of the high water level electrode 310, the water inlet solenoid valve 630 is closed to stop adding water into the preheating water tank 300, and when the water level falls to the height of the low water level electrode 320, the water inlet solenoid valve 630 is opened to add water into the preheating water tank 300.

The instant water bladder 400 comprises an instant heating bladder 410 and a boiled water storage bladder 420, wherein the lower end of the instant heating bladder 410 is communicated with the lower end of the preheating water bladder 300, and an instant heating pipe is arranged in the instant heating bladder 410 and penetrates into the instant heating bladder 410 from the lower end of the instant heating bladder 410. When the water in the instant heating bladder 410 is heated and boiled by the instant heating pipe, the volume of the water expands, and the water in the instant heating bladder 410 overflows into the boiled water storage bladder 420. The instant water container 400 is fixedly connected with a steam pipe 430, two ends of the steam pipe 430 are respectively provided with a steam inlet and a steam outlet, the steam inlet is communicated with the upper end of the boiled water storage container 420, the steam pipe 430 penetrates through the preheating water container 300, and the steam outlet is arranged below the preheating water container 300. The boiled water in the hot water bladder 400 can flow out through the steam pipe 430, so as to avoid the over-pressure in the hot water bladder 400.

The first water stop 421 is fixedly connected to the upper portion of the boiled water storage bladder 420, the first water stop 421 is a plate-shaped member, the first water stop 421 is disposed above the instant heating bladder 410, and the first water stop 421 is disposed below the steam inlet. The boiled water storage bladder 420 is communicated with a boiled water outlet nozzle 710.

The boiling water storage tank 420 is provided with a first water level monitoring device, the first water level monitoring device is configured as a float water level switch 422 (in other embodiments, other common water level detection devices, such as a water level electrode, etc., may also be adopted), and a float of the float water level switch 422 is located in the boiling water storage tank 420.

The boiled water storage bladder 420 is provided with a second water blocking member 423, the second water blocking member 423 is a plate-shaped member, and the second water blocking member 423 is disposed on a side of the float water level switch 422 close to the instant heating bladder 410. The second water stop 423 can prevent the boiled water from splashing to the first water level monitoring device, and can avoid the influence of the boiled water on the first water level monitoring device.

The lower end of the boiled water storage bladder 420 is communicated with the hot water inlet end of the heat exchanger 100. The water pump 200 has a water pumping end and a water pumping end, the water pumping end is connected to the hot water outlet end of the heat exchanger 100, and the warm boiled water tank 500 is connected to the water pumping end. In the process of producing warm boiled water, the water pump 200 can pump the boiled water in the boiled water storage tank 420 of the instant water tank 400 to the warm boiled water tank 500, the boiled water passes through the hot water channel of the heat exchanger 100, the heat of the boiled water is transferred to the cold water channel surrounding the hot water channel in the heat exchanger 100, the boiled water is cooled by the heat exchanger 100, the cooled boiled water (i.e. warm boiled water) flows into the warm boiled water tank, and the temperature of the water flowing into the warm boiled water tank 500 is 42-45 ℃. Meanwhile, cold water is introduced into the cold water pipe, heat of the boiled water is transferred to the cold water, and the cold water is heated in the heat exchanger 100 and finally flows into the preheating water tank 300.

The warm boiled water container 500 is internally provided with the LED ultraviolet lamp beads which can sterilize and bacteriostatically the water in the warm boiled water container 500. The warm boiled water container 500 is internally provided with a heating and heat-preserving pipe, and when the temperature reaches a preset range, the heating and heat-preserving pipe can preserve the heat of the water in the warm boiled water container 500, so that the temperature of the warm boiled water is kept at 42-45 ℃. The warm water bladder 500 is connected with a warm water outlet nozzle 720; when the temperature is lower than the preset range, the heating and heat-preserving pipe can heat the water in the warm boiled water liner 500 to ensure that the warm boiled water reaches the preset range.

The warm water container 500, the preheating water container 300, the instant water container 400 and the heat exchanger 100 are wrapped by the heat-preservation wrapping body to reduce the heat loss of the drinking water. The heat-insulating inclusion body can adopt an encapsulated structure or a non-encapsulated structure. The outer peripheral surface of the heat insulation inclusion is covered with a heat insulation layer or a heat insulation shell, so that heat exchange between the water dispenser module and the outside can be further prevented, and energy can be more effectively utilized.

