CN220757363U - Induced air mechanism and water vapor separation device - Google Patents

Abstract

The utility model discloses an induced air mechanism which comprises a mounting plate, a thin motor, a connecting cover, fan blades and fan blades, wherein the thin motor is arranged on the mounting plate, a space in the connecting cover accommodates the thin motor, the connecting cover is connected with an output shaft of the thin motor, the fan blades are connected with the connecting cover, and the fan blades are arranged on the fan blades and encircle the connecting cover. The utility model also discloses a water-vapor separation device with the air inducing mechanism. The utility model has the advantage of being capable of compressing the volume.

Description

Induced air mechanism and water vapor separation device

Technical Field

The utility model relates to an air inducing mechanism and a water-vapor separation device, and belongs to the technical field of dish washers.

Background

After the dish washing machine is finished, the residual heat of tableware is higher, more water vapor and water drops are reserved in the inner container, the water vapor is not dehumidified, and then is condensed again to form water drops which are attached to the inner wall and the dishes, so that bacteria are easy to breed. If the water vapor is directly discharged, the humidity of the environment of the dish-washing machine is increased, and the water vapor is attached to the outer shell of the dish-washing machine to influence the environment of a kitchen.

In order to solve the problem, the water-vapor separation device is arranged on the inner container of the dish washer, the wet and hot gas in the inner container is sucked into the water-vapor separation device by the water-vapor separation device, and the dry gas is sent into the inner container for drying after the water-vapor separation. The water-vapor separation device can use the induced air mechanism as the flow of guide gas, but is limited by a narrower space in the water-vapor separation device, so that the space occupied by the general induced draft fan mechanism in the water-vapor separation device is overlarge, and the suitability is poor.

Disclosure of Invention

The utility model aims to solve the technical problem of providing an air inducing mechanism and a water-vapor separation device, which can compress the volume.

The utility model is realized by the following technical scheme.

The utility model provides an induced air mechanism, includes mounting panel, slim motor, junction cover, fan blade board, flabellum, slim motor sets up on the mounting panel, the space in the junction cover holds slim motor, and junction cover and slim motor's output shaft, the flabellum board is connected junction cover, the flabellum sets up on the fan blade board and encircles the junction cover.

As a further development of the utility model, the blade plate is connected to the edge of the connecting cover.

As a further improvement of the utility model, the fan blade comprises a reinforcing frame, and the fan blade is connected with the reinforcing frame.

As a further improvement of the utility model, the part of the fan blade plate in the fan blade is provided with at least one first opening, and the part of the mounting plate in the induced air mechanism is provided with at least one second opening.

As a further development of the utility model, the total area of the first openings is smaller than the total area of the second openings.

As a further improvement of the utility model, the first openings are provided in plurality and are arranged symmetrically about the center of the connection cover, and the second openings are provided in plurality and are arranged symmetrically about the center of the thin motor.

A water vapor separation device comprising:

a housing having a first air inlet, at least one air outlet;

the air inducing mechanism is positioned in the shell, and the first air inlet is used for inputting air and enters an air inlet space in the air inducing mechanism from the front surface of the air inducing mechanism;

the air channel is used for communicating an air inlet space of the air inducing mechanism with an air outlet, and the air outlet is used for outputting gas;

and the water-steam separation device is arranged along at least part of the air duct wall of the air duct.

As a further improvement of the utility model, two air outlets are respectively a first air outlet and a second air outlet, and the air humidity output by the first air outlet is different from the air humidity output by the second air outlet.

A water vapor separation device comprising:

a housing having a first air inlet, a second air inlet, at least one air outlet;

the air inducing mechanism is positioned in the shell, the first air inlet is used for inputting air and enters an air inlet space in the air inducing mechanism from the front surface of the air inducing mechanism, and the second air inlet is used for inputting air and enters the air inlet space in the air inducing mechanism from the back surface of the air inducing mechanism;

the air channel is used for communicating an air inlet space of the air inducing mechanism with an air outlet, and the air outlet is used for outputting gas;

and the water-steam separation device is arranged along at least part of the air duct wall of the air duct.

