CN213075402U - Energy-saving drinking equipment - Google Patents

Abstract

The utility model discloses an energy-saving drinking water device, which comprises a machine body, a water inlet mechanism, a first water outlet component, a second water outlet component, a heat exchange mechanism and a heating mechanism; the heat exchange mechanism comprises a first spiral pipe and a second spiral pipe, the second spiral pipe is sleeved in the first spiral pipe, the output end of the water inlet mechanism is connected with the input end pipeline of the heating mechanism through the first spiral pipe, one output end of the heating mechanism is connected with the first water outlet assembly, and the other output end of the heating mechanism is connected with the second water outlet assembly through the second spiral pipe. The equipment can ensure that a user can drink warm boiled water, reduce the time required by boiling of a water body, recycle heat energy and achieve the aim of saving energy; moreover, the equipment is also provided with a high-temperature antivirus function, controls the waterway channel through the electromagnetic valve, and performs high-temperature antivirus on the water outlet waterway and the water liner of the equipment, thereby ensuring the drinking health of a user.

Description

Energy-saving drinking equipment

Technical Field

The utility model relates to a drinking water equipment technical field, in particular to energy-conserving drinking water equipment.

Background

An energy-saving warm boiled water drinking machine, also called a water boiler, is designed and developed for meeting the requirement of more people for drinking boiled water, and is drinking water equipment which is used for producing boiled water by converting electric energy or other fuels into heat energy through combustion. The boiler can be divided into an electric heating boiler and a steam boiler according to a heating source, wherein the electric heating boiler is divided according to different heating principles: the traditional energy-saving warm boiled water drinking machine, the boiling energy-saving warm boiled water drinking machine, the stepping energy-saving warm boiled water drinking machine, the instant energy-saving warm boiled water drinking machine and the electromagnetic energy-saving warm boiled water drinking machine. The energy-saving warm boiled water drinking machine is divided into the following parts according to the working form: a water storage type energy-saving warm boiled water dispenser and an instant heating type energy-saving warm boiled water dispenser; the steam boiler is divided into an intermittent steam boiler and a continuous steam boiler. The electric energy-saving warm boiled water drinking machine is generally simpler and easier to use than a steam water boiler, is cheap and good, and has small volume, so most of the electric energy-saving warm boiled water drinking machines appear in the market are the shadows of the electric energy-saving warm boiled water drinking machines.

When the energy-saving warm boiled water drinking machine in the related technology discharges water, the water is heated by the heater and then directly flows out, the water temperature is too high, the temperature reduction time of the boiled water is too long, and the boiled water is not suitable for direct drinking; when water enters, cold water directly enters the water storage tank, more heat energy needs to be consumed for heating, and the energy consumption is high.

SUMMERY OF THE UTILITY MODEL

According to one aspect of the utility model, an energy-saving drinking water device is provided, which comprises a machine body, a water inlet mechanism, a first water outlet assembly, a second water outlet assembly, a heat exchange mechanism and a heating mechanism, wherein the water inlet mechanism, the heating mechanism, the heat exchange mechanism, the first water outlet assembly and the second water outlet assembly are all arranged on the machine body; the heat exchange mechanism comprises a first spiral pipe and a second spiral pipe, the second spiral pipe is sleeved in the first spiral pipe, the output end of the water inlet mechanism is connected with the input end pipeline of the heating mechanism through the first spiral pipe, one output end of the heating mechanism is connected with the first water outlet assembly, and the other output end of the heating mechanism is connected with the second water outlet assembly through the second spiral pipe.

The utility model provides a drinking water equipment that can be energy-conserving. In the working process of the utility model, cold water enters from the water inlet mechanism, the cold water enters the heating mechanism through the first spiral pipe to be heated, and the boiling water heated in the heating mechanism can be directly output from the first water outlet assembly for a user to drink; the boiling water after being heated in the heating mechanism can also enter the second spiral pipe for cooling, the boiling water exchanges heat with the cold water in the first spiral pipe in the second spiral pipe, the boiling water in the second spiral pipe can be cooled into a warm water body, and the warm water body is output from the second water outlet assembly for a user to drink; the heat exchange process in the heat exchange mechanism can also enable the cold water in the first spiral pipe to be heated to form warm water, and the warm water enters the heating mechanism to be heated, so that the heating time of the boiling of the water body can be shortened. Through above structure, on the one hand can let the user can drink warm boiled water, on the other hand reduces the required time of boiling of water, can reach the purpose of energy saving to heat recovery.

