CN215637928U - Water baffle assembly and combined air conditioner with same - Google Patents

Abstract

The utility model relates to a water baffle assembly and a combined air conditioner with the same. The breakwater assembly includes: an outer frame enclosing an accommodation space having two end openings opposite to each other; a first water baffle group; a second splash plate set, the second splash plate set and the first splash plate set being disposed in the accommodation space and respectively adjacent to a corresponding one of the end openings; and a disinfecting member disposed between the first dam group and the second dam group; and sterilizing the first water baffle group and the second water baffle group. Through set up the disinfection component in the accommodation space of frame, can conveniently carry out disinfection and sterilization to the breakwater, prevent bacterial growing and produce the peculiar smell, reduce the washing frequency of breakwater.

Description

Water baffle assembly and combined air conditioner with same

Technical Field

The utility model relates to the technical field of air conditioners, in particular to a water baffle assembly and a combined air conditioner with the same.

Background

The combined air conditioner is an air treatment device assembled by a plurality of air treatment functional sections, has the functions of filtering, cooling, purifying and sterilizing air and the like, and is widely applied to occasions such as factory buildings, hospitals, markets and the like. A combined air conditioner is generally provided with an air intake section, a filtering section, a surface cooling section, a fan section, and the like. Wherein, the surface cooling section generally comprises a surface cooler and a water baffle. The surface air cooler is an important part of the combined air conditioner, and the working principle of the surface air cooler is that a heating medium (such as steam or hot water) or a cooling medium (such as R32) flows through a metal bent pipe so as to exchange heat with air flowing through the outer wall of the metal bent pipe, and the purpose of heating or cooling the air is achieved. When the combined air conditioner is in a refrigerating working condition, part of water vapor in the air is converted into condensed water when flowing across the surface of the surface cooler. Therefore, a water baffle is usually installed on the air outlet side of the surface air cooler, especially when the air outlet volume of the combined air conditioner is large. The water guard may effectively block the condensed water so that it can be discharged out of the cabinet along the water guard without being blown into other parts (e.g., a ventilation duct) of the combined air conditioner.

The prior art breakwater generally includes a fixed frame and a plurality of breakwater blades disposed within the fixed frame. In order to improve the efficiency of the water baffle for blocking the condensed water, the water baffle blade is usually configured to have a wave structure (for example, a water baffle device of an air conditioning unit disclosed in chinese utility model CN 205227737U). Therefore, when the water baffle works, the surface of the water baffle is in a wet state for a long time, and when the water baffle is not used, partial condensed water is inevitably remained, so that bacteria are easy to breed on the water baffle, and peculiar smell is generated. Bacteria and peculiar smell can be brought into a regulated room by an air supply system in the combined air conditioner, so that the use experience of a user is greatly reduced, and even diseases such as respiratory tract and the like can be induced to influence the health of the user.

In order to keep the water deflector clean, it is common practice to periodically clean the water deflector. When the water baffle is cleaned, the water baffle needs to be detached from the surface air cooler so as to be convenient for cleaning. However, the water baffle is generally made of stainless steel, aluminum alloy, galvanized sheet and other metal materials, so that the water baffle is heavy in weight and inconvenient to disassemble and assemble. In addition, the space in the combined air conditioner is limited, and the water baffle can be disassembled and assembled only by disassembling the machine, so that the difficulty of cleaning the water baffle is further increased.

Accordingly, there is a need in the art for a new solution to the above problems.

SUMMERY OF THE UTILITY MODEL

In order to solve the above-mentioned problem of inconvenient cleaning of the water baffle in the prior art, the present invention provides a water baffle assembly, comprising: an outer frame enclosing an accommodation space having two end openings opposite to each other; a first water baffle group; a second splash plate set, the second splash plate set and the first splash plate set being disposed in the accommodation space and respectively adjacent to a corresponding one of the end openings; and the disinfection component is arranged between the first water baffle group and the second water baffle group so as to disinfect the first water baffle group and the second water baffle group.

As can be appreciated by those skilled in the art, in the water guard plate assembly of the present invention, an outer frame, a first water guard plate group, a second water guard plate group and a sterilizing member are provided. The outer frame encloses an accommodation space having two open-ended portions opposite to each other. The first water baffle group and the second water baffle group are arranged in the accommodating space and are respectively close to the corresponding one of the end openings. The disinfection component is arranged between the first water baffle group and the second water baffle group to disinfect the first water baffle group and the second water baffle group. Through set up the disinfection component in the accommodation space of frame, can conveniently disinfect the breakwater, effectively kill the bacterium on breakwater surface, prevent bacterial growing and produce the peculiar smell, show the washing frequency that reduces the breakwater. Furthermore, the water baffle blades are arranged to be respectively close to the first water baffle group and the second water baffle group with the end openings, and the disinfection component is arranged between the first water baffle group and the second water baffle group, so that the disinfection component can disinfect the first water baffle group and the second water baffle group more uniformly, and a better disinfection effect is obtained.