As a further improvement of the present utility model, the humidity of the gas inputted from the first gas inlet is different from the humidity of the gas inputted from the second gas inlet.

As a further improvement of the utility model, two air outlets are respectively a first air outlet and a second air outlet, and the air humidity output by the first air outlet is different from the air humidity output by the second air outlet.

The utility model has the beneficial effects that:

1. the connecting cover is buckled on the thin motor, so that the edge of the connecting cover is close to the mounting plate, namely the fan blade plate is close to the mounting plate, and the whole structure of the induced air mechanism is flatter and is suitable for a narrow space in the water-vapor separation device;

2. the clearance between the fan blade plate and the mounting plate is smaller, so that water drops can be effectively prevented from leaking, and the problem of water inflow of the thin motor is avoided;

3. the reinforcing frame can play a role in reinforcing the structural strength of the fan blades, and the phenomenon that the fan blades are deformed or damaged due to the impact of gas is avoided;

4. through setting up first trompil and second trompil, formed double suction formula air inlet structure, can introduce two different grade type gases to when using at water vapor separation device, have higher using value.

Drawings

Preferred embodiments of the present utility model will be described in detail below with reference to the attached drawings, to facilitate understanding of the objects and advantages of the present utility model, wherein:

FIG. 1 is a schematic diagram of a wind-guiding mechanism;

FIG. 2 is an exploded view of the induced draft mechanism;

FIG. 3 is a side view of the induced draft mechanism;

FIG. 4 is a schematic view of the water vapor separator in a view;

FIG. 5 is a schematic view of the water vapor separator device in another view;

FIG. 6 is a schematic view of the internal structure of the air duct;

FIG. 7 is a schematic view of the internal structure of the wet air intake duct;

FIG. 8 is a schematic diagram of a water vapor separator device in one embodiment;

FIG. 9 is a schematic cross-sectional view of FIG. 8;

FIG. 10 is a schematic view of a water vapor separator device in another embodiment;

fig. 11 is a schematic cross-sectional view of fig. 10.

Detailed Description

The utility model is described in further detail below with reference to the drawings and the examples.

The terms of orientation such as up, down, left, right, front, rear, front, back, top, bottom, etc. mentioned or possible in this specification are defined with respect to the configurations shown in the drawings, and the terms "inner" and "outer" refer to the relative concepts of the terms toward or away from the geometric center of a particular component, respectively, and thus may be changed accordingly depending on the location and use state of the component. These and other directional terms should not be construed as limiting terms.

Embodiment case 1:

the air inducing mechanism 2 of the embodiment is mainly applied to a water-steam separation device of a dishwasher liner and is used for guiding air to flow. Referring to fig. 1 to 3, the air induction mechanism 2 of the present embodiment includes a mounting plate 21, a thin motor 22, a connection cover 23, a blade plate 24, and blades 25.

Because the space inside the water-vapor separation device is relatively narrow, the air induction mechanism 2 of this embodiment needs to be able to be fitted to the installation in a narrow space.

In this embodiment, the thin motor 22 is disposed on the fan blade plate 24, and the thin motor 22 is a motor with a smaller size and a thinner thickness, and generally adopts a brushless direct current motor (BLDC) technology, which has advantages of high efficiency, low noise, high speed, and the like, and is very suitable for the present embodiment due to the small size of the thin motor 22, so that the volume of the air induction mechanism 2 can be compressed, and in particular, the overall thickness of the air induction mechanism 2 can be compressed.

In this embodiment, the space in the connection cover 23 accommodates the thin motor 22 and is not in contact with the thin motor 22, the connection cover 23 is connected with the output shaft of the thin motor 22, the fan blade plate 24 is connected with the edge of the connection cover 23, the fan blades 25 are arranged on the fan blade plate 24 and encircle the connection cover 23, and the edge of the connection cover 23 is close to the mounting plate 21 due to the fact that the connection cover 23 is buckled on the thin motor 22, namely, the fan blade plate 24 is close to the mounting plate 21, so that the whole structure of the air inducing mechanism 2 is flatter and is adapted to the narrow space in the water-vapor separation device.

