CN219589090U - Air conditioning module and air conditioning smoke machine - Google Patents

Abstract

The utility model relates to an air conditioning module and an air conditioning smoke machine, which comprise a shell, an air guide channel and a baffle plate assembly, wherein an air conditioning air outlet is formed in the shell, the air guide channel is arranged outside the shell, one end of the air guide channel is communicated with the air conditioning air outlet, the other end of the air guide channel is provided with an air outlet positioned outside the shell, the baffle plate assembly comprises an air guide piece movably arranged in the air guide channel, and a plurality of first micropores for diffusing air flow are formed in the air guide piece in a penetrating manner. The air guide piece is provided with a first state and a second vertical state, wherein the axial direction of the first micropore is parallel to the air exhaust direction, the air guide piece can move in the air guide channel to be switched between the first state and the second state, and the dispersing effect on cold air is adjusted by moving the air guide piece to different positions, so that cold air with different dispersing effects is provided according to different suction effects of the smoke machine module, and the situation that the cold air directly reaches the smoke machine module and is sucked away is avoided.

Description

Air conditioning module and air conditioning smoke machine

Technical Field

The utility model relates to the technical field of air conditioning smoke machines, in particular to an air conditioning module and an air conditioning smoke machine.

Background

The kitchen is the main place that people cook, and the kitchen air circumstance's good or bad directly influences people's culinary art experience. The kitchen is hot in summer and cold in winter, and has the requirements of cooling and heating. Therefore, people invent an air conditioner smoke machine, cool kitchen air in summer, and provide hot air for a kitchen in winter so as to improve cooking comfort.

The main body of the air conditioner smoke machine can be divided into an air conditioner and a smoke machine. The main function of the range hood is to absorb oil smoke, and the main function of the air conditioner is to cool the kitchen. The range hood is used for sucking high-temperature oil smoke gas and discharging the high-temperature oil smoke gas outdoors, the air conditioner is used for absorbing hot air in a kitchen and exchanging heat with an outdoor environment, heat in the kitchen is transferred outdoors, and cold air is discharged into the kitchen through an air outlet positioned at a suspended ceiling of the kitchen, so that the aim of reducing the indoor temperature of the kitchen is fulfilled.

However, because the kitchen furred ceiling air outlet is nearer with the lampblack absorber smoke inlet distance on the top of a kitchen range, the cold wind air outlet of air conditioner and the two air current of the smoke inlet of lampblack absorber are easily influence each other, and the cold wind that the air conditioner produced extremely easily mixes with the hot-blast emergence that produces when cooking, appear not the condition that the cold wind that is not utilized just is sucked away by the smoke inlet of lampblack absorber directly, have not only increased the burden of lampblack absorber for the oil smoke can not all be completely smoked, smoking effect is not good, leads to the indoor cooling effect of kitchen to weaken moreover.

Disclosure of Invention

Based on the above, the utility model provides an air conditioning module and an air conditioning ventilator, which aim at the problem that cold air generated by the air conditioning ventilator is easily sucked by the ventilator, and the air conditioning module and the air conditioning ventilator have the effects of blocking, buffering and guiding the cold air and dispersing air outlet, and can adjust the dispersing effect of the cold air, so that the cold air cannot directly reach the ventilator.

An air conditioner module comprises a shell, wherein an air conditioner air outlet is formed in the shell;

the air guide channel is positioned outside the shell, one end of the air guide channel is communicated with the air outlet of the air conditioner, and the other end of the air guide channel is provided with an air outlet positioned outside the shell;

the baffle plate assembly comprises an air guide piece movably arranged in the air guide channel, and a plurality of first micropores for diffusing air flow are formed in the air guide piece in a penetrating manner;

the air guide piece is provided with a first state that the axial direction of the first micropore is parallel to the air exhaust direction and a second state that the axial direction of the first micropore is perpendicular to the air exhaust direction, and the air guide piece can move in the air guide channel to switch between the first state and the second state.

In one embodiment, the air guide piece is rotatably arranged in the air guide channel, and the air guide piece also has a third state that the axial direction of the first micropore is intersected with the air exhaust direction and is not vertical to the air exhaust direction;

the wind guide piece can rotate in the wind guide channel to be switched between the first state, the second state and the third state.

In one embodiment, the baffle assembly further comprises a baffle member disposed in the air guiding channel, wherein an outer edge of the baffle member is connected with an inner wall of the air guiding channel, and the baffle member is intersected with the air exhausting direction;

the air guide piece is configured to rotate in the air guide channel relative to the baffle piece, and a plurality of second micropores for diffusing air flow are formed in the baffle piece in a penetrating mode.

In one embodiment, the baffle member is disposed upstream of the air guide member in the air discharge direction.

