TWM583535U - Cooling device of evaporative air conditioning equipment and fair water piece structure thereof - Google Patents

Abstract

The creation discloses a cooling device of an evaporative air-conditioning equipment and a water guide plate structure thereof. The water deflector structure is disposed adjacent to a wind deflector structure to block a cooling water flowing along the wind deflector structure. The wind deflector and water deflector structure includes a main body portion and a terminal portion connected to the main body portion. The water deflector structure includes: a first side portion, a second side portion, and a water guide body portion. The second side portion corresponds to the first side portion. The water guiding body portion is connected between the first side portion and the second side portion. The projection area of the first side portion with respect to the end portion of the wind deflector structure is located on the first side of the end portion. The projection area of the second side portion with respect to the end portion of the wind deflector structure is located on the second side edge of the end portion, and the first side edge and the second side edge are located on both sides of the end portion, respectively.

Description

Cooling device of evaporative air-conditioning equipment and water guide plate structure thereof

The present invention relates to an air-conditioning equipment and a water guide plate structure thereof, and in particular to a cooling device of an evaporative air-conditioning equipment and a water guide plate structure thereof.

First, the cooling devices of the evaporative air-conditioning equipment in the prior art are generally provided with a wind guide plate, and the airflow generated by the blower flows upward through the guide of the wind guide plate to increase the heat dissipation efficiency of the coil. For example, in the "evaporative cooler and its water quality control device" disclosed in the TW M376751 patent, the blower 23 can be used to suck in the low-humidity cold air, guided upward by the air guide water guide plate 36, and passed through the cooling coil 26 The high-humidity hot air is discharged upward to increase the heat dissipation efficiency of the cooling coil 26.

However, in the TW M376751 patent, due to the arc design of the tip of one of the wind deflectors 36, the cooling water dripping from above will be splashed into the blower 23, causing the blower 23 to be damaged.

In addition, a fan of a cooling device of an evaporative air conditioner in the prior art is generally provided with a water blocking plate to prevent cooling water from being splashed on the blower. For example, in the TW M376751 patent, the cooling water sprayed from the sprinkler pipe 27 can be blocked by the water blocking plate 24 provided on the upper edge of the blower 23. Next, the water shield 24 of the TW M376751 patent is a thin flat plate structure. Generally, in order to prevent the cooling water from being sprayed to the blower, the extension of the water shield 24 is generally increased. However, when the extension length of the water baffle 24 is increased, the air flow generated by the air blower 24 is blocked by the water baffle 24, and the air flow cannot be effectively sent to the cooling coil 26. Therefore, in the existing solutions, the installation position of the blower 24 is moved outward to generate sufficient airflow under the condition that the cooling water can be prevented from splashing to the blower 24.

However, in the prior art, the technical solution of moving the installation position of the blower 24 outward will cause the overall volume of the cooling device of the evaporative air conditioning equipment to increase. Therefore, how to overcome the above-mentioned defects through the improvement of the structural design to avoid the cooling water splashing to the fan assembly and reduce the overall volume of the cooling device of the evaporative air-conditioning equipment has become an important issue to be solved in this business. one.

The technical problem to be solved by the present invention is to provide a cooling device of an evaporative air-conditioning equipment and a water guide plate structure thereof in view of the deficiency of the prior art.

In order to solve the above-mentioned technical problems, one of the technical solutions adopted in this creation is to provide a cooling device for an evaporative air-conditioning device, which includes: a carrier assembly, a fan assembly, a coil assembly, and a sprinkler pipe assembly A wind deflector structure and a water deflector structure. The carrier frame assembly includes a slot body and a support frame body disposed on the slot body, wherein the slot body includes a receiving space and a slot. The fan assembly is disposed on the carrier assembly and corresponds to the slot. The coil tube assembly is disposed on the carrier frame assembly, and the coil tube assembly includes a coil tube frame disposed on the support frame body and at least one coil tube disposed on the coil frame frame. The sprinkler pipe assembly is disposed on the carrier frame assembly. The sprinkler pipe assembly includes a water pipe, a sprinkler head connected to one end of the water pipe, and a water pump connected to the other end of the water pipe. Pu. The wind-guiding and water-guiding plate structure is disposed on the tank body, and the wind-guiding and water-guiding plate structure is provided in the accommodating space, wherein the wind-guiding and water-guiding plate structure includes a main body portion and a connecting portion. Said end portion of the body portion. The water deflector structure is disposed in the accommodation space, and the water deflector structure is adjacent to the wind deflector structure, wherein the water deflector structure includes a first side portion, a A second side portion of one side portion and a water guiding body portion connected between the first side portion and the second side portion. Wherein, a projection area of the first side portion with respect to the end portion of the wind deflector structure is located on a first side of the end portion. Wherein, a projection area of the second side portion with respect to the end portion of the wind deflector structure is located on a second side edge of the end portion, and the first side edge and the second side edge They are respectively located on both sides of the end portion.

