WO2019075874A1 - Flow guiding device for air conditioner, heat dissipating method, air conditioner and auxiliary device - Google Patents

Abstract

A flow guiding device for an air conditioner, a heat dissipating method, the air conditioner and an auxiliary device. A flow guiding device (1) is provided between a condenser fan (41) and a condenser coil (42) in an air conditioner (4), and the flow guiding device (1) is obliquely arranged on a bottom surface (48) in the air conditioner (4); the flow guiding device (1) comprises a plate body (10) and a plurality of flow guiding members (3), the plate body (10) having a plurality of holes (14) which penetrate the plate body (10) and a plurality of flow guiding protrusions (2) spaced apart on two opposite sides of the plate body (10), a plurality of concave areas (13) being located between the spaced-apart flow guiding protrusions (2); the flow guiding members (3) are disposed in the concave areas (13) and a part of the holes (14) on two plate faces (11) are engaged with the flow guiding members (3); and when the condenser fan (41) generates an air flow, part of the air flow passes through the flow guiding protrusions (2), and the flow guiding members (3) drive water vapor on the bottom surface (48) in the air conditioner (4) to move to the condenser coil (42). An auxiliary device (5) may also be provided on the flow guiding device (1) to increase the wind pressure so that the condenser coil (42) may be cooled more quickly.

Description

Flow guiding device for air conditioner, heat dissipation method, air conditioner and auxiliary device Technical field

The invention relates to a flow guiding device used in an air conditioner, an auxiliary device for improving heat dissipation of a flow guiding device, and a heat dissipating method thereof, in particular to a flow regulating speed of a heat dissipating airflow in an air conditioner by using a diversion device and an auxiliary device. The purpose of accelerating the discharge of hot exhaust gas and dust inside the air conditioner is achieved.

Background technique

As technology advances, people's quality of life also increases, but the benefits of technological advancement are not only benefits, but also negative damage. As the problem of global warming has become more serious, people have gradually begun to pay attention to environmental protection issues, and many products for environmental protection have followed.

At present, the air-conditioning products that are visible in the market are characterized by energy-saving. However, people ignore the issue of heat-dissipation of air-conditioning, and the hot air emitted by them has had a great impact on the environment, such as air pollution and heat pollution. The hot air emitted by a large number of air conditioners will form a heat island effect in urban areas higher than that in suburban rural areas, making the urban area as uncomfortable as an oven, and long-term operation of air conditioners at high temperatures will reduce the working efficiency and shorten the life expectancy. Damage due to overheating.

In addition, some existing air-conditioning equipment use the content fan to directly bring up the water vapor generated during the operation, so that the water vapor can be discharged outward with the wind, but the disadvantage is that the fan and the bottom of the air-conditioning device still need to have a height. Avoid the fan hitting the bottom and destroying it, so there will still be residual water left on the bottom surface and cannot be discharged. Furthermore, some of the dust will settle on the bottom surface and will not be discharged with the wind. After a certain period of time, it will adhere to the bottom surface, which indirectly affects the efficiency of heat dissipation.

In summary, how to quickly reduce the temperature inside the air conditioner has been discussed by the practitioners. For this reason, most of the operators have invested a large amount of money to try to develop air-conditioning equipment to solve the problem of enhanced gas speed to solve the problem of hot exhaust gas, but so far there is no comparison. Good solution.

Summary of the invention

In order to solve the above problems, the inventors have invented a device provided in an air conditioner and a heat dissipating method thereof to enhance the flow velocity of the heat dissipating airflow, and to obtain the moisture generated during the operation of the air conditioner and the dust inside the air conditioner. The foreign matter is accelerated and discharged outside the air conditioner. Furthermore, the invention can also improve the heat exchange efficiency of the air conditioner, thereby improving the cooling and energy saving effects.