In one embodiment, the air guide member comprises at least one group of air guide plate modules, and all the air guide plate modules are distributed along a direction intersecting with the air exhaust direction;

each group of air deflector modules comprises at least one air deflector, and one end of each air deflector is movably connected with the baffle piece and is rotatably connected with a fixed pivot;

the air deflector is configured to be rotatable relative to the baffle member about the fixed fulcrum.

In one embodiment, each group of air deflector modules comprises two air deflectors, the two air deflectors are arranged along the direction intersecting with the exhaust direction, and each air deflector is provided with the first micropores;

one end of each air deflector is movably connected with the baffle piece, and the baffle piece is configured to reciprocate along the exhaust direction so as to drive two air deflectors in each group of air deflector modules to synchronously rotate around the fixed pivot.

In one embodiment, the air conditioning module comprises a driving member which is in driving connection with the baffle member for driving the baffle member to reciprocate along the exhaust direction.

In one embodiment, the baffle assembly further comprises at least one connecting rod, one end of each connecting rod is rotatably connected with the baffle member, and the other end of each connecting rod is rotatably connected with one air deflector;

when the baffle piece moves along the exhaust direction, the connecting rod swings in the air guide channel and drives the air guide plate connected with the connecting rod to rotate relative to the fixed pivot.

In one embodiment, the first micropores are provided with a contraction section and a diffusion section which are sequentially arranged along the airflow direction, the pore diameter of the contraction section is gradually reduced, and the pore diameter of the diffusion section is gradually enlarged along the exhaust direction;

and the aperture of the end of the diffusion section far away from the contraction section is larger than the aperture of the end of the contraction section far away from the diffusion section.

In one embodiment, the first micropores further have a compression section disposed between the contraction section and the diffusion section, and the pore diameter of the compression section is equal to or smaller than the minimum pore diameter of the contraction section and the minimum pore diameter of the diffusion section.

According to another aspect of the utility model, there is also provided an air conditioning hood comprising a hood module and an air conditioning module according to any one of the above.

In one embodiment, the range hood module has a high range and a low range for extracting oil smoke;

when the smoke machine module is in the high gear, the air guide piece moves to the first state in the air guide channel;

when the smoke machine module is in the low gear, the air guide piece moves to the second state in the air guide channel.

In one embodiment, the range hood module further has a middle gear for exhausting oil smoke, and when the range hood module is in the middle gear, the air guide moves in the air guide channel to a third state that the axial direction of the first micropore is intersected with the exhaust direction and is not perpendicular to the exhaust direction.

According to the air conditioning module, after cold air generated in the shell enters the air guide channel, the cold air is firstly guided by the air guide piece and then blown out from the air outlet, when the air guide piece is in the first state, all air flows in the air guide channel are buffered, decelerated and dispersed through the first micropores on the air guide piece and then blown out, and when the air guide piece is in the second state, all air flows in the air guide channel are not directly blown out through the air guide piece. So, according to the position of wind-guiding spare in the wind-guiding passageway, provide different buffering, speed reduction and dispersion effect, not only can block, cushion and direction cold wind, reach the effect of dispersing the air-out, and can be through the dispersion effect to cold wind with the wind-guiding spare motion to different position adjustment to according to the different suction effect of cigarette machine module, provide the cold wind of different dispersion effects, avoid cold wind directly to arrive cigarette machine module department and be absorbed the condition.

Drawings

FIG. 1 is a schematic diagram of an air conditioning ventilator assembly structure provided in one or more embodiments;

FIG. 2 is a schematic diagram of an assembly of baffle assemblies and air guide channels according to one or more embodiments;

FIG. 3 is a schematic view of the structure of the air guide in the baffle assembly provided in FIG. 2 in a first state;

FIG. 4 is a schematic view of the structure of the air guide in the baffle assembly provided in FIG. 2 in a second state;

FIG. 5 is a schematic perspective view of an air deflector of the baffle assembly provided in FIG. 2;

FIG. 6 is a schematic view of the air guide in the baffle assembly provided in FIG. 2 in a third state;

FIG. 7 is a schematic view of the structure of a first or second aperture in the baffle assembly provided in FIG. 2;

FIG. 8 is a schematic flow diagram of an air outlet method of an air conditioner smoke machine according to one or more embodiments;

fig. 9 is a schematic diagram of a second flow chart of an air outlet method of an air conditioner smoke machine according to one or more embodiments.

