CN108413461B - Air conditioner smoke machine - Google Patents

Abstract

The invention discloses an air conditioner smoke machine, comprising: a fume assembly comprising a fume channel; an air conditioning assembly, the air conditioning assembly comprising: a condenser assembly; and the evaporator assembly is used for guiding condensed water generated by the evaporator assembly to the condenser assembly, and the condensed water is evaporated and then discharged along with the lampblack channel. According to the air conditioning smoke machine provided by the embodiment of the invention, condensed water can be eliminated, and the heat exchange efficiency of the condenser can be improved.

Description

Air conditioner smoke machine

Technical Field

The invention relates to the technical field of air-conditioning smoke machines, in particular to an air-conditioning smoke machine.

Background

Aiming at the problem of condensate water discharge in an air conditioning component of an air conditioning smoke machine, two solutions exist in the related art, wherein one solution is as follows: the condensed water is directly discharged out of the machine body through a pipeline; another scheme is as follows: through setting up atomizing subassembly to in with comdenstion water drainage to atomizing subassembly, become the water smoke by atomizing subassembly, atomizing subassembly links to each other with the subassembly of discharging fume, the water smoke discharges the organism through the subassembly of discharging fume. However, both the above solutions directly drain the condensed water, and do not utilize the cold carried by the condensed water, resulting in energy waste.

Disclosure of Invention

The present invention aims to solve at least one of the technical problems in the related art to some extent. Therefore, the invention provides the air conditioner smoke machine which can eliminate condensed water and can improve the heat exchange efficiency of the condenser.

According to an embodiment of the invention, an air conditioning smoke machine comprises: a fume assembly comprising a fume channel; an air conditioning assembly, the air conditioning assembly comprising: a condenser assembly; and the evaporator assembly is used for guiding condensed water generated by the evaporator assembly to the condenser assembly, and the condensed water is evaporated and then discharged along with the lampblack channel.

According to the air conditioning smoke machine provided by the embodiment of the invention, the condensed water generated by the evaporator assembly is evaporated and then discharged along with the oil smoke channel, so that the problem of condensed water accumulation in a machine body in the prior art is solved, the condensed water is eliminated, and the condensed water is guided to the condenser assembly, so that the condenser can be cooled by utilizing the cold quantity of the condensed water, the heat exchange efficiency of the condenser is improved, the energy consumption is reduced, and the refrigerating effect is improved.

And after the condensed water is evaporated to generate water vapor, the water vapor with high temperature can play a cleaning role in the oil smoke channel when being discharged into the oil smoke channel, so that the air conditioner smoke machine is convenient to clean.

According to one embodiment of the invention, the condenser assembly comprises a condensation air outlet which is communicated with the oil smoke channel, and the condensed water is discharged into the oil smoke channel through the condensation air outlet after being evaporated.

According to one embodiment of the invention, the evaporator assembly is higher than the condenser assembly.

According to one embodiment of the invention, the air conditioning ventilator further comprises a water guiding structure, via which the condensed water is guided to the condenser assembly.

According to one embodiment of the invention, the air conditioning unit further comprises a water storage tank arranged below the condenser assembly.

According to one embodiment of the invention, the air conditioning ventilator further comprises a water circulation device or a water suction device configured to direct fluid within the reservoir onto the condenser assembly.

According to an embodiment of the present invention, the water circulation device includes: a water spraying device or a water spraying device.

According to one embodiment of the invention, the water absorbing means comprises a water absorbing material.

According to one embodiment of the invention, the condenser assembly comprises a condensation air inlet and a condensation air outlet, the condensation air outlet is communicated with the oil smoke channel, and the condensation air inlet is independent from the oil smoke channel.

According to one embodiment of the present invention, the evaporator assembly and the condenser assembly are arranged in an up-down direction.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The foregoing and/or additional aspects and advantages of the invention will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

fig. 1 is a schematic structural view of an air conditioning assembly of an air conditioning cigarette machine according to an embodiment of the present invention;

fig. 2 is an exploded view of an air conditioning assembly of an air conditioning pack according to an embodiment of the present invention;

fig. 3 is an exploded view of an air conditioning assembly of an air conditioning pack according to an embodiment of the present invention;

fig. 4 is a cross-sectional view of an air conditioning assembly of an air conditioning tobacco machine according to an embodiment of the present invention;

fig. 5 is a cross-sectional view of an air conditioning assembly of an air conditioning tobacco machine according to an embodiment of the present invention;

Fig. 6 is a plan view showing a partial structure of an air conditioning assembly of an air conditioning tobacco machine according to an embodiment of the present invention;

fig. 7 is a cross-sectional view of an air conditioning assembly of an air conditioning tobacco machine in accordance with one embodiment of the present invention;

Fig. 8 is an enlarged view at a in fig. 7;

fig. 9 is a cross-sectional view of an air conditioning assembly of an air conditioning ventilator according to another embodiment of the present invention;

Fig. 10 is a cross-sectional view of an air conditioning assembly of an air conditioning tobacco machine in accordance with yet another embodiment of the present invention;

Fig. 11 is a schematic structural view of an air conditioner cigarette according to an embodiment of the present invention;

Fig. 12 is a schematic view of another angle structure of an air conditioner in accordance with an embodiment of the present invention;

fig. 13 is a partial structural schematic view of an air conditioner cigarette according to an embodiment of the present invention;

fig. 14 is a partial structural view of another angle of an air conditioner cigarette according to an embodiment of the present invention;

Fig. 15 is an exploded view of a condensing duct and oil smoke assembly of an air conditioning extractor, an air conditioning assembly, according to an embodiment of the present invention;

Fig. 16 is a schematic structural view of a smoke module of an air conditioner smoke machine according to an embodiment of the present invention;

fig. 17 is a schematic structural view of an air conditioning assembly of an air conditioning ventilator according to an embodiment of the present invention;

fig. 18 is a schematic view of an internal structure of a smoke module and an air conditioning module of an air conditioning smoke machine according to an embodiment of the present invention;

Fig. 19 is an exploded view of an air conditioning assembly of an air conditioning ventilator according to an embodiment of the present invention.

Reference numerals:

An air conditioning tobacco machine 100;

smoke box housing 10:

a fume housing 1; a fume chamber 11; a fume assembly 12; a smoke passage 121; a fume inlet 1211; a fume outlet 1212; a smoke ventilator 13; a fusion port 14; a check valve 15;

an air-conditioning case 2; an air conditioning chamber 21;

An air conditioning assembly 22;

An evaporator assembly 221; an evaporator 2211; an evaporation fan 2212; an evaporation air inlet 2213; a vapor outlet 2214; an air inlet grille 2215; an air deflector 2216;

a condenser assembly 222; a condenser 2221; a condensing fan 2222; a condensing inlet 2223; a condensation outlet 2224;

A water guiding structure 30;

A first water receiving tank 3; a drain port 31; a drain pipe 32;

a second water receiving tank 4; a drain structure (through hole) 41; a diversion trench 42;

a water storage tank 5; a water receiving portion 51; a first communication port 511;

a detection unit 52; a second communication port 521;

A baffle 53; an opening 531;

A buffer structure 54; bending tube 541; water penetration through holes 542; a bending plate 543; a spacing port 5431;

a water circulation device 6; a water-beating device 61; a motor 62;

a water level detection means 7;

A chassis 8;

a condensing duct 9; the fume collection hood 10.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

In the description of the present invention, it should be understood that the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present invention and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. In the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

An air conditioning tobacco machine 100 according to an embodiment of the present invention is described below with reference to fig. 1 to 19. As shown in fig. 1-19, an air conditioning extractor 100 according to an embodiment of the present invention includes an extractor hood assembly 12 and an air conditioning assembly 22.

The oil smoke assembly 12 can realize the functions of exhausting and sucking oil smoke, and the oil smoke assembly 12 comprises an oil smoke channel 121, for example, in the example shown in fig. 11, solid arrows in fig. 11 show the trend of air flow in the oil smoke channel 121, and oil smoke gas generated by a user during cooking flows in the oil smoke channel 121 along the direction shown by the arrows and is discharged outdoors.

