CN220417653U - Energy-saving warm water boiling equipment - Google Patents

Abstract

The utility model provides energy-saving warm water equipment. An energy-saving warm water apparatus comprising: the shell is provided with a shell inner cavity for accommodating each component, a first partition plate and a second partition plate, wherein the first partition plate and the second partition plate divide the shell inner cavity into a first cavity, a second cavity and a third cavity, the first cavity is communicated with the second cavity, and the second cavity is connected with the third cavity; a coil coiled in the second chamber; the heating chamber is arranged on the second partition board and penetrates through the first partition board, and at least one part of the heating chamber is positioned in the first chamber; the bottom of the liquid level control chamber is communicated with the bottom of the heating chamber in the second chamber and penetrates through the first partition plate, and at least one part of the liquid level control chamber is positioned in the first chamber; wherein, first baffle installs in the casing inner chamber with detachable mode, and the opening height of liquid level control room is at least with the opening height parallel and level of heating chamber. The utility model can realize the stable supply of boiled water and warm water, and has high energy utilization rate.

Description

Energy-saving warm water boiling equipment

Technical Field

The utility model relates to the field of heating of tap water or treated tap water, in particular to energy-saving warm water boiling equipment.

Background

For people, water is an important substance next to oxygen, water is not only a main component of a body, but also has a plurality of physiological functions, wherein boiled water is particularly important, and the boiled water is a neutral substance, so that yin, cold, dampness and toxin in the body can be taken away, sundries in the body can be taken out of the body in a metabolic mode, people who are used to drinking boiled water have high in vivo deoxidizing enzyme activity, little accumulation of lactic acid in muscles and are not easy to generate fatigue.

In the prior art, when the drinking water supply device supplies boiled water at 100 ℃, low-temperature tap water is required to be heated, and the heated boiled water is converted into warm water through natural heat dissipation, so that a large amount of energy is wasted.

Disclosure of Invention

The utility model solves the problems of improving the quality of water, using healthy water, reducing water using equipment, saving energy sources, and being more convenient and comfortable to use.

In order to solve the problems, the utility model provides energy-saving warm water equipment.

To achieve the object of the present utility model, an embodiment of the present utility model provides an energy-saving warm water apparatus comprising: the shell is provided with a shell inner cavity for accommodating each component, a first partition plate and a second partition plate, wherein the first partition plate and the second partition plate divide the shell inner cavity into a first cavity, a second cavity and a third cavity, the first cavity is communicated with the second cavity, and the second cavity is connected with the third cavity; a coil coiled in the second chamber; the heating chamber is arranged on the second partition board and penetrates through the first partition board, and at least one part of the heating chamber is positioned in the first chamber; the liquid level control chamber is communicated with the bottom of the heating chamber at the second chamber, penetrates through the first partition plate and at least one part of the liquid level control chamber is positioned in the first chamber; wherein, first baffle installs in the casing inner chamber with detachable mode, and the opening height of liquid level control room is at least with the opening height parallel and level of heating chamber.

The utility model solves the problems of improving the quality of water, using healthy water, reducing water using equipment, saving energy sources, and being more convenient and comfortable to use.

The embodiment of the utility model provides a shell and a cover body with a shell inner cavity, which are used for accommodating various components, wherein the shell inner cavity is divided into a first cavity, a second cavity and a third cavity by arranging a detachable first partition board and a fixed closed second partition board in the shell inner cavity, the first cavity, the second cavity and the third cavity are respectively used for accommodating boiled water, boiled water and normal-temperature water exchange areas and warm boiled water, the coil pipe is arranged in the second cavity, heat exchange between tap water in the coil pipe and the hot water in the second cavity is realized, the waste of energy is reduced, the energy utilization rate is improved, the heating chamber and the liquid level control chamber are arranged on the second partition board in a detachable mode, the heating chamber and the liquid level control chamber are arranged in the second cavity, the heating chamber and the liquid level control chamber penetrate through the first partition board, the openings of the heating chamber and the liquid level control chamber are positioned at the same height in the first cavity, and the bottoms of the heating chamber and the liquid level control chamber are communicated, so that the communicating vessel is realized.