Reference numerals: 1000. an air conditioning smoke machine; 100. an air conditioning module; 10. a housing; 11. an air outlet of the air conditioner; 20. an air guide channel; 21. an air outlet; 30. a baffle assembly; 31. a baffle member; 311. a second microwell; 32. an air guide member; 321. an air deflector module; 3211. an air deflector; 32111. a first microwell; k1, a contraction section; k2, compressing the section; k3, a diffusion section; 40. a fixed fulcrum; 50. a connecting rod; 200. a smoke machine module; 2000. an operator; 3000. a kitchen; 3100. suspended ceiling; l1, exhaust direction; l2, axial direction; l3, longitudinal extension direction.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model. The present utility model may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the utility model, whereby the utility model is not limited to the specific embodiments disclosed below.

In the description of the present utility model, it should be understood that, if any, these terms "center", "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc., are used herein with respect to the orientation or positional relationship shown in the drawings, these terms refer to the orientation or positional relationship for convenience of description and simplicity of description only, and do not indicate or imply that the apparatus or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the utility model.

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

In the present utility model, unless explicitly stated and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly. For example, the two parts can be fixedly connected, detachably connected or integrated; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present utility model, unless expressly stated or limited otherwise, the meaning of a first feature being "on" or "off" a second feature, and the like, is that the first and second features are either in direct contact or in indirect contact through an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

It will be understood that if an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present. If 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, if any, are for descriptive purposes only and do not represent a unique embodiment.

The air conditioner smoke machine generally comprises an air conditioner module and a smoke machine module, wherein the air conditioner module is used for realizing refrigeration or heating through a refrigerant circulation channel formed in the air conditioner module, so that the air temperature in a kitchen is regulated and controlled, and an operator can have better experience when cooking. When an operator cooks, the smoke machine module sucks the oil smoke in the kitchen into the air conditioner smoke machine and discharges the oil smoke to the outside.

According to the working principle of the air conditioner, when the air conditioner module operates, for example, during refrigeration, an air conditioner air outlet is formed in a region corresponding to the air conditioner module, cold air is blown out through the air outlet to cool the room, and during heating, hot air is blown out through the air conditioner air outlet to heat the room. However, because the smoke suction port of the air-conditioning air outlet smoke machine module of the air-conditioning module is closer, the air-conditioning air generated by the air-conditioning module during operation and the oil smoke hot air flow of the smoke inlet are easy to affect each other and mix, the condition that the unused air-conditioning air is directly sucked away by the smoke suction port of the smoke machine module occurs, the burden of the smoke machine module is increased, the oil smoke cannot be completely sucked, the smoke suction effect is poor, and the defect that the indoor cooling effect of a kitchen is weakened is caused.

In order to solve the above problems, referring to fig. 1, the present utility model provides an air-conditioning ventilator 1000, which includes an air-conditioning module 100 and a ventilator module 200, wherein the ventilator module 200 is used for sucking the oil smoke generated on the cooking bench, an operator 2000 can stand facing the cooking bench, the air-conditioning module 100 is used for exhausting air-conditioning air to the kitchen 3000 to cool the kitchen 3000 in hot summer and heat the kitchen 3000 in cold winter, and the cooling of the air-conditioning module 100 is exemplified below.

In one embodiment, referring to fig. 1 to 4, an air conditioning module 100 includes a housing 10 and an air guiding channel 20, an air conditioning system for cooling or heating is disposed in the housing 10, the air conditioning system includes a conventional compressor, a condenser, an evaporator and other structures, an air conditioning air outlet 11 is disposed on the housing 10, the air guiding channel 20 is located outside the housing 10, one end of the air guiding channel 20 is communicated with the air conditioning air outlet 11, and the other end is provided with an air outlet 21 located outside the housing 10.

Specifically, the air guide channel 20 may be mounted on the ceiling 3100 of the kitchen 3000, such that the air outlet 21 is formed on the ceiling 3100 to perform air outlet. In use, cool air generated by the air conditioning system is discharged from the air outlet 11 of the air conditioner, enters the air guide channel 20 after being discharged from the air outlet 21.

By providing the air guide passage 20, the cooling air generated by the air conditioning module 100 is guided out, and the air guide passage 20 is installed at a proper position according to the actual use condition, and the air is blown to the operator 2000 from the air outlet 21.

Still further, referring to fig. 2 to 5, the air conditioning module 100 further includes a baffle assembly 30, the baffle assembly 30 includes an air guiding member 32 movably disposed in the air guiding channel 20, a plurality of first micro holes 32111 for diffusing airflow are provided on the air guiding member 32, wherein the air guiding member 32 has a first state in which an axial direction L2 of the first micro holes 32111 is parallel to the air exhausting direction L1, and a second state in which an axial direction L2 of the first micro holes 32111 is perpendicular to the air exhausting direction L1, and the air guiding member 32 can move in the air guiding channel 20 to switch between the first state and the second state.