In order to solve the above technical problem, another technical solution adopted in this creation is to provide a water deflector structure, which is disposed adjacent to a wind deflector structure to block a flow and splash along the wind deflector structure. For cooling water, the air guide plate structure includes a main body portion and a terminal portion connected to the main body portion. The water guide plate structure includes a first side portion, a second side portion, and a water guide body portion. The second side portion corresponds to the first side portion. The water guiding body portion is connected between the first side portion and the second side portion. Wherein, a projection area of the first side portion with respect to the end portion of the wind deflector structure is located on a first side of the end portion. Wherein, a projection area of the second side portion with respect to the end portion of the wind deflector structure is located on a second side edge of the end portion, and the first side edge and the second side edge They are respectively located on both sides of the end portion.

One of the beneficial effects of this creation is that the cooling device of the evaporative air-conditioning equipment provided by this creation and its water guide plate structure can be provided by "the water guide plate structure is arranged adjacent to a wind guide plate structure" and "the water guide plate" The structure includes: a first side portion, a second side portion, and a water guiding body portion, and the water guiding body portion is connected between the first side portion and the second side portion. A splash of cooling water is flowed along the wind deflector structure to prevent the cooling water from being splashed onto the fan assembly, and at the same time, the overall volume of the cooling device of the evaporative air conditioner can be reduced.

In order to better understand the features and technical contents of this creation, please refer to the following detailed description and drawings about this creation. However, the drawings provided are only for reference and explanation, and are not intended to limit this creation.

The following is a specific embodiment to explain the implementation of the "cooling device of the evaporative air-conditioning equipment and the structure of its water deflector" disclosed in this creation. Those skilled in the art can understand the advantages and advantages of this creation from the content disclosed in this specification. effect. This creation can be implemented or applied through other different specific embodiments, and various details in this specification can also be based on different viewpoints and applications, and various modifications and changes can be made without departing from the concept of this creation. In addition, the drawings of this creation are only for simple and schematic illustrations, and are not drawn in actual size, so stated in advance. The following embodiments will further describe the technical content of this creation in detail, but the disclosed content is not intended to limit the scope of protection of this creation.

It should be understood that although the terms "first", "second", "third" and the like may be used herein to describe various elements, these elements should not be limited by these terms. These terms are mainly used to distinguish one element from another. In addition, the term "or" as used herein should, depending on the actual situation, include any one or more of the associated listed items.

[Example]

First, referring to FIG. 1 to FIG. 4, FIG. 1 is a schematic three-dimensional assembly diagram of a cooling device of an evaporative air-conditioning device according to the creative embodiment, and FIG. 2 is a perspective view of a part of the cooling device of the evaporative air-conditioning device according to the creative embodiment. For a combined schematic diagram, FIG. 3 is an exploded perspective view of a cooling device of an evaporative air-conditioning apparatus according to an embodiment of the present invention, and FIG. 4 is a schematic cross-sectional view of a side cross-section of FIG. 2. The embodiment of the present invention provides a cooling device U of the evaporative air conditioning equipment and a water guide plate structure 7 thereof. The main structure of the cooling device U of the evaporative air conditioner equipment will be described below, and the structure of the water guide plate structure 7 will be described later. However, it should be noted that although the water guide plate structure 7 provided in this creative embodiment is described by taking the cooling device U applied to the evaporative air-conditioning equipment as an example, in other implementation aspects, the creative embodiment provides The water deflector structure 7 can also be applied to other devices, and the creation is not limited to the application of the water deflector structure 7.

Following the above, please refer to FIG. 1 to FIG. 4 again. The cooling device U of the evaporative air-conditioning equipment may include: a carrier assembly 1, a fan assembly 2, a coil assembly 4, a sprinkler pipe assembly 5, a guide The air guide plate structure 6 and a water guide plate structure 7. The carrier frame assembly 1 may include a slot body 11, a support frame body 12 disposed on the slot body 11, and a closed cover body 13. The closed cover body 13 can be disposed on the groove body 11 to close the support frame body 12, the coil pipe assembly 4 and the sprinkler pipe assembly 5. The coil tube assembly 4 may be disposed on the carrier frame assembly 1. The coil tube assembly 4 may include a coil tube frame 41 disposed on the supporting frame body 12 and at least one coil tube 42 disposed on the coil tube frame 41. In addition, the coil 42 may have a coil inlet 421 and a coil outlet 422 for the refrigerant to flow.

