CN113803874B - Water receiving structure and onboard cooling unit - Google Patents

Abstract

The application provides a water receiving structure and an onboard cooling unit. This water receiving structure includes air inlet channel (1) and sets up water receiving baffle (2) in air inlet channel (1), air inlet channel (1) is including air intake (3) that are located the downside and air outlet (4) that are located the upside, water receiving baffle (2) are located between air intake (3) and air outlet (4), water receiving baffle (2) include guide plate (5) and set up water receiving tank (6) in guide plate (5) bottom, the both sides of guide plate (5) and the lateral wall sealing fit of air inlet channel (1), the top of water receiving tank (6) is provided with water receiving opening (7), water receiving tank (6) all with the lateral wall sealing fit of air inlet channel (1) except water receiving opening (7) other parts. According to the water receiving structure disclosed by the application, water receiving under different working states of the cooling unit can be adapted, water drops are effectively prevented from dripping, and the water receiving effect is improved.

Description

Water receiving structure and airborne cooling unit

Technical Field

The application relates to the technical field of air conditioning, in particular to a water receiving structure and an airborne cooling unit.

Background

In the operation process of the refrigerating terminal, when air exchanges heat through the heat exchanger, water vapor in the refrigerating terminal can form condensed water or generate frosting phenomenon under the action of low temperature, and when a defrosting program is operated by the system, a large amount of water can be generated, and if the water cannot be effectively received, the quality and the use of the refrigerating terminal can be greatly influenced.

When the traditional air conditioner indoor unit is used for solving the problem of condensed water, a water receiving disc is arranged at the lower part of the evaporator, and water drops naturally drop on the water receiving disc under the action of gravity and flow out from the outer connecting pipe. This scheme possesses better water receiving and drainage effect in steady environment, but in unstable environment or under the more circumstances of water that defrosting produced, the drainage effect of water collector is not good even appears receiving the water condition, consequently needs a water receiving structure in the unstable environment such as being fit for aircraft or boats and ships.

Disclosure of Invention

Therefore, the technical problem to be solved by the application is to provide the water receiving structure and the airborne cooling unit, which can adapt to water receiving of the cooling unit under different working states, effectively prevent water drops from dripping and improve the water receiving effect.

In order to solve the problems, the application provides a water receiving structure, which comprises an air inlet channel and a water receiving baffle arranged in the air inlet channel, wherein the air inlet channel comprises an air inlet positioned at the lower side and an air outlet positioned at the upper side, the water receiving baffle is positioned between the air inlet and the air outlet, the water receiving baffle comprises a guide plate and a water receiving groove arranged at the bottom of the guide plate, two sides of the guide plate are in sealing fit with the side wall of the air inlet channel, the top of the water receiving groove is provided with a water receiving opening, and other parts of the water receiving groove except the water receiving opening are in sealing fit with the side wall of the air inlet channel.

Preferably, the air inlet channel comprises an air guide section and an air outlet section, the air guide section is obliquely arranged relative to the air outlet section, the guide plate comprises a first guide section and a second guide section, the first guide section is positioned in the air outlet section, the second guide section is positioned in the air guide section, the second guide section is obliquely arranged relative to the first guide section, and the water receiving tank is arranged at the bottom of the second guide section.

Preferably, the first diversion section is arranged in parallel relative to the air outlet section, and the second diversion section is arranged in parallel relative to the air guiding section.

Preferably, the water receiving groove comprises a connecting section connected with the guide plate and a bending section connected with the connecting section, wherein the bending section is connected at the bottom of the connecting section and extends from the bottom of the connecting section to the air outlet.

Preferably, the cross section of the bending section is curved, and the height of the curve decreases from the middle to the two ends relative to the connecting section.

Preferably, the cross section of the bending section is arched or semi-elliptical.

Preferably, the number of the water receiving baffles in the air inlet channel is at least two, and the at least two water receiving baffles are arranged at intervals.

Preferably, the projection of the water receiving tank on the horizontal plane is positioned in the projection range of the guide plate adjacent to the water receiving tank and positioned on the upper side of the water receiving tank on the horizontal plane.