In order to achieve the above object, the present invention provides a flow guiding device in an air conditioner, the air conditioner includes a condenser fan and a condenser coil, and the operating condenser fan can generate an air flow toward the condenser disk to define a flow blowing direction, the flow guiding device is obliquely disposed on a bottom surface of the air conditioner; the flow guiding device comprises a plate body and a plurality of flow guiding members, wherein the plate body has a plurality of holes and a plurality of diversion holes penetrating the plate body itself a convex portion, the hole penetrates the opposite plate faces of the plate body, the flow guiding convex portion is spaced apart on opposite sides of the plate body, and the adjacent two guiding flow convex portions are defined as a concave portion; and the plurality of the flow guiding members are disposed a plurality of the recessed regions, and a portion of the holes on the two plates are engaged with the flow guiding member; wherein the inclined flow guiding device is interposed between the condenser fan and the condenser coil, wherein one of the plates Facing the windward side of the condenser fan, the windward side is inclined at an angle with the bottom surface, so that when the portion of the condenser fan that is operated moves the airflow toward the windward side, part of the airflow can be driven by the flow guiding convex portion and the flow guiding member. Bottom A blowing water vapor along the gas flow direction to move the condenser coil, thereby improving the heat exchange efficiency of the air conditioner, to enhance the effectiveness of cooling and energy conservation.

Further, the holes on the plate that are not connected to the flow guiding members can enhance the flow of the airflow.

Further, each of the flow guiding members is a solid cylinder, or each of the flow guiding members is a hollow cylinder, or part of the flow guiding members is a solid cylinder, and some of the guiding members are hollow cylinders. Wherein, when the flow guiding member is a hollow cylinder to be combined with the hole, the hollow cylinder has a front end surface and a connecting bottom surface engaged with the hole, and the front end surface is a flat shape or a non-rule. Thereby, the flow of the airflow can be effectively disturbed, thereby increasing the airflow speed.

Further, each of the flow guiding members on each of the concave regions further has an air hole penetrating through itself, wherein a central axis of the flow guiding member and a stomata axis of the air vent are perpendicular to each other, thereby enhancing the flow of the airflow.

Further, the guiding convex portion is a flat plate or a convex block, wherein the flat plate and the plate body form a slanting angle, and the protruding block protrudes from the plate surface and has a curved curved surface, thereby effectively disturbing and guiding the flow of the airflow. , thereby increasing the airflow speed.

Also, the height of the flow guiding device is lower than a fan axis of the condenser fan.

In order to achieve the above object, the present invention provides a heat dissipation method for discharging waste heat in an air conditioner, which is provided with a flow guiding device as described above in an air conditioner, wherein the flow guiding device is located in a condenser fan and a condenser in the air conditioner. Between the coils, and obliquely disposed on the bottom surface of the air conditioner, wherein when the condenser fan operates to generate airflow, a portion of the airflow toward the windward side passes through the flow guiding convex portion of the deflector and the flow guiding member drives the air conditioner The water vapor on the bottom of the inner part moves toward the condenser coil in the direction of the air flow. Through this method, the airflow speed can be enhanced, the heat exchange efficiency of the air conditioner can be improved, the cooling and energy saving effects can be improved, and the same advantages as the foregoing can be achieved.

In order to achieve the above object, the present invention further provides an air conditioner comprising a casing, a condenser fan, a condenser coil, an evaporator fan, an evaporator coil, a compressor, an expansion valve and a controller, a condenser fan, a condenser coil, an evaporator fan, the evaporator coil, a compressor and an expansion valve are disposed in the housing, and the controller is electrically connected to the condenser fan, the evaporator fan and the compressor, And one end of the condenser coil is connected to the compressor, and the other end is connected to the expansion valve; one end of the evaporator coil is connected to the compressor, and the other end is connected to the expansion valve; the condenser fan faces the condenser coil, and the evaporator fan faces An evaporator coil; a flow guiding device as described above is disposed between the condenser fan and the condenser coil, and the flow guiding device is obliquely disposed on a bottom surface of the air conditioner. Through the setting of the flow guiding device, the rapid flow of air inside the air conditioner can be greatly enhanced, and the performance of the air conditioner can be improved.

