CN114636245A - Air-conditioning smoke machine - Google Patents

Abstract

The application relates to an air-conditioning range hood. This air conditioner cigarette machine includes: air conditioner body and cigarette machine body. The cigarette machine body comprises a water storage component and an electrolysis device, wherein the water storage component is positioned below the air conditioner body and used for collecting condensed water generated by the air conditioner body, and the electrolysis device is used for electrolyzing the condensed water collected by the water storage component. In this application, the comdenstion water that air conditioner body refrigeration produced drops under the action of gravity in the water storage component of below, then forms hydrogen and oxygen under electrolytic device's electrolysis, has so realized the processing of comdenstion water. Compared with the prior art, utilize electrolytic device directly to form gaseous state material with the comdenstion water electrolysis, need not use the recovery vessel of any form, can reduce user's clearance number of times greatly, user uses and saves worry, experiences and feels better.

Description

Air-conditioning smoke machine

Technical Field

The application relates to the technical field of kitchen appliances, in particular to an air-conditioning range hood.

Background

The kitchen is the main place that people cook, and the culinary art of people is experienced directly to the good or bad of kitchen air environment. The kitchen is hot in summer and cold in winter, and has the requirements of cold supply and heat supply. Therefore, people invent various air conditioning smoke exhaust fans, cool the air in the kitchen in summer, and provide hot air to the kitchen in winter, so as to improve the cooking comfort.

Air conditioner cigarette machine can produce the comdenstion water when refrigerating, in order to avoid the comdenstion water to drip from the air conditioner cigarette machine and influence the user and use, need carry out recovery processing to the comdenstion water, in the correlation technique, the processing mode is with the comdenstion water drainage to the accumulator (like the oil cup of cigarette machine) and store the comdenstion water, but this kind of mode needs the user to clear up the accumulator frequently, and user experience feels poor.

Disclosure of Invention

This application when using the recovery container to handle the comdenstion water to current air conditioner cigarette machine, lead to the user to need frequently clear up the problem that recovery container, user experience feel poor, has provided an air conditioner cigarette machine, and this air conditioner cigarette machine has and need not to set up the recovery container, does not need user's clearance to retrieve container, user experience and feels good technological effect.

An air conditioning range hood comprising:

an air conditioner body; and

the cigarette machine body comprises a water storage component and an electrolysis device, the water storage component is located below the air conditioner body and used for collecting condensed water generated by the air conditioner body, and the electrolysis device is used for electrolyzing the condensed water collected by the water storage component.

In one embodiment, the air conditioner body comprises an evaporator assembly, the electrolysis device comprises an oxygen pipe for circulating the condensed water to generate oxygen through electrolysis of the electrolysis device;

wherein the oxygen tube is connected to the evaporator assembly such that oxygen produced by electrolysis is discharged to an indoor environment via the evaporator assembly.

In one embodiment, the evaporator assembly includes an evaporator, a first header and a first fan, the first header being coupled between the first fan and the evaporator for directing air from the first fan toward the evaporator, the evaporator being coupled to an indoor environment;

wherein the oxygen pipe is communicated with the first flow collecting cover.

In one embodiment, the air conditioner body further comprises a condenser assembly, the electrolysis device further comprises a hydrogen pipe for circulating the condensed water to generate hydrogen through electrolysis of the electrolysis device;

wherein the hydrogen pipe is connected to the condenser assembly such that hydrogen generated by electrolysis is discharged to an outdoor environment through the condenser assembly.

In one embodiment, the condenser assembly includes a condenser, a second collection header connected between the second fan and the condenser for directing air from the condenser to the second fan, and a second fan connected to an outdoor environment;

wherein, the hydrogen pipe is communicated with the second collecting cover.

In one embodiment, the electrolysis device comprises an electrolysis bath, a cathode electrode, an anode electrode, a semi-permeable membrane, a hydrogen pipe and an oxygen pipe, wherein the electrolysis bath is communicated with the water storage component, the semi-permeable membrane separates the electrolysis bath to form a first space and a second space for only water molecules to flow in an interaction way, the cathode electrode is arranged in the first space, and the anode electrode is arranged in the second space;

the hydrogen pipe is communicated with the first space and the outside of the electrolytic cell, and the oxygen pipe is communicated with the second space and the outside of the electrolytic cell.

