CN108397890B - Flow guide piece, air conditioner water guide structure and air conditioner - Google Patents

Abstract

The invention relates to the field of air conditioner structures, and aims to solve the problems of hidden danger such as water leakage and electricity utilization safety caused by the fact that condensed water flows out of a water receiving device in a converging mode in the existing air conditioner. The invention provides a flow guiding piece, an air conditioner water guiding structure and an air conditioner. The guide piece is used for guiding and removing condensate and is provided with an outer plate surface and an inner plate surface which are opposite. The diversion piece is provided with a diversion trench, one end of which is formed by the concave of the outer surface of the diversion piece and blocked by the first diversion structure. A diversion through hole penetrating through the outer plate surface and the inner plate surface is formed in the diversion trench close to the first diversion structure. The first flow guiding structure is configured to guide condensate flowing into the flow guiding groove to enter the inner plate surface side space of the flow guiding piece through the flow guiding through hole. The invention has the beneficial effects that the condensed water can be collected and orderly guided and discharged, and the problems of water leakage caused by the drainage of the condensed water in the open space of the outer plate surface and influence on an air conditioner power utilization system can be avoided.

Description

Flow guide piece, air conditioner water guide structure and air conditioner

Technical Field

The invention relates to the field of air conditioner structures, in particular to a flow guide piece, an air conditioner water guide structure and an air conditioner.

Background

When the air conditioner is used, cold and hot junction surfaces are easily formed on the surfaces of the air duct and the heat exchanger and the related parts, a large amount of condensed water is generated, and hidden dangers such as water leakage, electrical safety and the like are caused by the condensed water flowing out of the water receiving device in a converging way.

Disclosure of Invention

The invention aims to provide a guide piece to solve the problems of hidden danger such as water leakage, electricity utilization safety and the like caused by the fact that condensed water is collected and flows out of a water receiving device in an air conditioner in the prior art.

Another object of the present invention is to provide an air conditioner water guiding structure having the above-mentioned guiding member.

Another object of the present invention is to provide an air conditioner having the above-mentioned deflector.

Embodiments of the present invention are implemented as follows:

the embodiment of the invention provides a guide piece which is used for guiding and removing condensate and is provided with an outer plate surface and an inner plate surface which are opposite. The diversion piece is provided with a diversion trench, one end of which is formed by the concave of the outer surface of the diversion piece and blocked by the first diversion structure. A diversion through hole penetrating through the outer plate surface and the inner plate surface is formed in the diversion trench close to the first diversion structure. The first flow guiding structure is configured to guide condensate flowing into the flow guiding groove to enter the inner plate surface side space of the flow guiding piece through the flow guiding through hole.

The flow guiding piece in the embodiment is mainly used for an air conditioner. When the device is used, water vapor in the environment is condensed on the outer plate surface of the guide piece to form condensed water, and the condensed water is converged on the guide groove under gravity after converging and flows down along the guide groove. The condensed water flowing down enters into the inner plate surface side space of the guide piece through the guide through hole under the guide effect of the first guide structure, and then the subsequent organized drainage is carried out in the inner plate surface side space, so that the problems of water leakage caused by the drainage of the condensed water in the open space of the outer plate surface and the influence on an air conditioner electricity utilization system are avoided.

In one implementation of the present embodiment:

the guide piece comprises a main plate, a first slope wall and a second slope wall. The mainboard is long platelike structure. The first slope wall is connected to one side of the main board in the width direction and obliquely intersects with the main board. The second slope wall is connected to the wide outward side edge of the first slope wall and forms a diversion trench body defining a diversion trench together with the first slope wall. The diversion through hole is arranged on the first slope wall.

In one implementation of the present embodiment:

the first flow guiding structure comprises inclined flow guiding ribs. The oblique guide rib is connected in the guide groove and obliquely intersects with the first slope wall to form an acute angle.

In one implementation of the present embodiment:

the inclined guide rib is provided with a guide surface, and the guide surface is smoothly connected with the part of the inner surface of the first slope wall, which is positioned below the guide through hole.

In one implementation of the present embodiment:

the first diversion structure further comprises a water retaining rib, and the water retaining rib is formed by extending outwards along the width of the main plate from the position of the diversion through hole corresponding to the intersection line of the main plate and the first slope wall. The outer end of the water retaining rib extends to be connected with the inclined guide rib and is positioned at the corresponding position of the notch of the guide groove and the guide through hole.

In one implementation of the present embodiment:

one side of the inner plate surface of the flow guiding piece is provided with a second flow guiding structure which is positioned below the flow guiding through hole and used for guiding condensed water flowing in from the flow guiding through hole.

