CN114198911A

CN114198911A - Water dispenser based on intelligent induction

Info

Publication number: CN114198911A
Application number: CN202111459774.7A
Authority: CN
Inventors: 王星
Original assignee: Shenzhen Gaomeng Technology Co ltd
Current assignee: Yuyun Xiamen Network Technology Co ltd
Priority date: 2021-12-02
Filing date: 2021-12-02
Publication date: 2022-03-18
Anticipated expiration: 2041-12-02
Also published as: CN114198911B

Abstract

The invention relates to the technical field of intelligent home furnishing, and discloses a drinking device based on intelligent induction, wherein the output end of an energy accumulator is connected with the input ends of a temperature display panel, a temperature control panel and an inductor through a power supply line, when the device is in a closed state, water in a water supply pipeline flows into an inlet pipe under the action of water pressure, one end of a diversion hole is connected with the inlet pipe, the other end of the diversion hole is connected with a diversion pipe I, so that water flow can impact a power generation impeller to drive the power generation impeller to rotate when flowing into a power generation chamber through the diversion hole, the energy accumulator is driven to generate power and the temperature display panel, the temperature control panel and the inductor are not powered by a main power supply connection, the temperature display panel, the temperature control panel and the inductor in the device are not required to be additionally connected into a circuit from a main power supply connection, the structure and the production process of the device are simplified, the production cost of the device is reduced, and the energy consumption of the device is also reduced.

Description

Water dispenser based on intelligent induction

Technical Field

The invention relates to the technical field of intelligent home furnishing, in particular to a drinking device based on intelligent induction.

Background

Along with the development of science and technology, more and more intelligent house makes people can more conveniently use, wherein have intelligent watering device, possess intelligent response and remote control heating temperature's function, thereby the in-process user that uses can oneself demand mix hot water and cold water the drinking water that gets suitable temperature, its inside mainly by heating device, water supply installation and control system constitute, and convenient to use has, moreover, the steam generator is simple in structure, and advantages such as low cost are the most extensive watering device of application range at present.

Although drinking device of current intelligent response has a great deal of advantage, still have certain limitation in actual use, for example unable accurate control temperature when people's own perception comes mixed hot water and cold water, thereby can appear the too high problem of the temperature that the temperature is low, bring the puzzlement for the user, in addition, heating device prevents dry combustion method's function in intelligence, but lack the regulatory function of initiative, can't come the controlled heating power to the water yield, thereby lead to heating power to be in under higher consumption always, cause the wasting of resources, to this, this application file provides a drinking device based on intelligent response, aim at solving above-mentioned problem that provides.

Disclosure of Invention

Aiming at the defects of the existing intelligent induction-based drinking device in the use process, the invention provides the intelligent induction-based drinking device, which has the advantage of automatically allocating the temperature of drinking water and solves the problem of inaccurate temperature caused by manual allocation.

The invention provides the following technical scheme: a drinking device based on intelligent induction comprises a mounting seat, wherein a water outlet device is fixedly mounted at the position, close to one side, of the top of the mounting seat, a temperature display panel is fixedly mounted at the position, close to the other side, of the top of the mounting seat, a temperature control panel is fixedly mounted at the position, located between the water outlet device and the temperature display panel, of the top of the mounting seat, an inductor is fixedly mounted on the outer surface of the water outlet device, a water supply pipe is fixedly mounted at the bottom of the mounting seat and communicated with the water outlet device, a throttling valve is fixedly mounted at the position, close to the top, of the outer surface of the water supply pipe, a lead-in pipe is fixedly mounted at the position, located below the throttling valve, of the outer surface of the water supply pipe and communicated with the water supply pipe, a power generation device is fixedly mounted at one end of the lead-in pipe, a flow guide pipe I is fixedly mounted at one end of the power generation device, and a heat insulation device is fixedly mounted at the bottom of the flow guide pipe I, the bottom fixed mounting of heat-proof device has heating device, fixed mounting has the choked flow device on the position that the heating device bottom is close to the outside, the bottom fixed mounting of choked flow device has honeycomb duct II and honeycomb duct II to be linked together with the choked flow device, the one end fixed mounting of honeycomb duct II has the ooff valve, the fixed surface of ooff valve installs shunt tubes and is linked together with the ooff valve, fixed connection and shunt tubes and play water ware are linked together on the one end of shunt tubes and the position that goes out the water ware surface and be close to the bottom.

