CN215446796U - Negative oxygen ion air outlet structure - Google Patents

Abstract

The utility model discloses a negative oxygen ion air outlet structure, which comprises an inner frame, wherein a first flanging structure which is turned outwards is formed on the outer end surface of the inner frame, and the inner frame is fixedly connected with a decorative plate at a ceiling air outlet through the first flanging structure in a clamping manner; the inner end face of the inner frame is connected with an air outlet hose of the air conditioner; the negative oxygen ion grid is embedded in the inner frame. The negative oxygen ion diffusion mechanism improves the diffusion effect of negative oxygen ions by utilizing air flow blown out from an air conditioner air port, and simultaneously utilizes heat generated during heating of the air conditioner to further excite the negative oxygen ion material to accelerate the release of the negative oxygen ions. This air conditioner tripe panel, negative oxygen ion grid be convenient for the installation dismantle, when negative oxygen ion grid leads to negative oxygen ion release efficiency to obviously reduce owing to long-term the use, can dismantle tripe panel, change new negative oxygen ion grid, build permanent indoor negative oxygen ion environment, continuously improve air quality, beneficial health.

Description

Negative oxygen ion air outlet structure

Technical Field

The utility model relates to the technical field of assembled decorative materials, in particular to a negative oxygen ion air outlet structure.

Background

The central air conditioning system consists of a cold and heat source system and an air conditioning system. The air conditioner is characterized in that a main machine controls different rooms in a mode of passing air through an air duct or connecting a cold-hot water pipe with a plurality of tail ends so as to achieve the purpose of indoor air conditioning. The refrigerating system provides required cold energy for the air conditioning system to offset the cold load of the indoor environment; the heating system provides heat to the air conditioning system to offset the heat load of the indoor environment.

The air of central air conditioning passes through the air outlet and discharges, and air outlet department can set up the air outlet subassembly usually, in order to improve holistic aesthetic property on the one hand, and on the other hand can guide wind for reach better refrigeration heating effect. The outlet assembly typically includes an inner frame, which is typically mounted between the air conditioning outlet hose and a louvered panel, and a louvered panel. However, the air outlet assembly of the air conditioner in the prior art does not have the function of releasing negative oxygen ions, so that the air outlet assembly cannot provide negative oxygen ions indoors.

SUMMERY OF THE UTILITY MODEL

The utility model provides a negative oxygen ion air outlet structure.

The utility model provides the following scheme:

an oxygen anion outlet structure, comprising:

the outer end face of the inner frame forms a first flanging structure which is turned outwards, and the inner frame is fixedly connected with a decorative plate at a suspended ceiling air outlet in a clamping mode through the first flanging structure; the inner end face of the inner frame is connected with an air outlet hose of the air conditioner;

the negative oxygen ion grid is embedded in the inner frame;

the louver panel is fixedly connected with the inner frame in a clamping manner; the louver panel comprises a frame and a plurality of louvers, a third flanging structure which is turned outwards is formed on the outer end face of the frame, and a bent part is formed on the outer edge of the third flanging structure; the inner side face of the third flanging structure is used for achieving abutting joint with the outer surface of the first flanging structure, and the bent portion is used for achieving wrapping of the end face of the first flanging structure.

Preferably, the inner frame comprises four first side plates, and the four first side plates are connected end to enable the inner frame to form a cavity structure with two open ends.

Preferably, the frame comprises four second side plates, and the four second side plates are connected end to form a cavity structure with two open ends; the multiple louvers are arranged inside the frame in a spaced manner, and an airflow channel is formed between two adjacent louvers.

Preferably, at least one groove extending along the respective length direction is formed on at least two opposite first side plates respectively, and at least one protrusion extending along the respective length direction is formed on at least two opposite second side plates respectively; the inner frame and the frame are fixedly clamped and connected through the groove and the protrusion.

Preferably, a second flanging structure which is turned inwards is formed on the inner end face of the inner frame, and the second flanging structure is used for limiting the negative oxygen ion grids positioned in the second flanging structure.