In embodiments of the present invention, the air conditioning assembly 22 may perform air conditioning functions, which may include, for example, cooling, heating indoor air, increasing air flow rate, regulating air humidity, and the like. The particular functions that can be performed are determined by the particular configuration that air conditioning assembly 22 includes.

Air conditioning assembly 22 includes a condenser assembly 222 and an evaporator assembly 221.

Specifically, the condenser assembly 222 may include a condenser 2221, a condensation air inlet 2223, and a condensation air outlet 2224, wherein after air enters from the condensation air inlet 2223, heat exchange is performed with the condenser assembly 222, the condenser 2221 is condensed, the temperature of the air after heat exchange with the condenser 2221 may be increased, and the warmed air is discharged from the condensation air outlet 2224.

The evaporator assembly 221 includes an evaporator 2211, an evaporation air inlet 2213, and an evaporation air outlet 2214, the evaporator 2211 is arranged in a flow path from the evaporation air inlet 2213 to the evaporation air outlet 2214, air enters from the evaporation air inlet 2213 and exchanges heat with the evaporator 2211, condensation is performed on the evaporator 2211, the temperature of air after heat exchange with the evaporator 2211 may be reduced, cooled air is discharged from the evaporation air outlet 2214, and thus indoor refrigeration can be performed.

The condensed water generated by the evaporator assembly 221 is guided to the condenser assembly 222, and the condensed water is evaporated and discharged along with the oil smoke channel 121. It should be noted that, the "evaporation of condensed water" may be that the condensed water is evaporated after being heated by the condenser 2221, and the generated water vapor is guided into the oil smoke channel 121 to be discharged, or the condensed water may be directly evaporated in the air without being heated by the condenser 2221, and then is guided into the oil smoke channel 121 to be discharged.

According to the air conditioning ventilator 100 of the embodiment of the invention, the condensed water generated by the evaporator assembly 221 is evaporated and then discharged along with the oil smoke channel 121, so that the problem of condensed water accumulation in a machine body in the prior art is solved, the condensed water is eliminated, and the condensed water is guided to the condenser assembly 222, so that the condenser 2221 can be cooled by utilizing the cold energy of the condensed water, the heat exchange efficiency of the condenser 2221 is improved, the energy consumption is reduced, and the refrigerating effect is improved.

And after the condensed water is evaporated to generate water vapor, the water vapor with high temperature can play a cleaning role in the oil smoke channel 121 when being discharged into the oil smoke channel 121, so that the air conditioner smoke machine 100 is convenient to clean.

In some embodiments of the present invention, the condenser assembly 222 includes a condensation outlet 2224, the condensation outlet 2224 is in communication with the oil smoke channel 121, and the condensed water is evaporated and discharged into the oil smoke channel 121 through the condensation outlet 2224.

In the embodiment of the present invention, the condensation air outlet 2224 communicates with the oil smoke passageway 121, whereby the air discharged from the condensation air outlet 2224 is discharged to the outside through the oil smoke passageway 121. The condensed water is evaporated and then discharged into the oil smoke channel 121 through the condensed air outlet 2224.

That is, the oil smoke channel 121 according to the embodiment of the present invention can discharge three contents at the same time: cooking fume generated during cooking, high-temperature gas generated after heat exchange with the condenser 2221, and condensed water generated by the evaporator 2211. Therefore, according to the air conditioning ventilator 100 of the embodiment of the invention, the condensation air outlet 2224 is communicated with the oil smoke channel 121, so that hot air after heat exchange with the condenser 2221 can be discharged into the oil smoke channel 121 through the condensation air outlet 2224, and further heat generated by the condenser 2221 can be discharged by utilizing the oil smoke channel 121, so that heat generated by the condenser 2221 is prevented from being emitted to an indoor space, the refrigeration efficiency is ensured, and the comfort of a user is improved. In addition, because the high-temperature hot air is led into the oil smoke channel 121, the structure of the oil smoke assembly 12 can be operated at a higher temperature, and the upper grease of the oil smoke assembly 12 is heated and melted, so that the adhesion of the oil smoke on the internal structure of the oil smoke assembly is effectively reduced, the internal hot air cleaning function of the oil smoke assembly 12 is realized, and the user experience is improved. And the fume exhaust and the air conditioner exhaust of the air conditioner smoke machine 100 are discharged together after being collected, a heat dissipation pipeline is not required to be additionally cut, the assembly is quick and convenient, and the product assembly space is saved.

In an embodiment of the present invention, evaporator assembly 221 is taller than condenser assembly 222. Wherein, alternatively, the evaporator assembly 221 may be located directly above the condenser assembly 222, or the evaporator assembly 221 may be located obliquely above the condenser assembly 222, or a portion of the evaporator assembly 221 may be located directly above or obliquely above the condenser assembly 222. So long as the topmost position of the evaporator unit 221 is higher than the topmost position of the condenser unit 222, the condensate water produced by the evaporator unit 221 can be advantageously guided to the condenser unit 222 by the action of gravity.

It should be noted that "the evaporator assembly 221 is higher than the condenser assembly 222" herein means that the evaporator 2211 is higher than the condenser 2221, i.e., the topmost position of the evaporator 2211 is higher than the topmost position of the condenser 2221.

In the embodiment of the present invention, alternatively, when the evaporator 2211 and the condenser 2221 are arranged in the vertical direction, the condensed water may directly drop on the surface of the condenser 2221 by gravity for evaporation; when the evaporator 2211 and the condenser 2221 are arranged in a staggered manner in the up-down direction, condensed water can be guided to the condenser 2221 by providing a guide structure.

In one embodiment of the present invention, the air conditioner 100 further includes a water guide structure 30, and condensed water is guided to the condenser assembly 222 through the water guide structure 30. By providing the water guide structure 30, condensed water can be conveniently guided to the condenser 2221, and the positional arrangement of the evaporator 2211 and the condenser 2221 can be more flexible.

In some embodiments of the present invention, the water guiding structure 30 may include: a first water receiving tank 3 and a second water receiving tank 4.

The first water receiving tank 3 is disposed below the evaporator 2211 to collect condensed water on the evaporator 2211, the second water receiving tank 4 is disposed above the condenser 2221 and is communicated with the first water receiving tank 3, for example, as shown in fig. 1 to 5, the second water receiving tank 4 and the first water receiving tank 3 are communicated through a drain pipe 32, specifically, a drain port 31 is provided on the first water receiving tank 3, the drain pipe 32 is disposed between the first water receiving tank 3 and the second water receiving tank 4, an upper end of the drain pipe 32 is connected with the drain port 31, and a lower end of the drain pipe 32 extends into the second water receiving tank 4, thereby allowing condensed water collected in the first water receiving tank 3 to flow into the second water receiving tank 4.

The second water receiving tank 4 is provided with a drainage structure 41 to guide water in the second water receiving tank 4 to the surface of the condenser 2221 to exchange heat with the condenser 2221, at least a part of condensed water is heated and vaporized by the condenser 2221, and unvaporized condensed water flows down along the surface of the condenser 2221.

In one embodiment of the present invention, referring to fig. 6, the drain structure 41 is a through hole 41 formed on the bottom wall of the second water receiving tank 4, and condensed water in the second water receiving tank 4 flows to the surface of the condenser 2221 through the through hole 41, and the drain structure 41 is simple and convenient to manufacture. Referring to fig. 6, the drain structure 41 includes a plurality of through holes 41, and the plurality of through holes 41 are divided into two groups disposed at intervals in a lateral direction (front-rear direction as shown in fig. 6), each group including a plurality of through holes 41 disposed at intervals in sequence in a longitudinal direction (left-right direction as shown in fig. 6), thereby allowing water in the second water receiving tank 4 to be uniformly guided to the surface of the condenser 2221, making contact between the condensed water and the condenser 2221 more sufficient, making full use of the cold in the condensed water, and further improving the heat exchange efficiency of the condenser 2221. Preferably, referring to fig. 6, a diversion trench 42 is provided on the bottom wall of the second water receiving tank 4 to direct the water in the second water receiving tank 4 towards the through hole 41, so that the second water receiving tank 4 drains more smoothly, and better heat exchange between the condensed water and the condenser 2221 is ensured.