In order to achieve the above object, the present invention further provides an auxiliary device for enhancing and accelerating heat dissipation of the flow guiding device. The auxiliary device is disposed above the flow guiding device as described above, wherein the auxiliary device comprises a piece body and a plurality of wind blocking members, and the wind blocking device The members are disposed equidistantly disposed on one of the surfaces of the sheet body, wherein the auxiliary device is used to enhance and accelerate the water vapor driven by the flow guiding device to move toward the condenser coil along the wind blowing direction. By adding the auxiliary component to the flow guiding device, the flow velocity of the airflow can be further increased, and the heat exchange efficiency of the air conditioner can be improved, thereby improving the cooling and energy saving effects.

DRAWINGS

The following drawings are only intended to illustrate and explain the present invention, and do not limit the scope of the invention. among them:

1 is a perspective perspective view showing the components of the air conditioner and the flow guiding device of the present invention;

2 is a perspective view showing the flow guiding device of the present invention disposed in an air conditioner;

3A is a side elevational view showing one embodiment of the inclined flow guiding device of the present invention in an air conditioner;

3B is a side view showing another embodiment of the inclined flow guiding device of the present invention in an air conditioner;

Figure 4 is a schematic view of a preferred embodiment of the flow guiding device of the present invention;

Figure 5 is a schematic view showing another mode of the flow guiding member of the flow guiding device of the present invention;

Figure 6 is a schematic view showing another mode of the flow guiding convex portion of the flow guiding device of the present invention;

Figure 7 is a perspective perspective view showing the components of the air conditioner and the flow guiding device and the auxiliary device of the present invention;

Figure 8 is a perspective view showing the flow guiding device and the auxiliary device of the present invention disposed in the air conditioner;

Figure 9 is a schematic view of a preferred embodiment of the auxiliary device of the present invention;

Figure 10 is a top plan view showing one of the modes in which the auxiliary device of the present invention is disposed toward the condenser fan;

Figure 11 is a top plan view showing another mode in which the auxiliary device of the present invention is reversely disposed toward the condenser fan;

Figure 12 is a partial side elevational view showing the flow guiding device and the auxiliary device of the present invention disposed in the air conditioner;

Figure 13 is a schematic view showing different shapes of the wind blocking members of the auxiliary device of the present invention;

Figure 14 is a schematic view showing the wind blocking members of the auxiliary device of the present invention in different wavy patterns;

Fig. 15 is a schematic view showing the wind blocking member of the auxiliary device of the present invention in an integrally formed pattern.

Description of the reference numerals:

1 deflector 43 evaporator fan

10 plate body 44 evaporator coil

11 board surface 45 compressor

12 side 46 expansion valve

13 recessed area 47 controller

14 holes 48 underside

2 guide vanes 49 fan shaft

20 flat panel 5 auxiliary device

21 bumps 50 pieces

211 curved surface 500 surface

3 flow guiding member 501 surface

301 hollow cylinder 51 wind blocking member

302 solid cylinder 510 hole

31 Connect the bottom surface D Airflow direction

32 front end face F windward side

33 vent θ angle

4 air conditioner θ1 tilt angle

40 housing W water gas

41 condenser fan Ф1 central axis

42 condenser coil Ф2 vent hole axis

Detailed ways

The embodiments of the present invention are described below by way of specific examples, and those skilled in the art can readily understand the advantages and effects of the present invention from the disclosure of the present disclosure. In addition, the present invention may be embodied or applied in various other embodiments without departing from the spirit and scope of the invention.

1 is a perspective perspective view showing the arrangement of various parts in an air conditioner; FIG. 2 is a perspective view showing the flow guiding device of the present invention disposed in an air conditioner; and FIGS. 3A-3B are side views of the flow guiding device of the present invention disposed in an air conditioner; Configuration diagram. As shown in FIG. 1, the air conditioner 4 includes a casing 40, a condenser fan 41, a condenser coil 42, an evaporator fan 43, an evaporator coil 44, a compressor 45, and an expansion valve 46. A controller 47. The condenser fan 41, the condenser coil 42, the evaporator fan 43, the evaporator coil 44, the compressor 45 and the expansion valve 46 are disposed in the casing 40; the controller 47 is electrically connected to the condenser fan 41 and evaporates. The fan 43 and the compressor 45; one end of the condenser coil 42 communicates with the compressor 45 and the other end communicates with the expansion valve 46; one end of the evaporator coil 44 communicates with the compressor 45 and the other end communicates with the expansion valve 46. In general, the condenser fan 41 faces the condenser coil 42 and the evaporator fan 43 faces the evaporator coil 44. In this regard, FIG. 1 only schematically illustrates common parts of a general air conditioner, and is not shown as a limitation.