Preferably, the grid comprises a plurality of transverse partitions separated from each other; a plurality of vertical partition plates which are separated from each other are connected between every two adjacent transverse partition plates; the transverse partition plate and the vertical partition plate are both partition plates capable of releasing negative oxygen ions.

Preferably, a plurality of convex outer bracket parts are formed on the outer side surfaces of the transverse partition plate and the vertical partition plate which are positioned at the outermost ring; the outer support parts are used for separating the transverse partition plate and the vertical partition plate which are positioned at the outermost ring from the inner frame.

Preferably, a plurality of outer bracket parts included by the transverse clapboard positioned at the outermost ring are arranged in one-to-one correspondence with a plurality of vertical clapboards connected with the outer bracket parts; the vertical partition plate positioned at the outermost ring comprises a plurality of outer bracket parts and a plurality of transverse partition plates connected with the outer bracket parts in one-to-one correspondence.

Preferably, the molding material of the negative oxygen ion grid is gypsum.

Preferably, the inner frame and the negative oxygen ion grid are both manufactured by adopting an integral forming process.

According to the specific embodiment provided by the utility model, the utility model discloses the following technical effects:

according to the utility model, the negative oxygen ion air outlet structure can be realized, and in an implementation mode, the negative oxygen ion air outlet structure can comprise an inner frame, wherein the outer end surface of the inner frame forms a first flanging structure which is turned outwards, and the inner frame is fixedly connected with a decorative plate at the air outlet of the suspended ceiling in a clamping manner through the first flanging structure; the inner end face of the inner frame is connected with an air outlet hose of the air conditioner; the negative oxygen ion grid is embedded in the inner frame; the louver panel is fixedly connected with the inner frame in a clamping manner; the louver panel comprises a frame and a plurality of louvers, a third flanging structure which is turned outwards is formed on the outer end face of the frame, and a bent part is formed on the outer edge of the third flanging structure; the inner side face of the third flanging structure is used for achieving abutting joint with the outer surface of the first flanging structure, and the bent portion is used for achieving wrapping of the end face of the first flanging structure. The structure utilizes the airflow blown out from the air conditioner air port to improve the diffusion effect of negative oxygen ions, and simultaneously utilizes the heat generated during heating of the air conditioner to further excite the negative oxygen ion material to accelerate the release of the negative oxygen ions. This air conditioner tripe panel, negative oxygen ion grid be convenient for the installation dismantle, when negative oxygen ion grid leads to negative oxygen ion release efficiency to obviously reduce owing to long-term the use, can dismantle tripe panel, change new negative oxygen ion grid, build permanent indoor negative oxygen ion environment, continuously improve air quality, beneficial health.

Of course, it is not necessary for any product in which the utility model is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a negative oxygen ion outlet structure according to an embodiment of the present invention;

FIG. 2 is an enlarged partial schematic view of FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of an inner frame provided in an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a negative oxygen ion grid according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a louver panel provided by the embodiment of the utility model.

In the figure: the air outlet structure comprises an inner frame 1, a first side plate 11, a groove 111, a first flanging structure 12, a second flanging structure 13, a negative oxygen ion grid 2, a transverse partition plate 21, a vertical partition plate 22, an outer support part 23, a louver panel 3, a second side plate 31, a protrusion 311, a third flanging structure 32, a bending part 33, a louver blade 34, a decorative plate 4 and an air outlet hose 5.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments that can be derived by one of ordinary skill in the art from the embodiments given herein are intended to be within the scope of the present invention.

Examples

Referring to fig. 1, fig. 2, fig. 3, fig. 4, and fig. 5, for a negative oxygen ion outlet structure according to an embodiment of the present invention, as shown in fig. 1, fig. 2, fig. 3, fig. 4, and fig. 5, the negative oxygen ion outlet structure may include:

the outer end face of the inner frame 1 forms a first flanging structure 12 which is turned outwards, and the inner frame 1 is fixedly connected with the decorative plate 4 at the air outlet of the suspended ceiling in a clamping manner through the first flanging structure 12; the inner end face of the inner frame 1 is connected with an air outlet hose 5 of an air conditioner; specifically, the inner frame 1 comprises four first side plates 11, and the four first side plates 11 are connected end to enable the inner frame 1 to form a cavity structure with two open ends. The inner frame is enclosed by four first side plates 11 to form a cavity structure with a rectangular section, and the inner side of the cavity structure is used for accommodating the negative oxygen ion grids and a part of shutter panels. In practical application, the inner frame can be made of metal or nonmetal materials, and the inner frame is made by adopting an integral forming process for manufacturing convenience.