In one embodiment, the electrolysis apparatus further comprises a gas tank connected between the oxygen pipe and the second space.

In one embodiment, the cigarette machine body further comprises a conveying pipe and a water stop switch, the conveying pipe is connected with the water storage component and the electrolytic tank, and the water stop switch is arranged on the conveying pipe and used for switching on or off the conveying pipe.

In one embodiment, the cigarette machine body further comprises a first water level detection piece and a controller, wherein the first water level detection piece is used for detecting the water level of the electrolytic bath;

the controller is in communication connection with the first water level detection piece and the water stop switch and is used for controlling the water stop switch to be switched on or switched off the delivery pipe and controlling the electrolysis device to electrolyze water according to the water level of the electrolysis bath.

In one embodiment, the machine body further comprises a second water level detection member for detecting the water level of the water storage member;

the controller is in communication connection with the second water level detection piece and the air conditioner body and is used for controlling whether the electrolysis device electrolyzes water or not according to the water level of the water storage component when the air conditioner body stops refrigerating.

In one embodiment, the cigarette maker body comprises a machine shell, the top of the machine shell is provided with a top plate, and the air conditioner body is positioned above the top plate;

the roof is sunken to be formed with the water catch bowl towards the inside of casing, the water catch bowl has the inside and outside mouth that leaks of intercommunication casing, the water storage component is located in the casing, and is located the below of leaking the mouth.

According to the air-conditioning range hood, the condensed water generated by refrigeration of the air-conditioning body falls into the water storage component below under the action of gravity, and then hydrogen and oxygen are formed under the electrolysis of the electrolysis device, so that the treatment of the condensed water is realized. Compared with the prior art, utilize electrolytic device directly to form gaseous state material with the comdenstion water electrolysis, need not use the recovery vessel of any form, can reduce user's clearance number of times greatly, user uses experience to feel better.

Drawings

FIG. 1 is a schematic structural diagram of an air-conditioning range hood in an embodiment of the present application;

FIG. 2 is a schematic view of a portion of the structure of the air-conditioned range hood shown in FIG. 1;

FIG. 3 is another perspective view of the structure shown in FIG. 2;

FIG. 4 is a logic control diagram of an air conditioning range hood in an embodiment of the present application;

fig. 5 is a logic control diagram of an air-conditioning range hood in another embodiment of the application.

Description of reference numerals:

1000. an air conditioner body; 1100. an evaporator assembly; 1110. an evaporator; 1120. a first manifold cap;

1130. a first fan; 1200. a condenser assembly; 1210. a condenser; 1220. a second manifold cap;

1230. a second fan; 1300. a compressor;

2000. a cigarette machine body; 2100. a water storage member; 2200. an electrolysis device; 2210. an electrolytic cell; 2220. a cathode electrode; 2230. an anode electrode; 2240. a semi-permeable membrane; 2250. a hydrogen pipe; 2260. an oxygen tube; k1, first space; k2, second space; 2270. a gas storage tank; 2300. a housing; 2310. a top plate; 2311. a water collection tank; 2400. a delivery pipe; 2500. and a water stop switch.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present application more comprehensible, embodiments accompanying the present application are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. This application is capable of embodiments in many different forms than those described herein and that modifications may be made by one skilled in the art without departing from the spirit and scope of the application and it is therefore not intended to be limited to the specific embodiments disclosed below.

In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or to implicitly indicate the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present application, "plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral parts; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through intervening media. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

The air conditioner cigarette machine includes cigarette machine body and air conditioner body, and the cigarette machine body is used for realizing the smoke ventilator function, and the air conditioner body is used for adjusting the temperature of kitchen environment. The body of the range hood generally includes a casing, a smoke exhaust fan disposed in the casing, a smoke collecting hood, and an oil cup connected to the bottom of the casing. The shell is provided with an oil smoke inlet and an oil smoke outlet which are communicated with the inside and the outside of the shell. When the fume exhaust fan is started, negative pressure is formed in the machine shell, fume outside the machine shell enters the machine shell from a fume inlet under the action of the negative pressure and collides with the fume collecting cover, gas in the fume is separated from oil stains in an inertia mode, the oil stains are adhered to the fume collecting cover and flow to the oil cup along the fume collecting cover, and the gas is exhausted outdoors through the fume exhaust channel through the fume exhaust outlet. The air conditioner body comprises a shell, and a compressor, an evaporator, a condenser and the like which are arranged in the shell, wherein the compressor, the evaporator and the condenser form a refrigerant circulation loop, an air outlet communicated with a kitchen environment is formed in the shell, and airflow generated by the evaporator is discharged to the kitchen environment through the air outlet so as to realize temperature adjustment of the kitchen environment. The evaporimeter can produce the comdenstion water when the heat transfer, and the processing problem of air conditioner cigarette machine comdenstion water has been solved in this application.