In a preferred embodiment of the above-mentioned water baffle assembly, the disinfecting member includes one or more of an ultraviolet disinfecting lamp, a disinfecting liquid spraying mechanism, an ozone generator, or an ion generator. Different types of disinfection equipment are arranged, so that the product types can be enriched, and the individual requirements of users can be met.

In a preferred embodiment of the above water baffle assembly, the sterilizing member includes at least one ultraviolet sterilizing lamp, and each of the ultraviolet sterilizing lamps is configured to extend along a length direction of the outer frame. The ultraviolet ray disinfection lamp has the working principle that ultraviolet rays with proper wavelength destroy molecular mechanisms of DNA (deoxyribonucleic acid) or RNA (ribonucleic acid) in cells of a microorganism body to cause death of growing cells and/or death of regenerative cells, so that the disinfection and sterilization effects are achieved. The disinfection component is configured into an ultraviolet disinfection lamp, so that a better disinfection and sterilization effect can be obtained. Accordingly, the number of the ultraviolet ray sterilizing lamps is increased, and the sterilizing effect can be enhanced. In addition, each ultraviolet disinfection lamp is configured to extend along the length direction of the outer frame, so that the illumination uniformity of the ultraviolet disinfection lamps can be improved, and the disinfection and sterilization effects can be further enhanced.

In a preferred technical solution of the foregoing water baffle assembly, the first water baffle group includes a plurality of first water baffle blades distributed at intervals along a length direction of the outer frame, the second water baffle group includes a plurality of second water baffle blades, and each of the second water baffle blades is configured to be aligned with the corresponding first water baffle blade along a wind flow direction. Each second water baffle blade is configured to be aligned with the corresponding first water baffle blade along the wind flow direction, so that the air subjected to heat exchange of the surface cooler is doubly blocked by the first water baffle group and the second water baffle group in the wind flow direction, and the water baffle effect is enhanced. In addition, the plurality of first water baffle blades are arranged along the length direction of the outer frame at intervals, so that air can pass through the gaps of the water baffle blades, and liquefied condensed water can flow downwards along the surfaces of the water baffle blades under the action of the gravity of the condensed water, and the purpose of gas-water separation is realized.

In a preferred embodiment of the foregoing splash guard assembly, each of the second splash guard blades is configured to have the same structure as the first splash guard blade or to be symmetrical to the first splash guard blade. The second water baffle blade can make the structure of the water baffle component more symmetrical, thereby facilitating the simplification of the manufacturing process and being easy to manufacture. In addition, the water baffle assembly has the same or symmetrical structure in the forward direction and the reverse direction, and the orientation does not need to be considered when the water baffle assembly is installed, so that the water baffle assembly is easy to assemble.

In the preferred technical scheme of above-mentioned breakwater, first breakwater blade with each of second breakwater blade all includes first flap portion and second flap portion, first flap portion includes first long limit and first minor face, first long limit with first minor face meets in order to form first summit and first predetermined contained angle, second flap portion includes second long limit and second minor face, the second long limit with the second minor face meets in order to form second summit and second predetermined contained angle, and keeping away from on the second long limit the tip on second summit is fixed being close to on first long limit the position department on first summit makes the second long limit with first long limit forms third predetermined contained angle. Dispose into each of first breakwater blade and second breakwater blade to by interconnect and form the combination of the long limit and the minor face of predetermined contained angle for when disinfection mechanism carries out disinfection treatment, disinfection factor (for example ultraviolet ray, antiseptic solution etc.) can receive blockking of first breakwater blade and second breakwater blade, takes place the multiple reflection, makes the distribution of disinfection factor more even, and the disinfection effect is better. In addition, the condensate water can receive and come from many times on first breakwater blade and the second breakwater blade and block when the breakwater, has effectively promoted manger plate efficiency.

In a preferred technical solution of the above water deflector assembly, the first predetermined included angle, the second predetermined included angle, and the third predetermined included angle are the same, and each predetermined included angle ranges from 45 ° to 75 °. The first preset included angle, the second preset included angle and the third preset included angle are configured to be the same, so that the first short edge is parallel to the second long edge, the first long edge is parallel to the second short edge, and the first water baffle blade and the second water baffle blade are simple in structure and easy to manufacture. In addition, the range of each preset included angle is set to be 45-75 degrees, the water retaining effect can be ensured, meanwhile, the types of products are enriched, and the individual requirements of users are met.

In a preferred embodiment of the foregoing water deflector assembly, the second vertex of each first water deflector blade and the first vertex of the adjacent first water deflector blade are aligned with each other along the wind flow direction, and the second vertex of each second water deflector blade and the first vertex of the adjacent second water deflector blade are aligned with each other along the wind flow direction. Each of the first water baffle blade and the second water baffle blade is configured into a second peak of the blade and a first peak of the adjacent water baffle blade which are aligned with each other along the wind flow direction, so that the distance between the adjacent water baffle blades is moderate, the water baffle requirement can be met, the air can smoothly pass through the gap between the water baffle blades, and the air supply efficiency is ensured.