In one implementation of the present embodiment:

the second diversion structure comprises a water receiving platform which is positioned below the diversion through hole and is used for receiving the condensed water flowing down from the diversion through hole, and an overflow platform which is used for receiving the condensed water flowing down from the water receiving platform and is provided with an overflow port. In the direction from the outer plate surface to the inner plate surface, the overflow platform is positioned outside the horizontal receiving platform, so that the two overflow platforms form a two-stage step shape.

In one implementation of the present embodiment:

a group of adjacent sides of the horizontal receiving platform are respectively connected with the main board and the first slope wall, and the horizontal receiving platform is perpendicular to the extending direction of the diversion trench. The other group of adjacent sides of the horizontal receiving platform extend downwards to form a drainage surface, the drainage surface extends outwards to form two opposite guide walls, and the lower ends of the two guide walls are respectively connected with the two wide ends of the overflow platform. The upper ends of the two guide walls extend upwards to form a horizontal receiving platform to form a flow blocking part for laterally blocking the horizontal receiving platform.

The embodiment of the invention also provides an air conditioner water guide structure which comprises a water receiving disc and the guide piece. The water pan is provided with a water collecting tank. The water conservancy diversion spare sets up water conservancy diversion through-hole one end and connects in the water collector, and water conservancy diversion through-hole intercommunication water catch bowl.

The embodiment of the invention also provides an air conditioner which comprises a heat exchanger, a water receiving disc and the flow guide piece. The water pan is provided with a water collecting tank. The guide piece is connected to the heat exchanger in a state that the inner plate surface of the guide piece is opposite to the heat exchanger, and the guide piece is positioned at an air duct of the air conditioner. The water conservancy diversion spare sets up water conservancy diversion through-hole one end and connects in the water collector, and water conservancy diversion through-hole intercommunication water catch bowl.

In summary, the flow guide piece, the air conditioner water guide structure and the air conditioner can collect and orderly guide and discharge condensed water, and can avoid water leakage caused by water discharge of the condensed water in the open space of the outer plate surface and the problem of influencing an air conditioner power utilization system.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic view of an air conditioner in an embodiment of the present invention;

FIG. 2 is a schematic structural view of a flow guiding member according to an embodiment of the present invention;

FIG. 3 is a cross-sectional view taken along line B-B of FIG. 2;

FIG. 4 is an enlarged view at C of FIG. 2;

FIG. 5 is a cross-sectional view taken along line D-D of FIG. 4;

FIG. 6 is a view in the direction A of FIG. 2;

FIG. 7 is an enlarged view at E of FIG. 6;

fig. 8 is a schematic structural diagram of an air conditioner water guiding structure in an embodiment of the invention.

Icon: 100-flow guiding piece; 10-a main board; 20-a first sloping wall; 30-a second sloping wall; 31-a first sub-wall; 32-a second sub-wall; 40-a first flow guiding structure; 41-oblique guide ribs; 42-water blocking ribs; 50-a second flow guiding structure; 51-a horizontal stage; 52-an overflow platform; 53-a deflector wall; 54-a baffle; 60-flanging; 61-snap-fit structure; b1-a diversion trench body; c1-diversion trenches; c2-a water collection sump; k1-a diversion through hole; k2-overflow port; k3-oblong holes; p1-an outer plate surface; p2-inner panel surface; p3-a guide surface; p4-drainage surface; p5-inclined surface; 001-an air conditioner; 010-air conditioner water guide structure; 200-a water pan; 300-heat exchanger.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. The components of the embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

The terms "first," "second," and the like, in the description of the present invention, are used for distinguishing between the descriptions and not be construed as indicating or implying a relative importance.

Examples

Fig. 1 is a schematic diagram of an air conditioner 001 according to an embodiment of the present invention. Referring to fig. 1, an air conditioner 001 in the present embodiment includes a heat exchanger 300, a water pan 200 and a flow guiding member 100. The drip tray 200 has a water collection tank C2. One side of the deflector 100 is connected to the heat exchanger 300, and the deflector 100 is located at an air duct of the air conditioner 001. The lower end of the deflector 100 is connected to the water pan 200.

When the air conditioner 001 of this embodiment is used, water vapor in the environment condenses on the outer surface of the guide member 100 to form condensed water, and the condensed water flows down along the guide member 100 to the water collection tank C2 of the water collection tray 200 under the action of gravity after converging, and then can be manually or automatically controlled to be discharged from the water collection tank C2. The outer surface of the deflector 100 herein refers to the surface of the deflector 100 that faces outward when installed.