Referring to fig. 1, an embodiment of the present application provides an air-conditioning range hood, which includes an air-conditioning body 1000 and a range hood body 2000. The cigarette machine body 2000 includes a water storage member 2100 and an electrolysis device 2200, the water storage member 2100 is located below the air conditioner body 1000 to collect the condensed water generated from the air conditioner body 1000, and the electrolysis device 2200 is used to electrolyze the condensed water collected through the water storage member 2100.

The electrolysis device 2200 is a device capable of electrolyzing condensed water to form hydrogen and oxygen, and the principle of the electrolysis device 2200 is common knowledge in the art and will not be described herein. The electrolytic apparatus 2200 is a component commonly used in the art, and its specific configuration is not limited herein.

The water storage member 2100 may be a water storage cup, a water storage tank, a water storage box, etc., which is located below the air conditioner body 1000 and collects condensed water falling down on the air conditioner assembly under the action of gravity. Preferably, the water storage member 2100 is located at least below the evaporator 1110, and since the evaporator 1110 is a main component generating condensed water when the air conditioner body 1000 is cooled, the water storage member 2100 is disposed below the evaporator 1110 to meet the requirement of collecting condensed water. Of course, the water storage member 2100 may be located below the condenser 1210, and under the working conditions of defrosting the air conditioner body 1000, the condenser 1210 may generate condensed water, or when the fan blows the condensed water generated by the evaporator 1110 to the condenser 1210 to cool the condenser 1210, the condensed water may fall from the condenser 1210, so that the water storage member 2100 can collect the part of the condensed water falling from the condenser 1210.

In the above air-conditioning cigarette machine, the condensed water generated by the refrigeration of the air-conditioning body 1000 falls into the water storage member 2100 below under the action of gravity, and then hydrogen and oxygen are formed under the electrolysis of the electrolysis device 2200, so that the treatment of the condensed water is realized. Compared with the prior art, utilize electrolytic device 2200 directly to form gaseous state material with the electrolysis of comdenstion water, need not use the recovery vessel of any form, can reduce user's clearance number of times greatly, user uses experience and feels better.

In some embodiments of the present application, referring to fig. 1, the air conditioner body 1000 includes an evaporator assembly 1100, and the electrolysis device 2200 includes an oxygen pipe 2260 for circulating oxygen generated by electrolysis of condensed water through the electrolysis device 2200, wherein the oxygen pipe 2260 is connected to the evaporator assembly 1100, so that the oxygen generated by electrolysis is discharged to an indoor environment through the evaporator assembly 1100.

The air-conditioning smoke machine is usually installed in a kitchen or other indoor environment with a small space for use, and can consume the oxygen content in the indoor environment in the use process, and can cause the reduction of the combustion efficiency of the gas stove in serious cases. When the air conditioner 1000 in the air conditioner range hood is refrigerating, the evaporator assembly 1100 discharges the refrigerating gas into the room.

At this time, the oxygen electrolyzed by the electrolysis device 2200 is transported by the oxygen hose 2260 and discharged to the indoor environment through the evaporator assembly 1100, so that the oxygen content of the indoor environment can be increased, and the negative oxygen ions generated by electrolysis are beneficial to the health of the user.

In particular, and with continued reference to fig. 1, the evaporator assembly 1100 includes an evaporator 1110, a first manifold 1120, and a first fan 1130, the first manifold 1120 coupled between the first fan 1130 and the evaporator 1110 for directing air from the first fan 1130 to the evaporator 1110, the evaporator 1110 coupled to an indoor environment. Wherein, the oxygen pipe 2260 is connected to the first flow collecting hood 1120.