In summary, the implementation of the utility model provides three chambers for accommodating boiled water, a boiled water and normal-temperature water energy exchange area and warm boiled water by arranging the detachable first partition board and the fixed closed second partition board in the inner cavity of the shell, and the detachable arrangement of the first partition board, the heating chamber, the liquid level control chamber, the heat exchange coil pipe and other parts is convenient for cleaning, maintenance, repair and replacement. The coil is arranged in the second chamber, so that a place for heat exchange between normal-temperature tap water and high-temperature water is provided, heat released when boiled water is converted into the high-temperature water is effectively utilized, energy waste is reduced, energy utilization rate is improved, the place for heating tap water is provided by arranging the heating chamber communicated with the liquid level control chamber, and due to the same arrangement of the opening heights of the heating chamber and the liquid level control chamber, the consistency of water levels in the heating chamber and the liquid level control chamber is ensured by virtue of a communicating vessel principle, and stable supply of boiled water after boiling is realized.

In addition, the technical scheme provided by the embodiment of the utility model can also have the following additional technical characteristics: the flow guide pipe is arranged on the first partition board and penetrates through the first partition board, the majority of the flow guide pipe is positioned in the second cavity, the minority of the flow guide pipe is positioned in the first cavity, and a certain gap exists between the lower end of the flow guide pipe and the second partition board; the warm water pipe is arranged on the second partition plate, penetrates through the second partition plate and is positioned in the honeycomb duct in the second cavity; the height of the warm water pipe is the same as that of the coil pipe, and the opening height of the warm water pipe is lower than that of the guide pipe in the first cavity.

Through the setting of honeycomb duct and warm water pipe, the water of different temperatures in the second cavity, the water of temperature minimum flows into the honeycomb duct from the honeycomb duct lower part, passes over the warm water pipe, flows into the warm water pipe from warm water pipe top, flows into the third cavity, ensures that the water in every three cavities is low-temperature boiled water.

In any of the above technical solutions, the energy-saving warm water apparatus further includes: the coil pipe winds the heating chamber and the liquid level control chamber from bottom to top in the second chamber, and the top end of the coil pipe is communicated with the part of the liquid level control chamber located in the second chamber.

Through setting up the coil pipe in the second cavity, the coil pipe coils from bottom to top, after the heating chamber heats, flow into the immersion coil pipe in the second cavity, the high temperature water that the heating chamber flows out and the low temperature water in the coil pipe exchange energy through the coil pipe wall, the water temperature in the coil pipe is risen by low, the water in the second cavity outside the coil pipe, the upper strata to the lower floor of water level, the temperature is from high to low, the temperature of the uppermost water is the highest, the temperature of the water of the lowermost layer is the lowest, the water in the coil pipe, the water temperature of minimum water inlet department is the lowest, the temperature of the highest end department of coil pipe is the highest, the end department of coil pipe communicates with liquid level control chamber, the high temperature running water after the temperature risen after absorbing heat in the coil pipe inputs liquid level control chamber.

In any of the above technical solutions, the energy-saving warm water apparatus further includes: the water inlet pipe is connected with the inlet end of the lower end of the coil pipe and penetrates through the third chamber, and at least one part of the water inlet pipe is positioned outside the shell.

Through the arrangement of the water inlet pipe, a channel for inputting low-temperature tap water is provided.

In any of the above technical solutions, the energy-saving warm water apparatus further includes: and the electromagnetic control valve is connected with the part of the water inlet pipe, which is positioned outside the shell.

By setting the electromagnetic control valve, the control of low-temperature tap water input is realized, and stable tap water input is provided.

In any of the above technical solutions, the energy-saving warm water apparatus further includes: the float switch penetrates through the cover body and is positioned in the liquid level control chamber, the float can move up and down in the liquid level control chamber, and the float switch is in communication connection with the electromagnetic control valve.

The float switch penetrates through the cover body and is positioned in the liquid level control chamber, can move up and down in the liquid level control chamber, and is in communication connection with the electromagnetic control valve.

In any of the above technical solutions, the energy-saving warm water apparatus further includes: the liquid level sensor is arranged on the cover body and is positioned in the liquid level control chamber.

Through setting up the liquid level inductor for equipment can be according to the opening function of liquid level control heating pipe in the liquid level control room, has realized the stable heating of equipment to the water of heating chamber, produces the boiled water.

In any of the above technical solutions, the energy-saving warm water apparatus further includes: the heating pipe penetrates through the shell, is positioned in the heating chamber and is in communication connection with the liquid level sensor.