Following the above, please refer to FIG. 4 again, the sprinkler pipe assembly 5 is disposed on the carrier frame assembly 1. The sprinkler pipe assembly 5 includes a water pipe 51, a sprinkler 52 connected to one end of the water pipe 51, and a connection to A water pump 53 at the other end of the water pipe 51. Further, the sprinkler head 52 may be disposed on the supporting frame body 12 of the carrier assembly 1, and the sprinkler head 52 is located above the coil tube 42. With this, the sprinkler pipe assembly 5 can use the water pump 53 to pump up the cooling water C in a water storage area 1103 of the tank 11, and spray the cooling water C on the coil tube 42 from the sprinkler head 52 to Achieve cooling effect. In addition, the closed cover 13 can prevent the cooling water C from splashing out.

Following the above, please refer to FIGS. 1 to 4 again, and also refer to FIGS. 5 to 7. FIGS. 5 to 7 are three-dimensional exploded views of the carrier assembly and the baffle structure of the creative embodiment. schematic diagram. Further, the tank body 11 may include a receiving space 1101, a housing 111 surrounding the receiving space 1101, and a slot 1102 passing through one side of the housing 111, and the water storage area 1103 may be located in the tank body 11 bottom of. The fan assembly 2 may be disposed on the slot body 11 of the carrier assembly 1 and corresponds to the slot 1102. In this way, in addition to being cooled by the cooling water C, the coil tube 42 can also use the fan assembly 2 to introduce external airflow through the slot 1102 to increase the heat dissipation efficiency of the coil tube 42.

Following the above, please refer to FIG. 1 to FIG. 7 again. The cooling device U of the evaporative air conditioner provided by this creative embodiment may further include: a wind guide plate structure 6, and the wind guide plate structure 6 may be provided. On the tank body 11, the wind guide plate structure 6 can be disposed in the accommodating space 1101. Preferably, the cooling device U of the evaporative air-conditioning apparatus provided in the present creative embodiment may include two or more wind deflectors 6. In addition, the two air deflector and water deflector structures 6 can be arc-shaped, and the two air deflector and water deflector structures 6 are spaced from each other. Thereby, the external air introduced by the fan assembly 2 can be guided to the coil 42 through the slot 1102 and guided by the wind guide plate structure 6 to increase the heat dissipation efficiency of the coil 42. At the same time, the cooling water C sprayed on the coil pipe 42 can also flow into the water storage area 1103 of the tank 11 through the guidance of the wind deflector plate structure 6. At the same time, the cooling water C in the water storage area 1103 can be further pumped by the water pump 53 to the cooling water C located in the water storage area 1103, and the cooling water C is sprayed on the coil 42 by the sprinkler 52 to achieve The effect of continuous cooling.

Following the above, please refer to FIG. 1 to FIG. 7 again. The water guide plate structure 7 may be disposed in the accommodating space 1101, and the water guide plate structure 7 may be adjacent to the air guide plate structure 6. For example, the water baffle structure 7 may be provided on the tank body 11, however, in other embodiments, the water baffle structure 7 may also be provided on the wind baffle plate structure 6. This creation does not use the water baffle structure 7 on The manner of accommodating the space 1101 is limited. Further, the water guide plate structure 7 may include a first side portion 71, a second side portion 72 corresponding to the first side portion 71, and a water guide connected between the first side portion 71 and the second side portion 72.体 部 73。 The body portion 73. The wind deflector and water deflector structure 6 may include a main body portion 61 and an end portion 62 connected to the main body portion 61. In addition, the water guide plate structure 7 is adjacent to the wind guide plate structure 6, and the water guide body portion 73 and the end portion 62 of the wind guide plate structure 6 are separated from each other by a predetermined distance.

Following the above, please refer to FIG. 4 to FIG. 7 again, the projection area of the first side portion 71 relative to the end portion 62 of the wind deflector structure 6 is located on the first side of the end portion 62 and the second side portion is opposite The projection area of the end portion 62 of the wind deflector structure 6 is located on the second side of the end portion 62, and the first side and the second side are located on both sides of the end portion 62, respectively. In other words, as shown in FIGS. 4 and 5, the first side portion 71 is located above the end portion 62 of the wind deflector structure 6 and the second side portion 72 is located below the end portion 62 of the wind deflector structure 6 .