In order to prevent the negative oxygen ion grids from being separated from the inner end face of the inner frame, a second flanging structure 13 which is turned inwards is formed on the inner end face of the inner frame 1, and the second flanging structure 13 is used for limiting the negative oxygen ion grids 2 positioned in the second flanging structure.

The negative oxygen ion grid 2 is embedded in the inner frame 1; in particular, the grid 2 comprises a plurality of transverse partitions 21 separated from each other; a plurality of vertical partition plates 22 which are separated from each other are connected between every two adjacent transverse partition plates 21; the transverse partition plates 21 and the vertical partition plates 22 are both partition plates capable of releasing negative oxygen ions, and the grille is used for being installed in an inner frame formed at an air outlet of the central air conditioner, so that the negative oxygen ions released by the grille can be diffused into a room along with air flow when the air conditioner is operated. In actual manufacturing, the grating is of an integrated structure manufactured by adopting an integrated forming process. The forming material of the negative oxygen ion grid is gypsum doped with glass fiber net. The gypsum is used as the main component, and the glass fiber net is added to improve the toughness and the integrity of the grid and prevent the grid from being cracked. The negative oxygen ion material is doped in the molding material to release negative oxygen ions, and the negative oxygen ion material can be prepared by crushing, ball milling, fine milling, adding materials and mixed milling of tourmaline, zirconia, silver oxide, titanium dioxide, graphene, rare earth and other materials when being prepared. The comprehensive material with multiple effects is formed by utilizing the piezoelectric property and the pyroelectricity of tourmaline, the far infrared effect of zirconium oxide, the adhesion effect of pumice powder and the effect of forming a three-dimensional microporous structure, the effect of improving the ion oscillation effect in tourmaline powder by rare earth materials, the carbon dioxide absorption and sterilization effects of silver oxide, the effect of efficiently degrading formaldehyde in air by photocatalysis of titanium dioxide and the effect of improving the electric discharge effect by graphene, so that the self discharge performance of tourmaline components is fully induced, and more negative ions are ionized and released.

A plurality of convex outer bracket parts 23 are formed on the outer side surfaces of the transverse partition plate 21 and the vertical partition plate 22 which are positioned at the outermost ring; the plurality of outer bracket portions 23 serve to separate the horizontal and vertical partitions 21 and 22 located at the outermost circumference from the inner frame 1. The transverse partition plate positioned at the outermost ring comprises a plurality of outer bracket parts which are arranged in a one-to-one correspondence manner with a plurality of vertical partition plates connected with the outer bracket parts; the vertical partition plate positioned at the outermost ring comprises a plurality of outer bracket parts and a plurality of transverse partition plates connected with the outer bracket parts in one-to-one correspondence. The grid can be the integral type structure, wherein including horizontal, vertical check, its outermost circle is equipped with grid outrigger portion, makes horizontal, vertical check and the inside casing of grid outermost circle keep apart, ensures that the two-sided of horizontal, vertical check of outermost circle can both fully contact the air conditioner air current, and then promotes negative oxygen ion release effect.

The louver panel 3 is fixedly connected with the inner frame 1 in a clamping manner; the louver panel 3 comprises a frame and a plurality of louvers 34, wherein a third flanging structure 32 which is turned outwards is formed on the outer end face of the frame, and a bent part 33 is formed on the outer edge of the third flanging structure 32; the inner side surface of the third flanging structure 32 is used for abutting against the outer surface of the first flanging structure 12, and the bent portion 33 is used for wrapping the end surface of the first flanging structure 12. In practical application, the louver panel can be made of metal or nonmetal materials, and the inner frame main body is made by adopting an integral forming process for manufacturing convenience. The frame can be made of plastic and the like through an integral molding process such as injection molding.