The first collecting cover 1120 has a flow guiding channel, one end of the first collecting cover 1120 extends to the evaporator 1110, the other end of the first collecting cover is connected with the first fan 1130, when the first fan 1130 is started, indoor air is enabled to enter the air conditioner body 1000, then the indoor air passes through the first collecting cover 1120, enters the flow guiding channel of the first collecting cover 1120, then flows through the evaporator 1110, exchanges heat with the evaporator 1110 to be refrigerated, and then flows back to the indoor, so that the indoor environment temperature is improved.

At this time, the oxygen pipe 2260 is communicated to the first collecting cover 1120, under the action of the first fan 1130, oxygen in the oxygen pipe 2260 is accelerated to flow into the first collecting cover 1120, and then is exhausted to the indoor environment through the evaporator 1110, and at this time, the oxygen is also refrigerated by the evaporator 1110 when being exhausted to the indoor environment, which is beneficial to ensuring the temperature balance of the refrigerating gas exhausted to the indoor environment through the air conditioner body 1000.

"evaporator 1110 is connected to the indoor environment" means that air flows through the evaporator 1110 to the indoor environment.

Specifically, the first fan 1130 includes a first volute and a first impeller disposed in the first volute, the first manifold 1120 connects the first volute and the evaporator 1110, and when the first impeller rotates, pressure on two sides of the first volute is different, so that air flows from the first volute to the first manifold 1120 and then flows through the evaporator 1110.

Of course, in other embodiments, the oxygen hose 2260 may also be directly connected to the outside of the cigarette maker body 2000 and connected to the indoor environment, so as to increase the indoor oxygen content.

In some embodiments of the present application, referring to fig. 1, the air conditioner body 1000 further includes a condenser assembly 1200, the electrolysis device 2200 further includes a hydrogen pipe 2250 for circulating hydrogen generated by electrolysis of condensed water through the electrolysis device 2200, wherein the hydrogen pipe 2250 is connected to the condenser assembly 1200, such that the hydrogen generated by electrolysis is discharged to the outdoor environment through the condenser assembly 1200.

The condenser assembly 1200 of the air conditioning machine is installed to be generally communicated with a smoke exhaust duct for kitchen when being installed, and when the air conditioning machine is refrigerating, the condenser 1210 in the air conditioning body 1000 exchanges heat with ambient air and heats the ambient air, and the formed hot air is discharged to the outside through the smoke exhaust duct.

At this time, the hydrogen gas electrolyzed by the electrolysis device 2200 is discharged to the outdoor environment through the condenser assembly 1200 by the hydrogen pipe 2250, and the hydrogen gas is prevented from being discharged to the indoor environment, so that the explosion of the hydrogen gas due to the concentration increase in the kitchen fire environment can be prevented, and the personal safety can be threatened.

In particular embodiment, referring to fig. 1, the condenser assembly 1200 includes a condenser 1210, a second collection hood 1220 and a second fan 1230, the second collection hood 1220 is coupled between the second fan 1230 and the condenser 1210 for directing air from the condenser 1210 to the second fan 1230, and the second fan 1230 is coupled to the outdoor environment.

The second collecting cover 1220 has a flow guiding channel, one end of the second collecting cover 1220 extends to the condenser 1210, the other end of the second collecting cover is connected to the second fan 1230, when the second fan 1230 is started, indoor air enters the air conditioner body 1000, then exchanges heat with the condenser 1210 through the condenser 1210, then enters the flow guiding channel of the first collecting cover 1120, and then flows through the first collecting cover and is discharged to the outdoor environment.

At this time, the hydrogen pipe 2250 is connected to the second collecting hood 1220, and under the action of the second blower 1230, the hydrogen in the hydrogen pipe 2250 accelerates to flow into the second collecting hood 1220 and is discharged to the outdoor environment through the second blower 1230, so as to implement the treatment of the hydrogen.

The phrase "the second fan 1230 is connected to the outdoor environment" means that the air flows through the second fan 1230 and then flows to the outdoor environment, and specifically, the second fan 1230 is connected to the smoke exhaust duct.

Of course, in other embodiments, the hydrogen gas may also be vented to the outdoor environment through a conduit.