Following the above, please refer to FIG. 4 to FIG. 7 again. For example, for the purpose of this creation, the cross-sectional profile of a length direction (Z direction) of the water deflector structure 7 may be arc-shaped, for example, may be a semicircle. shape. Further, the extending direction (negative X direction) of the first side portion 71 and the second side portion 72 of the wind guide plate structure 6 with respect to the water guide body portion 73 and the extension direction of the end portion 62 of the wind guide plate structure 7 ( (Positive X direction) are opposite to each other. Thereby, the concave surface formed by the water guide plate structure 7 can be used to stop the cooling water C flowing and splashing along the wind guide plate structure 6. In other words, the concave surface formed by the water guide plate structure 7 can guide the cooling water C that originally flows in the direction of the fan assembly 2 to flow away from the fan assembly 2. In addition, the arrangement of the water guide plate structure 7 can also increase the flow path of the cooling water C and improve heat dissipation efficiency.

Following the above, please refer to FIG. 4 to FIG. 7. Furthermore, the cooling water C sprayed on the coil tube 42 flows into the water storage area 1103 of the tank 11 through the guide of the air guide plate structure 6. In the process, the water guide plate structure 7 can be used to prevent the cooling water C from flowing along the air guide plate structure 6 to prevent the cooling water C from splashing into the fan assembly 2. However, it should be noted that, in other embodiments, a cross-sectional profile of a length direction (Z direction) of the water guide plate structure 7 may also have a long flat plate structure, which is not limited in this creation. In other words, the shape and installation position of the water deflector structure 7 can stop the cooling water C flowing along the wind deflector structure 6 from splashing. Thereby, the cooling water C flowing along the air deflector structure 6 is blocked by the water deflector structure 7, and the installation position of the fan assembly 2 can be closer to the air deflector structure 6. Therefore, the cooling device of the evaporative air conditioner The overall volume of U can be further reduced.

Following the above, please refer to FIG. 4 to FIG. 7 again. The cooling device U of the evaporative air-conditioning equipment may further include: a baffle plate structure 3, the baffle plate structure 3 may be disposed on the tank 11 and block water. The plate structure 3 is disposed in the accommodation space 1101 and is adjacent to the fan assembly 2. In addition, the water baffle structure 3 may be disposed above the fan assembly 2 to prevent the cooling water C sprayed by the sprinkler head 52 from splashing into the guide fan assembly 2. Further, in terms of the present creation, the flap structure 3 may include an arc-shaped water retaining body 31, a first water guiding groove 32 provided on one side of the arc-shaped water retaining body 31, and an arc-shaped water retaining body 31 The second water guide groove 33 on the other side of the water blocking body 31. In addition, the first water guide groove 32 and the second water guide groove 33 respectively extend in the direction of the wind guide plate structure 6.

Following the above, please refer to FIG. 4 to FIG. 7 again, a concave surface formed by the arc-shaped water retaining body 31 may face a first predetermined direction (negative Y direction), a concave surface formed by the first water channel 32 and the first A concave surface formed by the two water guiding grooves 33 may face a second predetermined direction (positive Y direction), and the first predetermined direction and the second predetermined direction are opposite to each other. In other words, the curved water retaining body 31 may include a top surface 311 and a bottom surface 312 corresponding to the top surface 311, and the top surface 311 of the curved water retaining body 31 is compared to the bottom surface 312 of the curved water retaining body 31. Closer to the coil 42. Therefore, since the arc-shaped water retaining body 31 provided in the present case has an arc-shaped top surface 311, the cooling water C sprayed by the sprinkler head 52 drops onto the arc-shaped water retaining body 31 of the water-shielding plate structure 3, It can flow along the curved top surface 311 of the curved water retaining body 31 to the first water guiding groove 32 and the second water guiding groove 33 respectively provided on both sides of the curved water retaining body 31.

Following the above, please refer to FIG. 4 to FIG. 7. Further, the first water channel 32 may be disposed between the arc-shaped water retaining body 31 and the casing 111, and the second water channel 33 may be disposed in the arc-shaped water barrier. Between the water body 31 and the casing 111, an arc-shaped water blocking body 31 may be disposed between the first water guide groove 32 and the second water guide groove 33. In addition, in terms of the present creation, the tank body 11 may further include a plate 112, and the sealing plate 112 may be disposed on the baffle plate structure 3 to prevent the cooling water C sprayed by the sprinkler 52 from flowing out of the tank body 11 Outside the space 1101. In addition, it is worth noting that although the drawing in this creative embodiment separates the sealing plate 112 from the flap structure 3, in other implementation aspects, the sealing plate 112 and the flap structure 3 may also be The integrally formed setting is not limited by the setting method of the cover plate 112 in this creation.

