CN108224737B

CN108224737B - Sliding door drainage structures and air conditioner

Info

Publication number: CN108224737B
Application number: CN201810225629.4A
Authority: CN
Inventors: 吴庆壮; 黄涛; 罗会斌; 谢斌; 张玉忠; 张小红; 邹波
Original assignee: Aux Air Conditioning Co Ltd
Current assignee: Aux Air Conditioning Co Ltd
Priority date: 2018-03-19
Filing date: 2018-03-19
Publication date: 2024-01-19
Anticipated expiration: 2038-03-19
Also published as: CN108224737A

Abstract

The invention provides a drainage structure of a sliding door and an air conditioner, and relates to the technical field of household appliances. The sliding door drainage structure comprises a front panel lining plate, wherein the front panel lining plate is provided with a track groove which is used for being in sliding fit with a sliding door, a drainage outlet is formed in the bottom wall of the track groove, and the drainage outlet penetrates through the bottom wall of the track groove. According to the sliding door drainage structure and the air conditioner, the drainage outlet is formed in the bottom wall of the track groove, and condensed water generated on the front panel lining plate and the sliding door can be collected into the track groove and drained through the drainage outlet. Thus, the condensed water is convenient to collect so as to process the condensed water discharged from the water discharge port, thereby preventing the condensed water from overflowing the air conditioner and improving the user experience. In addition, the track groove has multiple functions, and can realize the dual functions of guiding and sliding and draining.

Description

Sliding door drainage structures and air conditioner

Technical Field

The invention relates to the technical field of household appliances, in particular to a drainage structure of a sliding door and an air conditioner.

Background

At present, in the vertical air conditioner with the air outlet vertically arranged in the market, condensed water can be generated at the air outlet in the working process or after the air conditioner stops working for a period of time, and the condensed water can overflow the vertical air conditioner, so that the user experience is affected.

Disclosure of Invention

In view of the above, the present invention aims to provide a drainage structure of a sliding door, which can facilitate collection and treatment of condensed water, prevent the condensed water from overflowing an air conditioner, and improve user experience.

In order to achieve the above purpose, the technical scheme of the invention is realized as follows:

the utility model provides a sliding door drainage structures, includes the front panel welt, the front panel welt is provided with the track groove that is used for with a sliding door sliding fit, the outlet has been seted up to the diapire in track groove, the outlet runs through the diapire in track groove.

Further, a diversion surface is arranged at one side edge of the water outlet, and the diversion surface is adjacent to the bottom wall of the track groove.

Further, the guide surface is arranged obliquely downwards from one side of the guide surface connected with the bottom wall of the track groove.

Further, the bottom wall of the track groove is convexly provided with water diversion ribs.

Further, one end of the water diversion rib is inclined toward the water outlet.

Further, the water diversion rib is arranged at the edge of one side of the water outlet, which is opposite to the water diversion surface, a connection edge is formed at the connection part of the water diversion surface and the bottom wall of the track groove, one end part of the connection edge is obliquely arranged towards the water outlet, and the connection edge and the water diversion rib form a V shape.

Further, a transition surface is further arranged on the edge of the water outlet, the transition surface is connected with the bottom wall of the track groove, one end portion, close to the water diversion rib, of the diversion surface is connected with one end portion, facing the water outlet, of the water diversion rib in an inclined mode through the transition surface, and the transition surface is connected to one side of the bottom wall of the track groove in a downward inclined mode.

Further, the front panel lining board is provided with a water receiving disc below the water outlet.

Further, a drainage wall is arranged on one side of the water receiving disc, and the lower end part of the drainage surface is connected with the water receiving disc through the drainage wall.

Further, the upper end surface of the drainage wall is flush with the lower end of the drainage surface.

Further, the drain opening is located at the lowest position of the bottom wall of the rail groove.

Further, a first boss and a second boss are arranged at intervals on the lower end part of the front panel lining plate, the track groove is formed between the first boss and the second boss, and the lower end part of the first boss is connected with the lower end part of the second boss through the bottom wall of the track groove.

Further, the drain opening is located in a central region of the rail groove.