Of course, the present invention is not limited thereto, and the water drain structure 41 may be a water pump (not shown), wherein a water inlet of the water pump is communicated with the second water receiving tank 4, a water outlet of the water pump is opposite to the condenser 2221, and water in the second water receiving tank 4 is directly sprayed onto the condenser 2221 by the water pump.

In some embodiments of the present invention, the air conditioner 100 may further include a water storage tank 5, where the water storage tank 5 is disposed below the condenser 2221, and the water storage tank 5 may collect water flowing down from the surface of the condenser 2221 (i.e., the unvaporized condensed water). Wherein the reservoir 5 may be secured to the chassis 8 of the air conditioning assembly 22.

Optionally, in an embodiment of the present invention, the air conditioner flue 100 further comprises a water circulation device 6, the water circulation device 6 is configured to guide the fluid in the water storage tank 5 onto the condenser assembly 222, i.e. the condensed water can be guided to the surface of the condenser 2221, so that the unvaporized condensed water exchanges heat with the condenser 2221 again, and the condenser 2221 vaporizes the unvaporized condensed water again.

According to the air conditioning ventilator 100 of the embodiment of the invention, the cooling capacity of the condenser 2221 is utilized to improve the heat dissipation efficiency of the condenser 2221 by guiding the condensed water to the surface of the condenser 2221 to exchange heat with the condenser 2221, and the water circulation device 6 is arranged to circulate and guide the unevaporated condensed water to the surface of the condenser 2221 so as to fully utilize the cooling capacity of the condensed water.

In one embodiment of the present invention, referring to fig. 4, 5 and 7, the water circulation device 6 includes a water-taking device 61.

Wherein optionally, in order to drive the water pumping device to pump water, the air-conditioning smoke machine 100 further comprises a motor 62 for driving the water pumping device 61 to rotate, the water pumping device 61 is arranged in the water storage tank 5 to throw water in the water storage tank 5 to the surface of the condenser 2221, specifically, the motor 62 drives the water pumping device 61 to rotate, and the water in the water storage tank 5 is thrown to the surface of the condenser 2221 by utilizing centrifugal force, so that unvaporized condensed water exchanges heat with the condenser 2221 again, and the cold energy of the condensed water is fully utilized. Preferably, the rotation shaft of the water drawing device 61 is disposed adjacent to one side (left side as shown in fig. 5) of the condenser 2221, thereby making a contact area between the condensed water and the condenser 2221 larger, further improving heat exchange efficiency. Referring to fig. 4, when the condensers 2221 are the plural rows of condensers 2221, the water drawing device 61 is provided between the adjacent two rows of condensers 2221, thereby not only making contact between the condensed water and the condensers 2221 more sufficient, but also avoiding splashing of the condensed water.

It will be appreciated that in order to ensure that the water dispenser 61 works properly, the water dispenser 61 needs to be spaced from the bottom wall of the water storage tank 5, i.e. a certain gap needs to be reserved between the water dispenser 61 and the bottom wall of the water storage tank 5, so that when the water level of the condensed water in the water storage tank 5 is low, the water dispenser 61 cannot contact the condensed water in the water storage tank 5, i.e. when the water level of the condensed water in the water storage tank 5 is low, the water dispenser 61 has a problem that the condensed water cannot be pumped onto the condenser 2221.

In order to solve the above problems, in a preferred embodiment of the present invention, the bottom wall of the water storage tank 5 is extended to be inclined downward in a direction toward the water pumping device 61, and referring to fig. 5, the water pumping device 61 is provided at the left side of the water storage tank 5, and the bottom wall of the water storage tank 5 is extended to be inclined downward in a direction from right to left, thereby allowing condensed water in the water storage tank 5 to be collected at the water pumping device 61, and ensuring that the water pumping device 61 pumps water normally when the water level in the water storage tank 5 is not high.

In another embodiment of the present invention, the water circulation device 6 is a water pump (not shown), wherein a water inlet of the water pump is connected to the water storage tank 5, and a water outlet of the water pump is connected to the second water receiving tank 4. Therefore, the unvaporized condensate water in the water storage tank 5 can be pumped into the second water receiving tank 4 through the water pump, and the unvaporized condensate water is guided to the surface of the condenser 2221 again through the water discharging structure 41 of the second water receiving tank 4, so that the unvaporized condensate water exchanges heat with the condenser 2221 again, and the cold energy of the condensate water is fully utilized.

In still another embodiment of the present invention, the water circulation device 6 is a water pump (not shown), a water inlet of the water pump is connected to the water storage tank 5, a water outlet of the water pump is opposite to the condenser 2221 to spray water toward the condenser 2221, that is, the unvaporized condensed water in the water storage tank 5 is directly sprayed to the surface of the condenser 2221 by the water pump, so that the unvaporized condensed water exchanges heat with the condenser 2221 again, and the cold energy of the condensed water is fully utilized.

In yet another embodiment of the present invention, the water circulation means 6 may also be water spraying means (not shown) for spraying the fluid in the reservoir onto the surface of the condenser 2221. Therefore, by arranging the water spraying device, water can be guided to the surface of the condenser 2221 in a more dispersed state, so that the heat dissipation of the condenser 2221 can be more uniform, and the heat dissipation effect is good.

In some embodiments of the present invention, the air conditioner 100 may further include a water absorbing device configured to direct fluid within the reservoir onto the condenser assembly 222. Alternatively, the absorbent means comprises absorbent material, such as absorbent cotton, absorbent paper, or the like. Therefore, mechanical and electronic structure arrangement can be reduced, and the cost is reduced.

Alternatively, in a specific example of the present invention, the water absorbing device may include a sponge water absorbing strip (not shown), wherein the sponge water absorbing strip is attached to the surface of the condenser 2221, and one end of the sponge water absorbing strip extends into the water storage tank 5 to absorb water. Namely, the unvaporized condensate water is drained to the surface of the condenser 2221 again by utilizing the sponge water absorbing strips, so that the unvaporized condensate water exchanges heat with the condenser 2221 again, and the cold energy of the condensate water is fully utilized. The water circulation device 6 has simple structure and low cost.

In one embodiment of the present invention, referring to fig. 1 to 10, a water level detection device 7 is provided in the water storage tank 5 to detect the water level in the water storage tank 5, when the water level in the water storage tank 5 reaches the first water level, it is indicated that the vaporization efficiency of the condensed water is low, and at this time, the temperature of the condenser 2221, that is, the temperature of the Gao Lengning is raised 2221, so that the surface temperature of the condenser 2221 is raised, thereby accelerating the vaporization efficiency of the condensed water, thereby not only fully utilizing the cold amount of the condensed water, saving energy, but also avoiding the residual excessive condensed water to need to manually drain the condensed water; when the water level in the water storage tank 5 reaches the second water level, the water circulation device 6 is abnormal, the air conditioning smoke machine 100 sends out warning at the moment, the air conditioning assembly 22 stops working, the air conditioning assembly 22 is overhauled, and therefore the safe operation of the whole machine can be guaranteed when the water circulation device 6 is abnormal. It should be noted that, the second water level is greater than the first water level, and the magnitudes of the first water level and the second water level may be measured according to the test, and the values of the first water level and the second water level may be different for different types of air conditioning smoke machines 100.

It will be appreciated that the water level in the reservoir 5 fluctuates significantly during operation of the water circulation means 6, particularly during operation of the water pumping means 61, thereby resulting in inaccurate water level detection in the reservoir 5.

In order to solve the above problems, in a preferred embodiment of the present invention, referring to fig. 7 to 10, the water storage tank 5 includes a water receiving part 51 and a detecting part 52, the water receiving part 51 is positioned below the condenser 2221 to receive unvaporized condensed water flowing down from the condenser 2221, and the water circulating device 6 is coupled with the water receiving part 51 to circulate unvaporized condensed water in the water receiving part 51 to the surface of the condenser 2221 to exchange heat again with the condenser 2221. The water level detection device 7 is arranged in the detection part 52 to detect the water level in the detection part 52, the bottom walls of the water receiving part 51 and the detection part 52 are positioned at the same level, and the water receiving part 51 and the detection part 52 are communicated through the buffer structure 54 to reduce the fluctuation of the water level in the detection part 52. Accordingly, the condensed water in the water receiving portion 51 flows into the detecting portion 52 through the buffer structure 54, and since the bottom walls of the water receiving portion 51 and the detecting portion 52 are positioned at the same level, the water surface heights in the water receiving portion 51 and the detecting portion 52 are the same, and the water level in the detecting portion 52 detected by the water level detecting device 7 is the water level in the water receiving portion 51, and since the water receiving portion 51 and the detecting portion 52 are communicated through the buffer structure 54, the influence of the water surface fluctuation in the water receiving portion 51 on the water surface in the detecting portion 52 can be reduced, and the detection accuracy of the water level detecting device 7 can be improved.