In some embodiments, the energy-saving drinking water equipment further comprises a first electromagnetic valve, a second electromagnetic valve and a water inlet pipe, wherein the output end of the water inlet mechanism is connected with the input end pipeline of the heating mechanism through the water inlet pipe; the water inlet mechanism is connected with an input end pipeline of the first spiral pipe by shunting through the water inlet pipe, and an output end of the first spiral pipe converges into the water inlet pipe to be connected with a heating mechanism pipeline; first solenoid valve is located on the inlet tube and is located the reposition of redundant personnel section of inlet tube and converge between the section, and the second solenoid valve is located on the reposition of redundant personnel pipeline between water inlet mechanism, the first spiral pipe.

Therefore, the drinking water equipment also has a high-temperature disinfection function. When a waterway of the drinking water equipment needs to be disinfected, the first electromagnetic valve, the first water outlet assembly and the second water outlet assembly are opened, and the second electromagnetic valve is closed; the water body is directly led into the heating mechanism for heating through the water inlet mechanism, one part of the heated boiling water directly flows out from the first water outlet assembly, and the other part of the heated boiling water enters the second spiral pipe and flows out from the second water outlet assembly; thereby leading the heating mechanism and the two water outlet channels to be disinfected by boiled water at the high temperature of 100 ℃.

In some embodiments, the heating mechanism comprises a water bladder, a heating tube, a safety valve, a pressure release valve, and a water level sensor, wherein the heating tube is arranged in the water bladder, the safety valve is arranged at the input end of the water bladder, the water level sensor is arranged in the water bladder and is in signal connection with the safety valve, and the pressure release valve is arranged at the upper end of the water bladder.

Therefore, in the heating mechanism, the water body is heated in the water container, and the water container is provided with the water level sensor for identifying the maximum water level and the pressure release valve for preventing the air pressure from being too high, so that the heating mechanism has high safety.

In some embodiments, the heating mechanism further includes a safety temperature controller, a first temperature sensor, and a second temperature sensor, the safety temperature controller, the first temperature sensor, and the second temperature sensor are all disposed in the water tank, and the first temperature sensor and the second temperature sensor are distributed up and down.

Therefore, in order to further improve the safety performance of the heating mechanism, the heating mechanism is also provided with a safety type temperature controller, a first temperature sensor and a second temperature sensor which are used for detecting the temperature in the water container and preventing the temperature in the water container from being overhigh.

In some embodiments, the first water outlet assembly includes a third solenoid valve, a first water outlet button, and a first water outlet, the first water outlet is connected to the output end of the heating mechanism via a pipeline, the third solenoid valve is disposed on the pipeline between the first water outlet and the heating mechanism, and the first water outlet button is in signal connection with the third solenoid valve.

Therefore, in the first water outlet assembly, the third electromagnetic valve can be opened through the first water outlet key, and the water body flows out from the first water outlet.

In some embodiments, the second water outlet assembly includes a fourth solenoid valve, a second water outlet button and a second water outlet, the second water outlet pipeline is connected to the output end pipeline of the second spiral pipe, the plurality of fourth solenoid valves are disposed on the pipeline between the second water outlet and the second spiral pipe, and the second water outlet button is in signal connection with the fourth solenoid valves.

Therefore, in the second water outlet assembly, the fourth electromagnetic valve can be opened through the second water outlet key, and the water body flows out from the second water outlet.

In some embodiments, the water inlet mechanism comprises a water inlet and a filter, and the water inlet is connected with the filter pipeline.

Therefore, the equipment is also provided with the filter, and the water body is heated by the filter before entering the heating mechanism, so that the generation of scale can be prevented.

In some embodiments, the energy-saving drinking water device further comprises a temperature regulating valve, the temperature regulating valve is arranged on the machine body, the heating mechanism is connected with an input end pipeline of the second spiral pipe through the temperature regulating valve, and the second spiral pipe is connected with the second water outlet assembly pipeline through the temperature regulating valve.

From this, the thermo valve is the liquid way piece, can realize the pipe connection in water route through this night way piece.

In some embodiments, the energy-saving drinking water device further comprises an electrical assembly and a control device, wherein the electrical assembly is electrically connected with the control device, and the electrical assembly is electrically connected with the water inlet mechanism, the first water outlet assembly, the second water outlet assembly, the heat exchange mechanism, the heating mechanism, the first electromagnetic valve and the second electromagnetic valve.

Thus, the electrical components and control devices are the electrical control systems of the apparatus.