Compared with the prior art, the drainage structure of the sliding door has the following advantages:

according to the drainage structure of the sliding door, the drainage opening is formed in the bottom wall of the track groove, and condensed water generated on the front panel lining plate and the sliding door can be collected into the track groove and drained through the drainage opening. Thus, the condensed water is convenient to collect so as to process the condensed water discharged from the water discharge port, thereby preventing the condensed water from overflowing the air conditioner and improving the user experience. In addition, the track groove has multiple functions, and can realize the dual functions of guiding and sliding and draining.

Another object of the present invention is to provide an air conditioner, which is capable of facilitating collection and treatment of condensed water, preventing the condensed water from overflowing the air conditioner, and improving user experience.

the utility model provides an air conditioner, includes sliding door drainage structures, sliding door drainage structures includes the front panel welt, the front panel welt is provided with the track groove that is used for with a sliding door sliding fit, the outlet has been seted up to the diapire in track groove, the outlet runs through the diapire in track groove.

The air conditioner has the same advantages as the drainage structure of the sliding door compared with the prior art, and the description is omitted herein.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention. In the drawings:

fig. 1 is a schematic view of a part of an air conditioner to which a drainage structure of a sliding door according to an embodiment of the present invention is applied;

fig. 2 is a schematic structural view of a front panel liner of a drainage structure of a sliding door according to an embodiment of the present invention;

FIG. 3 is an enlarged view of a portion of the portion III of FIG. 2;

FIG. 4 is a schematic view of a partially cut-away structure of an air conditioner to which the drainage structure of a sliding door according to an embodiment of the present invention is applied;

fig. 5 is a partial enlarged view of V in fig. 4.

Reference numerals illustrate:

1-an air conditioner; 2-sliding door; 3-sliding door drainage structure; 4-a front panel liner; 5-an air outlet; 6-a track groove; 7-a water outlet; 8-a bottom wall; 9-a first boss; 10-a second boss; 11-connecting plates; 12-a first trough section; 13-a second trough section; 14-a guide surface; 15-connecting edges; 16-water diversion ribs; 17-transition surface; 18-a water pan; 19-drainage wall.

Detailed Description

It should be noted that, without conflict, the embodiments of the present invention and features of the embodiments may be combined with each other.

The invention will be described in detail below with reference to the drawings in connection with embodiments.

Examples

Referring to fig. 1, an embodiment of the present invention provides a drainage structure 3 for a sliding door, which is applied to an air conditioner 1, particularly a vertical air conditioner 1. The air conditioner 1 includes a sliding door 2 and the sliding door drainage structure 3 described above. The sliding door 2 and the sliding door drainage structure 3 are in sliding fit with each other. The sliding door drain structure 3 serves to collect and guide a part of condensed water generated from the air conditioner 1 to prevent the condensed water from overflowing the air conditioner 1.

Referring to fig. 2 and 3, the sliding door drainage structure 3 includes a front panel lining 4, and an air outlet 5 is disposed on the front panel lining 4. The sliding door 2 is in sliding fit with the front panel lining 4, and the sliding door 2 can slide relative to the front panel lining 4, so that the air outlet 5 is opened or the air outlet 5 is shielded.

The front panel lining 4 is provided with a track groove 6 for sliding engagement with the sliding door 2. The bottom wall 8 of the track groove 6 is provided with a water outlet 7, and the water outlet 7 penetrates through the bottom wall 8 of the track groove 6. In this embodiment, the track groove 6 is disposed at the lower end of the front panel liner 4 and below the lower end of the air outlet 5. The lower end portion of the sliding door 2 is inserted into the rail groove 6 and is capable of sliding along the rail groove 6.

The words "lower" and "lower" indicating the orientation refer to directions closer to the ground when the air conditioner 1 is in a stationary placement state in a use environment. Wherein "below" may be that the first structural feature is located vertically below the second structural feature, or may be located below the second structural feature in a staggered manner, so long as the first structural feature is closer to the ground than the second structural feature. Accordingly, the word "up" representing the azimuth refers to a direction farther from the ground when the air conditioner 1 is in a stationary placement state in the use environment. Similar "upper" and "lower" mentioned in the following detailed description will not be repeated.