In one example of the present invention, referring to fig. 1 to 8 and 10, the water receiving portion 51 and the detecting portion 52 are integrally formed, the water receiving portion 51 and the detecting portion 52 are separated by the baffle 53, that is, one side (left side as shown in fig. 1 to 8) of the baffle 53 is the detecting portion 52, the other side (right side as shown in fig. 1 to 8) of the baffle 53 is the water receiving portion 51, the baffle 53 is provided with a through opening 531, the buffer structure 54 is a bending plate 543 provided in the water receiving portion 51, the bending plate 543 is provided adjacent to the opening 531, one end of the bending plate 543 is in contact with an inner wall of the water receiving portion 51, a gap 5431 is formed between the other end of the bending plate 543 and the inner wall of the water receiving portion 51, and the water receiving portion 51 is sequentially communicated with the detecting portion 52 through the gap 5431 and the opening 531. The buffer structure 54 is simple, and the fluctuation of the water surface in the detection portion 52 is small.

In one example of the present invention, referring to fig. 10, the water receiving portion 51 and the detecting portion 52 are integrally formed, the water receiving portion 51 and the detecting portion 52 are partitioned by the baffle 53, that is, one side of the baffle 53 is the detecting portion 52, the other side of the baffle 53 is the water receiving portion 51, and the buffer structure 54 is a plurality of water penetration holes 542 formed on the baffle 53. The buffer structure 54 is simple, and the fluctuation of the water surface in the detection portion 52 is small.

In one example of the present invention, referring to fig. 9, the water receiving portion 51 and the detecting portion 52 are separated and spaced apart from each other, for example, the detecting portion 52 and the water receiving portion 51 shown in fig. 9 are spaced apart in a left-right direction, the buffer structure 54 is a bent pipe 541, both ends of the bent pipe 541 are respectively communicated with the water receiving portion 51 and the detecting portion 52, specifically, a first communicating port 511 is provided on the water receiving portion 51, a second communicating port 521 is provided on the detecting portion 52, one end of the bent pipe 541 is communicated with the first communicating port 511, and the other end of the bent pipe 541 is communicated with the second communicating port 521. The buffer structure 54 is simple, and the fluctuation of the water surface in the detection portion 52 is small. Alternatively, the bent tube 541 may be a U-shaped tube as shown in fig. 9.

Further, referring to fig. 9, a bending plate 543 is disposed in the water receiving portion 51, the bending plate 543 is disposed adjacent to the first communicating opening 511, one end of the bending plate 543 is connected to the inner wall of the water receiving portion 51, a spacing opening 5431 is formed between the other end of the bending plate 543 and the inner wall of the water receiving portion 51, the water receiving portion 51 is communicated with the detecting portion 52 through the spacing opening 5431, the first communicating opening 511, the bending tube 541 and the second communicating opening 521 in sequence, the bending plate 543 and the bending tube 541 perform a double buffering function, and fluctuation of the water surface in the detecting portion 52 is smaller.

Referring now to fig. 11-19, an air conditioning tobacco unit 100 according to an embodiment of the present invention is described.

Optionally, in the embodiment of the present invention, the condenser assembly 222 includes a condensation air inlet 2223 and a condensation air outlet 2224, the condensation air outlet 2224 is communicated with the oil smoke channel 121, and the condensation air inlet 2223 is independent from the oil smoke channel 121.

In the embodiment of the present invention, the condensation air outlet 2224 communicates with the oil smoke passageway 121, whereby the air discharged from the condensation air outlet 2224 is discharged to the outside through the oil smoke passageway 121.

It should be noted that, the independent condensation air inlet 2223 and the independent oil smoke channel 121 means that the air inlet of the oil smoke channel 121 and the air inlet of the condensation air inlet 2223 are independent, and do not affect each other, and do not cross, for example, the air inlet of the oil smoke channel 121 and the air inlet 2223 do not enter from the same direction of the air conditioner 100.

According to the air conditioning ventilator 100 of the embodiment of the invention, the condensation air inlet 2223 and the oil smoke channel 121 are independent, so that oil smoke can not enter the air conditioning assembly 22 from the condensation air inlet 2223, and thus, the oil smoke can not enter the air conditioning assembly 22 from the condensation air inlet 2223, and the air entering from the condensation air inlet 2223 is relatively clean, so that the structure in the air conditioning assembly 22 can be prevented from being polluted by the oil smoke, and the heat exchange effect of the condenser assembly 222 is ensured.

In addition, according to the air conditioning ventilator 100 of the embodiment of the invention, the air conditioning component 22 and the oil smoke component 12 are integrally arranged, so that the volume of a product can be reduced, the installation of the product is convenient, and the large damage to the home decoration is avoided.

In some embodiments of the present invention, the fume channel 121 includes a fume inlet 1211 and a fume outlet 1212, and the condensing air inlet 2223 is disposed spaced apart from the fume inlet 1211. For example, the oil smoke enters the oil smoke channel 121 from the bottom of the air conditioner 100, the condensation air inlet 2223 is not provided at the bottom of the air conditioner 100, and the condensation air inlet 2223 may be provided at the top or at the side of the air conditioner 100. This includes avoiding that oil smoke also enters into condensation air intake 2223 when entering into oil smoke passageway 121, can guarantee like this that the air inlet in the air conditioning unit 22 is relatively clean, and the heat transfer of air conditioning unit 22 has been guaranteed, improves user's use experience moreover.

As shown in fig. 11 and fig. 13-17, the air conditioner smoke machine 100 according to the embodiment of the invention comprises a smoke machine shell 10, an oil smoke cavity 11 and an air conditioner cavity 21 are defined in the smoke machine shell 10, a smoke component 12 is arranged in the smoke cavity 11, and an air conditioner component 22 is arranged in the air conditioner cavity 21. That is, the oil smoke assembly 12 and the air conditioning assembly 22 are respectively arranged in two independent cavities, thus facilitating the arrangement of the components of the oil smoke assembly 12 in the oil smoke cavity 11, facilitating the arrangement of the components of the condenser assembly 222 in the air conditioning cavity 21, and facilitating and compacting the structural arrangement. Moreover, the oil smoke assembly 12 and the air conditioning assembly 22 are arranged independently of each other, and are independently operated, so that the influence of the oil smoke assembly 12 and the air conditioning assembly 22 on each other during operation is avoided, and the service performance and the service life of the oil smoke assembly 12 and the air conditioning assembly 22 are ensured.

Wherein, at least a portion of the oil smoke channel 121 is defined in the oil smoke chamber 11, so that the air flow in the oil smoke chamber 11 and the air flow in the air conditioning chamber 21 are not interfered with each other, the occurrence of turbulence phenomenon is prevented, noise can be reduced, and the oil smoke in the oil smoke channel 121 can not flow into the air conditioning chamber 21, so that the problem that the oil smoke adheres to parts in the air conditioning chamber 21 can be reduced, the cleanness of the parts in the air conditioning chamber 21 is ensured, and the cleaning frequency of a user is reduced.

In one specific example of the present invention, as shown in fig. 11, a partition is provided in the hood housing 10, and the hood chamber 11 and the air conditioning chamber 21 are partitioned by the partition. That is, the oil smoke chamber 11 and the air conditioning chamber 21 are defined by the same housing, thereby improving the integrity of the air conditioning ventilator 100, improving the strength of the product, reducing the number of component parts of the oil smoke chamber 11 and the air conditioning chamber 21, avoiding leakage of the oil smoke chamber 11 and the air conditioning chamber 21, enhancing the gas tightness of the oil smoke chamber 11 and the air conditioning chamber 21, preventing hot gas from being emitted into the indoor environment, and improving the comfort of users.