In some embodiments of the present application, referring to fig. 2 and 3, the electrolysis apparatus 2200 includes an electrolysis cell 2210, a cathode electrode 2220, an anode electrode 2230, a semi-permeable membrane 2240, a hydrogen pipe 2250 and an oxygen pipe 2260, wherein the electrolysis cell 2210 is communicated with the water storage member 2100, the semi-permeable membrane 2240 separates the electrolysis cell 2210 into a first space k1 and a second space k2 through which water molecules can flow alternately, the cathode electrode 2220 is disposed in the first space k1, and the anode electrode 2230 is disposed in the second space k 2. The hydrogen pipe 2250 communicates the first space k1 with the outside of the electrolytic bath 2210, and the oxygen pipe 2260 communicates the second space k2 with the outside of the electrolytic bath 2210.

After the condensed water is collected by the water storage member 2100, the condensed water enters the electrolytic cell 2210. When the electrolytic bath 2210 contains condensed water, the cathode electrode 2220 and the anode electrode 2230 are electrified to form an electrified loop with the condensed water. The cathode electrode 2220 electrolyzes the condensed water and forms hydrogen to be filled in the first space k1, the anode electrode 2230 electrolyzes the condensed water and forms oxygen to be filled in the second space k2, and due to the semi-permeable membrane 2240, the hydrogen in the first space k1 cannot enter the second space k2, and the oxygen in the second space k2 cannot enter the first space k1, so that the split flow of the hydrogen and the oxygen is realized.

The hydrogen gas in the first space k1 is transported to the outside of the electrolyzer 2210, for example, at the condenser assembly 1200 mentioned in the above-described embodiment, via the hydrogen pipe 2250, and finally discharged to the outside. The oxygen in the second space k2 is delivered to the outside of the electrolytic cell 2210, for example, the evaporator assembly 1100 mentioned in the above embodiment, via the oxygen pipe 2260, and finally discharged to the room.

The semi-permeable membrane 2240 is an ion separation membrane that allows only water to pass through but does not allow gas to pass through, and is a common component in the art and will not be described herein.

In this embodiment, since the electrolyzer 2200 itself is provided with the electrolyzer 2210, the electrolyzer 2210 needs to have a certain sealing property (gas is supplied to the outside only through the hydrogen pipe 2250 and the oxygen pipe 2260), and thus the arrangement of the water storage member 2100 is more flexible and the electrolysis cost can be reduced, compared to the case where the cathode electrode 2220, the anode electrode 2230, the semi-diaphragm, and the like are directly provided in the water storage member 2100.

Preferably, referring to fig. 1, the electrolyzer 2210 is positioned below the water storage member 2100. Thus, the condensed water in the water storage member 2100 can flow into the electrolytic cell 2210 under the action of its own weight, thereby avoiding additional power devices, reducing the equipment cost, and having a simpler structure.

In a further embodiment, referring to fig. 1, the electrolysis apparatus 2200 further comprises a gas tank 2270, wherein the gas tank 2270 is connected between the oxygen pipe 2260 and the second space k 2.

Understandably, the air storage tank 2270 has a space for storing air, and the orifice diameter of the oxygen tube 2260 is far smaller than the second space k2 and the size of the space in the air storage tank. The air storage tank 2270 can relieve the pressure applied to the nozzle of the oxygen hose 2260 (close to the nozzle of the second space k2) by the too fast flow rate when the oxygen enters the oxygen hose 2260 from the second space k2, and release the pressure and reduce the flow rate when the oxygen enters the air storage tank from the second space k2, thereby helping to ensure the normal flow of the oxygen in the oxygen hose 2260 and protecting the oxygen hose 2260 to a certain extent.

In some embodiments of the present application, referring to fig. 1, the cigarette making machine body 2000 further includes a delivery pipe 2400 and a water stop switch 2500, the delivery pipe 2400 is connected to the water storage member 2100 and the electrolytic cell 2210, and the water stop switch 2500 is disposed on the delivery pipe 2400 for conducting the medium delivery pipe 2400.

When the water stop switch 2500 turns on the delivery pipe 2400, the condensed water in the water storage member 2100 can enter the electrolyzer 2210 through the delivery pipe 2400, and when the water stop switch 2500 turns off the delivery pipe 2400, the condensed water in the water storage member 2100 cannot enter the electrolyzer 2210 through the delivery pipe 2400.

In actual operation, the water-stop switch 2500 can be used to control the amount of condensed water entering the water storage member 2100 into the electrolyzer 2210, so as to prevent the water storage member 2100 from continuously draining condensed water into the electrolyzer 2210 when the condensed water in the electrolyzer 2210 overflows, or when the cathode electrode 2220 and the anode electrode 2230 cannot be normally energized, or when the cathode electrode 2220 and the anode electrode 2230 cannot normally electrolyze the condensed water, thereby causing the water level of the condensed water in the electrolyzer 2210 to be too high or overflow, and causing damage to the electrolyzer 2200.