Preferably, a water-absorbing layer is laid on the water-receiving surface of the deflector.

Preferably, the water-absorbing layer is a sponge.

Preferably, the bottom of the water receiving tank is provided with a drain pipe which is communicated with the water receiving tank.

Preferably, the water inlet is provided with a fixing seat, and the drain pipe is fixedly arranged on the fixing seat.

Preferably, the number of the air inlet channels is two, and the two air inlet channels are symmetrical about a vertical plane.

According to another aspect of the present application, there is provided an on-board cooling unit comprising a water receiving structure, the water receiving structure being the water receiving structure described above.

The application provides a water receiving structure, which comprises an air inlet channel and a water receiving baffle arranged in the air inlet channel, wherein the air inlet channel comprises an air inlet positioned at the lower side and an air outlet positioned at the upper side, the water receiving baffle is positioned between the air inlet and the air outlet, the water receiving baffle comprises a guide plate and a water receiving groove arranged at the bottom of the guide plate, two sides of the guide plate are in sealing fit with the side wall of the air inlet channel, the top of the water receiving groove is provided with a water receiving opening, and other parts of the water receiving groove except the water receiving opening are in sealing fit with the side wall of the air inlet channel. This water receiving structure can be through the water receiving baffle with the comdenstion water droplet water conservancy diversion to the water receiving tank in, then utilize the water receiving tank except that the other part of water receiving opening all with air inlet channel's lateral wall sealing fit's structure for the condensate water can keep in the water receiving tank well, even cooling unit is in different operating condition, also can remain in the water receiving tank all the time, can not spill in the water receiving tank, consequently can effectively prevent water droplet whereabouts, improves the water receiving effect.

Drawings

FIG. 1 is an exploded view of a water receiving structure according to an embodiment of the present application;

FIG. 2 is a schematic perspective view of a water receiving baffle of a water receiving structure according to an embodiment of the present application;

FIG. 3 is a schematic view of a water receiving structure according to an embodiment of the present application;

FIG. 4 is a schematic cross-sectional view of a water receiving structure according to an embodiment of the present application;

Fig. 5 is a schematic view of a water receiving structure according to an embodiment of the present application when an air inlet channel is inclined by 30 °.

The reference numerals are expressed as:

1. An air inlet channel; 2. a water receiving baffle; 3. an air inlet; 4. an air outlet; 5. a deflector; 6. a water receiving tank; 7. a water receiving opening; 8. an air guide section; 9. an air outlet section; 10. a first flow directing section; 11. a second flow directing section; 12. a connection section; 13. bending sections; 14. a water-absorbing layer; 15. a drain pipe; 16. a fixing seat.

Detailed Description

Referring to fig. 1 to 5, according to the embodiment of the application, the water receiving structure comprises an air inlet channel 1 and a water receiving baffle 2 arranged in the air inlet channel 1, the air inlet channel 1 comprises an air inlet 3 positioned at the lower side and an air outlet 4 positioned at the upper side, the water receiving baffle 2 is positioned between the air inlet 3 and the air outlet 4, the water receiving baffle 2 comprises a guide plate 5 and a water receiving groove 6 arranged at the bottom of the guide plate 5, two sides of the guide plate 5 are in sealing fit with the side wall of the air inlet channel 1, the top of the water receiving groove 6 is provided with a water receiving opening 7, and other parts of the water receiving groove 6 except the water receiving opening 7 are in sealing fit with the side wall of the air inlet channel 1.

This water receiving structure can be through water receiving baffle 2 with comdenstion water droplet water conservancy diversion to water receiving tank 6 in, then utilize water receiving tank 6 except that water receiving opening 7 other parts all with air inlet channel 1's lateral wall sealing fit's structural feature for the condensate water can keep in water receiving tank 6 well, even cooling unit is in different operating condition, when leading to air inlet channel 1 to take place the slope of great angle, also can make the comdenstion water remain in water receiving tank 6 all the time, can not spill in from water receiving tank 6, consequently can effectively prevent water droplet whereabouts, improve the water receiving effect.