In addition, it should be noted that, since the air guiding mechanism 2 of the present embodiment is applied to the water-vapor separation device, the air guided by the air guiding mechanism 2 contains moisture, and since the gap between the fan blade 24 and the mounting plate 21 is small, water drops can be effectively prevented from leaking, and the water inlet problem of the thin motor 22 is avoided.

The induced air mechanism 2 of this embodiment still includes reinforcing frame 26, and reinforcing frame 26 is annular structure to with flabellum 25 fixed connection, reinforcing frame 26 can play the effect of strengthening flabellum 25 structural strength, avoids flabellum 25 to receive the gas impact and leads to deformation or damage the phenomenon emergence.

In the present embodiment, the air guiding mechanism 2 is defined with a front face 2-a and a back face 2-b, the thin motor 22 is turned on to drive the fan blade 24 to rotate, so that the air inlet space 2A in the air guiding mechanism 2 forms a negative pressure environment, and thus, air can enter the air inlet space 2A in the air guiding mechanism 2 through the front face 2-a of the air guiding mechanism 2.

In the present embodiment, the part of the fan blade 24 within the fan blade 25 is provided with at least one first opening 241, and the part of the mounting plate 21 within the induced air mechanism 2 is provided with at least one second opening 211, so that when the induced air mechanism 2 is started, the gas can sequentially pass through the second opening 211 and the first opening 241 and enter the air intake space 2A within the induced air mechanism 2, i.e. the gas can enter the air intake space 2A within the induced air mechanism 2 through the back surface 2-b of the induced air mechanism 2.

The air induction mechanism 2 of the present embodiment forms a double suction type air intake structure by providing the first opening 241 and the second opening 211, can introduce two different types of gases, and has higher application value when used in a water-vapor separation device.

In this embodiment, the total area of the first openings 241 is smaller than the total area of the second openings 211, so that the gas flows into the air intake space 2A of the air introduction mechanism 2 through the rear surface 2-b more smoothly.

In the present embodiment, the first openings 241 are provided in plurality and are arranged symmetrically with respect to the center of the connection cover 23, and the second openings 211 are provided in plurality and are arranged symmetrically with respect to the center of the thin type motor 22, so that the inlet distribution of the gas is maintained uniformly, and the operation stability of the induced draft mechanism 2 is improved.

Embodiment case 2:

referring to fig. 4-11 in combination with fig. 1-3, the water-vapor separation device comprises an air duct 3, wherein the air duct 3 comprises an inertial separation section 3-2, an air return section 3-3 and an exhaust section 3-4, the inertial separation section 3-2 is provided with at least one inertial separation bending part 3-2A, inlets of the air return section 3-3 and the exhaust section 3-4 are connected in parallel to an outlet of the inertial separation section 3-2, the exhaust section 3-4 is positioned on an outer bending side of the closest inertial separation bending part 3-2A, and the air return section 3-3 is positioned on an inner bending side of the closest inertial separation bending part 3-2A.

The water-steam separation device of the embodiment is applied to the inner container of the dish-washing machine, and has the main functions of dividing the gas which flows through the air duct 3 and has certain humidity into high-humidity gas and low-humidity gas, wherein the low-humidity gas can be used for drying bowls and chopsticks in the inner container of the dish-washing machine, and the high-humidity gas is discharged out of the inner container of the dish-washing machine. The gas flowing in the air duct 3 can generate a gradient in moisture content when flowing through the inertia separation bending part 3-2A, the moisture content of the gas which is closer to the outer bending part 3-2A is higher, the moisture content of the gas which is closer to the inner bending part 3-2A is lower, and the gas flows into the air return section 3-3 and the exhaust section 3-4 by utilizing the characteristic and according to the arrangement of the positions of the air return section 3-3 and the exhaust section 3-4, the moisture content of the part of the gas flowing into the air return section 3-3 is obviously lower than that of the part flowing into the exhaust section 3-4, namely, the split flow is formed, the low-moisture gas flows into the air return section 3-3, and the high-moisture gas flows into the exhaust section 3-4.