Of course, the present invention is not limited thereto, and as shown in fig. 13-17, in another specific example of the present invention, the range hood housing 10 includes a range hood housing 1 and an air conditioner housing 2, wherein the range hood housing 1 defines a range hood chamber 11 therein, the air conditioner housing 2 defines an air conditioner chamber 21 therein, and the air conditioner housing 2 is arranged side by side with the range hood housing 1. That is, the oil smoke chamber 11 and the air conditioning chamber 21 are respectively defined by different housings, so that the oil smoke housing 1 and the oil smoke assembly 12 form an independent oil smoke system, the air conditioning housing 2 and the condenser assembly 222 form an independent air conditioning system, and thus the oil smoke system and the air conditioning system can be mutually and independently pre-installed when products are assembled, so that the oil smoke system and the air conditioning system can be respectively assembled on different product lines, and then the oil smoke system and the air conditioning system are assembled together, thereby improving the assembly efficiency, and the arrangement positions of the oil smoke system and the air conditioning system can be flexibly selected after the oil smoke system and the air conditioning system are respectively assembled, and improving the arrangement flexibility of the products.

The air-conditioning case 2 and the oil smoke case 1 are arranged side by side, alternatively, the air-conditioning case 2 and the oil smoke case 1 may be arranged side by side in the up-down direction; or the air-conditioning shell 2 and the oil smoke shell 1 can be arranged side by side along the left-right direction; of course, the air conditioning case 2 and the oil smoke case 1 may be arranged side by side in the front-rear direction.

In a specific example of the present invention, as shown in fig. 13, the air conditioning case 2 and the oil smoke case 1 may be arranged side by side in the front-rear direction, wherein the air conditioning case 2 is disposed at the front side of the oil smoke case 1, so that the air conditioning unit 22 delivers cool air or hot air indoors without being blocked by other structures of the product, and the air delivery effect is good.

According to an alternative embodiment of the present invention, the air conditioner 100 further includes: the fume collecting hood 10, the fume collecting hood 10 is arranged at the bottom of the fume extractor housing 10, optionally, the fume collecting hood 10 is independently arranged at the bottoms of the fume extractor housing 1 and the air conditioner housing 2, as shown in fig. 11-17, that is, the fume extractor housing 1 and the air conditioner housing 2 are arranged at the upper end of the fume collecting hood 10 side by side front and back. Of course, alternatively, the fume collecting hood 10 may be disposed only at the bottom of the fume assembly 12, and the bottom of the fume collecting hood 10 may be flush with the bottom of the air conditioning assembly 22, so that the fume collecting hood is compact and neat in appearance.

As indicated by the solid arrows in fig. 11 and 12, the chamber defined by the hood 10 is oriented toward a cooking appliance, and during cooking, cooking fumes may be drawn into the chamber and then into the fume assembly 12 and exhausted.

In other embodiments of the present invention, the fume collecting hood 10 forms part of a fume channel, i.e. the fume collecting hood 10 is disposed within the fume assembly 12, which is more compact and saves space.

In some embodiments of the present invention, the condenser assembly 222 may further include an evaporator 2211, a compressor and a throttling element, wherein the compressor, the condenser assembly 222, the throttling element and the evaporator 2211 are sequentially connected by pipes from end to end, so as to form a closed refrigerant loop, and further cool or heat the environment. Alternatively, the evaporator 2211, compressor and throttling element may be disposed within the air conditioner 100, integrally mounted with the condenser assembly 222; or alternatively, the evaporator 2211, the compressor, and the throttle element may be provided at other locations indoors or outdoors, independently of the air conditioner smoke machine 100.

In a specific example of the present invention, as shown in fig. 14, 15, 17-19, the air conditioning assembly 22 further includes an evaporator assembly 221. The air conditioning ventilator 100 includes a ventilator housing 10, an air conditioning chamber 21 is defined in the ventilator housing 10, an evaporator assembly 221 is disposed in the air conditioning chamber 21, and a condenser assembly 222 is also disposed in the air conditioning chamber 21. In the example of the present invention, both the evaporator assembly 221 and the condenser assembly 222 are integrated within the air conditioning cavity 21 of the air conditioning tobacco machine 100, so that the air conditioning tobacco machine 100 can cool or heat the interior. The evaporator assembly 221 is integrated in the air-conditioning ventilator 100, so that integration of products can be improved, and inconvenience in installation caused by the fact that the evaporator assembly 221 is independently arranged indoors can be avoided.

In the embodiment of the present invention, the air conditioning unit 22 includes a condenser unit 222, the condenser unit 222 includes a condensation air inlet 2223, a condensation air outlet 2224 and a condenser 2221, the condenser 2221 is disposed in a flow path from the condensation air inlet 2223 to the condensation air outlet 2224, after air enters from the condensation air inlet 2223, heat exchange is performed with the condenser 2221, a condensation effect is performed on the condenser 2221, the temperature of the air after heat exchange with the condenser 2221 may be increased, and the air after temperature increase is discharged from the condensation air outlet 2224.

A condensation air intake 2223 is formed in the hood housing 10 and communicates with the air conditioning chamber 21. When the hood housing 10 includes the hood housing 1 and the air conditioner housing 2, the condensation air intake 2223 is formed on the air conditioner housing 2. Thereby, the condensation air inlet 2223 and the oil smoke channel 121 can be ensured to be independent and not to interfere with each other.

In an embodiment of the present invention, the smoke assembly 12 includes a smoke blower 13, the smoke blower 13 being configured to drive smoke drawn in from the smoke inlet 1211 and then exhausted from the smoke outlet 1212.

In an embodiment of the present invention, the condenser assembly 222 includes a condenser 2221 and a condensing fan 2222, wherein the condenser 2221 is used for condensing the refrigerant. The condensing fan 2222 is configured to drive air into the condenser 2223 through the condensing air inlet, exchange heat with the condenser 2221, and then discharge the air from the condensing air outlet 2224, thereby forming an air cycle. In the embodiment of the invention, the oil smoke assembly 12 provides the flowing power of oil smoke gas through the oil smoke fan 13, the condenser assembly 222 provides the flowing power of air through the condensing fan 2222, so that the two systems are respectively provided with independent fans for driving, the two systems cannot interfere, the air flows independently flow, the air flows cannot cross, and the independent operation of the two systems is further ensured.

The condensation air outlet 2224 may be formed on the condensation fan 2222 or the condenser 2221, wherein the condensation air outlet 2224 communicates with the oil smoke channel 121, that is, air may flow to the oil smoke channel 121 after passing through the condensation fan 2222, or air may flow to the oil smoke channel 121 after passing through the condenser 2221.

It should be noted here that, the formation of the condensation air outlet 2224 on the condensation fan 2222 may include the following structural forms: for example, the condensing fan 2222 may include a fan housing, and the condensing air outlet 2224 may be configured as a through hole formed in the fan housing; or the condensing fan 2222 includes a fan inlet and a fan outlet, which may be configured as the condensing air outlet 2224.

The condensation air outlet 2224 formed on the condenser 2221 may include the following structural forms: the condenser 2221 is a fin type heat exchanger, and gaps between fins of the condenser 2221 are configured as the condensation air outlet 2224; or alternatively, the outside of the condenser 2221 may be provided with a housing provided with a through hole so as to constitute the condensation outlet 2224.

As shown in fig. 13 and 18, the evaporator assembly 221 includes an evaporation air inlet 2213, an evaporation air outlet 2214 and an evaporator 2211, the evaporator 2211 is arranged in a flow path from the evaporation air inlet 2213 to the evaporation air outlet 2214, air enters from the evaporation air inlet 2213 and exchanges heat with the evaporator 2211 to condensate the evaporator 2211, the temperature of the air after heat exchange with the evaporator 2211 may be reduced, and the cooled air is discharged from the evaporation air outlet 2214, so that indoor refrigeration can be performed.

Alternatively, an evaporation air inlet 2213 is formed on the hood housing 10 and communicates with the air conditioning chamber 21, an evaporation air outlet 2214 is formed on the hood housing 10 and communicates with the air conditioning chamber 21, and the evaporator 2211 is provided inside the air conditioning chamber 21.