The second embodiment:

referring to fig. 3, in the present embodiment, different from the first embodiment, the water dispenser module of the present embodiment includes a heat insulation enclosure, a heat exchanger 100, a preheating water tank 300, an instant water tank 400, a water pump 200, and a cold water inlet pipeline. The heat-insulating inclusion wraps the heat exchanger 100, the preheating water tank 300 and the instant heating water tank 400 to reduce heat loss of the drinking water. The water outlet end of the water pump 200 of the present embodiment is connected to a warm water nozzle 720.

While the preferred embodiments of the present invention have been described, the present invention is not limited to the above-described embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present invention, and such equivalent modifications or substitutions are to be included within the scope of the present invention defined by the claims.

Claims (10)

1. The water dispenser module is characterized in that: the method comprises the following steps:

the heat exchanger (100) is provided with a cold water channel and a hot water channel, two ends of the cold water channel are respectively a cold water inlet end and a cold water outlet end, two ends of the hot water channel are respectively a hot water inlet end and a hot water outlet end, and the cold water inlet end is communicated with the cold water outlet end;

the water pump (200) is provided with a water pumping end and a water pumping end, and the water pumping end is connected with the hot water outlet end;

the preheating water container (300), the preheating water container (300) is communicated with the cold water outlet end; the instant hot water liner (400), the instant hot water liner (400) is communicated with the preheating water liner (300); the instant heating water container (400) comprises an instant heating container (410) and a boiled water storage container (420), wherein an instant heating pipe is installed in the instant heating container (410), the upper end of the instant heating container (410) extends into the boiled water storage container (420), and the instant heating container (410) is communicated with the boiled water storage container (420).

2. The water dispenser module of claim 1 wherein: the instant heating water container (400) is connected with a steam pipe (430), the steam pipe (430) is communicated with the boiled water storage container (420), two ends of the steam pipe (430) are respectively provided with a steam inlet and a steam outlet, the steam inlet is arranged above the instant heating container (410), and the steam pipe (430) penetrates through the preheating water container (300).

3. The water dispenser module of claim 1 wherein: the boiling water storage container (420) is provided with a first water stop piece (421), and the first water stop piece (421) is arranged above the instant heating container (410).

4. The water dispenser module of claim 1 wherein: the boiled water storage container (420) is provided with a first water level monitoring device.

5. The water dispenser module of claim 4 wherein: the boiled water storage container (420) is provided with a second water stop piece (423), and the second water stop piece (423) is arranged on one side, close to the instant heating container (410), of the first water level monitoring device.

6. The water dispenser module of claim 1 wherein: the heat exchanger is characterized by further comprising a cold water inlet pipeline assembly, wherein the cold water inlet pipeline assembly comprises a water inlet electromagnetic valve (630), a one-way valve (610), a flow stabilizing valve (620) and a cold water inlet pipe body, one end of the cold water inlet pipe body is connected with the cold water inlet end, the water inlet electromagnetic valve (630), the flow stabilizing valve (620) and the one-way valve (610) are sequentially arranged along the extending direction of the cold water inlet pipe body, and the one-way valve (610) is arranged on one side, close to the heat exchanger (100), of the flow stabilizing valve (620).

7. The water dispenser module of claim 1 wherein: the warm boiled water storage assembly comprises a warm boiled water liner (500) and a warm boiled water connecting pipe body, and two ends of the warm boiled water connecting pipe body are connected with the warm boiled water liner (500) and the water outlet end of the pump respectively.

8. The water dispenser module of claim 7 wherein: and a heating and heat-preserving pipe is arranged in the warm boiled water liner (500).

9. The water dispenser module of claim 1 wherein: a high water level detection device and a low water level detection device are arranged in the preheating water container (300), the height of the low water level detection device is lower than that of the high water level detection device, and the height of the high water level detection device is lower than that of the upper end of the instant heating container (410).

10. The water dispenser is characterized in that: comprising a housing and a water dispenser module as claimed in any one of claims 1 to 9 mounted within the housing, the water dispenser module being relatively fixed to the housing.

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