After entering the air guide channel 20, the cold air generated in the shell 10 is guided by the air guide piece 32 and then blown out from the air outlet 21, and when the air guide piece 32 is in the first state, all air flows in the air guide channel 20 need to be buffered, decelerated and dispersed through the first micropores 32111 on the air guide piece 32 and then blown out. When the air guide piece 32 is in the second state, all the air flows in the air guide channel 20 are not required to be directly blown out through the air guide piece 32, and when the air guide piece 32 is switched between the first state and the second state, part of the air flows in the air guide channel 20 are buffered, decelerated and dispersed through the first micropores 32111 on the air guide piece 32 and then blown out, and part of the air flows are not directly blown out through the air guide piece 32.

Thus, according to the position of the air guide piece 32 in the air guide channel 20, different buffering, decelerating and dispersing effects are provided, cold air can be blocked, buffered and guided, the effect of dispersing air out is achieved, and the dispersing effect of the cold air can be adjusted by moving the air guide piece 32 to different positions, so that cold air with different dispersing effects is provided according to different suction effects of the smoke machine module 200, and the situation that the cold air directly reaches the smoke machine module 200 and is sucked away is avoided.

In one embodiment, the wind guiding member 32 is rotatably connected to the wind guiding channel 20, referring to fig. 6, the wind guiding member 32 further has a third state in which the axial direction L2 of the first micro-hole 32111 intersects with the air exhausting direction L1 and is not perpendicular, and the wind guiding member 32 can rotate in the wind guiding channel 20 to switch between the first state, the second state and the third state.

It will be appreciated that the position of the air guide 32 in the third state is not unique, and that the position of the air guide 32 within the air guide channel 20 may be considered the third state as long as it is not the first state or the second state. In the third state, part of the airflow in the air guide channel 20 is blown out after buffering, decelerating and dispersing actions of the first micro holes 32111 on the air guide 32, and part of the airflow is not directly blown out through the air guide 32.

In the third state, the axial direction L2 of the first micro-hole 32111 may form a plurality of angles with the air exhaust direction L1, and with the change of the angles, the air flow in the air guide channel 20 may enter the first micro-hole 32111 at various angles, so that the air guide 32 provides different buffering, decelerating and dispersing effects when the axial direction L2 of the first micro-hole 32111 forms different angles with the air exhaust direction L1.

Further, the air guide 32 may rotate circumferentially in the air guide 20, and when the air guide 32 is in the first state, the air guide 32 is controlled to rotate clockwise or anticlockwise to the third state relative to the air guide 20, then rotate to the second state, continue to rotate to the second state, and then return to the first state, thereby realizing the two-by-two switching among the first state, the second state and the third state.

In one embodiment, a fulcrum may be disposed on the inner wall of the air guiding channel 20, and the driving structure drives the air guiding element 32 to rotate, or other structures may be used to implement the rotation of the air guiding element 32, as described in detail below.

In one embodiment, referring to fig. 2 to 6, the baffle assembly 30 further includes a baffle member 31 disposed in the air guiding channel 20, wherein an outer edge of the baffle member 31 is connected to an inner wall of the air guiding channel 20, the baffle member 31 is disposed intersecting with the air exhausting direction L1 of the air outlet 21, the air guiding member 32 is configured to rotate in the air guiding channel 20 relative to the baffle member 31, and a plurality of second micro holes 311 for diffusing air flow are formed through the baffle member 31.

The air flow in the air guide passage 20 is buffered, decelerated, and dispersed by the baffle member 31 and the air guide member 32 before being blown out from the air outlet 21. The baffle member 31 can be contoured with the cross-sectional shape of the air guide channel 20, so that the peripheral outer edges of the baffle member 31 are connected with the inner wall of the air guide channel 20, and the air flow in the air guide channel 20 is ensured to be blocked by the baffle member 31 and spread through the second micropores 311.

Thus, even if the air guiding member 32 is in the second state and cannot provide buffering, decelerating and dispersing effects, the baffle member 31 can provide a certain buffering, decelerating and dispersing effects to achieve the effect of dispersing the air.

For example, the air guide duct 20 may be formed in a cylindrical shape, and the baffle member 31 may be formed in a circular plate-like structure and may be fitted inside the air guide duct 20 in the cross-sectional direction of the cylinder.

In one embodiment, the wind guiding member 32 may be rotatably connected to the baffle member 31 or directly rotatably connected to the inner wall of the wind guiding channel 20, so long as the wind guiding member 32 can rotate in the wind guiding channel 20, all are within the scope of the present utility model, and the present utility model is not limited thereto.