The water stop switch 2500 may be a water stop valve member, and the specific shape is not limited herein as long as the on state of the delivery pipe 2400 can be controlled.

In particular embodiments, the cigarette maker body 2000 further comprises a first water level detector (not shown) for detecting the water level of the electrolyzer 2210, and a controller (not shown). The controller is connected to the first water level detector and the water stop switch 2500 in a communication manner, and is used for controlling the water stop switch 2500 to turn on or off the delivery pipe 2400 and controlling the electrolysis device 2200 to electrolyze water according to the water level of the electrolysis bath 2210.

The first water level detecting member may be a float assembly, an ultrasonic level sensor, an infrared level sensor, etc., and the specific type is not limited thereto.

At this time, the controller controls the operation of the water stop switch 2500 by obtaining the water level of the electrolytic cell 2210, so that condensed water with an appropriate capacity is available in the electrolytic cell 2210, which helps to ensure the normal operation of the electrolysis apparatus 2200 and to prevent the overflow of the electrolytic cell 2210. Meanwhile, controlling the electrolyzer 2200 to electrolyze water according to the water level of the electrolyzer 2210 can avoid damage to the apparatus caused by the electrolyzer 2200 still electrolyzing water under the condition that the water level of the electrolyzer 2210 is insufficient.

Wherein, controlling whether the electrolysis apparatus 2200 electrolyzes water can be controlled by controlling whether the anode electrode 2230 and the cathode electrode 2220 are electrified. Electrolyzer 2200 can be used to electrolyze water when anode electrode 2230 and cathode electrode 2220 are energized, and cannot electrolyze water when not energized.

Referring to fig. 4, a control logic diagram of an air-conditioning range hood in an embodiment is shown. In this embodiment, the electrolyzer 2210 has a minimum level A, a maximum level C, and a reference level B, where the B level is between the A level and the C level. When the water level of the electrolytic cell 2210 is higher than the C liquid level, it indicates that the condensed water of the electrolytic cell 2210 is excessive and overflows quickly. When the water level of the electrolytic cell 2210 is lower than the A liquid level, it is indicated that the condensed water in the electrolytic cell 2210 is insufficient.

The control logic of the air-conditioning range hood is as follows: starting the air conditioner body 1000 for refrigeration, starting the electrolysis device 2200, and obtaining the water level of the electrolysis bath 2210; and judging whether the water level of the electrolytic cell 2210 is higher than the C liquid level.

If the water level is higher than the C liquid level, the water stop switch 2500 is turned off (the water storage member 2100 stops injecting water into the electrolytic cell 2210 to prevent the electrolytic cell 2210 from overflowing), whether the water level of the electrolytic tank is lower than the B liquid level is continuously judged, if the water level is lower than the B liquid level (which indicates that condensed water in the electrolytic cell 2210 is quickly consumed by electrolysis and needs to be supplemented with water), the water stop switch 2500 is turned on, and the execution is returned to: and judging whether the water level of the electrolytic cell 2210 is higher than the C liquid level.

If not, the electrolysis device continues to operate and judges whether the water level of the electrolysis bath is lower than the liquid level A, if not, the execution is returned: and judging whether the water level of the electrolytic cell 2210 is higher than the C liquid level. If the water level is lower than the A liquid level (preventing the water level of the electrolytic cell 2210 from being too low to influence the operation of the device), controlling the electrolytic device to stop operating; and continuously judging whether the water level of the electrolytic water tank is higher than the liquid level B, if so, returning to execute: judging whether the water level of the electrolytic cell 2210 is higher than the liquid level C, and then judging according to the logic mode of the liquid level C; if the water level is not higher than the B liquid level, the electrolysis device is maintained to stop running.

In some embodiments of the present application, the cigarette machine body 2000 further comprises a second water level detector (not shown) for detecting the water level of the water storage member 2100. The controller is in communication connection with the second water level detector and the air conditioner body 1000, and is configured to control whether the electrolysis device 2200 electrolyzes water according to the water level of the water storage member 2100 when the air conditioner body 1000 stops cooling.