Through the arrangement of the heating pipe, the liquid is heated, and the stable supply of the boiled water is realized.

In any of the above technical solutions, the energy-saving warm water apparatus further includes: and the thermostatic tube penetrates through the shell and is positioned in the third chamber.

Through the setting of thermostatic tube, carry out constant temperature heating to the liquid in the third cavity, realized the equipment and to the stable control of warm water.

In any of the above technical solutions, the energy-saving warm water apparatus further includes: the first water outlet is arranged outside the shell and is communicated with the bottom of the first cavity; the second water outlet is arranged outside the shell and is communicated with the bottom of the second cavity; the third water outlet is arranged outside the shell and is communicated with the bottom of the third cavity; the breather valve is arranged outside the cover body and is communicated with the inner cavity of the cover body.

By arranging the first water outlet, the second water outlet and the third water outlet, the boiled water and the warm boiled water can be stably output.

Drawings

Fig. 1 is a schematic structural view of an energy-saving warm water boiling device provided by the utility model.

Reference numerals illustrate:

100: energy-saving warm water equipment; 101: a first separator; 102: a second separator; 110: a housing; 111: a housing interior; 112: a first chamber; 113: a second chamber; 114: a third chamber; 120: a coiled pipe; 130: a warm water pipe; 140: a flow guiding pipe; 150: a heating chamber; 160: a liquid level control chamber; 161: a liquid level sensor; 162: a float switch; 163: a full water inductive switch; 170: a water inlet pipe; 180: an electromagnetic control valve; 201: heating pipes; 202: a thermostatic tube; 301: a first water outlet; 302: a second water outlet; 303: a third water outlet; 304: a respiratory valve; 401: and a cover body.

Detailed Description

In order that the above-recited objects, features and advantages of the present utility model will be more clearly understood, a more particular description of the utility model will be rendered by reference to the appended drawings and appended detailed description. It should be noted that, in the case of no conflict, the embodiments of the present application and the features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model, however, the present utility model may be practiced in other ways than those described herein, and therefore the scope of the present utility model is not limited to the specific embodiments disclosed below.

The following describes some embodiments of the present utility model with reference to fig. 1.

As shown in fig. 1, the present utility model provides an energy-saving warm water apparatus comprising: a housing 110, a cover 401; the housing 110 is provided with a housing inner cavity 111 for accommodating each component, a first partition board 101 and a second partition board 102, wherein the first partition board 101 and the second partition board 102 divide the housing inner cavity 111 into a first chamber 112, a second chamber 113 and a third chamber 114, the first chamber 112 and the second chamber 113 are in non-closed and isolated communication, and the second chamber 113 and the third chamber 114 are in closed and isolated communication; a coil 120, the coil 120 being coiled in the second chamber 113; a heating chamber 150, the heating chamber 150 being provided on the second partition 102 and penetrating the first partition 101, at least a portion of the heating chamber 150 being located in the first chamber 112; the bottom of the liquid level control chamber 160 is communicated with the bottom of the heating chamber 150 in the second chamber 113, the liquid level control chamber 160 penetrates through the first partition 101, and at least one part of the liquid level control chamber 160 is positioned in the first chamber 112; wherein, the first baffle plate 101 is detachably installed in the inner cavity 111 of the shell, the first baffle plate is a non-sealing baffle plate and is provided with a plurality of small water permeable holes, so that the water in the first chamber can freely flow into the second chamber; the second partition board is a closed partition board for preventing water in the second chamber from flowing to the third chamber; the opening height of the liquid level control chamber is at least flush with the opening height of the heating chamber. The liquid level control chamber 160, the heating chamber 150, the coil 120, and the first partition 101 are all detachable.

The utility model solves the problems of improving the quality of water, using healthy water, reducing water using equipment, saving energy sources, and being more convenient and comfortable to use.