The structures of the second micro-holes 311 and the first micro-holes 32111 may be the same or different, and they are used to buffer, slow down and disperse the airflow passing through. For example, referring to fig. 6 to 7, in one embodiment, the first micro-hole 32111 has a contraction section k1 and a diffusion section k3 sequentially arranged along the exhaust direction L1, and after the airflow in the air guiding channel 20 enters the first micro-hole 32111, the airflow first passes through the contraction section k1 and then flows out through the diffusion section k 3.

Further, along the exhaust direction L1, the aperture of the contraction section k1 is gradually reduced, at this time, the contraction section k1 compresses the exhaust air flow, the aperture of the diffusion section k3 is gradually enlarged, and the aperture of the end of the diffusion section k3 away from the contraction section k1 is larger than the aperture of the end of the contraction section k1 away from the diffusion section k 3.

The contraction section k1 forms a smaller chamfer angle, the diffusion section k3 forms a larger chamfer angle, exhaust air flow enters from the smaller chamfer angle and is discharged from the larger chamfer angle after being compressed, and the originally compressed air volume is instantaneously amplified, so that the blocking, buffering and dispersion of the air flow are realized.

Alternatively, a C1 chamfer may be formed at the constriction k1 and a C5 chamfer may be formed at the diffusion k3 to achieve dispersion of the gas flow.

In one embodiment, referring to fig. 7, the first micro-hole 32111 further includes a compression section k2 disposed between the contraction section k1 and the diffusion section k3, where the aperture of the compression section k2 is smaller than or equal to the minimum aperture of the contraction section k1 and the minimum aperture of the diffusion section k3, and the compression section k2 may further compress the air flow flowing from the contraction section k1, thereby improving the diffusion effect.

In one embodiment, the compressing section k2 may have a cylindrical shape with an equal aperture, and the aperture of the compressing section k1 is equal to the aperture of the end connected to the compressing section and the aperture of the end connected to the diffusing section k 3.

The second micro-holes 311 may be equal to the first micro-holes 32111, or may be in other hole structures capable of realizing airflow dispersion and blocking, and the aperture size of the second micro-holes 311 and the aperture size of the first micro-holes 32111 may be the same or different, which specifically needs to be adaptively adjusted according to the specification size of the actual air-conditioning smoke machine 1000.

In one embodiment, along the exhaust direction L1, the baffle member 31 is disposed upstream of the air guiding member 32, and after all buffering, decelerating and dispersing actions are performed on the air flow in the air guiding channel 20 by the baffle member 31, the air flow is secondarily buffered, decelerated and dispersing actions or directly blown out by the air guiding member 32, so that the dispersing effect on the air flow is further enhanced.

In other embodiments, the baffle member 31 may be provided in multiple layers according to practical situations, and the wind guiding member 31 may provide more than one layer of buffering, decelerating and dispersing effects, which is not limited herein.

In one embodiment, referring to fig. 2 to 6, the air guiding member 32 includes at least one set of air guiding plate modules 321, all air guiding plate modules 321 are arranged along a direction intersecting with the air exhausting direction L1, each set of air guiding plate 3211 assembly includes at least one air guiding plate 3211, one end of the air guiding plate 3211 is movably connected with the baffle member 31 and rotatably connected with a fixed supporting point 40, and the air guiding plate 3211 is configured to be capable of rotating around the fixed supporting point 40 relative to the baffle member 31.

The direction intersecting the air discharge direction L1 is defined as a longitudinal extending direction L3 of the air guide plate 3211, and fig. 2 shows an example in which the longitudinal extending direction L3 is perpendicular to the air discharge direction L1. The plurality of groups of air guide plate modules 321 are arranged along the longitudinal extending direction L3, so that a plurality of areas are divided in the air guide channel 20 along the longitudinal extending direction L3, and the air guide plates 3211 in the air guide plate modules 321 in each area can independently rotate, so that the effect of regional regulation in the air guide channel 20 is realized.

Specifically, the fixed supporting point 40 may be a supporting point formed in the air guiding channel 20 fixedly connected to the suspended ceiling 3100, and when the air guiding plate 3211 is stressed, the air guiding plate 3211 rotates around the fixed supporting point 40. It can be understood that, when the air guide 32 is in the first state, the axial directions L2 of the first micro holes 32111 on all the air guide plates 3211 are parallel to the air exhaust direction L1, and when the air guide 32 is in the second state, the axial directions L2 of the second micro holes 311 on all the air guide plates 3211 are perpendicular to the air exhaust direction L1.

In one embodiment, referring to fig. 2 to 6, each set of air deflector modules 321 includes two air deflectors 3211, the two air deflectors 3211 are arranged along a longitudinal extending direction L3, and each air deflector 3211 is provided with a first micropore 32111. One end of each air deflector 3211 is movably connected with the baffle member 31, and the baffle member 31 is configured to reciprocate along the air exhaust direction L1 to drive the two air deflectors 3211 of each air deflector module 321 to rotate around the fixed pivot 40.