By providing the drain port 7 in the bottom wall 8 of the rail groove 6, condensed water generated in the front panel liner 4 and the sliding door 2, particularly condensed water generated in the air outlet 5, can be collected in the rail groove 6 and discharged through the drain port 7 when flowing downward. Thus, the condensed water is convenient to collect so as to process the condensed water discharged from the water outlet 7, thereby preventing the condensed water from overflowing the air conditioner 1 and improving the user experience.

In addition, the portion of the lower end portion of the sliding door 2 inserted into the track groove 6 is spaced from the bottom wall 8 of the track groove 6, so that the condensed water in the track groove 6 is facilitated to flow, so that the condensed water is discharged from the water discharge port 7, and the collection of the condensed water is not affected when the sliding door 2 slides relative to the front panel lining 4.

In this embodiment, a first boss 9 and a second boss 10 are disposed at intervals on the lower end portion of the front panel lining board 4, a track groove 6 is formed between the first boss 9 and the second boss 10, and the lower end portion of the first boss 9 is connected with the lower end portion of the second boss 10 through a bottom wall 8 of the track groove 6. It will be appreciated that the rail groove 6 is generally U-shaped in longitudinal section. The side walls of the first boss 9 and the second boss 10, which correspond to each other, serve as the groove walls of the track groove 6.

In addition, the first boss 9 has a substantially arc-shaped strip-like structure protruding from the outer surface of the front panel liner 4. The second boss 10 is a substantially arc-shaped strip-like structure, and is disposed outside the first boss 9. Thus, the track groove 6 is substantially arc-shaped, which matches the cross-sectional arc shape of the sliding door 2. Alternatively, one end of each of the first boss 9 and the second boss 10 extends to one side portion of the front panel liner 4, and the other end extends to the opposite other side portion of the front panel liner 4. Thus, one end of the rail groove 6 extends to one side portion of the front panel backing 4, and the other end extends to the opposite other side portion of the front panel backing 4.

In this embodiment, the front panel liner 4 is provided with a connection plate 11 at the lower end edge of the air outlet 5, and the lower end of the connection plate 11 is connected to the first boss 9. The condensed water generated by the air outlet 5 flows to the connecting plate 11, flows to the first boss 9 along the connecting plate 11, and flows into the track groove 6 from the first boss 9. This is more advantageous in guiding the condensed water generated from the air outlet 5 into the rail groove 6.

In this embodiment, the drain opening 7 is located at the lowest position of the bottom wall 8 of the rail groove 6. In this way, the condensed water can flow to the drain port 7 very conveniently under the action of self gravity. Optionally, the drain opening 7 is located in a central region of the rail groove 6.

Referring to fig. 4, the bottom wall 8 of the track groove 6 is divided into a first groove section 12 and a second groove section 13 by the drain opening 7, and an end of the first groove section 12 near the drain opening 7 and an end of the second groove section 13 near the drain opening 7 are inclined downward, so that the drain opening 7 is at the lowest position of the bottom wall 8 of the track groove 6.

In addition, referring to fig. 4 and 5, in the present embodiment, the drain opening 7 is substantially triangular. One side of the drain opening 7 is formed by a side wall of the first boss 9. The drain port 7 has a guide surface 14 provided at one side edge thereof, the guide surface 14 being connected to the bottom wall 8 of the rail groove 6, and the guide surface 14 being provided so as to be inclined downward from the side thereof connected to the bottom wall 8 of the rail groove 6. In this embodiment, the diversion surface 14 is connected to a portion of the first groove section 12 near the drain port 7. The flow guiding surface 14 may be an inclined plane, an inclined cambered surface, or an irregular curved surface inclined downward. When the condensed water flows to the drain port 7, the condensed water can be guided by the guide surface 14, and the drain direction of the condensed water is restricted. Alternatively, a connection edge 15 is formed at the connection of the guide surface 14 and the bottom wall 8 of the rail groove 6, and one end of the connection edge 15 is disposed obliquely toward the drain opening 7. It should be understood that the shape of the connecting edge 15 may be straight, curved, etc. In this embodiment, the connecting edge 15 is a straight edge.