The utility model also provides a combined air conditioner which comprises the surface air cooler and the water baffle assembly, wherein the water baffle assembly is arranged on the air outlet side of the surface air cooler. By configuring any one of the water baffle assemblies mentioned above, the combined air conditioner can effectively kill bacteria on the surface of the water baffle plate and prevent the bacteria from breeding and generating peculiar smell. In addition, the disinfection component is integrated inside the water baffle component instead of being arranged independently, so that the internal space of the combined air conditioner can be effectively utilized, the design space is prevented from being wasted, the size of the combined air conditioner is reduced, the manufacturing cost can be reduced, and the assembly requirement of a smaller space can be met.

In a preferred embodiment of the above-mentioned combined air conditioner, the sterilizing unit includes at least one ultraviolet sterilizing lamp, and each of the ultraviolet sterilizing lamps is configured to extend in a length direction of the outer frame. Through the configuration, the combined air conditioner can obtain better disinfection and sterilization effects.

Drawings

Preferred embodiments of the present invention are described below with reference to the accompanying drawings, in which:

fig. 1 is a schematic structural view of an embodiment of a combined type air conditioner of the present invention;

FIG. 2 is a schematic structural view of an embodiment of the present breakwater assembly mounted on a surface cooler;

FIG. 3 is a schematic structural view of an embodiment of the water dam assembly of the present invention;

FIG. 4 is a first cross-sectional view of the embodiment of the splash plate assembly of the present invention taken along section line A-A of FIG. 3;

FIG. 5 is a schematic view of the assembled position of two adjacent first breakwater blades of the breakwater assembly of the present invention;

FIG. 6 is a second cross-sectional view of the embodiment of the splash plate assembly of the present invention taken along section line A-A of FIG. 3;

FIG. 7 is a third cross-sectional view of the embodiment of the splash plate assembly of the present invention taken along section line A-A of FIG. 3.

List of reference numerals:

1. a combined air conditioner; 10. a box body; 11. an air inlet; 12. a first access door; 13. a filter assembly; 14. a surface cooler; 141. an air inlet side; 142. an air outlet side; 143. an inlet pipe; 144. an outlet pipe; 145. a heat exchange pipe; 146. a surface cooler fixing plate; 146a, an upper intercooler guard plate; 146b, a surface cooler guard plate; 146c, a left surface cooler tube plate; 146d, a right surface cooler tube plate; 15. a water baffle assembly; 151. an outer frame; 151a, an upper outer frame wall; 151 b; a lower outer frame wall; 151c, a left outer frame wall; 151d, right outer frame wall; 1512. an accommodating space; 1513. the end part is open; 1513a, the front end is open; 1513b, the rear end is open; 152. a first water baffle group; 1521. a first breakwater blade; 5211. a first flap portion; 5211a, a first long side; 5211b, a first short side; 5212. a second flap portion; 5212a, a second long side; 5212b, a second short side; p₁A first vertex; p₂A second vertex; alpha is alpha₁A first preset included angle; alpha is alpha₂A second preset included angle; alpha is alpha₃A third predetermined included angle; alpha is alpha₄A fourth predetermined included angle; 153. a second water baffle group; 1531. a second water deflector vane; 154. a sterilizing member; 1541. an ultraviolet disinfection lamp; 16. a second access door; 17. a fan; 171. a motor; 172. an impeller; 18. and (7) air outlet.

Detailed Description

Preferred embodiments of the present invention are described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and are not intended to limit the scope of the present invention.

It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "upper", "lower", "left", "right", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, which are only for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; either directly or indirectly through intervening media, or through the communication between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In order to solve the technical problem of inconvenient cleaning of the water baffle in the prior art, the utility model provides a water baffle assembly 15, wherein the water baffle assembly 15 comprises: an outer frame 151, the outer frame 151 enclosing an accommodation space 1512 having two end openings 1513 opposite to each other; a first splash plate set 152; the second water baffle group 153, the second water baffle group 153 and the first water baffle group 152 are arranged in the accommodating space 1512 and are respectively close to corresponding ones of the end openings 1513; and a sterilizing member 154 disposed between the first and second baffle groups 152 and 153 to sterilize the first and second baffle groups 152 and 153.

The terms "upper", "lower", "left" and "right" as referred to herein, unless expressly stated to the contrary, are relative to the orientation shown in figure 2.

Fig. 1 is a schematic structural view of an embodiment of a combined type air conditioner of the present invention; FIG. 2 is a schematic structural view of an embodiment of the present breakwater assembly mounted on a surface cooler; FIG. 3 is a schematic structural view of an embodiment of the water dam assembly of the present invention; FIG. 4 is a first cross-sectional view of the embodiment of the splash plate assembly of the present invention taken along section line A-A of FIG. 3; FIG. 5 is a schematic view of the assembled position of two adjacent first breakwater blades of the breakwater assembly of the present invention; FIG. 6 is a second cross-sectional view of the embodiment of the splash plate assembly of the present invention taken along section line A-A of FIG. 3; FIG. 7 is a third cross-sectional view of the embodiment of the splash plate assembly of the present invention taken along section line A-A of FIG. 3.