Following the above, please refer to FIG. 4 to FIG. 7. Furthermore, the first water channel 32 may include a first side plate 321, a second side plate 322 corresponding to the first side plate 321, and a first connection plate connected to the first side plate 321. A first connection plate 323 between the side plate 321 and the second side plate 322. In addition, the second water channel 33 may include a third side plate 331, a fourth side plate 332 corresponding to the third side plate 331, and a second connection plate 333 connected between the third side plate 331 and the fourth side plate 332. Thereby, the first side plate 321 of the first water guiding tank 32 can abut against the casing 111 of the tank body 11, and the third side plate 331 of the second water guiding tank 33 can abut against the casing 111 of the tank body 11. In addition, it is worth noting that, in other embodiments, the first side plate 321 of the first water channel 32 and the casing 111 may be the same member, and the third side plate 331 of the second water channel 33 and the casing 111 may be the same member. member. In other words, as long as a water flow channel is formed between the first water guide 32 and the second water guide 33 and the casing 111, this creation is not limited to this.

Following the above, please refer to FIG. 4 to FIG. 7. Preferably, as shown in FIG. 4, according to the present creation, the vertical projection of the first water guide 32 on the tank 11 can form a first projection area. The vertical projection of the second water guide tank 33 on the tank body 11 can form a second projection area, and the vertical projection of the wind guide plate structure 6 on the tank body 11 can form a third projection area. At the same time, the third projection area and the first projection area at least partially overlap, and the third projection area and the second projection area at least partially overlap. In other words, the first water guide groove 32 and the second water guide groove 33 can extend to the position of the air guide plate structure 6. Thereby, the cooling water C sprayed by the sprinkler head 52 can not only be guided by the arc-shaped water retaining body 31 to flow to the first water guide 32 and the second water guide 33, but also use the first water guide 32 and The second water guiding tank 33 guides the cooling water C to the wind guiding plate structure 6 and then flows into the water storage area 1103 to prevent the cooling water C from splashing onto the fan assembly 2.

Following the above, please refer to FIG. 4 to FIG. 7 again. It is worth noting that the extended length of the first water guide 32 and the extended length of the second water guide 33 are greater than the extended length of the arc-shaped water retaining body 31. In other words, the ends of the first water guide groove 32 and the second water guide groove 33 are closer to the wind guide plate structure 6 than the arc-shaped water retaining body 31. Thereby, since the extension length of the arc-shaped water retaining body 31 is relatively short, the arc-shaped water retaining body 31 can be prevented from blocking the air flow generated by the fan assembly 2. At the same time, because of the extension length of the first water guide groove 32 and the second water guide groove 33 has a longer extension length, so that the cooling water C can be guided to the wind deflector structure 6 and then flows into the water storage area 1103.

Next, please refer to FIG. 8 and FIG. 9. FIG. 8 is a schematic front view of the coiled tube frame body of the creative embodiment, and FIG. 9 is an exploded view of the coiled tube frame body and the coiled pipe of the creative embodiment. Further, in terms of the present creation, the coil frame body 41 may include a plate body 410, at least one positioning hole 411 penetrating through the plate body 410, and at least one heat dissipation hole 412 penetrating through the plate body 410. In addition, the at least one coiled tube 42 can pass through the at least one positioning hole 411. Preferably, the plate body 410 of the coil pipe rack body 41 may be made of plastic material, but this creation is not limited thereto.

Following the above, please refer to FIG. 8 and FIG. 9 again, the cross-sectional profile of the at least one coiled tube 42 may be a narrow shape, and the at least one positioning hole 411 has a shape corresponding to the cross-sectional profile of the at least one coiled tube 42. For example, the cross-sectional profile of the at least one coil tube 42 may be oval. Therefore, the positioning hole 411 may also be oval. However, the present invention is not limited to this. Further, the positioning hole 411 has a first predetermined width W1 in a third predetermined direction (Y direction), a second predetermined width W2 in a fourth predetermined direction (Z direction), and the first predetermined width W1 The size is smaller than the size of the second predetermined width W2. Further, since the airflow generated by the fan assembly 2 is directed upward, when the size of the first predetermined width W1 is smaller than the size of the second predetermined width W2, the resistance to the airflow is small, and it can be installed more.的 管管 42。 The coil 42.