As for the arrangement number and distribution positions of the inertia separation bending parts 3-2A of the inertia separation section 3-2, comprehensive consideration needs to be carried out according to the length of the air duct 3, the water-vapor separation amount requirement and other factors.

In this embodiment, the inlet level of the return air section 3-3 and the exhaust air section 3-4 is higher than the first air outlet k1. The inner container of the dish washer can prevent washing water from flowing into the exhaust section 3-4 from the inlet of the exhaust section 3-4 beyond the inlet of the return air section 3-3 in the washing process, so that the inner circulation in the inner container and the outer circulation outside the inner container are kept relatively stable.

In the present embodiment, the air return section 3-3 is provided with the heating member 34, which can heat the low-humidity air flowing through the air return section 3-3, so that the drying effect of the low-humidity air flowing back into the inner container from the first air outlet k1 is more excellent.

In this embodiment, the heating part 34 includes a plurality of heating plates 341, where the heating plates 341 are disposed along the extending direction of the air return section 3-3 and are spaced apart from each other, and a circulation gap allowing the low-moisture air to pass through is formed between adjacent heating plates 341, and the heating plates 341 can be specifically made of PTC heating elements, which have advantages of small thermal resistance and high heat exchange efficiency, and are particularly suitable for heating air. The flow gap formed between the adjacent heating sheets 341 does not affect the flow of the low-humidity gas in the return air section 3-3, and the low-humidity gas can sufficiently contact the heating sheets 341 on both sides when passing through the flow gap, thereby improving the heating effect of the heating sheets 341 on the low-humidity gas.

In order to enhance the separation effect of the inertial separation section 3-2 on the moisture in the gas, in this embodiment, a wire mesh structure (not shown in the figure) is arranged in the inertial separation section 3-2, the specific setting position of the wire mesh structure is located in the middle flow channel in the inertial separation section 3-2, the setting of the wire mesh structure increases the solid area contacted with the inertial separation section 3-2 and the gas, so that the moisture of the gas is trapped when the gas flows through the wire mesh structure, the moisture separation of the gas and the moisture is realized, the overall moisture content of the gas is reduced, and the moisture content of the low-humidity gas flowing back into the liner of the dish washer can be further reduced, so that the dish washer has better drying effect. The silk screen structure is usually made of metal materials, and the structure strength is stable and not easy to damage, so that the water-vapor separation effect of the silk screen structure is well maintained.

In the embodiment, the air duct 3 further comprises a volute section 3-1, the volute section 3-1 is connected with an inlet of the inertial separation section 3-2, and an air inducing mechanism 2 is arranged in the volute section 3-1.

As shown in embodiment 1, the air inducing mechanism 2 forms a negative pressure environment under the rotation of the air inducing mechanism 2, hot and humid air in the inner container of the dish washer can be pumped into the air duct 3 under the action of the negative pressure environment, and the volute section 3-1 is matched with the centrifugal action of the air inducing mechanism 2, so that the mixed air has excellent flowing performance in the air duct 3, the resistance in flowing is reduced, and the wind noise is reduced.

In this embodiment, the air duct 3 has an air duct wall 31, and the air duct 3 is provided with a water-vapor separation structure along at least part of the air duct wall 31, and the water-vapor separation structure can perform water-vapor separation treatment on the gas flowing in the air duct 3 to reduce the moisture content thereof, so that the moisture content of the low-moisture gas flowing back into the inner container of the dish washer is lower, and a better drying effect is obtained.