In order to solve the problems of water leakage of the air conditioner 001 or influence on the power utilization system of the air conditioner 001, which may be caused by the unorganized flow of the condensed water, the inventor of the present invention has independently designed a guide member 100 with a special structure, which can condense the condensed water at the air duct of the air conditioner 001 on the guide member, and organically flow down and discharge the condensed water, thereby avoiding the problems of water leakage and influence on the power utilization system of the air conditioner 001, which may be caused by the unorganized flow of the condensed water. Of course, to match the specially designed flow guiding member 100, the water receiving tray 200 and other structures to be matched or connected with the flow guiding member 100 in this embodiment are also designed in some structures.

The structure of the deflector 100 in the present embodiment is described below.

Referring to fig. 2, the flow guiding member 100 in the present embodiment is generally elongated, and its length and width dimensions can be set to match the overall dimensions of the air conditioner 001, and the characteristics of the heat exchanger 300, the air outlet, etc. matched with the same.

The flow guide 100 provided in this embodiment is used for guiding condensate (such as condensate condensed on the flow guide 100), and has an outer plate surface P1 and an inner plate surface P2 opposite to each other. The deflector 100 has a deflector groove C1 recessed from its outer surface P1 and blocked at one end by the first deflector structure 40. A diversion through hole K1 penetrating through the outer plate surface P1 and the inner plate surface P2 is formed in the diversion trench C1 near the first diversion structure 40. The first flow guide structure 40 is configured to guide condensate flowing into the flow guide groove C1 to enter the space on the inner plate surface P2 side of the flow guide 100 through the flow guide through hole K1.

The deflector 100 in the present embodiment is mainly used for an air conditioner 001. When in use, water vapor in the environment is condensed on the outer plate surface P1 of the guide piece 100 to form condensed water, and the condensed water is converged on the guide groove C1 under the gravity after converging and flows down along the guide groove C1. The condensed water flowing down enters into the space on the side of the inner plate surface P2 of the guide piece 100 through the guide through hole K1 under the guide action of the first guide structure 40, and then the space on the side of the inner plate surface P2 is subjected to subsequent organized drainage, so that the problems of water leakage caused by the drainage of the condensed water in the open space of the outer plate surface P1 and influence on an air conditioner electricity utilization system are avoided.

Fig. 3 is a cross-sectional view of fig. 2 taken along line B-B. Referring to fig. 3 (see fig. 2 in combination), in an implementation of the present embodiment, optionally, the flow guiding member 100 includes a main plate 10, a first slope wall 20, and a second slope wall 30. The main board 10 is an elongated plate-like structure. The first slope wall 20 is connected to one widthwise side of the main plate 10 and obliquely intersects the main plate 10. The second sloping wall 30 is connected to the wide outward side of the first sloping wall 20 and together with the first sloping wall 20 constitutes a channel body B1 defining a channel C1. The diversion through hole K1 is formed in the first sloping wall 20. Optionally, the second slope wall 30 includes a first sub-wall 31 and a second sub-wall 32, the second sub-wall 32 is opposite to the first slope wall 20, and the first sub-wall 31 connects the second sub-wall 32 and the first slope wall 20 to form an approximately U-shaped diversion trench B1.

With continued reference to fig. 2 and 3, for convenience of lateral installation, the guide member 100 in the present embodiment is provided with a connection structure on two sides in the width direction. Optionally, additional connection structures are provided on the flow guiding groove body B1, for example oblong holes K3 for mounting connection elements are provided at suitable positions on the first sub-wall 31 and on the second sub-wall 32, respectively, so that the flow guiding groove body B1 doubles as a connection structure for this side of the flow guiding element 100. The other side of the guide member 100 may be provided with a flange 60, and a plurality of fastening structures 61 are provided on the flange 60, so as to facilitate connection and cooperation of the side of the guide member 100. Also, to facilitate the installation of the two ends in the longitudinal direction, the two ends of the flow guiding member 100 in the present embodiment may be adaptively configured, for example, the structure with smaller two ends shown in fig. 2.