Preferably, power generation facility includes insulating casing, the electricity generation room has been seted up to insulating casing's inside, the top of insulating casing one side has been seted up water conservancy diversion hole and has been link up with the electricity generation room, the one end in water conservancy diversion hole is connected with the induction pipe and the other end in water conservancy diversion hole is connected with honeycomb duct I, electricity generation impeller has been cup jointed in the activity on the position that electricity generation room one side is located the center, one side fixed mounting of insulating casing surface has the output shaft of energy accumulator and energy accumulator to run through insulating casing and with electricity generation impeller fixed connection.

Preferably, the output end of the energy storage device is connected with the input ends of the temperature display panel, the temperature control panel and the inductor through a power supply line, the output end of the temperature control panel is connected with the input end of the switch valve in a signal connection mode, and the output end of the inductor is connected with the input end of the throttle valve in a signal connection mode.

Preferably, the heat insulation device comprises a heat insulation bin, a round through hole is formed in the top of the heat insulation bin, the top of the round through hole is fixedly connected with the flow guide pipe I, the bottom of the heat insulation bin is provided with a circular through hole, the inner wall of the circular through hole is fixedly provided with a sleeving block, a sliding rod is movably sleeved at the position of the top of the sleeving block positioned at the center, a fixed bracket is fixedly arranged at the position of the top of the sleeving block positioned at the outer side of the sliding rod, a spoiler is fixedly arranged at the top of the sliding rod and matched with the round through hole at the top of the heat insulation bin, the spoiler is made of heat insulating material, a return spring is fixedly arranged at the position, between the slide bar and the fixed bracket, of the top of the sleeving block, the top of the reset spring is fixedly connected with the bottom of the spoiler, and the bottom of the heat insulation bin is fixedly provided with a connecting pipe, and the bottom of the connecting pipe is fixedly connected with the heating device.

Preferably, heating device includes the heated warehouses, the top of heated warehouses is linked together with connecting pipe fixed connection and connecting pipe and the inner chamber of heated warehouses, the inner wall fixed mounting of heated warehouses has the heating strip, the top fixed mounting of heated warehouses inner chamber has circular telegram board I and circular telegram board I's surface and heating strip to contact, fixed mounting has the telescopic link on the position that the heated warehouses bottom is located the center, the telescopic link output shaft runs through the heated warehouses and extends to the inside of heated warehouses and the one end fixed mounting of telescopic link output shaft has the stroke board, the top fixed mounting of stroke board has circular telegram board II and circular telegram board II's surface and heating strip to contact, fixed mounting has the choked flow device on the position that the heated warehouses bottom just is located the telescopic link outside.

Preferably, the choked flow device has included the choked flow storehouse, the choked flow storehouse has gone up fixed mounting and has had the inside that discharge pipe and choked flow storehouse were linked together on the surface was close to the position at top, the inside activity that the choked flow storehouse had been cup jointed choked flow piece and choked flow piece highly be less than the distance that discharge pipe had arrived the bottom in choked flow storehouse, the bottom in choked flow storehouse and II fixed connection of honeycomb duct and intercommunication each other.

Preferably, the power-on plate I and the power-on plate II are connected into a circuit and supply power to the heating strip.

The invention has the following beneficial effects:

1. the invention connects the output end of the energy accumulator with the input ends of the temperature display panel, the temperature control panel and the inductor through the power supply line, when the device is in a closed state, the water in the water supply pipeline flows into the lead-in pipe under the action of water pressure, one end of the flow guide hole is connected with the lead-in pipe and the other end of the flow guide hole is connected with the flow guide pipe I, so that the water flow impacts the power generation impeller to drive the power generation impeller to rotate when flowing into the power generation chamber through the flow guide hole, thereby driving the energy accumulator to generate power and not supplying power to the temperature display panel, the temperature control panel and the inductor, leading the temperature display panel, the temperature control panel and the inductor in the device not to be additionally connected with a circuit from a main power supply, simplifying the structure and the production process of the device and reducing the production cost of the device, and simultaneously, the energy consumption of the device is also reduced.