In this embodiment, the inner side of the air duct wall 31 is provided with an inner peripheral wall 32 spaced therefrom, and the water-vapor separation structure includes a plurality of water removal openings 32a, the water removal openings 32a being spaced apart along the extending direction of the inner peripheral wall 32. The water-vapor separation structure of the present embodiment is at least disposed on the inner wall 32 corresponding to the volute section 3-1 and the inner wall 32 corresponding to the outer bend of the inertial separation bending portion 3-2A. The hot and humid gas is pumped into the air inlet space 2A in the induced draft mechanism 2 and is thrown out to the volute section 3-1, firstly, the mixed gas forms flowing water drops on the inner peripheral wall 32 of the volute section 3-1, and enters the drainage channel 3A through the water removal port 32A, so that the water-vapor separation effect of the volute section 3-1 on the mixed gas is formed. The mixed gas flows along the air duct 3, and when flowing through the inertial separation section 3-2, particularly the inertial separation bending part 3-2A, under the action of inertia, the mixed gas forms flowing water drops on the inner peripheral wall 32 corresponding to the outer bending of the inertial separation bending part 3-2A, and enters the water drainage channel 3A through the water removal port 32A, so that the water-vapor separation effect of the inertial separation section 3-2 on the mixed gas is formed. In the case where the moisture content of the hot and humid gas is large, the water droplets form a thin and flowing film of water on the inner peripheral wall 32, and can be continuously discharged from the water discharge port 32a into the water discharge passage 3A.

In the present embodiment, the drain 3A is communicated with the exhaust section 3-4, and water droplets entering the drain 3A through the dewatering port 32a finally flow into the exhaust section 3-4 and are discharged together with the high-humidity gas, so as to solve the problem of the treatment of separated water after the water-vapor separation. Because exhaust section 3-4 is arranged outside the dish washer inner bag, consequently under the continuous effect of steam separator of this embodiment, the moisture content in the dish washer inner bag can obtain gradually reducing, is favorable to whole internal environment stoving effect and the efficiency in the dish washer inner bag.

The water-vapor separation device of the embodiment further comprises a shell 1, the shell 1 is provided with a first air inlet d1, a first air outlet k1 and a second air outlet k2, the air duct 3 is arranged in the shell 1, the first air inlet d1 is communicated with an air inlet space 2A in the air inducing mechanism 2, and damp and hot air enters the air inlet space 2A through the front face 2-a of the air inducing mechanism 2.

The first air outlet k1 and the second air outlet k2 are respectively communicated with the air return section 3-3 and the exhaust section 3-4. The water-steam separation device of this embodiment is applied on the dish washer inner bag, under the effect of induced air mechanism 2, can be with the wet and hot gas in the dish washer inner bag by first air inlet d1 suction wind channel 3, the low wet gas of final production is by first gas outlet k1 backward flow to the dish washer inner bag in drying, and high wet gas then is outside the dish washer inner bag by second gas outlet k2 discharge dish washer inner bag, under water-steam separation device's continuous operation, can reduce the humidity in the dish washer inner bag gradually to make its stoving effect better.

The housing 1 is provided with a wet air inlet 4, and the inlet of the wet air inlet 4 forms a first air inlet d1.

The wet air inlet channel 4 is provided with a backwater bend 41, and the horizontal position of the backwater bend 41 is higher than that of the first air inlet d1, so that washing water is difficult to pass through the backwater bend 41 in the washing process of the inner container of the dish washer, and flows into the air inlet space 2A in the air inducing mechanism 2 along the wet air inlet channel 4, and washing water is prevented from flowing into the air duct 3.

The moisture air inlet channel 4 is provided with two air inlet bent parts 42 with the same turning direction, the backwater bend 41 is positioned between the two air inlet bent parts 42, the two air inlet bent parts 42 arranged at the upstream and downstream of the backwater bend 41 increase the bending quantity of the moisture air inlet channel 4, and the difficulty of washing water entering the air channel 3 is further improved.