In some embodiments, the energy-saving drinking water device further comprises a water tank and a water discharge pipe, the water tank is arranged on the machine body and located below the first water outlet assembly and the second water outlet assembly, and the water discharge pipe is arranged on the machine body and communicated with the lower end of the water tank.

Thus, the water tank is configured to receive the overflowing waste water and discharge the waste water to the outside of the machine body through the drain pipe.

The utility model has the advantages that: through the cold and heat exchange of the heat exchange mechanism, on one hand, a user can drink warm boiled water, on the other hand, the time required by boiling of a water body is reduced, heat energy can be recycled, and the purpose of saving energy is achieved; moreover, the equipment is also provided with a high-temperature antivirus function, controls the waterway channel through the electromagnetic valve, and performs high-temperature antivirus on the water outlet waterway and the water liner of the equipment, thereby ensuring the drinking health of a user.

Drawings

Fig. 1 is a schematic plan view of an energy-saving drinking water device according to an embodiment of the present invention.

Fig. 2 is a partially enlarged structural diagram of a water drinking mode a of the energy-saving water drinking device shown in fig. 1.

Fig. 3 is a partially enlarged structural diagram of a disinfection mode A of the energy-saving drinking water device shown in fig. 1.

Fig. 4 is a schematic plane structure view of the energy-saving drinking water device shown in fig. 1 in the direction B.

Fig. 5 is a schematic circuit structure diagram of an electrical part of the energy-saving drinking water device shown in fig. 1.

Reference numbers in the figures: 0-machine body, 1-water inlet mechanism, 11-water inlet, 12-filter, 2-first water outlet assembly, 21-third electromagnetic valve, 22-first water outlet key, 23-first water outlet, 3-second water outlet assembly, 31-fourth electromagnetic valve, 32-second water outlet key, 33-second water outlet, 4-heat exchange mechanism, 41-first spiral pipe, 42-second spiral pipe, 5-heating mechanism, 51-water container, 52-heating pipe, 53-safety valve, 54-pressure relief valve, 55-water level sensor, 56-safety temperature controller, 57-first temperature sensor, 58-second temperature sensor, 61-first electromagnetic valve, 62-second electromagnetic valve, 63-water inlet pipe, 7-temperature regulating valve, 81-electrical component, 82-control device, 91-water tank and 92-water discharge pipe.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Fig. 1 schematically shows an energy-saving drinking water device according to an embodiment of the present invention, which includes a machine body 0, a water inlet mechanism 1, a first water outlet assembly 2, a second water outlet assembly 3, a heat exchange mechanism 4 and a heating mechanism 5, wherein the water inlet mechanism 1, the heating mechanism 5, the heat exchange mechanism 4, the first water outlet assembly 2 and the second water outlet assembly 3 are all disposed on the machine body 0; the water inlet mechanism 1 and the heating mechanism 5 are both positioned below the machine body 0, the water inlet mechanism 1 and the heating mechanism 5 are distributed adjacently, and the heat exchange mechanism 4 is positioned above the machine body 0 and the water inlet mechanism 1; the first water outlet assembly 2 and the second water outlet assembly 3 are positioned on the upper end surface of the machine body 0. The heat exchange mechanism 4 comprises a first spiral pipe 41 and a second spiral pipe 42, the second spiral pipe 42 is sleeved in the first spiral pipe 41, the output end of the water inlet mechanism 1 is connected with the input end pipeline of the heating mechanism 5 through the first spiral pipe 41, one output end of the heating mechanism 5 is connected with the first water outlet assembly 2, and the other output end of the heating mechanism 5 is connected with the second water outlet assembly 3 through the second spiral pipe 42.

The utility model provides a drinking water equipment that can be energy-conserving. In the working process of the utility model, cold water enters from the water inlet mechanism 1, the cold water enters the heating mechanism 5 through the first spiral pipe 41 to be heated, and the boiling water heated in the heating mechanism 5 can be directly output from the first water outlet component 2 for a user to drink; the boiling water heated in the heating mechanism 5 can also enter the second spiral pipe 42 for cooling, the boiling water exchanges heat with the cold water in the first spiral pipe 41 in the second spiral pipe 42, the boiling water in the second spiral pipe 42 can be cooled into a warm water body, and the warm water body is output from the second water outlet assembly 3 for a user to drink; the heat exchange process in the heat exchange mechanism 4 can also heat the cold water in the first spiral pipe 41 to form warm water, and the warm water enters the heating mechanism 5 for heating, so that the heating time for boiling the water body can be reduced. Through above structure, on the one hand can let the user can drink warm boiled water, on the other hand reduces the required time of boiling of water, can reach the purpose of energy saving to heat recovery.