The bottom wall 8 of the track groove 6 is convexly provided with a water diversion rib 16, and one end part of the water diversion rib 16 is obliquely arranged towards the water outlet 7. It should be noted that the number and shape of the water diversion ribs 16 are not particularly limited, and the number of the water diversion ribs 16 may be one or two or more, for example, when the number of the water diversion ribs 16 is two, the two water diversion ribs 16 may form an "eight" shape, and the condensed water is led to the water outlet 7 at the position where the interval between the two water diversion ribs gradually decreases. The water diversion ribs 16 can be linear or arc-shaped. In this embodiment, the water diversion rib 16 is a straight line.

In this embodiment, the water diversion rib 16 is provided on the side edge of the drain port 7 opposite to the diversion surface 14. And, the water deflector 16 is located on the second trough section 13. One end of the water diversion rib 16 is connected to the side wall of the first boss 9, and the other end is inclined toward the drain port 7 and spaced from the side wall of the second boss 10. The connecting edge 15 and the water diversion rib 16 form a V shape. So that the condensed water on the second groove section 13 is guided by the water diversion rib 16, passes through the gap between the water diversion rib 16 and the side wall of the second boss 10 and enters the first groove section 12, and then enters the water outlet 7 through the water diversion surface 14.

In addition, the edge of the water outlet 7 is also provided with a transition surface 17, the transition surface 17 is connected with the bottom wall 8 of the track groove 6, one end part of the diversion surface 14, which is close to the diversion rib 16, is connected with one inclined end part of the diversion rib 16, which faces the water outlet 7, through the transition surface 17, and the transition surface 17 is arranged in a downward inclined way from one side of the transition surface connected with the bottom wall 8 of the track groove 6. The transition surface 17 may be an inclined plane, an inclined cambered surface, or an irregular curved surface. The condensed water on the second groove section 13 passes through the drainage of the water diversion rib 16, passes through the gap between the water diversion rib 16 and the side wall of the second boss 10, and then can enter the water outlet 7 through the transition surface 17.

In addition, the condensed water discharged from the water outlet 7 may be collected and carried by a carrying structure externally connected to the air conditioner 1, or may be carried by a carrying structure of the air conditioner 1 itself. The present embodiment uses the bearing structure of the air conditioner 1 itself to carry the condensed water discharged from the water discharge port 7.

With continued reference to fig. 3, in this embodiment, the front panel liner 4 has a water pan 18 below the water outlet 7 for carrying water flowing down from the water outlet 7, so that condensed water does not overflow the air conditioner 1, and user experience is improved. The water pan 18 carries condensed water, so that the condensed water can be naturally air-dried in the water pan 18. Of course, in other embodiments of the present invention, it is also possible to provide a bearing structure on other structures of the air conditioner 1, and guide the condensed water flowing out of the drain port 7 to the bearing structure through a water guiding structure.

In this embodiment, the lower end of the front panel liner 4 has a cavity opening outwards, and the bottom of the cavity is the water pan 18.

A drainage wall 19 is arranged on one side of the water pan 18, and the lower end part of the drainage surface 14 is connected with the edge of the water pan 18 through the drainage wall 19. Alternatively, the upper end surface of the drainage wall 19 is flush with the lower end of the drainage surface 14. The condensed water flows to the drainage wall 19 from the guiding surface 14, and then is guided to the water pan 18 from the guiding surface 14. In this way, the condensed water flows along the guide surface 14 and the guide wall 19, and does not directly drip into the water receiving tray 18 from the water outlet 7, thereby causing splashing. Of course, in other embodiments of the present invention, the upper end surface of the drainage wall 19 and the lower end of the drainage surface 14 may also form a stepped structure, as long as condensed water can flow from the drainage surface 14 to the drainage wall 19.

The working principle of the sliding door drainage structure 3 provided in this embodiment is: condensed water formed on the front panel liner 4 and the sliding door 2 or condensed water formed at the air outlet 5 flows into the rail groove 6 in the downward flow process. The drain outlet 7 is positioned at the lowest position of the bottom wall 8 of the track groove 6, and condensed water in the first groove section 12 flows to the drain outlet 7 and flows down by the guide surface 14; the condensed water in the second groove section 13 flows to the water outlet 7 and is drained through the drainage of the water diversion rib 16, and when the condensed water passes over the gap between the water diversion rib 16 and the second boss 10, the condensed water enters the water outlet 7 from the diversion surface 14 or the transition surface 17 and is drained. The condensed water discharged from the drain port 7 flows along the guide surface 14 toward the drain wall 19, and flows into the water receiving tray 18 along the drain wall 19.