Regarding the arrangement of the flow guiding device of the present invention, as shown in FIGS. 1 , 2 and 3A to 3B , the flow guiding device 1 is obliquely disposed between the condenser fan 41 and the condenser coil 42 , and the flow guiding device The height of 1 is lower than the axial center 49 of the condenser fan 41, and thus the airflow generated by the operating condenser fan 41 is first blown to the condenser coil 42 by the flow guiding device 1.

In order to make the invention easier to understand its structure and its operation, it is explained by different figures, but the actual scope is still based on the scope of patent application.

4 to 6 show a preferred embodiment of the flow guiding device of the present invention for explaining different embodiments of the flow guiding device. Referring first to FIG. 4, the flow guiding device 1 includes a plate body 10 and a plurality of flow guiding members 3, wherein the plate body 10 has a plurality of holes 14 penetrating the plate body 10 itself and a plurality of flow guiding protrusions 2, and The holes 14 are formed through the opposite plate faces 11 of the plate body 10. The flow guiding protrusions 2 are spaced apart from the opposite sides 12 of the plate body 10. The two adjacent flow guiding protrusions 2 are defined as a recessed area 13. A plurality of flow guiding members 3 are provided in each of the recessed portions 13 of the plate body 10, and a part of the holes 14 on the two plate faces 11 are engaged with the flow guiding members 3, that is, each of the holes 14 on the plate surface 11 is not actually It is necessary to fully integrate the flow guiding member 3.

Referring to FIG. 4, each of the flow guiding members 3 is a solid cylinder 302, or each of the flow guiding members is a hollow cylinder 301, or part of the flow guiding member 3 is a solid cylinder 302, and a portion thereof. The flow guiding member 3 is a hollow cylinder 302. When the flow guiding member 3 is combined with the hole 14, the hollow cylindrical body 301 has a connecting bottom surface 31 and a front end surface 32. The bottom surface 31 is connected to the hole 14. And the front end face 32 can also have a different structure, as shown in FIG. 4, the front end face 32 is planar, and in FIG. 5, the front end face 32 is an irregular jagged surface. Herein, if the flow guiding member 3 is a hollow cylinder 301, the airflow operation can be made smoother. Otherwise, when the flow guiding member 3 is a solid cylindrical body 302, the airflow can be shunted, thereby causing a spoiler phenomenon, which is solid or hollow. Diversion The member 3 can effectively enhance the flow velocity of the airflow, and more quickly take out foreign matter such as a water vapor W and dust (not shown) inside the air conditioner 4 as shown in FIGS. 3A to 3B.

Further, in order to accelerate the operation of the airflow passing through the flow guiding member 3, each of the flow guiding members 3 located on the respective recessed portions 13 may have an air hole 33 penetrating through itself. As shown in FIG. 5, the pinhole axis 2 of the air hole 33 penetrates the flow guiding member 3, that is, a central axis Ф1 of the flow guiding member 3 and the stomata axis Ф2 of the air hole 33 are perpendicular to each other.

In order to more effectively interfere with the flow of the airflow, thereby increasing the airflow velocity, and guiding the flow direction of the airflow, the flow guiding protrusion 2 is preferably designed as a flat plate 20 or a bump 21 in this embodiment. Specifically, as shown in FIG. 4 to FIG. 5, the guiding protrusion 2 is a flat plate 20 to form an inclined angle θ1 with the plate body 10, and the inclination angle θ1 can be changed from 0 to 180 degrees according to actual use. In FIG. 6, in particular, the lower flow guiding convex portion 2, that is, the flow guiding convex portion 2 which is close to the bottom surface of the air conditioner, if the convex block 21 extends from the plate surface 11 and has a curved curved surface 211.