With reference to fig. 2-3, the energy-saving drinking water device further includes a first solenoid valve 61, a second solenoid valve 62, and a water inlet pipe 63, wherein the output end of the water inlet mechanism 1 is connected with the input end of the heating mechanism 5 through the water inlet pipe 63; the water inlet mechanism 1 is connected with an input end pipeline of the first spiral pipe 41 through a water inlet pipe 63 in a shunting manner, and an output end of the first spiral pipe 41 converges into the water inlet pipe 63 to be connected with a heating mechanism 5 through a pipeline; the first electromagnetic valve 61 is arranged on the water inlet pipe 63 and is positioned between the flow dividing section and the flow converging section of the water inlet pipe 63, and the second electromagnetic valve 62 is arranged on the flow dividing pipeline between the water inlet mechanism 1 and the first spiral pipe 41.

The drinking water equipment also has a high-temperature disinfection function. When the waterway of the drinking water equipment needs to be disinfected, the first electromagnetic valve 61, the first water outlet assembly 2 and the second water outlet assembly 3 are opened, and the second electromagnetic valve 62 is closed; the water body is directly led into the heating mechanism 5 for heating through the water inlet mechanism 1, one part of the heated boiling water directly flows out from the first water outlet component 2, and the other part of the heated boiling water enters the second spiral pipe 42 and flows out from the second water outlet component 3; thereby leading the heating mechanism 5 and the two water outlet channels to be disinfected by boiled water at the high temperature of 100 ℃.

Referring to fig. 1, the heating mechanism 5 includes a water tank 51, a heating pipe 52, a safety valve 53, a pressure release valve 54, and a water level sensor 55. The water liner 51 is of a liner wall with an interlayer structure, and a heat insulation layer is arranged in the interlayer structure; the heating tube 52 is arranged in the water container 51, the safety valve 53 is arranged at the input end of the water container 51, the water level sensor 55 is arranged in the water container 51 and is in signal connection with the safety valve 53, and the pressure release valve 54 is arranged at the upper end of the water container 51.

In the heating mechanism 5, the water body is heated in the water tank 51, and the water tank 51 is provided with the water level sensor 55 for identifying the maximum water level and the relief valve 54 for preventing the air pressure from being too high, so that the heating mechanism 5 has high safety.

Referring to fig. 1, the heating mechanism 5 further includes a safety temperature controller 56, a first temperature sensor 57, and a second temperature sensor 58, wherein the safety temperature controller 56, the first temperature sensor 57, and the second temperature sensor 58 are all disposed in the water tank 51, and the first temperature sensor 57 and the second temperature sensor 58 are distributed vertically.

In order to further enhance the safety of the heating mechanism 5, a safety thermostat 56, a first temperature sensor 57, and a second temperature sensor 58 are provided to detect the temperature in the water tank 51 and prevent the temperature in the water tank 51 from being too high.

Referring to fig. 1, the first water outlet assembly 2 includes a third solenoid valve 21, a first water outlet button 22 and a first water outlet 23, the first water outlet 23 is connected to an output end of the heating mechanism 5 through a pipeline, the third solenoid valve 21 is disposed on a pipeline between the first water outlet 23 and the heating mechanism 5, and the first water outlet button 22 is in signal connection with the third solenoid valve 21.

In the first water outlet assembly 2, the third electromagnetic valve 21 can be opened through the first water outlet button 22, so that the water body flows out from the first water outlet 23.

Referring to fig. 1, the second water outlet assembly 3 includes a fourth solenoid valve 31, a second water outlet button 32 and a second water outlet 33, a pipeline of the second water outlet 33 is connected to an output end pipeline of the second spiral pipe 42, a plurality of fourth solenoid valves 31 are disposed on a pipeline between the second water outlet 33 and the second spiral pipe 42, and the second water outlet button 32 is in signal connection with the fourth solenoid valves 31. In the second water outlet assembly 3, the fourth electromagnetic valve 31 can be opened through the second water outlet button 32, so that the water body flows out from the second water outlet 33.

Referring to fig. 1, the water inlet mechanism 1 includes a water inlet 11 and a filter 12, and the water inlet 11 is connected to the filter 12 through a pipe. The equipment is also provided with a filter 12, and the water body is heated by the filter 12 before entering the heating mechanism 5, so that the generation of scale can be prevented.