The second water level detecting member may be a float assembly, an ultrasonic level sensor, an infrared level sensor, etc., and the specific type is not limited thereto.

At this time, the controller controls whether or not the electrolysis device 2200 electrolyzes water by acquiring the water level of the water storage member when the air conditioner main body 1000 stops cooling, and can shut down the electrolysis device 2200 when the water amount in the water storage member 2100 is too small when the air conditioner main body 1000 stops cooling, thereby preventing the device from being damaged.

Referring to fig. 5, a logic control diagram of an air conditioning range hood in an embodiment is shown. In this embodiment, the water storage member 2100 has a minimum liquid level D, and its control logic is: when the air conditioner body 1000 stops cooling, the water level of the water storage member 2100 is acquired; and judging whether the water level of the water storage member 2100 is higher than the liquid level D, if not, closing the electrolysis device 2200, and if so, continuing to operate the electrolysis device 2200. In this case, the normal operation of the electrolysis apparatus can be prevented from being affected by a small amount of water in the water storage member 2100.

In some embodiments of the present application, referring to fig. 1, the cigarette maker body 2000 includes a housing 2300, the top of the housing 2300 has a top plate 2310, the air conditioner body 1000 is located above the top plate 2310, the top plate 2310 is recessed towards the inside of the housing 2300 to form a water collection groove 2311, the water collection groove 2311 has a water drain opening communicating the inside and the outside of the housing 2300, and the water storage member 2100 is located inside the housing 2300 and below the water drain opening.

In actual operation, a water collecting groove 2311 is formed in the top plate 2310, water dropping from the air conditioner body 1000 is collected by the water collecting groove 2311, and the water directly enters the water storage member 2100 through a water leakage port after entering the water collecting groove 2311. At this moment, the condensed water is collected through the water collecting groove 2311 processed on the top plate 2310, the water collecting structure does not need to be additionally arranged, the structure is simpler, the structure of the air-conditioning range hood is simplified, and the cost is low.

The top plate 2310 is a plate located at the top of the housing 2300. The specific configuration of the housing 2300 is not limited in this application and reference may be made to the existing configuration.

In the embodiment, the condenser 1210 and the evaporator 1110 of the air conditioner body 1000 are projected on the ceiling 2310 at both sides of the drain port. At the moment, the condenser 1210 and the evaporator 1110 are respectively positioned at two sides of the water leakage port, namely, the condenser 1210 and the evaporator 1110 are adjacently arranged at two sides of the top plate 2310, the whole structure of the air-conditioning range hood is compact, the water flow path of water dropping from the condenser 1210 and the evaporator 1110 through the water leakage port is short, the processing length of the water collecting groove 2311 can be reduced, and the process is simplified.

Of course, the arrangement of the condenser 1210 and the evaporator 1110 is not limited to the above arrangement, and may be such as that the drain port is located directly below the evaporator 1110, or is arranged close to the position corresponding to the condenser 1210.

Further, with continued reference to fig. 1, the ends of the sump 2311 below the condenser 1210 and the evaporator 1110 extend obliquely downward to the drain openings, respectively. At this time, the water collection groove 2311 is a V-shaped groove, and the water leakage port is located at the lowest position of the water collection groove 2311, so that the flowing speed of water entering two ends of the water collection groove 2311 towards the water leakage port can be increased, and the collection of condensed water is increased.

The application provides an air conditioner cigarette machine, the comdenstion water that air conditioner body 1000 refrigeration produced drops under the action of gravity in water storage component 2100 in the below, then forms hydrogen and oxygen under electrolysis of electrolytic device 2200, has so realized the processing of comdenstion water. Compared with the prior art, utilize electrolytic device 2200 directly to form gaseous state material with the electrolysis of comdenstion water, need not use the recovery vessel of any form, can reduce user's clearance number of times greatly, user uses experience and feels better.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the claims. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (11)

1. An air conditioner cigarette machine, its characterized in that includes:

an air conditioner body (1000); and

the cigarette machine body (2000) comprises a water storage component (2100) and an electrolysis device (2200), wherein the water storage component (2100) is located below the air conditioner body (1000) and used for collecting condensed water generated by the air conditioner body (1000), and the electrolysis device (2200) is used for electrolyzing the condensed water collected by the water storage component (2100).