In one embodiment, the air inlet channel 1 comprises an air guiding section 8 and an air outlet section 9, the air guiding section 8 is obliquely arranged relative to the air outlet section 9, the air guiding plate 5 comprises a first air guiding section 10 and a second air guiding section 11, the first air guiding section 10 is positioned in the air outlet section 9, the second air guiding section 11 is positioned in the air guiding section 8, the second air guiding section 11 is obliquely arranged relative to the first air guiding section 10, and the water receiving groove 6 is arranged at the bottom of the second air guiding section 11.

In this embodiment, the second guiding section 11 is obliquely arranged relative to the first guiding section 10, so that the condensed water at the air outlet 4 can be guided for the first time by using the first guiding section 10, and then the condensed water flowing from the first guiding section 10 to the second guiding section 11 or dropping from the air outlet 4 to the second guiding section 11 is guided further by using the second guiding section 11, so that the guiding effect of the guiding plate 5 is improved, and the condensed water can be stored in the water receiving tank 6 more quickly and effectively.

In one embodiment, the first diversion section 10 is parallel to the air outlet section 9, and the second diversion section 11 is parallel to the air guide section 8, so that the first diversion section 10 is matched with the extending direction of the air outlet section 9, and the second diversion section 11 is matched with the extending direction of the air guide section 8, thereby reducing the resistance of the diversion plate 5 received by the air flow in the air inlet channel 1 and improving the flow efficiency of the air flow in the air inlet channel 1.

In one embodiment, the second deflector segment 11 is bent at an angle of 30 ° to 60 °, preferably 45 °, relative to the first deflector segment 10.

In one embodiment, the water receiving tank 6 comprises a connecting section 12 connected with the deflector 5 and a bending section 13 connected with the connecting section 12, wherein the bending section 13 is connected at the bottom of the connecting section 12 and extends from the bottom of the connecting section 12 towards the air outlet 4. In this embodiment, through dividing the water receiving tank 6 into the connecting section 12 and the bending section 13, can utilize the connecting section 12 to realize being connected with the guide plate 5 to in the convenience is drained the comdenstion water on the guide plate 5 to the water receiving tank 6, the bending section 13 can form the water receiving space with the connecting section 12 simultaneously, carries out the storage of comdenstion water.

In one embodiment, the cross-section of the bending section 13 is curved, the height of the curve decreasing from the middle to the ends with respect to the connecting section 12.

In one embodiment, the cross-section of the bending section 13 is arched or semi-elliptical.

In this embodiment, the bending section 13 is set to a curve structure, and the curve is made to form a structure with the height decreasing from the middle to the two ends relative to the connecting section 12, so that the bending section 13 can form an arc-shaped flow guiding structure along the airflow direction, thereby ensuring that the bending section 13 conveniently forms a smaller water receiving opening 7 between the top and the connecting section 12 or the flow guiding plate 5, avoiding the condensed water from spilling from the water receiving opening 7, avoiding the condensed water from splashing out of the water receiving groove 6 even if the cooling unit is in an unstable environment, and simultaneously effectively reducing the disturbance of the water receiving groove 6 to the airflow in the air inlet process of the air inlet channel 1 due to the curved surface structure formed by the bending section 13, improving the airflow flowing efficiency and reducing the flowing noise.

In the present embodiment, the water receiving opening 7 should be as small as possible, so long as the condensed water can be ensured to smoothly flow from the baffle 5 into the water receiving tank 6.

In one embodiment, the number of the water receiving baffles 2 in the air inlet channel 1 is at least two, and the at least two water receiving baffles 2 are arranged at intervals. In this embodiment, a plurality of water receiving baffles 2 can form more comprehensive water receiving structure, realize the water receiving to the cross-section of whole air inlet channel 1 in, avoid taking place the phenomenon of leaking, improve water receiving efficiency and water receiving effect.