The downstream department at return water bend 41 of moisture intake duct 4 is equipped with screen cloth structure (not shown in the drawing), and the wet and hot gas in the dish washer inner bag takes place to contact with it when flowing through screen cloth structure, and screen cloth structure can promote the moisture coalescence benefit in the wet and hot gas, promotes the water droplet that is the granule in the wet and hot gas to form bigger water droplet to be favorable to the water vapor separation structure in the wind channel 3 to carry out water vapor separation to it, further strengthen water vapor separation effect. The screen structure can be made of metal materials, and the structure strength is stable and not easy to damage.

In another embodiment, the housing has a second air inlet d2, the second air inlet d2 being in communication with the air intake space 2A of the air introduction mechanism 2, and the drying gas is introduced into the air intake space 2A through the rear face 2-b of the air introduction mechanism 2.

The second air inlet d2 is used for introducing dry air outside the inner container of the dish washer into the air inlet space 2A, and the dry air and the wet and hot air are mixed into mixed air in the air inlet space 2A. The inlet of the air intake duct 5 forms a second air inlet d2, the outlet of the wet air intake duct 4 and the outlet of the air intake duct 5 respectively correspond to two sides of the air guiding mechanism 2, that is, the wet hot air and the dry air respectively enter the air intake space 2A inside the air guiding mechanism 2 from two sides of the air guiding mechanism 2, and it should be noted that two sides of the air guiding mechanism 2 are two virtual sides defined by the shape of the air guiding mechanism 2 and are not real sides. The moisture inlet duct 4 and the air inlet duct 5 are each of a flattened structure and are spaced apart in the thickness direction of the housing 1, so that the size of the volume occupied by the housing 1 can be compressed, facilitating the spatial layout on assembly.

The semiconductor refrigerating sheet 6 is arranged in the shell 1, the semiconductor refrigerating sheet 6 is also called a hot spot refrigerating sheet, the principle is that the Peltier effect of semiconductor materials is utilized, when direct current passes through a couple formed by connecting two different semiconductor materials in series, heat can be respectively absorbed and released at two ends of the couple, and the purposes of refrigeration and heating can be realized. The semiconductor refrigeration sheet 6 of this embodiment absorbs heat and emits heat on two surfaces respectively, that is, a cold surface and a hot surface are formed, and the cold surface and the hot surface of the semiconductor refrigeration sheet 6 are both provided with a plurality of heat exchange fins 61 and 62, so that the heat exchange fins 61 on the cold surface can absorb heat and the heat exchange fins 62 on the hot surface can emit heat.

In one embodiment, the projections of the air inlet 5 and the exhaust section 3-4 in the thickness direction of the housing 1 have overlapping portions, the heat exchanging fins of the cold face are located in the exhaust section 3-4, and the heat exchanging fins of the hot face are located in the air inlet 5. The heat exchange fins 61 on the cold surface can absorb heat in the exhaust section 3-4, condense the high-humidity gas in the exhaust section 3-4, and reduce the water vapor content in the high-humidity gas, thereby preventing the kitchen environment from being wet due to more water vapor in the high-humidity gas discharged by the second air outlet k 2. The heat exchange fins 62 on the hot surface can release heat in the air inlet channel 5, and heat the dry air entering the air inlet channel 5 from the second air inlet d2, so that the temperature of the low-humidity gas finally output by the first air outlet k1 is increased, and the drying effect in the liner of the dish washer is facilitated.