With reference to fig. 1, the energy-saving drinking water device further comprises a temperature adjusting valve 7, the temperature adjusting valve 7 is arranged on the machine body 0, the heating mechanism 5 is connected with an input end pipeline of the second spiral pipe 42 through the temperature adjusting valve 7, and the second spiral pipe 42 is connected with the second water outlet assembly 3 through the temperature adjusting valve 7. The temperature adjusting valve 7 is a liquid path block, can realize the pipeline connection of a water path through the night path block, and can control the flow of a water body through the temperature adjusting valve 7.

Referring to fig. 1 and 4, the energy-saving drinking water device further comprises an electrical component 81 and a control device 82, wherein the electrical component 81 has a circuit diagram as shown in fig. 5. The electrical component 81 is electrically connected with the control device 82, and the electrical component 81 is electrically connected with the water inlet mechanism 1, the first water outlet assembly 2, the second water outlet assembly 3, the heat exchange mechanism 4, the heating mechanism 5, the first electromagnetic valve 61 and the second electromagnetic valve 62.

The electrical component 81 and the control device 82 are the electrical control system of the apparatus. The electrical component 81 is shown in fig. 5.

Referring to fig. 1, the energy-saving drinking water device further includes a water tank 91 and a water discharge pipe 92, the water tank 91 is disposed on the machine body 0 and located below the first water outlet assembly 2 and the second water outlet assembly 3, and the water discharge pipe 92 is disposed on the machine body 0 and communicated with a lower end of the water tank 91. The water tank 91 is configured to receive the overflowing waste water and discharge the waste water out of the machine body 0 through a drain pipe 92. The drain 92 is plumbed to the pressure relief valve 54.

In this embodiment, the disinfection function is automatically turned on, the disinfection time is set when leaving the factory, and the disinfection interval time can be adjusted by the user at the later stage as required. In a normal use state, the first electromagnetic valve 61 is normally closed, the second electromagnetic valve 62 is normally open, and the third electromagnetic valve 21 and the fourth electromagnetic valve 31 are controlled by the first key switch and the second key switch.

And (3) heating the water body: as shown in fig. 2, cold water enters from the water inlet mechanism 1, the cold water enters the water container 51 through the first spiral pipe 41 to be heated, and the heated boiling water in the water container 51 can be directly output from the first water outlet assembly 2 for a user to drink; the boiling water heated in the heating mechanism 5 can also enter the second spiral pipe 42 for cooling, the boiling water exchanges heat with the cold water in the first spiral pipe 41 in the second spiral pipe 42, the boiling water in the second spiral pipe 42 can be cooled into a warm water body, and the warm water body is output from the second water outlet assembly 3 for a user to drink; the heat exchange process can also heat the cold water in the first spiral pipe 41 to form warm water, and the warm water enters the water liner 51 to be heated, so that the heating time for boiling the water can be shortened.

And (3) high-temperature disinfection process: as shown in fig. 3, according to the preset disinfection time, at intervals, the first electromagnetic valve 61, the first water outlet assembly 2 and the second water outlet assembly 3 are opened, and the second electromagnetic valve 62 is closed; the water body is directly led into the heating mechanism 5 for heating through the water inlet mechanism 1, one part of the heated boiling water directly flows out from the first water outlet component 2, and the other part of the heated boiling water enters the second spiral pipe 42 and flows out from the second water outlet component 3; thereby leading the heating mechanism 5 and the two water outlet channels to be disinfected by boiled water at the high temperature of 100 ℃.

Through the cold and heat exchange of the heat exchange mechanism 4, on one hand, the equipment can enable a user to drink warm boiled water, on the other hand, the time required by boiling of a water body is reduced, heat energy can be recycled, and the purpose of saving energy is achieved; moreover, the equipment is also provided with a high-temperature antivirus function, controls the waterway channel through the electromagnetic valve, and performs high-temperature antivirus on the water outlet waterway and the water liner 51 of the equipment, thereby ensuring the drinking water health of a user.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (9)