2. According to the invention, the circuit is connected with the power supply plate I and the power supply plate II and supplies power to the heating strip, when water flow enters the heat insulation device through the power generation device and the flow guide pipe I, the top of the flow blocking plate is in an open state under the action of water flow pressure, so that the water flow can enter the heating device through the flow blocking plate, and the stroke plate is pushed to move in the vertical downward direction under the action of the water pressure, so that the length of the heating strip between the power supply plate I and the power supply plate II is increased, the temperature of the heating strip is increased and the water in the heating bin is heated under the action of power supply, and the length of the circuit part connected with the heating strip is in direct proportion to the water storage amount in the heating bin, so that the heating efficiency of the device is in an optimal state, the waste of electric power is avoided, and the use cost is reduced.

3. The invention is connected with the input end of the switch valve by the signal connection way through the output end of the inductor, when the inductor is activated, the switch valve is controlled to be in the open state by the signal connection way, the water outlet temperature can be set by the temperature control board, when the set temperature is lower, the throttle valve is in the fully open state, so that the water flow in the water supply pipe completely flows into the water outlet device through the throttle valve and is discharged, when the set temperature is higher, the throttle valve is in the half-open state, the opening degree of the throttle valve is lower when the temperature is higher, at the moment, the resistance of the throttle valve to the water flow in the water supply pipe is higher, the water flow enters the heating device through the flow dividing pipe, the switch valve and the flow guiding pipe II, so as to jack up the stroke plate, and the water which is heated in the heating device and is positioned above the stroke plate flows into the water supply pipe through the flow guiding pipe I and the guiding pipe and heats the water, thereby guarantee that the device can provide the comparatively accurate hot water of temperature constantly to compare in traditional heating methods's watering device, this kind of heating methods can not lead to the temperature of the water that flows earlier to hang down because of the reason of preheating, has improved the device's practicality.

4. According to the invention, the spoiler is the heat insulation material, so that when the inner cavity of the heating device is filled with water, the water pressures on the two sides of the spoiler are the same, the spoiler is reset under the action of the reset spring, the heat insulation device is in a closed state, the waste of electric energy caused by overlong time of the heating strip in a heating state due to heat loss caused by heat exchange of the heated water in the heating device, the flow guide pipe I and the water in the water supply pipe is avoided, and the use cost is further reduced.

5. The bottom of the flow resisting bin is fixedly connected and communicated with the flow guiding pipe II, so that when the water pressure in the flow guiding pipe II rises, water flow in the flow guiding pipe II flows into the heating device through the flow resisting bin, the flow resisting block is pushed to move upwards to block the discharging pipe in the process, the situation that the pressure is reduced due to the fact that the water flow is discharged through the discharging pipe in the process, the hot water supplying capacity is reduced is avoided, the stability of the device in the operation process is improved, meanwhile, when the device stops operation, the flow resisting block loses acting force and falls and resets due to the fact that the throttling valve and the switch valve are in a closed state, the discharging pipe is in an open state, liquid below the stroke plate in the heating device is discharged, water can flow into the heating device through the heat insulation device, and therefore the hot water in the heating device is sufficient, the reliability of the operation of the device is improved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic cross-sectional view of the structure of the present invention;

FIG. 3 is an enlarged view of the point A in FIG. 2;

FIG. 4 is a schematic view of a power plant constructed in accordance with the present invention;

FIG. 5 is a schematic cross-sectional view of a power generation device according to the present invention;

FIG. 6 is a schematic view of a heating apparatus according to the present invention;

FIG. 7 is a schematic right sectional view of a heating apparatus according to the present invention;

FIG. 8 is a schematic sectional front view of a heating apparatus according to the present invention;

FIG. 9 is an enlarged view of the point B in FIG. 8;

FIG. 10 is a schematic view of a structural power board I of the present invention;

FIG. 11 is a schematic view of a structural energization plate II of the present invention.