In another embodiment, the projections of the air inlet 5 and the moisture inlet 4 in the thickness direction of the shell 1 have overlapped parts, the heat exchanging fins 61 on the cold surface of the semiconductor refrigerating plate 6 are positioned in the moisture inlet 4, and the heat exchanging fins 62 on the hot surface are positioned in the air inlet 5. The heat exchange fins 61 on the cold surface can absorb heat in the wet gas inlet channel 4, the wet and hot gas entering the wet gas inlet channel 4 is condensed through the first air inlet d1, moisture in the wet and hot gas can be condensed out in advance, on one hand, the water-vapor separation load of a water-vapor separation structure in the subsequent air channel 3 can be lightened, on the other hand, large granular water drops formed by condensation in advance have larger inertia compared with small granular water drops, and when mixed gas flows through the inertia separation bending part 3-2A, more water drops can be formed on the inner peripheral wall 32 corresponding to the outer bending of the mixed gas and enter the water drainage channel 3A through the dehydration opening 32A, so that the water-vapor separation performance of the subsequent water-vapor separation structure can be improved, and the water-vapor separation effect is improved. The heat exchanging fin 62 of the hot surface can release heat in the air inlet 5, and heat the dry air entering the air inlet 5 from the second air inlet d2, so that the temperature of the mixed gas formed by mixing the dry gas and the hot humid gas is not reduced, and therefore, the temperature of the low-humidity gas flowing back into the inner container of the dish-washing machine can be basically maintained unchanged, the water content of the low-humidity gas is further reduced, and the drying effect in the inner container of the dish-washing machine is facilitated.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and not for limiting the same; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme recorded in each embodiment can be modified or part of technical features in the technical scheme can be replaced equivalently; such modifications and substitutions do not depart from the spirit of the utility model.

Claims (11)

1. The utility model provides an induced air mechanism, its characterized in that includes mounting panel, slim motor, junction cover, fan blade board, flabellum, slim motor sets up on the mounting panel, the space in the junction cover holds slim motor, and junction cover and slim motor's output shaft, the flabellum board is connected junction cover, the flabellum sets up on the fan blade board and encircles the junction cover.

2. The air induction mechanism of claim 1, wherein said fan blade plate is attached to an edge of said attachment cover.

3. The air induction mechanism of claim 1, further comprising a stiffening frame, wherein the fan blade is coupled to the stiffening frame.

4. A wind-guiding mechanism according to any of claims 1-3, wherein the part of the blade plate within the blade is provided with at least one first aperture and the part of the mounting plate within the wind-guiding mechanism is provided with at least one second aperture.

5. The air induction mechanism of claim 4, wherein the total area of the first apertures is less than the total area of the second apertures.

6. The air induction mechanism of claim 4, wherein the first opening is provided in plurality and is disposed symmetrically about a center of the connecting cover, and the second opening is provided in plurality and is disposed symmetrically about a center of the thin motor.

7. A water vapor separator device, comprising:

a housing having a first air inlet, at least one air outlet;

a wind-guiding mechanism according to any one of claims 1-3, located within the housing, the first gas inlet for inputting gas and entering the gas inlet space within the wind-guiding mechanism from the front side of the wind-guiding mechanism;

the air channel is used for communicating an air inlet space of the air inducing mechanism with an air outlet, and the air outlet is used for outputting gas;

and the water-steam separation device is arranged along at least part of the air duct wall of the air duct.

8. The water-vapor separator according to claim 7, wherein two gas outlets are provided, namely a first gas outlet and a second gas outlet, and the gas humidity output by the first gas outlet is different from the gas humidity output by the second gas outlet.

9. A water vapor separator device, comprising:

a housing having a first air inlet, a second air inlet, at least one air outlet;

an air induction mechanism according to any one of claims 4 to 6, located within the housing, the first air inlet for inputting air into the air intake space within the air induction mechanism from the front of the air induction mechanism, and the second air inlet for inputting air into the air intake space within the air induction mechanism from the back of the air induction mechanism;

the air channel is used for communicating an air inlet space of the air inducing mechanism with an air outlet, and the air outlet is used for outputting gas;

and the water-steam separation device is arranged along at least part of the air duct wall of the air duct.

10. The water vapor separator device of claim 9, wherein the humidity of the gas input to the first gas inlet is different from the humidity of the gas input to the second gas inlet.

11. The water-vapor separator according to claim 9, wherein two gas outlets are provided, namely a first gas outlet and a second gas outlet, and the gas humidity output by the first gas outlet is different from the gas humidity output by the second gas outlet.