According to an embodiment of the present invention, alternatively, the evaporation air outlet 2214 may be formed on the front wall surface of the smoke housing 10, so that the cooled cold air can be blown out from the front of the smoke housing 10, the air outlet is not blocked by other structures of the product, and the evaporation air outlet 2214 is far away from the oil smoke inlet 1211, so that the problems of air short circuit and the like are not generated, and the heat exchange effect is good.

As shown in fig. 18, the evaporator assembly 221 further includes an evaporation fan 2212, the evaporation fan 2212 is used for driving air to enter from an evaporation air inlet 2213, and after exchanging heat with the evaporator 2211, the air is discharged from an evaporation air outlet 2214 to cool the indoor environment, and of course, the air conditioning assembly 22 can also heat the indoor environment.

Alternatively, as shown in fig. 18, the evaporator 2211 includes two sections, the upper ends of the two sections of evaporators 2211 are adjacently disposed, and the lower ends are disposed away from each other, so as to be configured as a "herringbone", the evaporation fan 2212 is disposed between the two sections of evaporators 2211, and the evaporation fan 2212 is optionally a cross flow wind wheel.

In an alternative example of the present invention, the evaporation intake 2213 shares an opening formed in the hood housing 10 with the condensation intake 2223. That is, the tobacco casing 10 is provided with an opening, and the opening may be used for heat radiation and air intake of the evaporator 2211 or heat radiation and air intake of the condenser 2221. Therefore, the number of the openings on the smoke machine shell 10 can be reduced, the product integration degree is improved, the heat dissipation air inlet of the evaporator assembly 221 and the heat dissipation air inlet of the condenser assembly 222 share one opening, the air inlet smoothness can be facilitated, the air inlet interference is reduced, and the pneumatic noise can be reduced. In addition, the air inlet grille 2215 can be arranged at the opening, so that the air conditioner cavity 21 and the indoor environment can be relatively isolated while air inlet is ensured, the evaporator 2211 and the condenser 2221 share the same air inlet grille 2215, the structure is simple and compact, and the utilization rate of the air inlet grille 2215 is improved.

Specifically, in the present application, the filter screen is provided at the opening, and by providing the filter screen, it is possible to prevent foreign substances such as dust from entering the air conditioning chamber 21. Moreover, it is understood that the evaporation air inlet 2213 and the condensation air inlet 2223 share the opening, so that the evaporator 2211 and the condenser 2221 share one air inlet filter screen, that is, the air exchanging heat with the evaporator 2211 and the air exchanging heat with the condenser 2221 are filtered by the air inlet filter screen, which simplifies the structure, reduces the number of parts and saves the production cost.

The opening may be provided in any orientation on the housing 10 of the cigarette. In particular, the opening may be provided at the top of the hood housing 10. Preferably, in the embodiment of the present invention, as shown in fig. 14, 15 and 18, the evaporator 2211 and the condenser 2221 are arranged in the up-down direction, the evaporation air inlet 2213 and the condensation air inlet 2223 share an opening formed on the smoke machine housing 10, the opening is formed above the evaporator 2211, so that air enters the air conditioning cavity 21 through the opening and exchanges heat with the evaporator 2211 first, the temperature of the air after heat exchange is reduced, and cold air is formed, a part of the cold air is discharged from the evaporation air outlet 2214, so that the indoor environment is refrigerated, the environmental temperature in a kitchen is reduced, and the cooking environment of a user is improved; the other part of the cold air continues to flow downwards to exchange heat with the condenser 2221, the condenser 2221 is subjected to condensation, the temperature is reduced because the air is cooled after passing through the evaporator 2211, and the low-temperature air exchanges heat with the condenser 2221, so that the condensation effect of the condenser 2221 can be improved, namely, the air is primarily cooled before exchanging heat with the condenser 2221, and then exchanging heat with the condenser 2221 can be performed in unit time and unit flow, and the heat exchange efficiency is improved.

And, the air temperature after heat exchange with the condenser 2221 rises, and the air after rising is discharged into the oil smoke air flue through the condensation air outlet 2224 and is discharged together with the flue gas, so that the hot air can be utilized to thermally clean the oil smoke assembly 12, and the hot air can be effectively prevented from flowing back into the kitchen again. In addition, the hot air is discharged by utilizing the channel for discharging the flue gas, and a special discharging channel for discharging the hot air is not needed, so that the structure is simplified, the structure is compact, the occupied volume is reduced, and the production cost is saved.

In an embodiment of the present invention, an evaporation air outlet 2214 may be formed at a front side of the housing 10 of the cigarette and opposite to the evaporator 2211, and as shown in fig. 17 and 19, an air deflector 2216 may be provided at the evaporation air outlet 2214, and the air deflector 2216 may open and close the evaporation air outlet 2214. Wherein, air can be directly discharged from the evaporation air outlet 2214 after heat exchange with the evaporator 2211, the air outlet path is short, and the air outlet is smooth, thereby improving the refrigerating effect to the indoor environment.

In some embodiments of the present invention, the air conditioner hood 100 further includes a condensation duct 9, and the condensation air outlet 2224 communicates with the oil smoke channel 121 through the condensation duct 9. Thereby facilitating more convenient communication between the condensation air outlet 2224 and the oil smoke passage 121.

As shown in fig. 11-16, alternatively, the condensation duct 9 may be disposed outside the oil smoke housing 1, so that the condensation air outlet 2224 and the oil smoke channel 121 may be communicated outside the oil smoke housing 1, so as to avoid the installation space of other parts due to the communication pipeline disposed in the oil smoke housing 1.

As shown in fig. 13-16, according to an alternative example of the present invention, a part of the condensation duct 9 is connected to the oil smoke housing 1, another part of the condensation duct 9 is connected to the air conditioning housing 2, for example, an upper part of the condensation duct 9 is connected to the oil smoke housing 1, and a lower end of the condensation duct 9 is connected to the air conditioning housing 2, so that it is advantageous to communicate the air conditioning assembly 22 with the oil smoke assembly 12, and hot air in the air conditioning assembly 22 is sent to the oil smoke assembly 12 through the condensation duct 9, so that the hot air is discharged together with the smoke.

Specifically, in some embodiments of the present invention, the condensation duct 9 may be connected to the air conditioning casing 2 or the oil smoke casing 1 by a clamping connection, for example, a protrusion is disposed at an edge of an opening of the oil smoke casing 1, a buckle matched with the protrusion is disposed at an upper end of the condensation duct 9, a buckle is disposed at an edge of the condensation air outlet 2224, and a clamping groove matched with the buckle is disposed at a lower end of the condensation duct 9, so that a connection manner between the condensation duct 9 and the air conditioning casing 2 or the oil smoke casing 1 is simple and convenient.

In other embodiments of the present invention, the condensation duct 9 may be welded to the air conditioning case 2 or the oil smoke case 1, in still other embodiments of the present invention, the condensation duct 9 may be connected to the air conditioning case 2 or the oil smoke case 1 by a connection member, for example, a bolt may be used as the connection member, so that both ends of the condensation duct 9 are reliably connected to the air conditioning case 2 or the oil smoke case 1, respectively, and in addition, the connection manner of the condensation duct 9 to the air conditioning case 2 or the oil smoke case 1 may be any combination of the above two manners, for example, a snap connection is adopted between the condensation duct 9 and the air conditioning case 2, and a connection manner of a snap connection and a bolt connection may be adopted between the condensation duct 9 and the oil smoke case 1, for example, the present invention is not limited thereto.

Of course, the present invention is not limited thereto, and the condensation duct 9 may be provided inside the hood housing 1, whereby the overall product structure of the air conditioning ventilator 100 is more integrated.

Optionally, ribs are defined in the condensation duct 9. Therefore, the ribs can play a role in guiding and rectifying the flow of air, and the structural strength of the condensation pipeline 9 can be enhanced, so that the service life of the condensation pipeline is prolonged.

Optionally, the connection between the condensation duct 9 and the condensation air outlet 2224 is formed into an arc shape, that is, the connection between the condensation duct 9 and the condensation air outlet 2224 is smoothly transited, so that abrupt change of the connection is avoided, and air can be guided and guided through the arc-shaped part when flowing into the condensation duct 9 from the condensation air outlet 2224, so that the air flow is smoother, and turbulence is reduced. In this way, the flow of the hot air is facilitated, the resistance of the hot air in flowing is reduced, and the hot air can smoothly enter the condensation duct 9 through the condensation air outlet 2224.