Next, please refer to FIG. 10, which is a schematic perspective view of another embodiment of the cooling device of the evaporative air-conditioning apparatus according to the creative embodiment. The cooling device U of the evaporative air-conditioning equipment provided by this creation may further include: a body frame F, a control module M, and at least one compressor R coupled to the control module M. The carrier assembly 1, the fan assembly 2, the coil assembly 4, the sprinkler pipe assembly 5, the control module M and at least one compressor R may all be disposed in the body frame F. With this, the cooling device U of the evaporative air-conditioning equipment provided by this creation can be packaged and integrated into a unit. In addition, it is worth noting that the body frame F shown in FIG. 10 may be provided with two sets of cooling devices U of evaporative air-conditioning equipment, and the two sets of cooling devices U of evaporative air-conditioning equipment may be installed in parallel or in series. Creation is not limited to this.

Following the above, please refer to FIG. 10 again, because the cooling device U of the evaporative air-conditioning equipment provided by this creation can use the design of the aforementioned baffle plate structure 3 and / or the baffle plate structure 7 and so on, so that the evaporative air conditioner The overall volume of the cooling device U of the equipment can be reduced. Therefore, at least one compressor R may be disposed on one side of the groove body 11 of the carrier assembly 1. At the same time, the pipelines of the cooling device U and / or the control module M of the evaporative air-conditioning equipment can also be disposed on one side of the tank 11 of the carrier assembly 1. Therefore, compared with the prior art, the volume of the cooling device U of the evaporative air-conditioning equipment is relatively large, so that the equipment such as the compressor R or the pipeline can only be installed below or above the cooling device U of the evaporative air-conditioning equipment due to space constraints. In the case of the cooling device U of the evaporative air-conditioning equipment provided by this creation, the overall volume of the cooling device U of the evaporative air-conditioning equipment can be reduced, and at least one of the compressor R, the pipeline, and / or the control module M, etc. The device is disposed on one side of the groove body 11 of the carrier assembly 1, thereby greatly improving the convenience of maintenance.

[Advantageous Effects of the Embodiment]

One of the beneficial effects of this creation is that the cooling device U of the evaporative air-conditioning equipment provided by this creation and its water guide plate structure 7 can be provided by "the water guide plate structure 7 adjacent to a wind guide plate structure 6" and " The water guide plate structure 7 includes a first side portion 71, a second side portion 72, and a water guide body portion 73, and the water guide body portion 73 is connected between the first side portion 71 and the second side portion 72. " A block of cooling water C splashing and flowing along the wind guide plate structure 6 is blocked to prevent the cooling water C from being sprayed onto the fan assembly 2. At the same time, the overall volume of the cooling device U of the evaporative air conditioning equipment can be reduced.

Furthermore, in this creation, a technical solution in which a cross-sectional profile of a lengthwise direction of the water guide plate structure 7 is arc-shaped can be used to block the cooling water C flowing along the wind guide plate structure 6 from flowing. Therefore, the fan assembly 2 The installation position can be closer to the wind guide plate structure 6, so the overall volume of the cooling device U of the evaporative air conditioning equipment can be further reduced.

Furthermore, this creation can also be described by “the first water channel 32 is provided on one side of the curved water retaining body 31” and “the second water channel 33 is provided on the other side of the curved water retaining body 31, and The second water channel 33 corresponds to the technical solution of “the first water channel 32 is provided” to prevent the cooling water C from being splashed onto the fan assembly 2, and at the same time, the overall volume of the cooling device U of the evaporative air conditioner can be reduced.

Furthermore, in this creation, the curved top surface 311 of the curved water retaining body 31 can be used to guide the cooling water C to the first water guiding groove 32 and the second water guiding groove provided on both sides of the curved water retaining body 31. 33, so that the cooling water C is guided to both sides of the fan assembly 2, and the cooling water C is prevented from splashing onto the fan assembly 2.

Furthermore, compared to the prior art, which uses a metal plate as the plate body 410, the plate body 410 in this case is made of plastic material, which can avoid the problem of rusting at the junction between the coil tube 42 and the plate body 410. Furthermore, compared with the circular coils of the prior art, the present invention can make use of the narrow cross-sectional profile of the coils 42 to reduce wind resistance and increase heat dissipation efficiency. In addition, when the wind resistance is reduced, a lower power fan assembly 2 can also be selected to achieve the effect of reducing energy consumption. Furthermore, the heat dissipation efficiency of the cooling device U of the evaporative air conditioner can be further increased by opening the heat dissipation holes 412 in the plate 410, which can also increase the flow efficiency of the airflow generated by the fan assembly 2.