As shown in fig. 1, in one or more embodiments, the combined air conditioner 1 of the present invention includes a cabinet 10. In one or more embodiments, the housing 10 has a predetermined length, and the housing 10 can have a square or rectangular cross-section perpendicular to its length (which extends left and right in a horizontal direction based on the orientation shown in FIG. 1). The predetermined length can be determined according to actual needs. The housing 10 may be divided into 4 functional segments, denoted a-D, in sequence along its length, according to functional division. Wherein, function section A is the air inlet section, and function section B is the filter segment, and function section C is the cold section of table, and function section D is the air-out section. Alternatively, other suitable functional sections, such as a sterilization section, a sound attenuation section, etc., may be provided on the combined air conditioner 1 to provide the combined air conditioner 1 with more functions.

As shown in fig. 1, an air inlet 11 is disposed at the air inlet section a. The intake vent 11 is configured to communicate with the outdoor to introduce air into the outdoor environment. In one or more embodiments, a first access door 12 is disposed on the air intake section a, so as to facilitate entering the box 10 from the first access door 12 for detection, maintenance, cleaning, and the like. In one or more embodiments, a return air section (not shown) for introducing indoor air is further disposed near the air intake section a, and a return air inlet (not shown) is disposed on the return air section to improve the energy efficiency ratio of the combined air conditioner 1, thereby saving energy. The filter section B is located downstream of the air intake section a, and a filter assembly 13 is provided in the filter section B. The filter assembly 13 may be a primary or intermediate filter to filter air entering the housing 10 from the air inlet 11. The surface cooling section C is positioned at the downstream of the filtering section B and comprises a surface cooler 14 and a water baffle plate assembly 15. In one or more embodiments, a second access door 16 is further provided at the surface cooling section C to facilitate access into the box 10 through the second access door 16, so as to perform operations of inspection, maintenance, cleaning, and the like on the surface cooler 14 and the water baffle assembly 15. The air outlet section D is positioned at the downstream of the surface cooling section C and is provided with a fan 17. The fan 17 includes a motor 171 and an impeller 172 connected to a drive shaft (not shown) of the motor 171. The motor 171 drives the impeller 172 to rotate, so that outdoor air is sucked into the cabinet 10 from the intake opening 11. And an air outlet 18 is also arranged at the tail end of the air outlet section D. The outlet vents 18 are arranged in air communication with the fan 17 and with the room via an air duct (not shown).

In one or more embodiments, as shown in FIG. 2, the surface cooler 14 is a serpentine coil surface cooler 14. Alternatively, the surface cooler 14 may be a riser, cross-tube, or other suitable surface cooler. Taking a serpentine coil type surface cooler as an example, the surface cooler 14 includes an inlet pipe 143, an outlet pipe 144, a plurality of heat exchange pipes 145 spaced apart from and parallel to each other, and a surface cooler fixing plate 146. The inlet pipe 143 and the outlet pipe 144 are respectively brought into communication with the heat exchange pipe 145 through a header or a distributor (not shown in the drawings). The surface cooler fixing plate 146 includes an upper surface cooler protective plate 146a, a lower surface cooler protective plate 146b, a left surface cooler tube plate 146c, and a right surface cooler tube plate 146d which are interconnected to define a substantially rectangular-shaped containable space such that all the heat exchange tubes 145 are confined within the containable space. Heating or cooling media (not shown) are provided to enter the heat exchange tubes 145 through the inlet tubes 143, exchange heat with air flowing through the outer wall of the surface air cooler 14 therein, and then exit the surface air cooler 14 through the outlet tubes 144. Fins (not shown) may be further provided on the heat exchange tube 145 to extend and coil continuously and spirally along the outer wall of the tube body of the heat exchange tube 145 to increase the heat exchange efficiency of the air with the surface air cooler 14.

When the combined air conditioner 1 is in a cooling condition, the refrigerant is configured to flow in the heat exchange pipe 145. The air filtered by the filtering assembly 13 flows through the surface of the surface air cooler 14 from the air inlet side 141 (as shown in fig. 1) of the surface air cooler 14 to complete heat exchange, and then flows out from the air outlet side 142 of the surface air cooler 14, so as to achieve the refrigeration purpose of the combined air conditioner 1. In the process, part of the steam in the air is converted into condensed water under the action of condensation. In order to prevent the condensed water from entering other functional sections of the combined air conditioner 1 to corrode functional components or enter the room along the air duct to affect the indoor temperature and humidity regulation, a water baffle assembly 15 is arranged on the air outlet side 142 of the surface air cooler 14. In one or more embodiments, a water pan (not shown) is disposed directly below the surface cooler 14 and the splash plate assembly 15. The drip pan is configured to collect and drain condensate that flows down from the surface cooler 14 and the splash plate assembly 15.