Specifically, the frame comprises four second side plates 31, and the four second side plates 31 are connected end to form a cavity structure with two open ends; the louvers 34 are disposed inside the frame so as to be separated from each other, and an airflow path is formed between two adjacent louvers. In order to adjust the direction of the louver blades and change the air outlet direction, the louver blades are rotatably arranged on the inner side of the frame and can be automatically closed based on the angle orientation of the louver blades. This shutter plate can link to each other through parts such as connecting axle and the inboard of inside casing, and the shutter plate can rotate around the connecting axle, rotates corresponding angle after, can brake, and the mode of braking can adopt shutter plate and axle interference fit's mode, but relative rotation under the exogenic action between the two, can be braked after the exogenic action disappears. In another embodiment, the blind further comprises a closing device operatively associated with the louver and directionally braking the louver based on the angle of the louver. The closure device may employ a rotational positioning mechanism having a ratchet member or the like.

The outer end face of the inner frame is connected with the louver board, the connection mode can adopt any mode capable of realizing connection in the prior art, and in order to facilitate connection and disassembly, under one realization mode, at least one groove 111 extending along the respective length direction is respectively formed on at least two opposite first side boards 11, and at least one protrusion 311 extending along the respective length direction is respectively formed on at least two opposite second side boards 31; the inner frame 1 and the frame are fixedly clamped and connected through the groove 111 and the protrusion 311. The two side plates which are opposite up and down of the frame can be provided with bulges along the respective length direction, and one bulge or a plurality of bulges in the same direction can be arranged on each side plate. The bulge can be fixedly connected with the groove formed in the inner frame in a clamping manner, the stability of the inner frame after being connected with the shutter panel can be guaranteed by adopting the clamping and fixing connection manner, and the purpose of quick disassembly can be achieved. The frame and the inner frame are connected without fastening parts such as screws, so that the purpose of stable connection can be achieved, and the frame and the inner frame are favorable for being detached from each other.

The application provides a negative oxygen ion air outlet structure, the turn-ups that the inside casing outer end of air outlet department set up block furred ceiling wind gap department decorative board, and the inside casing bottom is held by components such as flitch, and the one end and the air conditioner air-out hose connection that the inside casing is close to the air conditioner. The inner frame is provided with a groove at the inner side of the upper side plate and the lower side plate, and the groove is used for being clamped with the bulge at the outer side of the side plate of the shutter panel. The end of the inner frame, which is close to the air conditioner, is provided with a limiting flange for limiting the negative oxygen ion grid and preventing the negative oxygen ion grid from separating from the inner frame.

The negative oxygen ion grid takes gypsum, glass fiber net and the like as main forming materials, wherein the negative oxygen ion material is doped, so that the negative oxygen ion grid can automatically release negative oxygen ions, improve the air quality and is beneficial to the health of human bodies. When the air conditioner operates, the negative oxygen ions are diffused indoors along with the airflow at the air outlet of the air conditioner, so that the diffusion efficiency of the negative oxygen ions is improved. If the air conditioner is in a heating mode, the negative oxygen ion material is heated to improve the release efficiency. The size of the grating is matched with that of the inner frame, and the grating can be arranged between the limiting flanging of the inner frame and the shutter panel. The grid formula structure as an organic whole wherein including horizontal, vertical check, its outermost circle is equipped with the grid outer support, makes horizontal, vertical check and the inside casing of grid outermost circle keep apart, ensures that the horizontal of outermost circle, the two-sided of vertical check can both fully contact the air conditioner air current, and then promotes negative oxygen ion release effect.

The blind panel is equipped with the turn-ups all around by decorative board one end, and the turn-ups outer edge is equipped with the kink, makes blind panel and decorative board wrap up the inside casing turn-ups completely jointly, ensures that any part of inside casing can not appear on the visible surface, when promoting decorative effect, ensures that the installation of blind panel is firm. The side plates of the louver panel are matched with the side plates of the inner frame in size and can be just sleeved in the inner frame, and the side plates of the louver panel are provided with bulges matched with the side plates of the inner frame and are clamped with the inner frame, so that the louver panel is further fixed and is prevented from falling out of the inner frame.