In the figure: 1. a mounting seat; 2. a water outlet device; 3. a temperature display panel; 4. a temperature control panel; 5. an inductor; 6. a water supply pipe; 7. a throttle valve; 8. an introducing pipe; 9. a power generation device; 91. an insulating housing; 92. a power generation chamber; 93. a flow guide hole; 94. a power generation impeller; 95. an energy storage device; 10. a flow guide pipe I; 11. a thermal insulation device; 111. a heat insulation bin; 112. sleeving and connecting blocks; 113. a slide bar; 114. fixing a bracket; 115. a spoiler; 116. a return spring; 117. a connecting pipe; 12. a heating device; 121. a heating chamber; 122. heating the strip; 123. a power-on plate I; 124. a telescopic rod; 125. a stroke plate; 126. a power-on plate II; 13. a flow blocking device; 131. a flow blocking bin; 132. a discharge pipe; 133. a flow choking block; 14. a flow guide pipe II; 15. an on-off valve; 16. and (4) dividing the tube.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-2, a drinking device based on intelligent sensing comprises a mounting base 1, a water outlet device 2 is fixedly mounted at a position close to one side of the top of the mounting base 1, a temperature display panel 3 is fixedly mounted at a position close to the other side of the top of the mounting base 1, a temperature control panel 4 is fixedly mounted at a position on the top of the mounting base 1 and between the water outlet device 2 and the temperature display panel 3, a sensor 5 is fixedly mounted on the outer surface of the water outlet device 2, a water supply pipe 6 is fixedly mounted at the bottom of the mounting base 1 and communicated with the water outlet device 2, a throttle valve 7 is fixedly mounted at a position on the outer surface of the water supply pipe 6 and close to the top, a lead-in pipe 8 is fixedly mounted at a position on the outer surface of the water supply pipe 6 and above the throttle valve 7 and communicated with the water supply pipe 6, a power generation device 9 is fixedly mounted at one end of the lead-in pipe 8, a guide pipe i 10 is fixedly mounted at one end of the power generation device 9, the bottom fixed mounting of honeycomb duct I10 has heat-proof device 11, the bottom fixed mounting of heat-proof device 11 has heating device 12, fixed mounting has choked flow device 13 on the position that heating device 12 bottom is close to the outside, fixed mounting has honeycomb duct II 14 and honeycomb duct II 14 is linked together with choked flow device 13 bottom fixed mounting of choked flow device 13, the one end fixed mounting of honeycomb duct II 14 has ooff valve 15, the fixed surface mounting of ooff valve 15 has shunt tubes 16 and shunt tubes 16 is linked together with ooff valve 15, the fixed connection is gone up on the position that the one end of shunt tubes 16 and the outer surface of water outlet ware 2 are close to the bottom and shunt tubes 16 is linked together with water outlet ware 2.

Referring to fig. 4 to 5, the power generation device 9 includes an insulating housing 91, a power generation chamber 92 is disposed inside the insulating housing 91, a diversion hole 93 is disposed at a top of one side of the insulating housing 91, the diversion hole 93 is communicated with the power generation chamber 92, one end of the diversion hole 93 is connected to the inlet pipe 8, the other end of the diversion hole 93 is connected to the diversion pipe i 10, a power generation impeller 94 is movably sleeved on a center position of one side of the power generation chamber 92, an energy storage device 95 is fixedly mounted on one side of an outer surface of the insulating housing 91, and an output shaft of the energy storage device 95 penetrates through the insulating housing 91 and is fixedly connected to the power generation impeller 94.