An embodiment of the splash plate assembly 15 of the present invention is described in detail below with reference to fig. 3-7.

As shown in fig. 3 and 4, in one or more embodiments, the dam assembly 15 includes an outer frame 151, a first dam group 152, a second dam group 153, and a disinfecting member 154. The outer frame 151 includes an upper outer frame wall 151a, a lower outer frame wall 151b, a left outer frame wall 151c, and a right outer frame wall 151d interconnected to define a substantially rectangular accommodation space 1512. The accommodation space 1512 has two end openings 1513, a front end opening 1513a and a rear end opening 1513b, respectively, which are opposite to each other. The upper frame wall 151a, the lower frame wall 151b, the left frame wall 151c, and the right frame wall 151d are detachably fixed by screws, bolts, rivets, or other suitable fixing methods. The outer frame 151 is made of metal materials such as stainless steel, aluminum alloy, galvanized sheet and the like to enhance strength; other suitable materials such as ABS, PP and the like can be adopted to reduce the manufacturing cost, and the weight can be reduced, so that the transportation and the assembly are convenient. As shown in FIG. 2, the upper outer frame wall 151a is configured to be secured to the upper cooler guard plate 146a of the surface cooler 14. Accordingly, the lower frame wall 151b is fixed to the lower surface cooler protective plate 146b of the surface cooler 14, the left frame wall 151c is fixed to the left surface cooler tube plate 146c of the surface cooler 14, and the right frame wall 151d is fixed to the right surface cooler tube plate 146d of the surface cooler 14. The fixing method can adopt screw fixation, bolt fixation, rivet fixation or other suitable fixing methods. In one or more embodiments, the housing 151 is sized to mate with the surface cooler 14 such that there is a small mounting gap between the housing 151 and the surface cooler 14. Through the configuration, the wind resistance generated by the air flowing through the mounting gap can be reduced, the air supply efficiency is improved, and the noise is reduced. The small installation gap can also effectively prevent the condensed water from flowing to other functional sections of the combined air conditioner 1 from the installation gap, and the water retaining efficiency is improved. In one or more embodiments, a plurality of drainage holes (not shown) are formed in the lower outer frame 151 b. The drain hole is disposed between the adjacent water baffle blades of the first water baffle group 152 and the second water baffle group 153, so that the condensed water blocked by the first water baffle group 152 and the second water baffle group 153 can conveniently flow through the drain hole to the water receiving tray located right below the water baffle assembly 15. The drain holes may be circular, semi-circular, square or other suitable shapes.

Fig. 4 is a first cross-sectional view of the embodiment of the splash plate assembly of the present invention taken along line a-a of fig. 3. As shown in fig. 4, in one or more embodiments, the first set of water baffles 152 is disposed in the accommodation 1512 proximate the front end opening 1513 a. The first breakwater group 152 includes a plurality of first breakwater blades 1521 uniformly spaced apart along a length direction of the outer frame 151 (i.e., a direction parallel to a horizontal extension direction of the upper or lower outer frame 151a or 151b when the outer frame 151 is horizontally disposed). It is understood that the number of the first breakwater blades 1521 may be set according to actual needs, rather than being fixed. In one or more embodiments, each first breakwater blade 1521 is configured to extend substantially in a vertical direction, so that condensed water may conveniently flow down along the surface of each first breakwater blade 1521 under its own weight. Alternatively, each first water baffle blade 1521 may also be disposed to be clamped at a certain angle with the vertical direction, so as to obtain richer products and meet the personalized needs of the users. The clamping angle may be set at 5 °, or other suitable angle greater or less than 5 °. Each first water baffle blade 1521 can be made of metal materials such as stainless steel, aluminum alloy and galvanized plates so as to enhance strength; other suitable materials such as ABS, PP and the like can be adopted to reduce the manufacturing cost, and the weight can be reduced, so that the transportation and the assembly are convenient.