By forming a linked relationship between the shutter member 31 and the air guide plate 3211, the air guide plate 3211 can be naturally driven to rotate about the fixed fulcrum 40 when the shutter member 31 is driven to move in the air discharge direction L1. For example, when the baffle member 31 moves to a side close to the ground along the air exhaust direction L1, all the air deflectors 3211 are driven to rotate until the air guide member 32 is switched to the first state, at this time, the air flow in the air guide channel 20 will firstly perform all buffering, decelerating and dispersing effects through one layer of the baffle member 31, and then perform secondary buffering, decelerating and dispersing effects through the air guide member 32, so as to enhance the buffering, decelerating and dispersing effects on the air flow.

When the baffle member 31 moves to a side far away from the ground along the air exhaust direction L1, all the air deflectors 3211 are driven to rotate until the air guide member 32 is switched to the second state, and at this time, the air flow in the air guide channel 20 is directly blown out after all buffering, decelerating and dispersing actions are performed by one layer of the baffle member 31.

In one embodiment, the air conditioning module 100 includes a driving member (not specifically shown in the drawings) drivingly connected to the baffle member 31 for driving the baffle member 31 to reciprocate in the air discharge direction L1.

The driving member may be a conventional driving type structure such as a motor, a cylinder, etc., and the present utility model is not limited thereto, and it will be understood that the total distance of the reciprocating movement of the baffle member 31 in the air exhausting direction L1 is short, and the up-and-down movement thereof will not affect the air exhausting effect.

In one embodiment, referring to fig. 2 to 6, the baffle assembly 30 further includes at least one link 50, one end of each link 50 is rotatably connected to the baffle member 31, and the other end is rotatably connected to one of the air deflectors 3211, and when the baffle member 31 moves in the air exhausting direction L1, the link 50 swings in the air guiding channel 20 and drives the air deflectors 3211 connected thereto to rotate relative to the fixed pivot 40.

The air deflector 3211 is under the dual action of the connecting rod 50 and the fixed supporting point 40, when the baffle member 31 moves, the air deflector 3211 is linked by the connecting rod 50 to provide a force, so that the air deflector 3211 rotates relative to the fixed supporting point 40.

In one embodiment, the range hood module 200 has a high gear for exhausting the oil smoke, and the range hood module 200 is in the high gear, so that the suction force of the oil smoke is strong, and at the moment, the mixing and influence degree of the cold air flow on the cooking hot air flow are high, and the influence on the oil smoke absorbing effect is serious. A higher degree of buffering, decelerating and dispersing of the cool air generated by the air conditioning module 100 is required to reduce the easy direct mixing and interaction of the cool air flow and the cooking hot air flow. Specifically, the baffle member 31 can be driven to move by the driving member, and the air guide member 32 is driven to rotate in the air guide channel 20 to a first state, so that the buffering, decelerating and dispersing effects of at least two layers (the first micropore 32111 and the second micropore 311) are formed, the speed of cold air is finally reduced to the greatest extent, the cold air flow is dispersed more fully, the air outlet 21 of the suspended ceiling 3100 slowly sinks, the body of a cooking person is blown more uniformly, the soft experience of refrigeration and cooling is improved, and the mixing and influence of the cold air flow on the hot air flow of cooking are reduced.

In one embodiment, the range hood module 200 further has a low gear for exhausting oil smoke, and the range hood module 200 is in the low gear, so that the mixing and influencing degree of the cold air flow on the cooking hot air flow are the lowest, the oil smoke exhausting effect is basically not influenced, and only the lowest buffering, decelerating and dispersing of the cold air generated by the air conditioner module 100 is needed. Specifically, the driving member drives the baffle member 31 to move and drives the air guide member 32 to rotate in the air guide channel 20 to the second state, so that the exhaust air flow is only buffered, decelerated and dispersed by a single layer (the second micropores 311), the reduction degree of the flow velocity of the corresponding cold air is minimum, the cold air is dispersed and not directly blown, and the rapid cooling efficiency in the space of the kitchen 3000 is highest.

The range hood module 200 also has a middle gear for exhausting oil smoke, when the range hood module 200 is in the middle gear, the mixing and influencing degree of the cold air flow on the cooking hot air flow are low, and only the cold air generated by the air conditioner module 100 is required to be buffered, decelerated and dispersed to a low degree. Specifically, the baffle member 31 is driven to move by the driving member, and drives the air guide member 32 to rotate in the air guide channel 20 to a third state, so that a certain included angle is formed between the air guide plate 3211 and the baffle plate, a part of exhaust air flow is only blown out after buffering, decelerating and dispersing effects of a single layer (the second micropores 311), and a part of exhaust air flow is buffered, decelerating and dispersing effects of double layers (the first micropores 32111 and the second micropores 311), so that cold air dispersing and non-direct blowing are considered, and cooling efficiency in a space of the kitchen 3000 is improved.