Referring to fig. 1-5, the output end of the energy storage device 95 is connected to the input ends of the temperature display panel 3, the temperature control panel 4 and the sensor 5 through power supply lines, so that when the device is in a closed state, water in the water supply pipe 6 flows into the inlet pipe 8 under the action of water pressure, one end of the water guide hole 93 is connected to the inlet pipe 8, and the other end of the water guide hole 93 is connected to the flow guide pipe i 10, so that the water flows into the power generation chamber 92 through the water guide hole 93 and impacts the power generation impeller 94 to drive the power generation impeller 94 to rotate, thereby driving the energy storage device 95 to generate power without the temperature display panel 3, the temperature control panel 4 and the sensor 5 being powered by the main power supply line, so that the temperature display panel 3, the temperature control panel 4 and the sensor 5 in the device need not be additionally connected to the circuit from the main power supply line, the structure and the production process of the device are simplified, the production cost of the device is reduced, and the energy consumption of the device is also reduced, the output end of the temperature control plate 4 is connected with the input end of the throttle valve 7 in a signal connection mode, the output end of the inductor 5 is connected with the input end of the switch valve 15 in a signal connection mode, when the inductor 5 is activated, the switch valve 15 is controlled to be in an open state in a signal connection mode, the water outlet temperature can be set through the temperature control plate 4 at the moment, when the set temperature is lower, the throttle valve 7 is in a fully open state, so that the water flow in the water supply pipe 6 completely flows into the water outlet device 2 through the throttle valve 7 and is discharged, when the set temperature is higher, the throttle valve 7 is in a half-open state, the opening degree of the throttle valve 7 is lower as the temperature is higher, and the resistance of the throttle valve 7 to the water flow in the water supply pipe 6 is higher at the moment, at this moment, water flow enters the heating device 12 through the shunt pipe 16, the switch valve 15 and the guide pipe II 14, so that the stroke plate 125 is jacked up, the water which is heated above the stroke plate 125 in the heating device 12 flows into the water supply pipe 6 through the guide pipe I10 and the guide pipe 8, and the water is heated, the device is guaranteed to be capable of supplying hot water with relatively accurate temperature constantly, compared with a water drinking device adopting a traditional heating mode, the heating mode cannot lead to the temperature of water flowing out firstly due to preheating to over-low, and the practicability of the device is improved.

Referring to fig. 3, the thermal insulation device 11 includes a thermal insulation bin 111, a circular through hole is formed at the top of the thermal insulation bin 111, the top of the circular through hole is fixedly connected to the flow guide tube i 10, a circular through hole is formed at the bottom of the thermal insulation bin 111, a sleeving block 112 is fixedly installed on the inner wall of the circular through hole, a sliding rod 113 is movably sleeved on the top of the sleeving block 112 at the center, a fixed bracket 114 is fixedly installed at the top of the sleeving block 112 and at the outer side of the sliding rod 113, a spoiler 115 is fixedly installed at the top of the sliding rod 113, the spoiler 115 is matched with the circular through hole at the top of the thermal insulation bin 111, the spoiler 115 is a thermal insulation material, when the inner cavity of the heating device 12 is filled with water, the water pressures at both sides of the spoiler 115 are the same, so that the spoiler 115 is reset under the action of a reset spring 116 and the thermal insulation device 11 is in a closed state, thereby preventing the heated water in the heating device 12 from heat exchanging with the water in the flow guide tube i 10 and the water supply tube 6 to cause heat loss The heating bar 122 is in a heating state for too long time to cause waste of electric energy, so that the use cost is further reduced, a return spring 116 is fixedly installed at a position, between the sliding rod 113 and the fixed support 114, of the top of the sleeving block 112, the top of the return spring 116 is fixedly connected with the bottom of the spoiler 115, a connecting pipe 117 is fixedly installed at the bottom of the heat insulation bin 111, and the bottom of the connecting pipe 117 is fixedly connected with the heating device 12.