In order to stably provide boiled water and warm water after boiling and improve the energy utilization rate, the embodiment of the utility model provides a shell 110 with a shell inner cavity 111, a cover 401 for accommodating various components, the shell inner cavity 111 is divided into a first cavity 112, a second cavity 113 and a third cavity 114 by arranging a detachable first partition board 101, a fixed closed partition board and a second partition board 102 in the shell inner cavity 111, the shell inner cavity 111 is respectively used for accommodating boiled water, the boiled water and warm water heat exchange areas, warm boiled water, and the like, by arranging a coil 120 in the second cavity 113, the heat exchange between tap water in the coil and the warm water in the second cavity 113 is realized, the waste of energy is reduced, the energy utilization rate is improved, a heating chamber 150 is detachably arranged on the second partition board 102, a liquid level control chamber 160 is arranged in the second cavity 113, the bottom of the liquid level control chamber is communicated with the bottom of the heating chamber 150, the heating chamber 150 and the liquid level control chamber 160 penetrate through the first partition board, and the openings of the heating chamber 150 and the liquid level control chamber 160 are positioned at the same height in the first cavity 112, and the arrangement principle of a communicating vessel is realized. The liquid level control chamber 160, the heating chamber 150, the coil 120, and the first partition 101 are all detachable.

In summary, the embodiment of the utility model provides three chambers for containing boiled water, boiled water and normal temperature water heat exchange area, warm boiled water through arranging the detachable first partition board 101 and the fixed closed second partition board 102 in the inner cavity 111 of the shell, and the liquid level control chamber 160, the heating chamber 150, the coil 120 and the first partition board 101 are convenient to clean, maintain and repair and replace, by arranging the coil 120 in the second chamber 112, the place for exchanging heat between tap water and warm water is provided, the heat released when the boiled water is converted into warm water is effectively utilized, the waste of energy is reduced, the utilization rate of energy is improved, the place for heating tap water is provided by arranging the communicated heating chamber 150 and the liquid level control chamber 160, and due to the same arrangement of the opening heights of the heating chamber 150 and the liquid level control chamber 160, the consistency of water levels in the heating chamber 150 and the liquid level control chamber 160 is ensured by virtue of a communicating vessel principle, and the stable supply of boiled water after boiling is realized.

As shown in fig. 1, an embodiment of the present utility model provides an energy-saving warm water apparatus, which further includes the following technical features in addition to the technical features of the above embodiment.

The energy-saving warm water apparatus of the embodiment includes: the flow guide pipe 140 is arranged on the first partition board 101 and penetrates through the first partition board 101, a large part of the flow guide pipe 140 is positioned in the second chamber 113, a small part of the flow guide pipe 140 is positioned in the first chamber 112, and a certain gap exists between the lower end of the flow guide pipe 140 and the second partition board 102; a warm water pipe 130, wherein the warm water pipe 130 is arranged on the second partition plate 102, penetrates through the second partition plate, and is positioned inside the guide pipe 140 in the second chamber 113; wherein the warm water pipe 130 has the same height as the coil 120, and the opening height of the warm water pipe 130 is lower than the opening height of the guide pipe 140 in the first chamber 112.

For example, in the embodiment provided by the utility model, by arranging the flow guide pipe 140 on the first partition board 112, a certain gap exists between the lower end of the flow guide pipe 140 and the second partition board 102, and the water in the second chamber 113 flows into the flow guide pipe 140 from the bottom of the flow guide pipe 140, and according to the density principle of the water, the higher the temperature of the water is, the lower layer is the low-density high-temperature water, the upper layer is the low-density high-temperature water, and the bottom is the high-density low-temperature water, so that the water flowing into the flow guide pipe 140 from the bottom is the low-density water in the second chamber. The water in the second chamber 113 flows into the flow guide pipe 140 from the bottom of the flow guide pipe 140, and the warm water pipe 130 is arranged on the second partition board 102, and the warm water pipe 130 is positioned inside the flow guide pipe 140 in the second chamber 113 and penetrates through the second partition board 102 to communicate the second chamber 113 and the third chamber 114; so that warm boiled water having completed heat exchange in the second chamber 113 enters from the lower end of the draft tube 140, passes over the warm water tube 130, enters the warm water tube 130 from the top of the warm water tube 130, and enters the third chamber.

In this embodiment, through the arrangement of the guide pipe and the warm water pipe, the water with different temperatures in the second chamber flows into the guide pipe from the lower part of the guide pipe, passes over the warm water pipe, flows into the warm water pipe from the top of the warm water pipe, flows into the third chamber, and ensures that the water in each three chambers is low-temperature boiled water.

As shown in fig. 1, an embodiment of the present utility model provides an energy-saving warm water apparatus, which further includes the following technical features in addition to the technical features of the above embodiment.