As described above, the first flow guiding structure 40 in the present embodiment serves to guide the condensed water flowing into the flow guiding groove C1 through the flow guiding through hole K1 into the inner plate surface P2 side of the flow guiding member 100 without continuing to flow down from the outer plate surface P1 side. For this purpose, the first flow guiding structure 40 may be provided in various forms. In this embodiment, referring to fig. 4, the first guiding structure 40 includes an inclined guiding rib 41. The inclined guide rib 41 is connected in the guide groove C1 and forms an acute angle with the inclination of the first slope wall 20. Referring to fig. 5, optionally, the inclined guide rib 41 has a guide surface P3, and the guide surface P3 is smoothly connected to a portion of the inner surface of the first slope wall 20 located below the guide through hole K1. In this way, the condensed water flowing down from the diversion trench C1 is guided by the inclined diversion ribs 41, and directly flows along the diversion plane P3 to the inner surface of the first slope wall 20, so that the condensed water smoothly flows from the outer plate plane P1 to the inner plate plane P2 of the diversion member 100. In order to further realize water guiding, the first guiding structure 40 further includes a water blocking rib 42, where the water blocking rib 42 extends from the intersection line of the main board 10 and the first slope wall 20 to the corresponding guiding through hole K1 along the main board 10 in the wide direction. The outer end of the water retaining rib 42 extends to be connected with the inclined guide rib 41 and is positioned at the corresponding position of the notch of the guide groove C1 and the guide through hole K1. The water retaining rib 42 is located at the notch of the diversion trench C1 and corresponds to the diversion through hole K1, so that condensate water flowing down from the diversion trench C1 can be further prevented from overflowing the first diversion structure 40 to continue flowing on the outer plate surface P1, and the condensate water is ensured to enter one side of the inner plate surface P2 through the diversion through hole K1.

Referring to fig. 6 and 7, after the condensed water enters the inner plate surface P2 through the flow guiding hole K1, a second flow guiding structure 50 is disposed on the inner plate surface P2 of the flow guiding member 100 below the flow guiding hole K1 for guiding the condensed water flowing in from the flow guiding hole K1 for keeping the condensed water flowing and discharging. The second flow directing structure 50 may be provided in a variety of forms. For example, referring to fig. 7, the second flow guiding structure 50 includes a water receiving platform 51 positioned below the flow guiding through hole K1 for receiving the condensed water flowing down from the flow guiding through hole K1, and an overflow platform 52 having an overflow port K2 for receiving the condensed water flowing down from the water receiving platform 51. The overflow platform 52 is located outside the horizontal receiving platform 51 in a direction from the outer plate surface P1 to the inner plate surface P2, so that both are formed in a two-stage step shape. When the condensed water flows from the flow guide through hole K1 to the inner plate surface P2 side, the condensed water flows along the inner plate surface P2 to the water receiving table 51. And then continues downwardly from the level stand 51 to the overflow platform 52 and flows down from the overflow port K2 to the sump C2 (see fig. 1 for mating) of the drip tray 200 for collection or drainage. Alternatively, the horizontal receiving platform 51 is a substantially rectangular platform structure, a group of adjacent sides of the horizontal receiving platform 51 are respectively connected to the first sloping wall 20 and the main board 10, and the horizontal receiving platform 51 is perpendicular to the extending direction of the diversion trench C1; the other group of adjacent sides extend downwards to form a diversion surface P4, the diversion surface P4 extends outwards to form two opposite diversion walls 53, and the lower ends of the two diversion walls 53 are respectively connected with the two wide ends of the overflow platform 52. The upper ends of the two guide walls 53 extend upwards out of the horizontal receiving platform 51 to form a blocking part 54 for laterally blocking the horizontal receiving platform 51. Alternatively, the width of the overflow platform 52 is set smaller than the width of the water receiving platform 51, so that the overflow port K2 is sufficiently low to concentrate the condensed water. For this purpose, one of the guide walls 53 is arranged obliquely, and the two guide walls 53 and the overflow platform 52 together form an approximately V-shaped structure. Optionally, the lower end surface of overflow platform 52 is an inclined surface P5 that serves to ensure that condensate flows directly down overflow K2 without flowing inwardly along the surface to prevent ingress and leakage into sump C2 (see also FIG. 8 below). The function of the two baffles 54 is to avoid lateral outflow of condensate flowing to the water receiving platform 51.

Referring to fig. 1, in order to make the air guide member 100 of the present embodiment better protect the internal structure of the air conditioner 001, the air guide member 100 is connected to the heat exchanger 300 with its inner plate P2 facing the heat exchanger 300, and the air guide member 100 is located at the air duct of the air conditioner 001. The advantage of this arrangement is that the flow guide 100 is located at the cold-hot junction of the air duct and is capable of receiving most of the condensate water generated. In addition, in order to promote the condensed water on the outer surface of the main board 10 to flow into the diversion trench C1, the diversion member 100 in the present embodiment is suitably inclined vertically when the diversion member 100 is installed, so that the condensed water flowing down the outer surface of the main board 10 falls into the diversion trench C1 as much as possible.