Referring to fig. 6-8 and 10-11, the heating device 12 includes a heating chamber 121, the top of the heating chamber 121 is fixedly connected to a connecting pipe 117, the connecting pipe 117 is communicated with an inner cavity of the heating chamber 121, a heating strip 122 is fixedly installed on an inner wall of the heating chamber 121, a power-on plate i 123 is fixedly installed on the top of the inner cavity of the heating chamber 121, an outer surface of the power-on plate i 123 contacts the heating strip 122, a telescopic rod 124 is fixedly installed at a central position of the bottom of the heating chamber 121, an output shaft of the telescopic rod 124 penetrates through the heating chamber 121 and extends into the heating chamber 121, a stroke plate 125 is fixedly installed at one end of the output shaft of the telescopic rod 124, a power-on plate ii 126 is fixedly installed at the top of the stroke plate 125, an outer surface of the power-on plate ii 126 contacts the heating strip 122, and a flow blocking device 13 is fixedly installed at a position of the bottom of the heating chamber 121 and located outside the telescopic rod 124.

Referring to fig. 6-8 and 10-11, the first and second current-carrying plates 123 and ii 126 are electrically connected to supply power to the heating strip 122, when water flows through the power generation device 9 and the flow guide tube i 10 into the heat insulation device 11, the top of the flow guide plate 115 is opened under the pressure of the water flow, so that the water flows through the flow guide plate 115 into the heating device 12, and the stroke plate 125 is pushed by the water pressure to move in a vertical downward direction, so that the length of the heating strip 122 between the first and second current-carrying plates i 123 and ii 126 is increased, the temperature of the heating strip 122 is increased under the power supply, the water inside the heating chamber 121 is heated, and the length of the circuit-connecting portion of the heating strip 122 is proportional to the water storage amount inside the heating chamber 121, so that the heating efficiency of the device is in an optimal state, and waste of power is avoided, the use cost is reduced.

Referring to fig. 9, the flow blocking device 13 includes a flow blocking chamber 131, a discharge pipe 132 is fixedly installed at a position near the top of the outer surface of the flow blocking chamber 131, the discharge pipe 132 is communicated with the inside of the flow blocking chamber 131, a flow blocking block 133 is movably sleeved inside the flow blocking chamber 131, the height of the flow blocking block 133 is smaller than the distance from the discharge pipe 132 to the bottom of the flow blocking chamber 131, the bottom of the flow blocking chamber 131 is fixedly connected and communicated with the flow guiding pipe ii 14, so that when the water pressure inside the flow guiding pipe ii 14 is increased, the water inside the flow guiding pipe ii 14 flows into the heating device 12 through the flow blocking chamber 131, the flow blocking block 133 is pushed to move upwards to block the discharge pipe 132 in the process, thereby preventing the water from being discharged through the discharge pipe 132 to cause pressure reduction and reduce the supply capacity of hot water, improving the stability of the device during operation, and simultaneously, the device stops operation, at this time, since the throttle valve 7 and the on-off valve 15 are both in the closed state, the choke block 133 loses its force and falls to be reset, the discharge pipe 132 is in the open state and discharges the liquid inside the heating device 12 below the stroke plate 125, so as to ensure that the water can flow into the heating device 12 through the heat insulation device 11, thereby ensuring that the hot water inside the heating device 12 is sufficient and improving the operation reliability of the device.

The using method of the invention is as follows:

in the using process, when the device is in a closed state, at the moment, water in the pipeline of the water supply pipe 6 flows into the inlet pipe 8 under the action of water pressure, at the moment, one end of the flow guide hole 93 is connected with the inlet pipe 8, and the other end of the flow guide hole 93 is connected with the flow guide pipe I10, so that when water flows into the power generation chamber 92 through the flow guide hole 93, the water impacts the power generation impeller 94 to drive the power generation impeller 94 to rotate, the energy storage device 95 is driven to generate power, the temperature display panel 3, the temperature control panel 4 and the inductor 5 are not powered, the temperature display panel 3, the temperature control panel 4 and the inductor 5 in the device are not required to be additionally connected into a circuit from a main power supply, when the water flows into the heat insulation device 11 through the power generation device 9 and the flow guide pipe I10, at the moment, the top of the flow blocking plate 115 is in an open state under the action of water flow pressure, so that water flow can enter the inside of the heating device 12 through the flow blocking plate 115, and the stroke plate 125 is pushed to move in a vertically downward direction under the action of water pressure, so that the length of the heating strip 122 between the energization plate i 123 and the energization plate ii 126 is increased, the temperature of the heating strip 122 is increased under the action of energization to heat water inside the heating chamber 121, and the length of the circuit connection part of the heating strip 122 is in proportion to the water storage amount inside the heating chamber 121, so that the heating efficiency of the device is in an optimal state.