The structure utilizes the airflow blown out from the air conditioner air port to improve the diffusion effect of negative oxygen ions, and simultaneously utilizes the heat generated during heating of the air conditioner to further excite the negative oxygen ion material to accelerate the release of the negative oxygen ions. This air conditioner tripe panel, negative oxygen ion grid be convenient for the installation dismantle, when negative oxygen ion grid leads to negative oxygen ion release efficiency to obviously reduce owing to long-term the use, can dismantle tripe panel, change new negative oxygen ion grid, build permanent indoor negative oxygen ion environment, continuously improve air quality, beneficial health.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention shall fall within the protection scope of the present invention.

Claims (10)

1. The utility model provides a negative oxygen ion air outlet structure which characterized in that includes:

the outer end face of the inner frame forms a first flanging structure which is turned outwards, and the inner frame is fixedly connected with a decorative plate at a suspended ceiling air outlet in a clamping mode through the first flanging structure; the inner end face of the inner frame is connected with an air outlet hose of the air conditioner;

the negative oxygen ion grid is embedded in the inner frame;

the louver panel is fixedly connected with the inner frame in a clamping manner; the louver panel comprises a frame and a plurality of louver blades, a third flanging structure which is turned outwards is formed on the outer end face of the frame, and a bent part is formed on the outer edge of the third flanging structure; the inner side face of the third flanging structure is used for achieving abutting joint with the outer surface of the first flanging structure, and the bent portion is used for achieving wrapping of the end face of the first flanging structure.

2. The negative oxygen ion air outlet structure of claim 1, wherein the inner frame comprises four first side plates, and the four first side plates are connected end to form a cavity structure with two open ends.

3. The negative oxygen ion air outlet structure of claim 2, wherein the frame comprises four second side plates, and the four second side plates are connected end to form a cavity structure with two open ends; the multiple louvers are arranged inside the frame in a spaced manner, and an airflow channel is formed between two adjacent louvers.

4. The negative oxygen ion outlet structure of claim 3, wherein at least two opposing first side plates are respectively formed with at least one groove extending along a respective length direction, and at least two opposing second side plates are respectively formed with at least one protrusion extending along a respective length direction; the inner frame and the frame are fixedly clamped and connected through the groove and the protrusion.

5. The negative oxygen ion air outlet structure of claim 1, wherein the inner end surface of the inner frame is formed with a second flanging structure which is turned inwards, and the second flanging structure is used for limiting the negative oxygen ion grid positioned in the inner frame.

6. The negative oxygen ion air outlet structure of claim 1, wherein the grille comprises a plurality of transverse partitions separated from each other; a plurality of vertical partition plates which are separated from each other are connected between every two adjacent transverse partition plates; the transverse partition plate and the vertical partition plate are both partition plates capable of releasing negative oxygen ions.

7. The negative oxygen ion air outlet structure of claim 6, wherein a plurality of convex outer support portions are formed on the outer side surfaces of the transverse partition plate and the vertical partition plate which are positioned on the outermost ring; the outer support parts are used for separating the transverse partition plate and the vertical partition plate which are positioned at the outermost ring from the inner frame.

8. The negative oxygen ion air outlet structure of claim 7, wherein the transverse partition plate positioned at the outermost ring comprises a plurality of outer support portions which are arranged in one-to-one correspondence with the plurality of vertical partition plates connected with the outer support portions; the vertical partition plate positioned at the outermost ring comprises a plurality of outer bracket parts and a plurality of transverse partition plates connected with the outer bracket parts in one-to-one correspondence.

9. The negative oxygen ion air outlet structure of claim 6, wherein the forming material of the negative oxygen ion grid is gypsum.

10. The negative oxygen ion air outlet structure of claim 1, wherein the inner frame and the negative oxygen ion grille are manufactured by an integral forming process.

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