In one embodiment, the projection of the water receiving tank 6 on the horizontal plane is located within the projection range of the baffle 5 adjacent to the water receiving tank 6 and located on the upper side of the water receiving tank 6 on the horizontal plane. Because the water receiving groove 6 is positioned in the projection range of the guide plate 5 at the upper side along the vertical direction, no water leakage interval exists between the adjacent water receiving baffles 2, the condensed water entering the air inlet channel 1 can be ensured to be received by the water receiving baffles 2, and the water receiving effect of the water receiving baffles 2 is further improved.

In this embodiment, a plurality of water receiving baffles 2 are evenly spaced and set up, and the water receiving groove 6 of each water receiving baffle 2 bottom has the water conservancy diversion effect of buckling for the air current flow field that gets into upper portion heat exchanger distributes more evenly, effectively improves the heat exchange efficiency of heat exchanger.

In one embodiment, a water-absorbing layer 14 is laid on the water-receiving surface of the baffle 5. In this embodiment, by providing the water-absorbing layer 14, kinetic energy of water droplets falling down can be effectively absorbed, and when the water droplets are broken, the water droplets can be effectively absorbed, and compared with a structure without adding the water-absorbing layer 14, the embodiment of the application can effectively reduce splashing of the water droplets.

In one embodiment, the water-absorbing layer 14 is a sponge, but may be other structures capable of absorbing water.

In one embodiment, the bottom of the water receiving tank 6 is provided with a drain pipe 15, the drain pipe 15 being in communication with the water receiving tank 6. The condensed water stored in the water receiving tank 6 can be discharged into the drain pipe 15 and then discharged through the drain pipe 15, thereby effectively preventing the condensed water in the water receiving tank 6 from overflowing. In this embodiment, an opening is provided at the bottom of the water receiving tank 6, and the drain pipe 15 and the water receiving tank 6 are connected and fixed by welding.

In one embodiment, a fixing seat 16 is arranged at the air inlet 3, and a drain pipe 15 is fixedly arranged on the fixing seat 16. Through set up fixing base 16 on the lateral wall of air intake 3 at air inlet channel 1, can conveniently carry out the installation of drain pipe 15 fixed, improve the stability and the reliability of the arrangement structure of drain pipe 15.

In one embodiment, the number of the air inlet channels 1 is two, and the two air inlet channels 1 are symmetrical about a vertical plane, so that the water receiving structure has good water receiving effect in two inclined directions of the air guide section of the air inlet channel 1, and the water receiving capacity and the water receiving effect of the water receiving structure are further improved.

In this embodiment, the evaporator of the cooling unit is arranged at the upper part of the air inlet channel 1, and the air entering from the air inlet 3 uniformly reaches the air outlet 4 of the air inlet channel 1 under the action of the water receiving baffle 2, so that the heat exchange efficiency of the evaporator can be effectively improved. In addition, condensed water or defrosting water is formed on the evaporator to form melting water, and in the process of dripping downwards, even in an unstable environment inclined by 30 degrees, water drops can be prevented from flying out of the air inlet channel 1 due to the blocking effect of the water receiving baffle plate 2.

The comdenstion water that forms on the evaporimeter or by defrosting formation melting water possess great kinetic energy in the whereabouts in-process, when it runs into water receiving baffle 2, if do not have better buffer, the drop will break into many little drops that splash, outside the air inlet channel 1 flies out easily, through the mode of installing thin sponge on water receiving baffle 2, can utilize the effectual kinetic energy of absorbing the drop of sponge, prevent the splashing of drop, can also carry out effectual absorption to the drop of drop in addition.

The water receiving tank 6 at the lower part of the water receiving baffle 2 adopts an elliptical-like design, two ends of the water receiving tank 6 are connected with the shell of the water receiving baffle 2, the opening of the water receiving tank 6 is smaller, and when falling water drops enter the water receiving tank 6 through the guide plate 5 of the water receiving baffle 2, the water receiving tank 6 can effectively block water from overflowing even in an unstable environment, and in addition, the drain pipe 15 is arranged at the lower part of the water receiving tank 6, so that water can be effectively and timely discharged, and the effectiveness of a water receiving structure is ensured.