The content disclosed above is only the preferred and feasible embodiment of this creation, and therefore does not limit the scope of the patent application for this creation. Therefore, any equivalent technical changes made using this creation specification and diagram content are included in this creation application Within the scope of the patent.

U‧‧‧ Cooling device for evaporative air conditioning equipment

1‧‧‧Carrier frame components

11‧‧‧ trough

1101‧‧‧accommodation space

1102‧‧‧Slotted

1103‧‧‧Water storage area

111‧‧‧shell

112‧‧‧Seal Board

12‧‧‧ support frame

13‧‧‧closed cover

2‧‧‧fan assembly

3‧‧‧ water baffle structure

31‧‧‧arc water retaining body

311‧‧‧Top

312‧‧‧ underside

32‧‧‧ first aqueduct

321‧‧‧First side plate

322‧‧‧Second side plate

323‧‧‧The first connection board

33‧‧‧Second Aqueduct

331‧‧‧third side plate

332‧‧‧Fourth side plate

333‧‧‧Second connection board

4‧‧‧ coil assembly

41‧‧‧ Coil frame

410‧‧‧board

411‧‧‧ Positioning hole

412‧‧‧Ventilation hole

42‧‧‧ coil

421‧‧‧coil entrance

422‧‧‧ Coil exit

5‧‧‧Sprinkler pipe assembly

51‧‧‧ water pipe

52‧‧‧Sprinkler

53‧‧‧Water Pump

6‧‧‧ wind deflector structure

61‧‧‧Body

62‧‧‧ tip

7‧‧‧ Water guide plate structure

71‧‧‧first side

72‧‧‧ second side

73‧‧‧ Water Diversion Body

F‧‧‧frame

C‧‧‧ cooling water

R‧‧‧compressor

M‧‧‧Control Module

W1‧‧‧First predetermined width

W2‧‧‧ Second predetermined width

X, Y, Z‧‧‧ directions

FIG. 1 is a schematic perspective three-dimensional assembly diagram of a cooling device of an evaporative air-conditioning apparatus according to an embodiment of the present invention.

FIG. 2 is a schematic three-dimensional assembly diagram of a part of a cooling device of an evaporative air-conditioning apparatus according to an embodiment of the present invention.

FIG. 3 is a schematic exploded perspective view of a cooling device of an evaporative air-conditioning apparatus according to an embodiment of the present invention.

4 is a schematic cross-sectional view of a side cross-section of FIG. 1.

FIG. 5 is an exploded perspective view of a carrier assembly and a flap structure according to an embodiment of the present invention.

FIG. 6 is another schematic three-dimensional exploded view of the carrier assembly and the flap structure according to the creative embodiment.

FIG. 7 is another schematic three-dimensional exploded view of the carrier assembly and the flap structure according to the creative embodiment.

FIG. 8 is a schematic front view of a coil tube body according to an embodiment of the present invention.

FIG. 9 is an exploded schematic view of a coil tube frame and a coil tube according to an embodiment of the present invention.

FIG. 10 is a schematic perspective view of another embodiment of the cooling device of the evaporative air-conditioning apparatus according to the creative embodiment.

Claims (17)