When the sensor 5 is activated, the switch valve 15 is controlled to be in an open state by means of signal connection, the outlet water temperature can be set by the temperature control board 4, when the set temperature is lower, the throttle valve 7 is in a fully open state, so that the water flow inside the water supply pipe 6 completely flows into the water outlet 2 through the throttle valve 7 and is discharged, when the set temperature is higher, the throttle valve 7 is in a half-open state, and the opening degree of the throttle valve 7 is lower as the temperature is higher, at this time, the water flow resistance to the water flow inside the water supply pipe 6 by the throttle valve 7 is higher, at this time, the water flow enters the inside of the heating device 12 through the shunt pipe 16, the switch valve 15 and the guide pipe II 14, so that the stroke plate 125 is jacked up, the water heated in the heating device 12 and above the stroke plate 125 flows into the inside the water supply pipe 6 through the guide pipe I10 and the guide pipe 8 and heats the water, when the inner cavity of the heating device 12 is filled with water, the water pressure on both sides of the spoiler 115 is the same, so that the spoiler 115 is reset under the action of the reset spring 116 and the heat insulation device 11 is in a closed state, when the water pressure in the flow guide pipe ii 14 is increased, the water flow in the flow guide pipe ii 14 flows into the heating device 12 through the spoiler bin 131, and the spoiler 133 is pushed to move upwards to block the discharge pipe 132 in the process.

When the device stops operating, the choke block 133 loses its action force and falls to reset because the throttle valve 7 and the on-off valve 15 are both closed, the discharge pipe 132 is opened and discharges the liquid inside the heating device 12 below the stroke plate 125, so as to ensure that the water can flow into the heating device 12 through the heat insulation device 11, thereby ensuring that the hot water inside the heating device 12 is sufficient.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a watering device based on intelligence response, includes mount pad (1), its characterized in that: the water supply device is characterized in that a water outlet device (2) is fixedly mounted at the position, close to one side, of the top of the mounting seat (1), a temperature display panel (3) is fixedly mounted at the position, close to the other side, of the top of the mounting seat (1), a temperature control panel (4) is fixedly mounted at the position, located between the water outlet device (2) and the temperature display panel (3), of the top of the mounting seat (1), an inductor (5) is fixedly mounted on the outer surface of the water outlet device (2), a water supply pipe (6) is fixedly mounted at the bottom of the mounting seat (1), the water supply pipe (6) is communicated with the water outlet device (2), a throttle valve (7) is fixedly mounted at the position, close to the top, of the outer surface of the water supply pipe (6), a guide-in pipe (8) is fixedly mounted at the position, located below the throttle valve (7), the guide-in pipe (8) is communicated with the water supply pipe (6), one end fixed mounting of leading-in pipe (8) has power generation facility (9), the one end fixed mounting of power generation facility (9) has honeycomb duct I (10), the bottom fixed mounting of honeycomb duct I (10) has heat-proof device (11), the bottom fixed mounting of heat-proof device (11) has heating device (12), fixed mounting has choked flow device (13) on the position that heating device (12) bottom is close to the outside, the bottom fixed mounting of choked flow device (13) has honeycomb duct II (14) and honeycomb duct II (14) to be linked together with choked flow device (13), the one end fixed mounting of honeycomb duct II (14) has ooff valve (15), the outer fixed mounting of ooff valve (15) has shunt tubes (16) and shunt tubes (16) to be linked together with ooff valve (15), fixed connection and shunt tubes (16) link to each other with water outlet device (2) on the one end of shunt tubes (16) and water outlet device (2) surface are close to the position of bottom on fixed connection and shunt tubes (16) and water outlet device (2) are continuous The method is simple.