It should be noted that, a sealing gasket may be added at the position of the condensation duct 9 and the condensation air outlet 2224 to enhance the tightness, and may be directly connected according to the actual requirement, and a sealing gasket may be added between the interface of the condensation duct 9 and the oil smoke channel 121 to enhance the tightness, and may be directly connected according to the actual requirement.

Alternatively, the junction of the condensing duct 9 and the oil smoke channel 121 is formed in an arc shape. Similarly, the joint of the condensation pipeline 9 and the oil smoke channel 121 is smoothly transited, abrupt change of the joint is avoided, and therefore, when air flows into the oil smoke channel 121 from the condensation pipeline 9, the air can be guided and guided through the arc-shaped part, the air flow is smoother, and the turbulence is reduced. In this way, the flow of hot air is facilitated, the resistance to the flow of hot air is reduced, and the hot air can be smoothly collected into the flue gas by the condensation pipeline 9.

Optionally, a volute tongue is disposed at the condensation air outlet 2224, so that the flow of the air can be guided and guided by the volute tongue, and the flow of the air is smoother, so that turbulence is reduced. Alternatively, the volute tongue may be integrally formed at the condensation outlet 2224, for example, may be integrally formed on the fume housing 1, or may be integrally formed on the condensation duct 9. Of course, the volute tongue is a separate component and is assembled on the fume housing 1 or the condensation duct 9.

Optionally, a protrusion is provided on the rear edge of the condensation outlet 2224, the protrusion being configured as a volute tongue. Wherein the thickness of one end of the convex part adjacent to the rear end of the condensation air outlet 2224 is greater than the thickness of the other end far away from the rear end of the condensation air outlet 2224, the thickness of the convex part gradually decreases along the flowing direction of hot air, and by arranging the convex part at the rear end of the condensation air outlet 2224, the flowing resistance of hot air at the condensation air outlet 2224 can be reduced, and the noise at the condensation air outlet 2224 is reduced.

As shown in fig. 15, optionally, a side wall of the condensation duct 9 facing the oil smoke housing 1 is opened, the condensation duct 9 is attached to the side wall of the oil smoke housing 1, and a channel for gas flow is defined between the outer wall of the condensation duct 9 and the side wall of the oil smoke housing 1. This reduces the manufacturing material of the condensation duct 9 and reduces the cost.

In some embodiments of the present invention, as shown in fig. 11-16, the oil smoke passageway 121 includes a fusion port 14, and the condensation air outlet 2224 communicates with the fusion port 14. That is, the condensation air outlet 2224 communicates with the oil smoke passage 121 through the merging port 14. In this way, the hot air after heat exchange with the condenser 2221 enters and is collected into the flue gas through the fusion port 14, and finally is discharged together with the flue gas. By providing the fusion port 14, the condensation air outlet 2224 can be more conveniently communicated with the oil smoke channel 121.

As shown in fig. 11 to 16, in one embodiment of the present invention, the air conditioner smoke machine 100 further includes a smoke housing 1, at least a portion of the smoke passage 121 is formed in the smoke housing 1, and a through hole is provided in the smoke housing 1, the through hole being configured as at least a portion of the fusion port 14. The through hole may be formed on a sidewall of the oil smoke housing 1, and the condensation air outlet 2224 may be formed on a sidewall of the same side of the oil smoke housing 1, whereby the condensation air outlet 2224 may be conveniently communicated with the oil smoke channel 121.

Optionally, as shown in fig. 13-15, in the embodiment of the present invention, the air conditioner smoke machine 100 further includes a condensation duct 9, and the condensation air outlet 2224 communicates with the fusion port 14 through the condensation duct 9. Through setting up condensation duct 9 to can utilize condensation duct 9 to communicate condensation air outlet 2224 and fusion mouth 14 conveniently, this condensation duct 9 can set up in the oil smoke casing 1 outside moreover, that is to say, condensation air outlet 2224 and fusion mouth 14's intercommunication can go on in the outside of oil smoke casing 1, avoid setting up the intercommunication pipeline and occupy the installation space of other spare part in oil smoke casing 1.

Wherein, one end of the condensation duct 9 is communicated with the condensation air outlet 2224, and the other end of the condensation duct 9 is communicated with the fusion port 14. Thereby, the communication between the fusion port 14 and the condensation air outlet 2224 can be facilitated.

Optionally, the fusion port 14 is higher than the condensation air outlet 2224, and the condensation duct 9 is obliquely arranged. That is, the high temperature air discharged from the condensation air outlet 2224 flows obliquely upward and enters the oil smoke passage 121 through the fusion port 14.

Because the density of the hot air is low and moves upwards, the position of the fusion port 14 is set to be higher than the position of the condensation air outlet 2224, so that the hot air can move upwards along the extending direction of the condensation pipeline 9, the hot air can be collected into the flue gas to be discharged, the flowing resistance of the hot air is reduced, the condensation pipeline 9 is obliquely connected with the oil smoke assembly 12 upwards, and meanwhile, the oil smoke can be effectively prevented from flowing backwards into parts of the air conditioning assembly 22.

In addition, the smoke discharging performance of the air conditioner smoke machine 100 is not affected by collecting the hot air into the smoke in the smoke housing 1, and the hot air is discharged conveniently. The fusion port 14 between the condensation pipeline 9 and the oil smoke shell 1 can be arranged on the side surface of the oil smoke shell 1, the fusion port 14 can be arranged on the front side, the back side, the left side and the right side of the oil smoke shell 1, and the fusion port can be arranged according to actual needs.

Of course, the present invention is not limited thereto, and the condensation air outlet 2224 and the fusion port 14 may also communicate through a passage defined inside the oil smoke housing 1.

Where it is to be construed herein that "the through hole is configured as at least a portion of the fusion port 14" means that the fusion port 14 may include only the through hole, or that the fusion port 14 may include structures other than the through hole. Different embodiments of the "fusion port 14" will be described below.

Optionally, in an alternative embodiment of the invention, the fume assembly 12 comprises a fume fan 13, the fume fan 13 comprising a fan inlet configured as at least a portion of the fusion port 14. Wherein optionally, the oil smoke blower 13 may comprise a blower housing and the oil smoke blower 13 disposed in the housing, and the blower inlet is formed on the blower housing.

As shown in fig. 16, in an embodiment of the present invention, the oil smoke blower 13 may be a centrifugal blower, the blower inlet may be formed at the front end of the oil smoke blower 13, of course, the blower inlet may also be formed at the rear end of the oil smoke blower 13, or both the front end and the rear end of the oil smoke blower 13 may be provided with the blower inlet.

Alternatively, the fusion port 14 may include only the blower inlet, that is, the condensation air outlet 2224 may be directly connected to the blower inlet, although the present invention is not limited thereto, and the fusion port 14 may include other structures.

In the embodiment of the invention, the air conditioning smoke machine 100 further comprises a smoke housing 1, and the smoke blower 13 is arranged in the smoke housing 1. Alternatively, the condensation air outlet 2224 may communicate with the fan inlet through a channel inside the oil smoke housing 1, or the condensation air outlet 2224 may communicate with the fan inlet through a channel outside the oil smoke housing 1. Wherein when the condensation air outlet 2224 is communicated with the fan inlet through the channel outside the oil smoke shell 1, a through hole can be arranged on the oil smoke shell 1 for the condensation air outlet 2224 to be communicated with the fan inlet after passing through the through hole.

In some embodiments of the present invention, the air conditioning ventilator 100 further includes a check valve 15, where the check valve 15 gradually decreases in radial dimension from bottom to top, and the check valve 15 can enable the smoke to flow along the discharged path, that is, the forward flow direction of the smoke, and can avoid the smoke from returning along the reverse flow direction of the smoke, so as to ensure the effect of smoke sucking of the smoke assembly 12. The check valve 15 is provided to prevent the back flow of the smoke and the hot air.