2. The machine as claimed in claim 1, wherein the air conditioning body (1000) comprises an evaporator assembly (1100), the electrolysis device (2200) comprises an oxygen tube (2260) for generating oxygen by electrolysis of the condensed water via the electrolysis device (2200) by circulating the condensed water;

wherein the oxygen tube (2260) is connected to the evaporator assembly (1100) such that oxygen generated by electrolysis is discharged to an indoor environment via the evaporator assembly (1100).

3. The machine as claimed in claim 2 wherein said evaporator assembly (1100) includes an evaporator (1110), a first manifold (1120) and a first fan (1130), said first manifold (1120) connected between said first fan (1130) and said evaporator (1110) for directing air from said first fan (1130) to said evaporator (1110), said evaporator (1110) communicating to an indoor environment;

wherein the oxygen pipe (2260) is communicated with the first flow collecting cover (1120).

4. The machine as claimed in claim 1, wherein the air-conditioning body (1000) further comprises a condenser assembly (1200), the electrolysis device (2200) further comprises a hydrogen pipe (2250) for generating hydrogen by electrolyzing the condensed water through the electrolysis device (2200);

wherein the hydrogen pipe (2250) is connected to the condenser assembly (1200) such that the electrolytically generated hydrogen is discharged to the outdoor environment via the condenser assembly (1200).

5. The range hood as defined in claim 4 wherein said condenser assembly (1200) includes a condenser (1210), a second collection hood (1220) and a second fan (1230), said second collection hood (1220) connected between said second fan (1230) and said condenser (1210) for directing air flow from said condenser (1210) to said second fan (1230), said second fan (1230) being connected to an outdoor environment;

wherein the hydrogen pipe (2250) communicates with the second manifold cap (1220).

6. The machine as claimed in claim 1, wherein the electrolyzer (2200) comprises an electrolyzer (2210), a cathode electrode (2220), an anode electrode (2230), a semi-permeable membrane (2240), a hydrogen pipe (2250) and an oxygen pipe (2260), the electrolyzer (2210) is communicated with the water storage member (2100), the semi-permeable membrane (2240) separates the electrolyzer (2210) into a first space (k1) and a second space (k2) for water molecules to flow in a mutual way, the cathode electrode (2220) is disposed in the first space (k1), and the anode electrode (2230) is disposed in the second space (k 2);

the hydrogen pipe (2250) communicates the first space (k1) and the outside of the electrolytic bath (2210), and the oxygen pipe (2260) communicates the second space (k2) and the outside of the electrolytic bath (2210).

7. The machine as claimed in claim 6, wherein the electrolysis means (2200) further comprises a gas tank (2270), the gas tank (2270) being connected between the oxygen tube (2260) and the second space (k 2).

8. The machine as claimed in claim 6, wherein the machine body (2000) further comprises a delivery pipe (2400) and a water stop switch (2500), the delivery pipe (2400) connects the water storage member (2100) and the electrolyzer (2210), the water stop switch (2500) is provided on the delivery pipe (2400) for turning on or off the delivery pipe (2400).

9. The machine as claimed in claim 8, characterized in that said machine body (2000) further comprises a first water level detecting member for detecting the water level of said electrolyzer (2210) and a controller;

the controller is in communication connection with the first water level detection piece and the water stop switch (2500) and is used for controlling the water stop switch (2500) to switch on or off the delivery pipe (2400) and controlling the electrolysis device (2200) to electrolyze water according to the water level of the electrolysis bath (2210).

10. The air conditioning machine as recited in claim 9, wherein said machine body (2000) further comprises a second water level detecting member for detecting a water level of said water storage member (2100);

the controller is in communication connection with the second water level detection piece and the air conditioner body (1000) and is used for controlling whether the electrolysis device (2200) electrolyzes water according to the water level of the water storage component (2100) when the air conditioner body (1000) stops refrigerating.

11. The air conditioning machine as recited in claim 1, wherein said machine body (2000) comprises a cabinet (2300), said cabinet (2300) having a top panel (2310) on top, said air conditioning body (1000) being located above said top panel (2310);

the roof (2310) is sunken towards the inside of the machine shell (2300) to form a water collecting tank (2311), the water collecting tank (2311) is provided with a water leakage port communicated with the inside and the outside of the machine shell (2300), and the water storage component (2100) is positioned in the machine shell (2300) and below the water leakage port.

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