The present utility model also provides an air conditioning module 100 according to any of the above embodiments, and specific features thereof are described above and are not repeated here.

According to another aspect of the present utility model, there is further provided an air outlet method of an air conditioning ventilator, which is applied to the air conditioning ventilator 1000 in any of the above embodiments to control air outlet thereof, referring to fig. 8, the air outlet method specifically includes:

s10, acquiring a smoking gear of the smoke machine module 200;

common gears of the range module 200 can be divided into a high gear, a low gear, and a middle gear between the two gears, wherein the smoke suction of the range module 200 is strongest in the high gear, the smoke suction of the range module 200 is weakest in the low gear, and the smoke suction of the range module 200 is medium in the middle gear. As can be appreciated, the stronger the suction of the fume exhaust fan module 200, the greater its effect on the exhaust air of the air outlet 21.

S20, controlling the air guide 32 to move in the air guide channel 20 according to the smoking gear of the smoke machine module 200 so that the axial direction L2 of the first micro-holes 32111 and the air exhaust direction L1 form different included angles.

So, can adjust the position of wind-guiding piece 32 in wind-guiding passageway 20 according to the strong and weak suction of cigarette machine module 200 to the oil smoke, provide different buffering, speed reduction and dispersion effect, not only can block, cushion and the direction to cold wind, reach the effect of dispersing the air-out, and can be through the dispersion effect to cold wind with wind-guiding piece 32 motion to different positions adjustment. The air flow directly impacting on the air guide piece 32, the air guide piece 32 provides a certain dispersing effect, the air flow which does not impact on the air guide piece 32 is directly blown out from the air outlet 21, and the dispersing effect is weaker.

Thus, the method provided by the utility model can provide cold air with different dispersion effects according to different suction forces of the smoke machine module 200, and avoid the condition that the cold air discharged by the air conditioner module 100 directly reaches the smoke machine module 200 and is sucked away.

In one embodiment, referring to fig. 9, step S20 specifically includes:

s21, judging whether the smoking gear of the smoke machine module 200 is in a high gear, if so, controlling the air guide piece 32 to move in the air guide channel 20 to a first state that the axial direction L2 of the first micropore 32111 is parallel to the air exhaust direction L1;

s22, judging whether the smoking gear of the smoke machine module 200 is at a low gear, if so, controlling the air guide 32 to move in the air guide channel 20 to a second state that the axial direction L2 of the first micro holes 32111 is perpendicular to the air exhaust direction L1.

S23, judging whether the smoking gear of the smoke machine module 200 is at the middle gear, if so, controlling the air guide 32 to move in the air guide channel 20 to a third state that the axial direction L2 of the first micro holes 32111 is intersected with the air exhaust direction L1 and is not vertical.

Specifically, the specific air outlet effects in the first state, the second state, and the third state are described in detail above, which is not repeated herein, and the controller may be provided in the internal structure of the air conditioning ventilator 1000 to obtain and determine the smoking gear of the ventilator module 200, and execute the step S21, the step S22, or the step S23 according to the determination result.

Further, the air conditioner can realize up-and-down adjustment of the baffle member 31 in the air exhaust direction L1 by controlling the driving member, so as to realize control of the air guiding member 32, and the specific content is referred to above, and will not be described again here.

It will be appreciated that the middle gear may refer to one gear or may refer to a plurality of gears, for example, when the smoke machine module 200 has 1, 2, 3, 4, 5-gear smoke extraction gears, 1-gear and 5-gear are high-gear and low-gear, 2, 3, 4-gear are middle gears, and under different middle gears, the axial direction L2 of the air deflector 3211 to the first micro-holes 32111 forms different included angles with the air exhaust direction L1, thereby providing buffering, decelerating and dispersing effects of different degrees.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The foregoing examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the claims. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (13)

1. An air conditioning module for an air conditioning hood, comprising:

the shell (10), offer the air conditioner wind outlet (11) on the said shell (10);

the air guide channel (20) is positioned outside the shell (10), one end of the air guide channel (20) is communicated with the air outlet (11) of the air conditioner, and the other end of the air guide channel is provided with an air outlet (21) positioned outside the shell (10);

the baffle assembly (30) comprises an air guide piece (32) movably arranged in the air guide channel (20), and a plurality of first micropores (32111) for diffusing air flow are formed in the air guide piece (32) in a penetrating manner;

the air guide member (32) has a first state in which an axial direction (L2) of the first micro-hole (32111) is parallel to an air exhaust direction (L1), and a second state in which the axial direction (L2) of the first micro-hole (32111) is perpendicular to the air exhaust direction (L1), and the air guide member (32) is movable in the air guide passage (20) to switch between the first state and the second state.