In some alternative examples, the blend port 14 is located downstream of the check valve 15. The structure of the check valve 15 may be the same as that of the check valve 15 in the range hood in the prior art, and will not be described herein. The fact that the fusion port 14 is located downstream of the check valve 15 means that the fusion port 14 is located downstream of the flow of the check valve 15 in the flow path of the gas. In an embodiment of the present invention, the fusion port 14 may be located above the check valve 15, and the condensation air outlet 2224 may be in communication with the fusion port 14 through a pipe, a pipeline, or the like.

In some alternative examples, the fusion port 14 may be disposed upstream of the check valve 15. That is, the fusion port 14 is located upstream of the flow of the check valve 15 in the flow path of the gas, and the flow of the gas flows into the check valve 15 through the fusion port 14.

In some embodiments of the present invention, the fume channel 121 includes a fume inlet 1211 and a fume outlet 1212, the fume outlet 1212 being configured as at least a portion of the fusion port 14.

Optionally, the air conditioner 100 may further include a check valve 15, and the fume outlet 1212 may be disposed on the check valve 15, and the condensation air outlet 2224 communicates with the fume outlet 1212, that is, the condensation air outlet 2224 communicates with the check valve 15. Whereby the high-temperature hot gas discharged from the condensation outlet 2224 is discharged to the outside through the check valve 15.

Optionally, the air conditioner smoke machine 100 further comprises a smoke tube, and the smoke outlet 1212 is provided on the smoke tube. Wherein a smoke pipe is provided on the check valve 15 for exhausting to the outside, the fusion port 14 may be provided on the smoke pipe, whereby the high temperature hot gas exhausted from the condensation air outlet 2224 may directly flow into the smoke pipe and be exhausted to the outside. Thus, the internal structure of the air conditioning ventilator 100 is prevented from being changed, and the condensation air outlet 2224 can be directly communicated with the smoke pipe through a pipe or a pipeline.

An air conditioner smoke machine 100 according to an embodiment of the present invention is described in detail below with reference to fig. 11 to 19.

In a specific example of the present invention, the air conditioning ventilator 100 includes an air conditioning case 2 and a fume case 1, an air conditioning cavity 21 is defined in the air conditioning case 2, a fume cavity 11 is defined in the fume case 1, an air conditioning assembly 22 is disposed in the air conditioning cavity 21, and a fume assembly 12 is disposed in the fume case 1. The air conditioning ventilator 100 further includes a fume collecting hood 10, and the fume housing 1 and the air conditioning housing 2 are disposed side by side in the front-rear direction on the fume collecting hood 10, for example, the air conditioning housing 2 is disposed on the front side of the fume housing 1.

The fume enters the fume chamber 11 through the suction inlet of the fume collecting hood 10, and in the embodiment of the invention, the fume assembly 12 comprises a fume fan 13, and fume gas flows in a fume channel 121 until being discharged outdoors under the driving of the fume fan 13.

In an embodiment of the present invention, the air conditioning assembly 22 includes an evaporator 2211, a condenser 2221, an evaporation fan 2212 and a condensation fan 2222, the evaporator 2211 is disposed above the condenser 2221, the evaporation fan 2212 is disposed between the evaporator 2211 and the condenser 2221, and the condensation fan 2222 is disposed at a rear side of the condenser 2221. The top of the air-conditioning case 2 is provided with an opening, which serves as an evaporation air inlet 2213 and a condensation air inlet 2223, and indoor air enters the air-conditioning cavity 21 through the opening at the top of the air-conditioning case 2, and is firstly subjected to heat exchange with the evaporator 2211, and the air after heat exchange is cooled, and a part of the air is discharged into the room through an evaporation air outlet 2214 at the front side of the air-conditioning case 2 so as to refrigerate the indoor environment. The other part of air flows downwards to exchange heat with the condenser 2221, the cooled air is subjected to heat exchange with the condenser 2221 to obtain heat, the heat is changed into high-temperature gas, the high-temperature gas is discharged from the condensation air outlet 2224 and is conveyed to the fusion port 14 through the condensation pipeline 9, the fusion port 14 is arranged on the side wall of the oil smoke shell 1, the high-temperature gas enters the oil smoke channel 121, and the high-temperature gas is discharged outdoors together with the oil smoke gas.

The invention provides a condensing air-out discharging and internal cleaning scheme of an air-conditioning smoke machine 100, wherein after condensing and radiating in a condenser 2221, a large amount of hot air is accumulated near the condenser 2221 by condensing the condensing agent in an air-conditioning component 22, the hot air can be discharged into a condensing pipeline 9 through a fan system at the rear end of the condenser 2221 by a side air inlet mode of the condensing pipeline 9, a large amount of hot air enters the main fan system due to the fact that the condensing pipeline 9 is communicated with the main fan system of an oil smoke component 12, and the hot air enters the main fan system through a condensing air inlet 2223 of a volute, so that the temperature in the main fan system is increased, and grease in the main fan system is heated and melted.

When the air conditioning assembly 22 and the oil smoke assembly 12 run simultaneously for a long time, the main fan system continuously pumps and discharges oil smoke, and the fan of the condenser 2221 continuously inputs hot air, so that the impeller runs in an environment with higher temperature, the grease adhesion on the surface of the impeller is effectively reduced, the self-cleaning function inside the oil smoke assembly 12 is realized, and the user experience is improved.

According to the air conditioning ventilator 100 provided by the embodiment of the invention, the condensation air outlet 2224 is communicated with the oil smoke channel 121, so that hot air subjected to heat exchange with the condenser 2221 can be discharged into the oil smoke channel 121 through the condensation air outlet 2224, and further, heat generated by the condenser 2221 can be discharged by utilizing the oil smoke channel 121, so that the heat generated by the condenser 2221 is prevented from being emitted to an indoor space, the refrigeration efficiency is ensured, and the comfort of a user is improved. In addition, because the high-temperature hot air is led into the oil smoke channel 121, the structure of the oil smoke assembly 12 can be operated at a higher temperature, and the upper grease of the oil smoke assembly 12 is heated and melted, so that the adhesion of the oil smoke on the internal structure of the oil smoke assembly is effectively reduced, the internal hot air cleaning function of the oil smoke assembly 12 is realized, and the user experience is improved. And the fume exhaust and the air conditioner exhaust of the air conditioner smoke machine 100 are discharged together after being collected, a heat dissipation pipeline is not required to be additionally cut, the assembly is quick and convenient, and the product assembly space is saved.

In the description of the present specification, reference to the terms "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: many changes, modifications, substitutions and variations may be made to the embodiments without departing from the spirit and principles of the invention, the scope of which is defined by the claims and their equivalents.

Claims (8)

1. An air conditioning smoke machine, characterized by comprising:

A fume assembly comprising a fume channel;

an air conditioning assembly, the air conditioning assembly comprising:

A condenser assembly including a condenser;

The evaporator assembly is used for guiding condensed water generated by the evaporator assembly to the condenser assembly, and the condensed water is evaporated and then discharged along with the oil smoke channel;

The water storage tank is arranged below the condenser assembly and comprises a water receiving part and a detection part, and the water receiving part is arranged below the condenser;

a water circulation device configured to direct fluid within the reservoir onto the condenser assembly, the water circulation device comprising: a water spraying device or a water spraying device;

The water level detection device is arranged in the detection part to detect the water level in the detection part, and the water receiving part is communicated with the detection part through a buffer structure.

2. The air conditioning hood according to claim 1 wherein the condenser assembly includes a condensation air outlet in communication with the oil smoke passageway, the condensation water being evaporated and discharged into the oil smoke passageway through the condensation air outlet.

3. The air conditioner of claim 1, wherein the evaporator assembly is higher than the condenser assembly.

4. The air conditioning hood according to claim 1 further comprising a water guide structure, the condensed water being directed to the condenser assembly via the water guide structure.

5. The air conditioner of claim 1, wherein a water absorbing device is configured to direct fluid within the reservoir onto the condenser assembly.

6. The air conditioning tobacco unit of claim 5 wherein the water absorbing means comprises a water absorbing material.

7. The air conditioning hood according to claim 1 wherein the condenser assembly includes a condensing air inlet and a condensing air outlet, the condensing air outlet being in communication with the oil smoke passageway, the condensing air inlet being independent of the oil smoke passageway.

8. The air conditioner of claim 1, wherein the evaporator assembly and the condenser assembly are arranged in an up-down direction.