According to an embodiment of the present application, the on-board cooling unit includes a water receiving structure, which is the water receiving structure described above.

It will be readily appreciated by those skilled in the art that the above advantageous ways can be freely combined and superimposed without conflict.

The foregoing description of the preferred embodiments of the application is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the application. The foregoing is merely a preferred embodiment of the present application, and it should be noted that it will be apparent to those skilled in the art that modifications and variations can be made without departing from the technical principles of the present application, and these modifications and variations should also be regarded as the scope of the application.

Claims (13)

1. The utility model provides a water receiving structure, its characterized in that includes air inlet channel (1) and sets up water receiving baffle (2) in air inlet channel (1), air inlet channel (1) are including being located air intake (3) of downside and being located air outlet (4) of upside, water receiving baffle (2) are located between air intake (3) and air outlet (4), water receiving baffle (2) include guide plate (5) and set up water receiving tank (6) in guide plate (5) bottom, the both sides of guide plate (5) with the lateral wall sealing fit of air inlet channel (1), the top of water receiving tank (6) is provided with water receiving opening (7), water receiving tank (6) all with the lateral wall sealing fit of air inlet channel (1) except water receiving opening (7). The water receiving tank (6) comprises a connecting section (12) connected with the guide plate (5) and a bending section (13) connected with the connecting section (12), wherein the bending section (13) is connected to the bottom of the connecting section (12) and extends from the bottom of the connecting section (12) to the air outlet (4).

2. The water receiving structure according to claim 1, wherein the air inlet channel (1) comprises an air guiding section (8) and an air outlet section (9), the air guiding section (8) is obliquely arranged relative to the air outlet section (9), the air guiding plate (5) comprises a first air guiding section (10) and a second air guiding section (11), the first air guiding section (10) is positioned in the air outlet section (9), the second air guiding section (11) is positioned in the air guiding section (8), the second air guiding section (11) is obliquely arranged relative to the first air guiding section (10), and the water receiving groove (6) is arranged at the bottom of the second air guiding section (11).

3. The water receiving structure according to claim 2, characterized in that the first deflector segment (10) is arranged in parallel with respect to the air outlet segment (9) and the second deflector segment (11) is arranged in parallel with respect to the air guide segment (8).

4. The water receiving structure according to claim 1, characterized in that the cross section of the bending section (13) is curved, the height of the curve decreasing from the middle to the two ends with respect to the connecting section (12).

5. A water receiving structure according to claim 4, wherein the cross section of the bending section (13) is arched or semi-elliptical.

6. The water receiving structure according to claim 1, wherein the number of the water receiving baffles (2) in the air inlet channel (1) is at least two, and at least two water receiving baffles (2) are arranged at intervals.

7. The water receiving structure according to claim 6, characterized in that the projection of the water receiving tank (6) on the horizontal plane is located in the projection range of the deflector (5) adjacent to the water receiving tank (6) and located on the upper side of the water receiving tank (6) on the horizontal plane.

8. The water receiving structure according to claim 1, characterized in that a water absorbing layer (14) is laid on the water receiving surface of the deflector (5).

9. The water receiving structure according to claim 8, wherein the water absorbing layer (14) is a sponge.

10. The water receiving structure according to any one of claims 1 to 9, characterized in that a drain pipe (15) is provided at the bottom of the water receiving tank (6), the drain pipe (15) being in communication with the water receiving tank (6).

11. The water receiving structure according to claim 10, characterized in that a fixing seat (16) is provided at the air inlet (3), and the drain pipe (15) is fixedly provided on the fixing seat (16).

12. The water receiving structure according to claim 1, wherein the number of air inlet channels (1) is two, and the two air inlet channels (1) are symmetrical about a vertical plane.

13. An on-board cooling unit comprising a water receiving structure, characterized in that the water receiving structure is a water receiving structure according to any one of claims 1 to 12.