As shown in fig. 5, in one or more embodiments, each first breakwater blade 1521 includes a first flap portion 5211 and a second flap portion5212. The first flap portion 5211 includes a first long side 5211a and a first short side 5211 b. Based on the orientation shown in fig. 5, the first long side 5211a is disposed so as to be sandwiched by a fourth predetermined angle α from the front end opening 1513a in the longitudinal direction of the outer frame 151₄Extending to the upper right. Fourth predetermined angle alpha₄In the range of 45 to 75. Preferably, the fourth predetermined angle α₄Is 60 degrees. A first short side 5211b is formed from the end of the first long side 5211a, and the first short side 5211b and the first long side 5211a form a first vertex P₁And a first predetermined angle alpha₁. Based on the orientation shown in fig. 5, the first short side 5211b is configured to be clamped at a first predetermined angle α from the end of the first long side 5211a along the first long side 5211a₁Extending to the lower right. The second flap portion 5212 includes a second long side 5212a and a second short side 5212 b. The second long side 5212a is connected to the second short side 5212b to form a second vertex P₂And a second predetermined angle alpha₂. Based on the orientation shown in fig. 5, the second short side 5212b is configured to be closer to the second vertex P than the second long side 5212a₂At a second predetermined angle alpha between the end edge and the second long side 5212a₂Extending to the lower left. The second long side 5212a is far from the second vertex P₂Is fixed to the first long side 5211a near the first vertex P₁At a position such that the second long side 5212a forms a third predetermined included angle α with the first long side 5211a₃. In one or more embodiments, the first predetermined included angle α₁A second predetermined angle alpha₂And a third predetermined angle alpha₃With the same angle. At this time, the first short side 5211b and the second long side 5212a are parallel to each other, and the first long side 5211a and the second short side 5212b are parallel to each other, so that each first breakwater blade 1521 has a stable structure, so as to simplify the manufacturing process and facilitate the manufacturing. First predetermined angle alpha₁A second predetermined angle alpha₂And a third predetermined angle alpha₃In the range of 45 to 75. Preferably, the first predetermined angle α₁A second predetermined angle alpha₂And a third predetermined angle alpha₃Are all configured at 60 deg.. In one or more embodiments, the second vertex P of each first breakwater blade 1521₂Adjacent to the first water baffleFirst vertex P of blade 1521₁Aligned with each other in the direction of the wind flow (direction indicated by arrows in fig. 5). With the above configuration, the sterilization factors (e.g., ultraviolet rays, sterilizing liquid, etc.) of the sterilizing member 154 can be blocked by the first water barrier blades 1521, and multiple reflections occur between the first and second flap portions 5211 and 5212, so that the distribution of the sterilization factors is more uniform and the sterilization effect is better. In addition, by placing the second vertex P of each first breakwater blade 1521₂The first vertex P of the adjacent first breakwater blade 1521₁The arrangement is aligned with one another along the direction of wind flow and also allows the gap between adjacent ones of the breakwater blades to be neither too large nor too small.

As shown in fig. 4, in one or more embodiments, the second set of water baffles 153 is disposed in the accommodation space 1512 proximate the rear end opening 1513 b. The second shutter group 153 includes a plurality of second shutter blades 1531 uniformly spaced apart along the length direction of the outer frame 151. It is understood that the number of the second baffle blades 1531 may be set according to actual needs, rather than being fixed. Preferably, the number of the second baffle blades 1531 is configured to be the same as the number of the first baffle blades 1521, so that the manufacturing process is simplified and the manufacturing is easy. Alternatively, the number of the second baffle blades 1531 may also be configured to be different from the number of the first baffle blades 1521 as long as the water blocking requirement can be satisfied. In one or more embodiments, each second baffle vane 1531 is configured to extend in a substantially vertical direction such that the condensate may conveniently flow down the surface of each second baffle vane 1531 under its own weight. Alternatively, each second shutter blade 1531 may also be disposed at an angle to the vertical to obtain a richer product, meeting the user's personalized needs. The clamping angle may be set at 5 °, or other suitable angle greater or less than 5 °. Each second baffle blade 1531 may be made of a metal material such as stainless steel, aluminum alloy, galvanized sheet, etc. to enhance strength; other suitable materials such as ABS, PP and the like can be adopted to reduce the manufacturing cost, and the weight can be reduced, so that the transportation and the assembly are convenient.

As shown in fig. 4, in one or moreIn various embodiments, each of the second baffle blades 1531 and the first baffle blades 1521 are configured to have a symmetrical structure with each other, that is, the second baffle blades 1531 and the first baffle blades 1521 are symmetrical with each other with respect to the length direction of the outer frame 151. Meanwhile, the second vertex P of each second barrier blade 1531₂And the first vertex P of the adjacent second baffle blade 1531₁Aligned with each other along the wind flow direction. In addition, each second deflector blade 1531 and the corresponding first deflector blade 1521 are aligned with each other in the wind flow direction, i.e., the first vertex P of each second deflector blade 1531₁Corresponding to the first vertex P of the first water baffle 1521₁Aligned with each other along the wind flow direction, and a second vertex P of each second baffle blade 1531₂Corresponding to the second vertex P of the first baffle 1521₂Aligned with each other along the wind flow direction. Through the above configuration, the water baffle assembly 15 of the present invention has the first water baffle group 152 and the second water baffle group 153 which are symmetrical to each other, so that the structure of the water baffle assembly 15 is stable, which is not only beneficial to simplifying the manufacturing process, but also more important, the disinfection factor of the disinfection component 154 can be more uniformly distributed between the first water baffle group 152 and the second water baffle group 153, and a better disinfection and sterilization effect is obtained. Further, the orientation (i.e., the front opening 1513a and the rear opening 1513b can be oriented toward the front) of the splash plate assembly 15 is not required to be considered when assembling the splash plate assembly 15, which effectively improves the assembling efficiency of the splash plate assembly 15.