A cooling device for an evaporative air conditioner includes: a carrier frame assembly, the carrier frame assembly including a trough body and a support frame body disposed on the trough body, wherein the trough body includes a housing Space and a slot; a fan assembly, the fan assembly is disposed on the carrier frame assembly and corresponds to the slot; a coil unit, the coil unit is disposed on the carrier frame assembly, so The coil pipe assembly includes a coil pipe frame provided on the support frame body and at least one coil pipe provided on the coil pipe frame; a sprinkler pipe assembly, the sprinkler pipe assembly is disposed at the On the carrier assembly, the sprinkler pipe assembly includes a water pipe, a sprinkler head connected to one end of the water pipe, and a water pump connected to the other end of the water pipe; a wind guide plate structure, The wind-guiding and water-guiding plate structure is disposed on the tank body, and the wind-guiding and water-guiding plate structure is provided in the accommodating space, wherein the wind-guiding and water-guiding plate structure includes a main body portion and a connecting portion. On the body An end portion; and a water deflector structure disposed in the accommodating space, and the water deflector structure is adjacent to the wind deflector structure, wherein the water deflector structure includes a first A side portion, a second side portion corresponding to the first side portion, and a water guiding body portion connected between the first side portion and the second side portion; wherein the first side portion is opposite A projection area on the end portion of the wind deflector structure is located on a first side of the end portion; wherein the second side portion is relative to the end portion of the wind deflector structure. The projection area is located on a second side of the tip portion, and the first side and the second side are respectively located on two sides of the tip portion. The cooling device of the evaporative air-conditioning equipment according to item 1 of the scope of patent application, further comprising: a baffle structure, the baffle structure is provided on the tank body, and the baffle structure is provided In the accommodation space and adjacent to the fan assembly. The cooling device of the evaporative air conditioner according to item 2 of the patent application scope, wherein the flap structure includes an arc-shaped water retaining body, and a first portion disposed on one side of the arc-shaped water retaining body. A water guiding tank and a second water guiding tank disposed on the other side of the arc-shaped water blocking body. According to the cooling device of the evaporative air-conditioning equipment according to item 3 of the scope of patent application, wherein a vertical projection of the first water guiding tank on the tank body can form a first projection area, and the second water guiding tank is The vertical projection on the tank can form a second projection area, and the vertical projection of the wind guide plate structure on the tank can form a third projection area. The third projection area and the first projection area can form a third projection area. A projection area at least partially overlaps, and the third projection area and the second projection area at least partially overlap. According to the cooling device of the evaporative air conditioner according to item 3 of the scope of the patent application, wherein the first water guide groove and the second water guide groove respectively extend in the direction of the air guide plate structure. According to the cooling device of the evaporative air-conditioning equipment according to item 3 of the patent application scope, wherein a concave surface formed by the arc-shaped water retaining body faces a first predetermined direction, and a concave surface formed by the first water guide groove And a concave surface formed by the second water channel faces a second predetermined direction, and the first predetermined direction and the second predetermined direction are opposite to each other. The cooling device of the evaporative air-conditioning equipment according to item 3 of the scope of patent application, wherein the first water channel includes a first side plate, a second side plate corresponding to the first side plate, and a connection to the first side plate. A first connection plate between a first side plate and the second side plate; wherein the second water channel includes a third side plate, a fourth side plate corresponding to the third side plate, and a first plate connected to the first side plate; A second connection plate between the three side plates and the fourth side plate. The cooling device of the evaporative air-conditioning equipment according to item 1 of the scope of the patent application, wherein the coil frame body includes a plate body, at least one positioning hole penetrating through the plate body, and at least one penetrating through the plate body. A heat dissipation hole; wherein at least one of the coils is passed through at least one of the positioning holes. According to the cooling device of the evaporative air-conditioning equipment according to item 8 of the patent application scope, a cross-sectional profile of at least one of the coils has a narrow shape, and at least one of the positioning holes has a shape corresponding to at least one of the coils. Cross-sectional contour shape. According to the cooling device of the evaporative air conditioner according to item 8 of the scope of application for a patent, wherein the plate body of the coil tube frame body is made of plastic material. The cooling device of the evaporative air-conditioning equipment according to item 1 of the patent application scope, further comprising: a body frame, a control module, and at least one compressor coupled to the control module, wherein the bearing The rack assembly, the fan assembly, the coil unit, the sprinkler pipe assembly, the control module, and at least one of the compressors are all disposed in the body frame. According to the cooling device of the evaporative air conditioner according to item 11 of the scope of application for patent, at least one of the compressors is disposed on one side of the groove of the carrier frame assembly. According to the cooling device of the evaporative air-conditioning apparatus according to item 1 of the patent application scope, a cross-section profile of a length direction of the water guide plate structure is arc-shaped. The cooling device of the evaporative air-conditioning apparatus according to item 1 of the patent application scope, wherein an extension of the first side portion and the second side portion of the wind deflector structure with respect to the water guide body portion The direction and the extending direction of the end portion of the wind guide plate structure are opposite to each other. A water deflector structure is disposed adjacent to a wind deflector structure to block a cooling water flowing along the wind deflector structure. The wind deflector structure includes a body portion and a connection to the The tip portion of the body portion, the water guide plate structure includes: a first side portion; a second side portion, the second side portion corresponds to the first side portion; and a water guide body portion, the water guide The body portion is connected between the first side portion and the second side portion; wherein a projection area of the first side portion with respect to the end portion of the wind deflector structure is located at the end portion A first side edge of the first side edge, wherein a projection area of the second side portion relative to the end portion of the wind deflector structure is located on a second side edge of the end portion, and the first side edge and The second side edges are respectively located on two sides of the end portion. The water deflector structure according to item 15 of the scope of patent application, wherein a cross-sectional profile of a length direction of the water deflector structure is arc-shaped. The water deflector structure according to item 15 of the scope of patent application, wherein an extension direction of the first side portion and the second side portion of the wind deflector structure with respect to the water deflector body portion and the The extension directions of the end portions of the wind deflector structure are opposite to each other.