2. The air conditioning module according to claim 1, wherein the air guide (32) is rotatably disposed in the air guide channel (20), and the air guide (32) further has a third state in which an axial direction (L2) of the first micro-hole (32111) intersects with the air discharge direction (L1) and is non-perpendicular;

the air guide (32) is rotatable within the air guide channel (20) to switch between the first state, the second state and the third state in pairs.

3. The air conditioning module according to claim 2, wherein the baffle assembly (30) further comprises a baffle member (31) disposed in the air guide channel (20), an outer edge of the baffle member (31) is connected with an inner wall of the air guide channel (20), and the baffle member (31) is disposed intersecting the air discharge direction (L1);

the air guide piece (32) is configured to rotate in the air guide channel (20) relative to the baffle piece (31), and a plurality of second micropores (311) for diffusing air flow are formed in the baffle piece (31) in a penetrating manner.

4. An air conditioning module according to claim 3, characterized in that the baffle member (31) is arranged upstream of the air guiding member (32) in the air discharge direction (L1).

5. An air conditioning module according to claim 3, characterized in that the air guide (32) comprises at least one set of air deflector modules (321), all of the air deflector modules (321) being arranged in a direction intersecting the air discharge direction (L1);

each group of air deflector modules (321) comprises at least one air deflector (3211), and one end of each air deflector (3211) is movably connected with the baffle piece (31) and is rotatably connected with a fixed pivot (40);

the air deflector (3211) is configured to be rotatable about the fixed fulcrum (40) with respect to the baffle member (31).

6. The air conditioning module according to claim 5, wherein each set of air deflector modules (321) comprises two air deflectors (3211), the two air deflectors (3211) are arranged along a direction intersecting the air exhaust direction (L1), and the first micropores (32111) are formed in each air deflector (3211);

one end of each air deflector (3211) is movably connected with the baffle piece (31), and the baffle piece (31) is configured to reciprocate along the exhaust direction (L1) so as to drive two air deflectors (3211) in each group of air deflector modules (321) to synchronously rotate around the fixed pivot (40).

7. An air conditioning module according to claim 6, characterized in that the air conditioning module (100) comprises a driving member, which is in driving connection with the baffle member (31) for driving the baffle member (31) to reciprocate in the air discharge direction (L1).

8. The air conditioning module according to claim 6, wherein the baffle assembly (30) further comprises at least one link (50), one end of each link (50) being rotatably connected to the baffle member (31) and the other end being rotatably connected to one of the air deflectors (3211);

when the baffle piece (31) moves along the exhaust direction (L1), the connecting rod (50) swings in the air guide channel (20) and drives the air guide plate (3211) connected with the connecting rod to rotate relative to the fixed supporting point (40).

9. The air conditioning module according to claim 1, characterized in that the first micro-holes (32111) have a constriction section (k 1) and a diffusion section (k 3) arranged in sequence along the air discharge direction (L1), the aperture of the constriction section (k 1) being gradually reduced and the aperture of the diffusion section (k 3) being gradually enlarged along the air discharge direction (L1);

and the aperture of the end of the diffusion section (k 3) far away from the contraction section (k 1) is larger than the aperture of the end of the contraction section (k 1) far away from the diffusion section (k 3).

10. The air conditioning module according to claim 9, wherein the first micro-hole (32111) further has a compression section (k 2) provided between the contraction section (k 1) and the diffusion section (k 3), and a pore diameter of the compression section (k 2) is equal to or smaller than a minimum pore diameter of the contraction section (k 1) and a minimum pore diameter of the diffusion section (k 3).

11. An air conditioning ventilator, characterized by comprising a ventilator module (200) and an air conditioning module (100) according to any of claims 1-10.

12. The air conditioning extractor of claim 11, wherein the extractor module (200) has a high range, a low range for extracting oil smoke;

when the smoke machine module (200) is in the high gear, the air guide piece (32) moves to the first state in the air guide channel (20);

when the range module (200) is in the low range, the air guide (32) moves within the air guide channel (20) to the second state.

13. The air conditioning extractor of claim 12, wherein the extractor module (200) further has a mid range for extracting oil smoke;

when the smoke machine module (200) is in the middle gear, the air guide piece (32) moves in the air guide channel (20) to a third state that the axial direction (L2) of the first micropore (32111) is intersected with the air exhaust direction (L1) and is not perpendicular to the air exhaust direction.