Referring to fig. 8 in combination, the embodiment of the present invention further provides an air conditioner water guiding structure 010, which includes a water receiving tray 200 and the aforementioned water guiding member 100. The drip tray 200 has a water collection tank C2. The flow guiding piece 100 is provided with a flow guiding through hole K1, one end of the flow guiding through hole K1 is connected to the water receiving disc 200, and the flow guiding through hole K1 is communicated with the water collecting tank C2. Condensed water condensed on the guide piece 100 flows down to the water collecting tank C2 from the water receiving platform 51 and the overflow platform 52 on one side of the inner plate surface P2 through the guide through hole K1 and flows in an organized manner through the overflow port K2, so that the problems of water leakage and influence on an air conditioner power utilization system are avoided.

By combining the above description, the flow guide member 100, the air conditioner water guide structure 010 and the air conditioner 001 in the embodiment of the invention can collect and orderly guide and discharge condensed water, and can avoid the problems of water leakage caused by the water discharge of the condensed water in the open space of the outer plate surface P1 and influence on the air conditioner electricity utilization system.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. A deflector for guiding condensate removal, characterized by:

the flow guide piece is provided with an outer plate surface and an inner plate surface which are opposite;

the flow guiding piece is provided with a flow guiding groove, one end of which is formed by concave inner surface of the flow guiding piece and blocked by the first flow guiding structure;

a diversion through hole penetrating through the outer plate surface and the inner plate surface is formed in the diversion trench close to the first diversion structure;

the first flow guiding structure is configured to guide condensate flowing into the flow guiding groove to enter the inner plate surface side space of the flow guiding piece through the flow guiding through hole;

the flow guiding piece comprises a main plate, a first slope wall and a second slope wall;

the main board is of an elongated plate-shaped structure; the first slope wall is connected to one side of the main board in the width direction and obliquely intersects with the main board; the second slope wall is connected to the wide outward side edge of the first slope wall and forms a diversion trench body limiting the diversion trench together with the first slope wall;

the flow guide through hole is formed in the first slope wall;

the first flow guiding structure comprises inclined flow guiding ribs; the inclined guide rib is connected in the guide groove and obliquely intersects with the first slope wall to form an acute angle;

the inclined guide rib is provided with a guide surface, and the guide surface is smoothly connected with the part of the inner surface of the first slope wall, which is positioned below the guide through hole;

the first diversion structure further comprises water blocking ribs which are formed by extending outwards along the width of the main plate from the position, corresponding to the diversion through holes, of the intersection line of the main plate and the first slope wall; the outer end of the water retaining rib extends to be connected with the inclined flow guide rib and is positioned at the position of the notch of the flow guide groove corresponding to the flow guide through hole.

2. A baffle according to claim 1, wherein:

the inner plate surface side of the flow guiding piece is provided with a second flow guiding structure which is positioned below the flow guiding through hole and used for guiding condensed water flowing in from the flow guiding through hole.

3. A baffle according to claim 2, wherein:

the second diversion structure comprises a water receiving platform which is positioned below the diversion through hole and is used for receiving condensed water flowing down from the diversion through hole, and an overflow platform which is used for receiving condensed water flowing down from the water receiving platform and is provided with an overflow port;

and in the direction from the outer plate surface to the inner plate surface, the overflow platform is positioned outside the horizontal receiving platform, so that the two overflow platforms form a two-stage step shape.

4. A baffle according to claim 3, wherein:

a group of adjacent edges of the horizontal receiving platform are respectively connected with the main board and the first slope wall, and the horizontal receiving platform is perpendicular to the extending direction of the diversion trench;

the other group of adjacent edges of the horizontal receiving platform extend downwards to form a drainage surface, the drainage surface extends outwards to form two opposite guide walls, and the lower ends of the two guide walls are respectively connected with the two wide ends of the overflow platform; the upper ends of the two guide walls extend upwards to form a horizontal receiving table, so that a flow blocking part for laterally blocking the horizontal receiving table is formed.

5. An air conditioner water guide structure which characterized in that:

the air conditioner water guide structure comprises a water receiving disc and a guide piece according to any one of claims 1-4; the water receiving disc is provided with a water collecting groove;

the water collecting device comprises a water collecting disc, a water guide piece, a water guide through hole and a water guide piece.

6. An air conditioner, characterized in that:

the air conditioner comprises a heat exchanger, a water pan and the flow guide piece of any one of claims 1-4; the water receiving disc is provided with a water collecting groove;

the air guide piece is connected to the heat exchanger in a state that the inner plate surface of the air guide piece is opposite to the heat exchanger, and the air guide piece is positioned at an air duct of the air conditioner;

the water collecting device comprises a water collecting disc, a water guide piece, a water guide through hole and a water guide piece.