1. The energy-saving water drinking equipment is characterized by comprising an equipment body (0), a water inlet mechanism (1), a first water outlet assembly (2), a second water outlet assembly (3), a heat exchange mechanism (4) and a heating mechanism (5), wherein the water inlet mechanism (1), the heating mechanism (5), the heat exchange mechanism (4), the first water outlet assembly (2) and the second water outlet assembly (3) are all arranged on the equipment body (0); the heat exchange mechanism (4) comprises a first spiral pipe (41) and a second spiral pipe (42), the second spiral pipe (42) is sleeved in the first spiral pipe (41), the output end of the water inlet mechanism (1) is connected with the input end pipeline of the heating mechanism (5) through the first spiral pipe (41), one output end of the heating mechanism (5) is connected with the first water outlet assembly (2), and the other output end of the heating mechanism (5) is connected with the second water outlet assembly (3) through the second spiral pipe (42);

the water inlet mechanism is characterized by further comprising a first electromagnetic valve (61), a second electromagnetic valve (62) and a water inlet pipe (63), wherein the output end of the water inlet mechanism (1) is connected with the input end pipeline of the heating mechanism (5) through the water inlet pipe (63); the water inlet mechanism (1) is connected with an input end pipeline of a first spiral pipe (41) in a shunting manner through a water inlet pipe (63), and an output end of the first spiral pipe (41) converges into the water inlet pipe (63) to be connected with a heating mechanism (5) in a pipeline manner; first solenoid valve (61) are located inlet tube (63) and are located the reposition of redundant personnel section of inlet tube (63) and converge between the section, second solenoid valve (62) are located the reposition of redundant personnel pipeline between mechanism (1), first spiral pipe (41) of intaking.

2. The energy-saving drinking equipment according to claim 1, wherein the heating mechanism (5) comprises a water tank (51), a heating pipe (52), a safety valve (53), a pressure release valve (54) and a water level sensor (55), the heating pipe (52) is arranged in the water tank (51), the safety valve (53) is arranged at the input end of the water tank (51), the water level sensor (55) is arranged in the water tank (51) and is in signal connection with the safety valve (53), and the pressure release valve (54) is arranged at the upper end of the water tank (51).

3. The energy-saving drinking equipment as claimed in claim 2, wherein the heating mechanism (5) further comprises a safety temperature controller (56), a first temperature sensor (57) and a second temperature sensor (58), the safety temperature controller (56), the first temperature sensor (57) and the second temperature sensor (58) are all arranged in the water container (51), and the first temperature sensor (57) and the second temperature sensor (58) are distributed up and down.

4. The energy-saving drinking equipment as claimed in claim 1, wherein the first water outlet assembly (2) comprises a third electromagnetic valve (21), a first water outlet button (22) and a first water outlet (23), the first water outlet (23) is connected with an output end pipeline of the heating mechanism (5), the third electromagnetic valve (21) is arranged on a pipeline between the first water outlet (23) and the heating mechanism (5), and the first water outlet button (22) is in signal connection with the third electromagnetic valve (21).

5. The energy-saving drinking equipment as claimed in claim 1, wherein the second water outlet assembly (3) comprises a fourth electromagnetic valve (31), a second water outlet button (32) and a second water outlet (33), the second water outlet (33) is connected with an output end pipeline of the second spiral pipe (42) through a pipeline, a plurality of fourth electromagnetic valves (31) are arranged on a pipeline between the second water outlet (33) and the second spiral pipe (42), and the second water outlet button (32) is in signal connection with the fourth electromagnetic valves (31).

6. The energy-saving drinking water device according to claim 1, wherein the water inlet mechanism (1) comprises a water inlet (11) and a filter (12), and the water inlet (11) is connected with the filter (12) in a pipeline way.

7. The energy-saving drinking water device according to any one of claims 1 to 6, further comprising a temperature regulating valve (7), wherein the heating mechanism (5) is connected with an input end pipeline of the second spiral pipe (42) through the temperature regulating valve (7), and the second spiral pipe (42) is connected with a second water outlet assembly (3) through the temperature regulating valve (7).

8. The energy-saving water drinking device according to claim 7, further comprising an electrical component (81) and a control device (82), wherein the electrical component (81) is electrically connected with the control device (82), and the electrical component (81) is electrically connected with the water inlet mechanism (1), the first water outlet component (2), the second water outlet component (3), the heat exchange mechanism (4), the heating mechanism (5), the first electromagnetic valve (61) and the second electromagnetic valve (62).

9. The energy-saving drinking water equipment as claimed in claim 7, further comprising a water tank (91) and a water discharge pipe (92), wherein the water tank (91) is arranged on the machine body (0) and is positioned below the first water outlet assembly (2) and the second water outlet assembly (3), and the water discharge pipe (92) is arranged on the machine body (0) and is communicated with the lower end of the water tank (91).

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