FIG. 6 is a second cross-sectional view of the embodiment of the splash plate assembly of the present invention taken along section line A-A of FIG. 3. As shown in fig. 6, in this embodiment, each of the second dam blades 1531 of the second dam group 153 is configured to have the same structure as the first dam blade 1521 of the first dam group 152. Each of the first breakwater blades 1521 of the first breakwater group 152 is configured to have the same structure as the first breakwater blades 1521 shown in fig. 4 and 5, and thus, a detailed description thereof is omitted. Second vertex P of each first breakwater blade 1521₂The first vertex P of the adjacent first breakwater blade 1521₁Aligned with each other along the wind flow direction. Second vertex of each second shutter blade 1531P₂And the first vertex P of the adjacent second baffle blade 1531₁Aligned with each other along the wind flow direction. Meanwhile, each second deflector blade 1531 and the corresponding first deflector blade 1521 are aligned with each other in the wind flow direction, i.e., the second vertex P of each second deflector blade 1531₂Corresponding to the first vertex P of the first water baffle 1521₁Aligned with each other along the wind flow direction, and a first vertex P of each second baffle blade 1531₁Corresponding to the second vertex P of the first baffle 1521₂Aligned with each other along the wind flow direction.

FIG. 7 is a third cross-sectional view of the embodiment of the splash plate assembly of the present invention taken along section line A-A of FIG. 3. As shown in fig. 7, the first baffle group 152 is arranged in the opposite direction to the first baffle group 152 shown in fig. 6, and the second baffle group 153 is also arranged in the opposite direction to the second baffle group 153 shown in fig. 6. As shown in fig. 7, each of the first dam blades 1521 of the first dam group 152 includes a first flap portion 5211 and a second flap portion 5212. The first flap portion 5211 includes a first long side 5211a and a first short side 5211 b. Based on the orientation shown in fig. 7, the first long side 5211a is disposed so as to be sandwiched by a fourth predetermined angle α from the front end opening 1513a in the longitudinal direction of the outer frame 151₄Extending to the upper left. The first short side 5211b is disposed at a first predetermined angle α from the end of the first long side 5211a₁Extending to the lower left. The second flap portion 5212 includes a second long side 5212a and a second short side 5212 b. Based on the orientation shown in fig. 7, the second short side 5212b is arranged to be close to the second vertex P from the second long side 5212a₂At a second predetermined angle alpha between the end edge and the second long side 5212a₂Extending to the lower right. The second long side 5212a is far from the second vertex P₂Is fixed to the first long side 5211a near the first vertex P₁At a position such that the second long side 5212a forms a third predetermined included angle α with the first long side 5211a₃. First predetermined angle alpha₁A second predetermined angle alpha₂Third predetermined angle alpha₃And a fourth predetermined angle alpha₄In the range of 45 to 75. Preferably, the firstPredetermined angle alpha₁A second predetermined angle alpha₂Third predetermined angle alpha₃And a fourth predetermined angle alpha₄Are all configured at 60 deg.. Second vertex P of each first breakwater blade 1521₂The first vertex P of the adjacent first breakwater blade 1521₁Aligned with each other along the wind flow direction. Each second dam blade 1531 of the second dam group 153 is configured to have the same structure as the first dam blade 1521. Second vertex P of each second shutter blade 1531₂And the first vertex P of the adjacent second baffle blade 1531₁Aligned with each other along the wind flow direction. Meanwhile, each second deflector blade 1531 and the corresponding first deflector blade 1521 are aligned with each other in the wind flow direction, i.e., the second vertex P of each second deflector blade 1531₂Corresponding to the first vertex P of the first water baffle 1521₁Aligned with each other along the wind flow direction, and a first vertex P of each second baffle blade 1531₁Corresponding to the second vertex P of the first baffle 1521₂Aligned with each other along the wind flow direction.

As shown in fig. 3 and 4, in one or more embodiments, the disinfecting member 154 is configured as 1 ultraviolet disinfecting lamp 1541. The ultraviolet sterilizing lamp 1541 is disposed in the accommodating space 1512 and is positioned between the first water baffle group 152 and the second water baffle group 153. Preferably, the ultraviolet sterilizing lamp 1541 is configured to extend along the length direction of the outer frame 151, and two ends of the ultraviolet sterilizing lamp 1541 are respectively fixed at the central positions of the left outer frame 151c and the right outer frame 151d, so that the light of the ultraviolet sterilizing lamp 1541 is more uniform, and a better sterilizing effect is obtained. The ultraviolet lamp 1541 may be a hot cathode low-pressure mercury ultraviolet lamp, a cold cathode low-pressure mercury ultraviolet lamp, a high-pressure mercury ultraviolet lamp, or other suitable ultraviolet lamps. The number of the ultraviolet sterilizing lamps 1541 may be 2, 3 or other suitable number to enhance the sterilizing effect. Further, a plurality of uv sterilizing lamps 1541 may be connected in series so as to control the opening and closing of the uv sterilizing lamps 1541. Alternatively, a plurality of uv sterilizing lamps 1541 may be connected in parallel so as to control the on/off of each uv sterilizing lamp 1541 according to actual needs. Preferably, the plurality of ultraviolet sterilizing lamps 1541 are each configured to extend in a length direction of the outer frame 151 and to be evenly spaced in a direction parallel to the length direction of the left outer frame 151c (or the right outer frame 151d), so that irradiation of the ultraviolet sterilizing lamps 1541 is more uniform.