In summary, in the sliding door drainage structure 3 provided in this embodiment, the drainage opening 7 is formed in the bottom wall 8 of the track groove 6, so that condensed water generated on the front panel liner 4 can be collected into the track groove 6 and drained through the drainage opening 7. Thus, the condensed water is convenient to collect so as to process the condensed water discharged from the water outlet 7, thereby preventing the condensed water from overflowing the air conditioner 1 and improving the user experience. The rail groove 6 can be multifunctional, and the dual functions of sliding guiding and water draining can be realized.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims

1. The utility model provides a sliding door drainage structures, its characterized in that includes front panel welt (4), front panel welt (4) are provided with be used for with a sliding door (2) sliding fit's track groove (6), outlet (7) have been seted up to the diapire (8) of track groove (6), outlet (7) run through diapire (8) of track groove (6), be provided with first boss (9) and second boss (10) on the lower tip of front panel welt (4) at intervals, form between first boss (9) and second boss (10) track groove (6), the lower tip of first boss (9) with the lower tip of second boss (10) is through diapire (8) of track groove (6);

a diversion surface (14) is arranged at one side edge of the water outlet (7), and the diversion surface (14) is adjacent to the bottom wall (8) of the track groove (6);

the bottom wall (8) of the track groove (6) is divided into a first groove section (12) and a second groove section (13) through the water outlet (7), and one end part of the first groove section (12) close to the water outlet (7) and one end part of the second groove section (13) close to the water outlet (7) are inclined downwards;

the bottom wall (8) of the track groove (6) is convexly provided with a water diversion rib (16), the water diversion rib (16) is arranged at one side edge of the water outlet (7) opposite to the water diversion surface (14), the water diversion rib (16) is positioned on the second groove section (13), one end of the water diversion rib (16) is connected with the side wall of the first boss (9), and the other end of the water diversion rib is obliquely arranged towards the water outlet (7) and is arranged at intervals with the side wall of the second boss (10);

a connection edge (15) is formed at the connection position of the diversion surface (14) and the bottom wall (8) of the track groove (6), one end part of the connection edge (15) is obliquely arranged towards the water outlet (7), and the connection edge (15) and the water diversion rib (16) form a V shape.

2. Sliding door drainage structure according to claim 1, characterized in that the guide surface (14) is arranged inclined downwards from the side of the bottom wall (8) which is connected to the rail groove (6).

3. The sliding door drainage structure according to claim 2, characterized in that the edge of the drain opening (7) is further provided with a transition surface (17), the transition surface (17) is connected with the bottom wall (8) of the track groove (6), and an end portion of the diversion surface (14) close to the diversion rib (16) is connected with an end portion of the diversion rib (16) inclined toward the drain opening (7) through the transition surface (17), and the transition surface (17) is arranged by being connected with one side of the bottom wall (8) of the track groove (6) in a downward inclined manner.

4. Sliding door drain structure according to claim 1, characterized in that the front panel lining (4) has a water pan (18) below the drain opening (7).

5. The sliding door drainage structure according to claim 4, wherein a drainage wall (19) is provided on one side of the water receiving tray (18), and a lower end portion of the guide surface (14) is connected to the water receiving tray (18) through the drainage wall (19).

6. Sliding door drainage structure according to claim 5, characterized in that the upper end surface of the drainage wall (19) is flush with the lower end of the guide surface (14).

7. Sliding door drainage structure according to any of claims 1-6, characterized in that the drainage opening (7) is located at the lowest part of the bottom wall (8) of the track groove (6).

8. Sliding door drainage structure according to any of claims 1-6, characterized in that the drainage opening (7) is located in the middle area of the track groove (6).

9. An air conditioner comprising a sliding door drainage structure (3) according to any one of claims 1 to 8.