The energy-saving warm water equipment of the embodiment is characterized in that: the coil 120 is coiled in the second chamber 113 from bottom to top, the heating chamber 150 and the liquid level control chamber 160 are located in the second chamber 113, and the upper end of the coil is connected to the portion of the liquid level control chamber 160 located in the second chamber 113.

Preferably, by arranging the coil 120 in the second chamber, the coil 120 is coiled from bottom to top, water in the heating chamber 150 flows into the second chamber 113 after being heated and boiled by the heating pipe 201, the boiled water flowing out of the heating chamber submerges the coil 120 in the second chamber 113, the boiled water flowing out of the heating chamber and normal-temperature tap water in the coil exchange energy through the coil wall, the temperature of normal-temperature water in the coil is increased from low, the temperature of the boiled water in the second chamber outside the coil is increased from high to low according to the distribution from the upper layer to the lower layer of the water level, the temperature of the uppermost layer is the highest, the temperature of the water in the lowermost layer is the lowest, the temperature of the water in the coil is the lowest water inlet, and the water temperature at the highest end of the coil is the highest.

In this embodiment, by arranging the coil 120 in the second chamber 113 to coil the heating chamber 150 and the liquid level control chamber 160 from bottom to top, the upper end of the coil is communicated with the liquid level control chamber 160, which provides a place where normal-temperature tap water exchanges heat with high-temperature boiled water, and the original normal-temperature tap water absorbs heat to raise its temperature and then is input into the liquid level control chamber 160.

As shown in fig. 1, an embodiment of the present utility model provides an energy-saving warm water apparatus, which further includes the following technical features in addition to the technical features of the above embodiment.

The energy-saving warm water apparatus of the embodiment includes: a water inlet pipe 170, the water inlet pipe 170 being connected to the lower end of the coil 120 and extending through the third chamber 114, at least a portion of the water inlet pipe 170 being located outside the housing 110.

For example, in the embodiment provided by the present utility model, the water inlet pipe 170 penetrates the third chamber 114, is connected to the lower end of the coil 120 in the second chamber 113, and is connected to the solenoid control valve 180 outside the housing 110.

In this embodiment, a passage for the input of tap water at a low temperature is provided by the provision of the water inlet pipe 170.

As shown in fig. 1, an embodiment of the present utility model provides an energy-saving warm water apparatus, which further includes the following technical features in addition to the technical features of the above embodiment.

The energy-saving warm water apparatus of the embodiment includes: and an electromagnetic control valve 180, wherein the electromagnetic control valve 180 is connected with a portion of the water inlet pipe 170 located outside the housing 110.

For example, in the embodiment provided by the present utility model, the solenoid control valve 180 is located outside the housing 110 and is connected to the water inlet pipe 170 for controlling the input of tap water at normal temperature.

In this embodiment, control of normal-temperature tap water input is achieved by setting the electromagnetic control valve 180, and stable tap water input is provided.

As shown in fig. 1, an embodiment of the present utility model provides an energy-saving warm water apparatus, which further includes the following technical features in addition to the technical features of the above embodiment.

The energy-saving warm water apparatus of the embodiment includes: the float switch 162 is located in the liquid level control chamber 160 through the cover 401, and can move up and down in the liquid level control chamber 160, and the float switch 162 is in communication connection with the electromagnetic control valve 180.

For example, in the embodiment provided by the utility model, the float switch 162 is located in the liquid level control chamber 160 and can move up and down in the liquid level control chamber 160, meanwhile, the float switch 162 is in communication connection with the electromagnetic control valve 180, before the water level reaches the designated position, the float switch 162 sends a signal to open the electromagnetic control valve 180 to input tap water, when the water level reaches a distance from the top opening of the liquid level control chamber 160, about 10MM, the float switch 162 sends a signal to close the electromagnetic control valve 180 to stop the input of tap water.

In this embodiment, through the arrangement of the float switch 162, the device can control the opening or closing of the electromagnetic control valve according to the change of the liquid level in the liquid level control chamber 160, so as to realize the stable supply of normal-temperature tap water by the device.

As shown in fig. 1, an embodiment of the present utility model provides an energy-saving warm water apparatus, which further includes the following technical features in addition to the technical features of the above embodiment.