Hereinafter, the heat dissipation method by the flow guiding device will be described with the angle of the flow guiding device 1 coupled to the air conditioner 4. Since the internal components of the air conditioner have been described in detail above, the internal components of the air conditioner will not be described here.

Referring to FIGS. 3A-3B, the inclined flow guiding device 1 is interposed between the condenser fan 41 and the condenser coil 42, and the height of the flow guiding device 1 is lower than the axial center 49 of the condenser fan 41, one of which is The face 11 faces the windward side F of the condenser fan 41, and the face 11 is inclined to the windward side F to form an angle θ with the bottom face 48, that is, the face 11 of the leeward face faces the condenser coil 42. Therefore, when part of the airflow of the operating condenser fan 41 moves toward the windward side F, a part of the flow passes through the flow guiding protrusion 2 of the flow guiding device 1 and the flow guiding member 3 to drive the water vapor W on the bottom surface 48 to blow along the airflow. Direction D moves toward condenser coil 42. As can be seen from the above, the arrangement of the flow guiding device 1 can effectively guide and interfere with the flow direction and speed of the airflow, and the water vapor W and the dust on the bottom surface 48 in the casing 40 can be more quickly increased due to the enhanced flow velocity of the airflow ( The foreign matter is taken out of the casing 40 of the air conditioner 4, and the water vapor W can also be used to lower the internal temperature of the air conditioner 4.

Further, FIG. 3A is an embodiment of the inclined flow guiding device 1. The windward side F of the panel surface 11 forms an angle θ "less than" 90 degrees with the bottom surface 48 of the air conditioner 4, whereby the flow guiding device 1 It will cause a large wind pressure, and the relative air flow rate is also strong, thereby forcibly applying pressure to the airflow to flow the airflow along the windward side F to the bottom surface 48 in the air conditioner 4, and using the airflow to the air conditioner 4 The water vapor W of the bottom surface 48 is brought upward, and the water vapor W taken out by the airflow is carried to the condenser coil 42 by the air flow blowing direction D formed by the condenser fan 41.

On the other hand, Fig. 3B is another embodiment of the inclined flow guiding device 1, and the flow guiding device 1 is inclined in the other direction, even if the windward side F of the plate surface 11 forms an angle θ with the bottom surface 48 in the air conditioner 4. "greater than" 90 degrees, Therefore, the flow guiding device 1 causes a small wind pressure, and the flow velocity of the airflow is relatively weakened. Therefore, it is understood that the effect of adjusting the airflow velocity and guiding the airflow blowing direction D can be achieved by using different inclination angles.

By changing the inclination direction of the windward side F of the flow guiding device 1, the speed of the airflow can be adjusted, so that the flow guiding device 1 can change the design of the heat dissipation of the air conditioner according to the climate of each country or region. The shape and installation position of the flow guiding device are not limited to the drawings.

Next, FIG. 7 to FIG. 15 show another preferred embodiment. The present invention provides an auxiliary device for enhancing and accelerating heat dissipation of the flow guiding device. As shown in FIGS. 7 to 8, the auxiliary device 5 is provided above the flow guiding device 1.

Referring to FIG. 9 , the auxiliary device 5 includes a body 50 and a plurality of wind blocking members 51 . The wind blocking members 51 are adjacently disposed on one surface 501 of the body 50 . The sheet body 50 may be a flat surface (not shown) or a curved surface 500. Referring to FIG. 10 and FIG. 11 , the degree of flow interference of the airflow may have different effects depending on the difference in the direction in which the auxiliary device 5 is disposed. When the wind blocking member 51 of FIG. 10 is “forward” facing the condenser fan 41, The wind blocking member 51 has the effect of blocking the flow on the windward surface F. On the other hand, when the wind blocking member 51 of FIG. 11 faces the condenser fan 41 in the "reverse direction", that is, the surface of the sheet body 50 having no wind blocking member 51 is the windward surface F, the airflow is along the windward surface F of the sheet body 50. The sides of the sheet 50 are bypassed to flow rapidly toward the condenser coil 42.