2. The intelligent sensing-based drinking device according to claim 1, wherein: the power generation device (9) comprises an insulating shell (91), a power generation chamber (92) is arranged inside the insulating shell (91), a guide hole (93) and a guide hole (93) are formed in the top of one side of the insulating shell (91) and are communicated with the power generation chamber (92), one end of the guide hole (93) is connected with a guide pipe (8) and the other end of the guide hole (93) is connected with a guide pipe I (10), a power generation impeller (94) is movably sleeved on the position, located at the center, of one side of the power generation chamber (92), and an output shaft, fixedly provided with an energy accumulator (95) and an energy accumulator (95), of one side of the outer surface of the insulating shell (91) penetrates through the insulating shell (91) and is fixedly connected with the power generation impeller (94).

3. The intelligent sensing-based water dispenser device according to claim 2, wherein: the output end of the energy storage device (95) is connected with the input ends of the temperature display panel (3), the temperature control panel (4) and the inductor (5) through a power supply line, the output end of the temperature control panel (4) is connected with the input end of the switch valve (15) in a signal connection mode, and the output end of the inductor (5) is connected with the input end of the throttle valve (7) in a signal connection mode.

4. The intelligent sensing-based drinking device according to claim 1, wherein: the heat insulation device (11) comprises a heat insulation bin (111), the top of the heat insulation bin (111) is provided with a circular through hole, the top of the circular through hole is fixedly connected with the guide pipe I (10), the bottom of the heat insulation bin (111) is provided with a circular through hole, the inner wall of the circular through hole is fixedly provided with a sleeving block (112), the top of the sleeving block (112) is movably sleeved with a sliding rod (113) at the center, the top of the sleeving block (112) is fixedly provided with a fixed support (114) at the outer side of the sliding rod (113), the top of the sliding rod (113) is fixedly provided with a flow baffle (115), the flow baffle (115) is matched with the circular through hole at the top of the heat insulation bin (111), the flow baffle (115) is made of heat insulation materials, and a reset spring (116) is fixedly arranged at the position, between the sliding rod (113) and the fixed support (114), at the top of the sleeving block (112), the top of the return spring (116) is fixedly connected with the bottom of the spoiler (115), the bottom of the heat insulation bin (111) is fixedly provided with a connecting pipe (117), and the bottom of the connecting pipe (117) is fixedly connected with the heating device (12).

5. The intelligent sensing-based water dispenser according to claim 4, wherein: heating device (12) includes heating chamber (121), the top and connecting pipe (117) fixed connection and connecting pipe (117) of heating chamber (121) are linked together with the inner chamber of heating chamber (121), the inner wall fixed mounting of heating chamber (121) has heating strip (122), the top fixed mounting of heating chamber (121) inner chamber has the surface and the heating strip (122) of circular telegram board I (123) and circular telegram board I (123) to contact, fixed mounting has telescopic link (124) on the position that heating chamber (121) bottom is located the center, telescopic link (124) output shaft runs through heating chamber (121) and extends to the inside of heating chamber (121) and the one end fixed mounting of telescopic link (124) output shaft has stroke board (125), the top fixed mounting of stroke board (125) has circular telegram board II (126) and the surface and the heating strip (122) of circular telegram board II (126) to contact, and a flow blocking device (13) is fixedly arranged at the bottom of the heating bin (121) and at the position outside the telescopic rod (124).

6. The intelligent sensing-based drinking device according to claim 5, wherein: the flow blocking device (13) comprises a flow blocking bin (131), a discharge pipe (132) and a discharge pipe (132) are fixedly mounted on the position, close to the top, of the outer surface of the flow blocking bin (131) and communicated with the inside of the flow blocking bin (131), the flow blocking block (133) and the distance from the discharge pipe (132) to the bottom of the flow blocking bin (131) are sleeved in the inside of the flow blocking bin (131) in a movable mode, and the bottom of the flow blocking bin (131) is fixedly connected with a flow guide pipe II (14) and communicated with each other.

7. The intelligent sensing-based drinking device according to claim 5, wherein: the power-on plate I (123) and the power-on plate II (126) are connected into a circuit and supply power to the heating strip (122).