The energy-saving warm water apparatus of the embodiment includes: the liquid level sensor 161, the liquid level sensor 161 is disposed on the cover 401 and is located in the liquid level control chamber 160.

For example, in the embodiment provided by the utility model, the liquid level sensor 161 is disposed in the liquid level control chamber 160 and adjacent to the float switch 162, wherein the liquid level sensor 161 penetrates into the opening of the liquid level control chamber 160 by at least 20MM, when the liquid level in the liquid level control chamber 160 reaches the position 20MM away from the opening, the liquid level sensor 161 contacts the liquid to send a signal to control the heating tube 201 to start heating, and when the liquid in the heating chamber 150 reaches the designated temperature to overflow, the liquid level sensor 161 is separated from the liquid to send a signal to control the heating tube 201 to stop heating.

In the present embodiment, by providing the liquid level sensor 161 so that the apparatus can control the function of the heating pipe 201 according to the liquid level in the liquid level control chamber 160, stable supply of boiled water by the apparatus is achieved.

In another embodiment of the present utility model, a full water sensing switch 163 is disposed at the top of the first chamber 112, when the full water sensing switch 163 contacts with water, the water storage amount in the apparatus reaches the maximum value, and at this time, the water inlet switch 180 is turned off to stop water supply to the interior of the apparatus, and the heating pipe 201 stops working.

As shown in fig. 1, an embodiment of the present utility model provides an energy-saving warm water apparatus, which further includes the following technical features in addition to the technical features of the above embodiment.

The energy-saving warm water apparatus of the embodiment includes: the heating pipe 201, the heating pipe 201 penetrates through the cover 401 to be located in the heating chamber 150, and is in communication connection with the liquid level sensor 161.

For example, in the embodiment provided by the present utility model, the heating tube 201 is disposed in the heating chamber 150 through the cover 401 and is close to the bottom of the heating chamber 150, and the heating tube 201 starts or stops heating the liquid after receiving the signal of the liquid level sensor 161.

In the present embodiment, by the provision of the heating pipe 201, heating of the liquid is achieved, and stable supply of the boiled water is achieved.

As shown in fig. 1, an embodiment of the present utility model provides an energy-saving warm water apparatus, which further includes the following technical features in addition to the technical features of the above embodiment.

The energy-saving warm water apparatus of the embodiment includes: a thermostatic tube 202, the thermostatic tube 202 being located in the third chamber 114 through the housing 110.

For example, in the embodiment provided by the present utility model, the thermostat 202 is disposed on the housing 110 and located at the bottom of the third chamber 114, and when the third chamber 114 starts to store warm water, the thermostat 202 starts to operate to maintain the temperature of the warm water in the third chamber 114.

In the present embodiment, by providing the thermostatic tube 202, the liquid in the third chamber 114 is heated at a constant temperature, and stable supply of warm water by the apparatus is realized.

As shown in fig. 1, an embodiment of the present utility model provides an energy-saving warm water apparatus, which further includes the following technical features in addition to the technical features of the above embodiment.

The energy-saving warm water apparatus of the embodiment includes: the first water outlet 301, the first water outlet 301 is arranged outside the shell 110 and is communicated with the lower end part of the first chamber 112; the second water outlet 302, the second water outlet 302 is arranged outside the shell 110 and is communicated with the lower end part of the second chamber 113; the third water outlet 303, the third water outlet 303 is arranged outside the shell 110 and is communicated with the lower end part of the third chamber 114; the breather valve 304, the breather valve 304 is provided outside the cover 401, and communicates with the housing cavity 111.

For example, in the embodiment provided by the utility model, the first water outlet 301 is located outside the housing 110 and is in communication with a portion of the first chamber 112 adjacent to the first partition 101, the second water outlet 302 is located outside the housing 110 and is in communication with a portion of the second chamber 113 adjacent to the second partition 102, the third water outlet 303 is located outside the housing 110 and is in communication with a lower end portion of the third chamber 114, and the breather valve 304 is located at the top of the cover 401 and is in communication with the housing cavity 111.

In this embodiment, the air pressure inside and outside the device is balanced by setting the breather valve 304, and the boiled water and the warm water are stably output by setting the first water outlet 301, the second water outlet 302 and the third water outlet 303.

Although the present utility model is disclosed above, the present utility model is not limited thereto. Various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the utility model, and the scope of the utility model should be assessed accordingly to that of the appended claims.