Further, FIG. 12 is a partial side view showing the flow guiding device 1 and the auxiliary device 5 disposed in the air conditioner, and the auxiliary device 5 above the flow guiding device 1 is used to enhance and accelerate the water driven by the flow guiding device 1. The gas W moves toward the condenser coil 42 in the wind blowing direction D. The structure and operation mode of the flow guiding device 1 have been described in detail in the foregoing embodiments, and details are not described herein again.

Referring to FIG. 13 to FIG. 15, the wind blocking members 51 may have a semi-cylindrical (a), a rod-shaped (b), a hollow tubular (c), and a solid cylindrical body (d) as shown in FIG. As shown in FIG. 14 , the wind blocking member 51 can also be in various wave shapes. As shown in FIG. 15 , the wind blocking member 51 can be integrally formed into a predetermined distance of the wind blocking member 51 , so that the wind blocking member 51 can be easily It is combined with the sheet 50. Referring to FIG. 9 , a plurality of holes 510 may be added to each of the air blocking members 51 to enable the airflow to operate more rapidly, and the degree of flow interference of the airflow may change according to different shapes of the holes 510.

In summary, in order to solve the problem that the known air conditioner cannot quickly cool down and discharge the water vapor, the present invention provides a flow guiding device and an auxiliary device placed in the air conditioner, and the upper body of the deflector is used. The configuration in which the flow convex portion is formed and the arrangement of the flow guiding member are such that the air flow pressure of the condenser fan is forcibly applied and the wind direction of the direct air flow is downward, which effectively causes the moisture and dust to be taken outside the air conditioner. In addition, regardless of the diversion device or auxiliary device, the design of the windward direction and the tilt angle can be changed according to the climatic conditions of each country and region, so that the purpose of regulating the airflow velocity is achieved, which makes the use more convenient. And mobile.

The above are only the preferred embodiments of the present invention, and are not intended to limit the scope of the invention, and the equivalents of the present invention and the equivalents of the drawings are all included in the present invention. Within the scope of protection.

Claims (15)

1. A flow guiding device for use in an air conditioner, characterized in that the air conditioner comprises a condenser fan and a condenser coil, and the condenser fan that operates can generate an air flow toward the condenser coil to define For guiding the direction of the airflow, the flow guiding device is obliquely disposed on the bottom surface of the air conditioner, wherein the flow guiding device comprises:

   a plate body having a plurality of holes penetrating the plate body and a plurality of flow guiding protrusions, wherein the plurality of holes penetrate through opposite plate faces of the plate body, and the plurality of the flow guiding protrusions are spaced apart from the plate The opposite sides of the body, the two adjacent flow guiding protrusions are defined as a concave area;

   a plurality of flow guiding members are disposed in the plurality of recessed regions, and a portion of the holes on the two sides of the plate are engaged with the flow guiding member;