In one or more embodiments, disinfecting member 154 is configured as a disinfecting fluid spray mechanism (not shown). The disinfecting liquid spraying mechanism is disposed in the accommodating space 1512 and is positioned between the first water baffle group 152 and the second water baffle group 153. Preferably, the sterilizing liquid spraying mechanism is configured to extend along a length direction of the outer frame 151, and both ends are fixed to the top of the left outer frame 151c and the right outer frame 151d, respectively, so that the sterilizing liquid spraying mechanism can spray the sterilizing liquid more uniformly onto the first water baffle group 152 and the second water baffle group 153. The disinfectant spraying mechanism comprises but is not limited to a spraying rod, a liquid guide pipe, a liquid storage box, an infusion pump and the like. The disinfectant is stored in the liquid storage box, is pumped into the liquid guide pipe under the driving of the infusion pump and is sprayed out through the plurality of spraying ports arranged on the spraying rod, so that the process of spraying the disinfectant is completed. The disinfectant can be bleaching powder, alcohol, hydrogen peroxide or other suitable disinfectant. The concentration of the disinfectant can be selected according to actual conditions. After being sprayed to the water retaining blades of the first water retaining plate set 152 and the second water retaining plate set 153, the disinfectant can flow downwards along the surfaces of the water retaining blades under the action of its own gravity and is collected in a water receiving tray arranged below the water retaining plate assembly 15. In one or more embodiments, the disinfecting member 154 is configured as an ozone generator. Alternatively, the sterilizing member 154 may be configured as an ionizer, or other suitable sterilization means, as long as the first baffle group 152 and the second baffle group 153 can be sterilized. Further, the disinfecting member 154 may also be a combination of a plurality of ultraviolet disinfecting lamps 1541, a disinfecting liquid spraying mechanism, an ozone generator and an ion generator, so as to sterilize different types of bacteria, and obtain a better disinfecting and sterilizing effect.

So far, the technical solutions of the present invention have been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Without departing from the principle of the utility model, a person skilled in the art may combine technical features from different embodiments, and may make equivalent changes or substitutions for related technical features, and such changes or substitutions will fall within the scope of the utility model.

Claims (10)

1. A breakwater assembly, characterized in that it comprises:

an outer frame enclosing an accommodation space having two end openings opposite to each other;

a first water baffle group;

a second splash plate set, the second splash plate set and the first splash plate set being disposed in the accommodation space and respectively adjacent to a corresponding one of the end openings; and

a disinfecting member disposed between the first and second water baffle groups to disinfect the first and second water baffle groups.

2. The breakwater assembly of claim 1, wherein the disinfecting member comprises one or more of an ultraviolet disinfecting lamp, a disinfecting solution spraying mechanism, an ozone generator, or an ionizer.

3. The splash plate assembly of claim 2, wherein said sanitizing means includes at least one ultraviolet sanitizing light, each of said ultraviolet sanitizing lights being configured to extend along a length of said housing.

4. The dam assembly of claim 1, wherein the first dam assembly includes a plurality of first dam blades spaced apart along a length of the housing, the second dam assembly includes a plurality of second dam blades, and each of the second dam blades is configured to align with a corresponding one of the first dam blades along a direction of wind flow.

5. The breakwater assembly of claim 4, wherein each of the second breakwater blades is configured to have the same structure as the first breakwater blade or to be symmetrical with each other.

6. The breakwater assembly of claim 5, wherein each of the first breakwater blade and the second breakwater blade includes a first flap portion and a second flap portion, the first flap portion includes a first long side and a first short side, the first long side meets the first short side to form a first vertex and a first predetermined angle, the second flap portion includes a second long side and a second short side, the second long side meets the second short side to form a second vertex and a second predetermined angle, and an end of the second long side remote from the second vertex is fixed at a position of the first long side near the first vertex such that the second long side forms a third predetermined angle with the first long side.

7. The flashing assembly of claim 6 wherein the first, second and third predetermined angles are the same and each predetermined angle is in the range of 45-75 °.

8. The eliminator assembly of claim 6, wherein said second apex of each said first eliminator blade and said first apex of an adjacent said first eliminator blade are aligned with one another along said wind flow direction, and said second apex of each said second eliminator blade and said first apex of an adjacent said second eliminator blade are aligned with one another along said wind flow direction.

9. A combined air conditioner, characterized in that the combined air conditioner comprises a surface air cooler and a water baffle assembly according to any one of claims 1-8, wherein the water baffle assembly is arranged on the air outlet side of the surface air cooler.

10. The combined air conditioner according to claim 9, wherein the sterilizing mechanism includes at least one ultraviolet sterilizing lamp, and each of the ultraviolet sterilizing lamps is configured to extend in a length direction of the outer frame.

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