Claims (10)

1. An energy-saving warm water apparatus (100), characterized by comprising:

the device comprises a shell (110) and a cover body (401), wherein the shell (110) and the cover body (401) form a shell inner cavity (111) for accommodating various components, a first partition plate (101) and a second partition plate (102), the first partition plate (101) and the second partition plate (102) divide the shell inner cavity (111) into a first cavity (112), a second cavity (113) and a third cavity (114), the first cavity (112) and the second cavity (113) are in non-closed separation connection, and the second cavity (113) and the third cavity (114) are in closed connection;

-a coil (120), the coil (120) being coiled in the second chamber (113);

a heating chamber (150), wherein the heating chamber (150) is arranged on the second partition board (102) and penetrates through the first partition board (101), and at least one part of the heating chamber (150) is positioned in the first chamber (112);

a liquid level control chamber (160), wherein the liquid level control chamber (160) is communicated with the heating chamber (150) in the second chamber (113), the liquid level control chamber (160) penetrates through the first partition board (101), and at least one part of the liquid level control chamber (160) is positioned in the first chamber (112);

wherein, first baffle (101) is installed in the casing inner chamber (111) with detachable mode, the opening height of liquid level control room (160) is at least with the opening height parallel and level of heating chamber (150).

2. The energy-saving warm water apparatus as claimed in claim 1, comprising:

the flow guide pipe (140) is arranged on the first partition board (101) and penetrates through the first partition board (101), a large part of the flow guide pipe (140) is positioned in the second chamber (113), a small part of the flow guide pipe is positioned in the first chamber (112), and a certain gap exists between the lower end of the flow guide pipe (140) and the second partition board (102);

a warm water pipe (130), wherein the warm water pipe (130) is arranged on the second partition board (102) and penetrates through the second partition board, and is positioned inside the guide pipe (140) in the second chamber (113);

the warm water pipe (130) and the coil pipe (120) are the same in height, and the opening height of the warm water pipe (130) is lower than that of the guide pipe (140).

3. Energy saving warm water apparatus according to claim 1, characterized in that the coil (120) is coiled from bottom to top with the heating chamber (150) and the liquid level control chamber (160) in the second chamber (113), the top end of the coil being in communication with the portion of the liquid level control chamber (160) in the second chamber (113).

4. The energy-saving warm water apparatus as claimed in claim 1, comprising:

and the water inlet pipe (170) is connected with one end of the lower water inlet of the coil pipe (120) and penetrates through the third chamber (114), and at least one part of the water inlet pipe (170) is positioned outside the shell (110).

5. The energy saving warm water apparatus of claim 4, comprising:

and an electromagnetic control valve (180), wherein the electromagnetic control valve (180) is communicated with the part of the water inlet pipe (170) positioned outside the shell (110).

6. The energy saving warm water apparatus of claim 5, comprising:

the float switch (162) penetrates through the cover body (401) and is located in the liquid level control chamber (160) and can move up and down in the liquid level control chamber (160), and the float switch (162) is in communication connection with the electromagnetic control valve (180).

7. The energy-saving warm water apparatus as claimed in claim 2, comprising:

and the liquid level sensor (161) is arranged on the cover body (401) and is positioned in the liquid level control chamber (160).

8. The energy saving warm water apparatus of claim 7, comprising:

a heating pipe (201), wherein the heating pipe (201) penetrates through the cover body (401) and is positioned in the heating chamber (150) and is in communication connection with the liquid level sensor (161);

-a thermostatic tube (202), said thermostatic tube (202) being located in said third chamber (114) through said housing (110).

9. The energy-saving warm water apparatus as claimed in claim 1, comprising:

and the breather valve (304) is arranged outside the cover body (401) and is communicated with the inner cavity (111) of the shell.

10. The energy-saving warm water apparatus as claimed in claim 1, comprising:

a first water outlet (301), wherein the first water outlet (301) is arranged outside the shell (110) and is communicated with the lower end part of the first chamber (112);

the second water outlet (302) is arranged outside the shell (110) and is communicated with the lower end part of the second chamber (113);

a third water outlet (303), wherein the third water outlet (303) is arranged outside the shell (110) and is communicated with the lower end part of the third chamber (114);

and the breather valve (304) is arranged outside the cover body (401) and is communicated with the inner cavity (111) of the shell.