   Wherein the inclined flow guiding device is interposed between the condenser fan and the condenser coil, wherein one of the plate faces faces the condenser fan as a windward side, and the windward side is inclined with the bottom surface to form an angle Therefore, when a portion of the condenser fan that is in operation moves the airflow toward the windward side, a portion of the airflow passes through the plurality of the flow guiding protrusions and the plurality of the flow guiding members can drive water vapor along the bottom surface along The air flow blows toward the condenser coil.
2. The flow guiding device for use in an air conditioner according to claim 1, wherein each of said flow guiding members is a solid cylinder, or each of said flow guiding members is a hollow cylinder, or part of said The flow guiding member is a solid cylinder, and some of the flow guiding members are hollow cylinders, wherein when the flow guiding member is the hollow cylinder to be combined with the hole, the hollow cylinder has a front end surface and is engaged with the hole One of the bottom surfaces is connected to the bottom surface, and the front end surface is a flat surface, or the front end surface is irregular.
3. The flow guiding device for use in an air conditioner according to claim 1, wherein each of the flow guiding members on each of the concave portions further has an air hole penetrating through itself, wherein a central axis of the flow guiding member An axis of the air hole perpendicular to the air hole is perpendicular to each other.
4. The flow guiding device for use in an air conditioner according to claim 1, wherein the guiding convex portion is a flat plate or a convex block, wherein when the guiding convex portion is the flat plate, the flat plate and the flat plate The plate body forms a slanting angle. When the flow guiding protrusion is the protrusion, the protrusion extends from the plate surface and has a curved curved surface.
5. The flow guiding device for use in an air conditioner according to claim 1, wherein the height of the flow guiding device is lower than a fan axis of the condenser fan.
6. A heat dissipation method for discharging waste heat in an air conditioner, wherein the flow guiding device according to claim 1 is disposed in an air conditioner, wherein the flow guiding device is located in a condenser fan and a condenser coil in the air conditioner And disposed obliquely on a bottom surface of the air conditioner, wherein when the condenser fan operates to generate an air flow, the portion facing the windward side The airflow passes through the plurality of flow guiding protrusions of the flow guiding device and the plurality of flow guiding members to drive the water vapor on the bottom of the air conditioner to move toward the condenser coil along the air blowing direction.
7. The method of dissipating waste heat in a ventilating air conditioner according to claim 6, wherein each of said flow guiding members is a solid cylinder, or each of said flow guiding members is a hollow cylinder, or part of said The flow guiding member is a solid cylinder, and the part of the flow guiding member is a hollow cylinder, wherein when the flow guiding member is the hollow cylinder to be combined with the hole, the hollow cylinder has a front end surface and is engaged with the hole One of the bottom surfaces is connected to the bottom surface, and the front end surface is a flat surface, or the front end surface is irregular.
8. A heat dissipation method for waste heat in a discharge air conditioner according to claim 6, wherein each of the flow guiding members on each of the concave portions further has an air hole penetrating through itself, wherein a central axis of the flow guiding member An axis of the air hole perpendicular to the air hole is perpendicular to each other.
9. The method of dissipating waste heat in a ventilating air conditioner according to claim 6, wherein the guiding convex portion is a flat plate or a bump, wherein when the guiding convex portion is the flat plate, the flat plate and the flat plate The plate body forms a slanting angle. When the flow guiding protrusion is the protrusion, the protrusion extends from the plate surface and has a curved curved surface.
10. A method of dissipating waste heat in a ventilating air conditioner according to claim 6, wherein the height of the flow guiding device is lower than an axial center of the condenser fan.
11. An air conditioner comprising: a casing, a condenser fan, a condenser coil, an evaporator fan, an evaporator coil, a compressor, an expansion valve and a controller, the condenser fan The condenser coil, the evaporator fan, the evaporator coil, the compressor and the expansion valve are disposed in the housing, and the controller is electrically connected to the condenser fan, the evaporator fan and the compressor And one end of the condenser coil is connected to the compressor, and the other end is connected to the expansion valve; one end of the evaporator coil is connected to the compressor, and the other end is connected to the expansion valve; the condenser fan is facing the condensation a coiled tube facing the evaporator coil; characterized in that: a flow guiding device according to claim 1 is disposed between the condenser fan and the condenser coil, and the flow guiding The device is disposed obliquely on the bottom surface of the air conditioner.
12. The air conditioner according to claim 11, wherein the height of the flow guiding device is lower than the axial center of the condenser fan.
13. An auxiliary device for enhancing and accelerating the heat dissipation of the flow guiding device, the auxiliary device being provided above the flow guiding device according to any one of claims 1 to 5, characterized in that the auxiliary device comprises:

    a piece of body, and;

    a plurality of wind blocking members are disposed adjacent to each other on one surface of the sheet body,

    Wherein, the auxiliary device is used to enhance and accelerate the water vapor driven by the flow guiding device to move toward the condenser coil along the wind blowing direction.
14. The auxiliary device for enhancing and dissipating heat dissipation of the flow guiding device according to claim 13, wherein the wind blocking member is a semi-cylindrical, a rod-shaped, a hollow tubular shape, a solid cylindrical body or a wave shape.
15. The auxiliary device for enhancing and dissipating heat dissipation of the flow guiding device according to claim 13, wherein the sheet body is a plane or a curved surface.

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