CN220451702U - Multi-layer hollow cavity touch control cabinet door applied to wine cabinet - Google Patents

Abstract

The utility model provides a multilayer hollow cavity touch control cabinet door applied to a wine cabinet, and particularly relates to the technical field of glass cabinet doors. The cabinet door comprises a cabinet door body and a controller, wherein the cabinet door body comprises a door frame, and outer glass is fixedly arranged at the front end of the door frame; a double-layer transparent screen is arranged in the door frame through a sealing strip; a first hollow cavity is formed between the outer glass and the front glass; a second hollow cavity is formed between the front glass and the rear glass; by filling 96% of inert gas into the two hollow cavities, the heat transfer coefficient is reduced, so that on one hand, the visible light transmittance of glass can be improved, and on the other hand, the refrigeration energy consumption of the wine cabinet compressor can be reduced; simultaneously this cabinet door has still add touch screen, makes things convenient for the customer to customize propaganda picture, broadcast advertisement or propaganda video according to the demand.

Description

Multi-layer hollow cavity touch control cabinet door applied to wine cabinet

Technical Field

The utility model relates to the technical field of glass cabinet doors, in particular to a multilayer hollow cavity touch control cabinet door applied to a wine cabinet.

Background

The existing refrigeration industry products have diversified door body structural forms, and glass doors are more and more popular with customers. In order to ensure visual transparency, most of the current markets are a cavity, so that the glass door is kept clear and transparent all the time in various application environments, but because all glass production enterprises do not find proper product structures and corresponding materials to manufacture and process, it is difficult to ensure that the glass door is in a severe environment condition, for example: when the environment is high up to 35 ℃ and the relative humidity is up to 80%, the door glass is still clear and transparent when the refrigerating temperature in the cabinet is 2 ℃; for example, and in the event that the night is light limited, the interior of the glass door remains transparent and visible. The existing refrigeration industry products, the door body hollow structure form is a cavity in the market at present, and the door body hollow structure form can be limited by light irradiation. Under the condition that the door body is not opened, the interior decoration of the box body is not visible, and poor visual experience is brought.

In order to solve the defects in the prior art, the utility model aims to provide a hollow glass structure of a transparent glass door applied to a wine cabinet, wherein inert gas is filled in a hollow layer, so that the heat transfer coefficient of a product is reduced, and the visible light transmittance of glass is improved.

Disclosure of Invention

In order to overcome the defects in the prior art, the problem that the existing door body hollow structure is mostly a cavity body, is easy to be limited by light irradiation, is easy to form condensation fog on a glass door, and has low visibility of box objects under the condition that the door body is not opened is solved. The utility model provides a multi-layer hollow cavity touch control cabinet door applied to a wine cabinet, which has the following specific technical scheme:

the multilayer hollow cavity touch control cabinet door comprises a cabinet door body, wherein the cabinet door body comprises a door frame, and outer glass is fixedly arranged at the front end of the door frame; a double-layer transparent screen is arranged in the door frame through a sealing strip.

Preferably, the touch screen is attached to one side of the outer layer glass, which is close to the door frame.

Preferably, the double-layer transparent screen comprises front glass and rear glass which are identical in size and are arranged in parallel, and four end surfaces of the front glass and the rear glass are fixedly connected through tooth-shaped soft strips; the front glass, the rear glass and the soft strip are sealed by sealant.

Still preferably, the door frame includes an upper molding at the top, a lower molding at the bottom, and extruded bars at the left and right sides; a controller is arranged in the upper decorative strip.

It is also preferable that a first hollow cavity is formed between the outer glass and the front glass; a second hollow cavity is formed between the front glass and the rear glass.

It is also preferred that the first hollow cavity and the second hollow cavity are both filled with 96% of inert gas.

Further preferably, a temperature display screen is arranged at one side of the front end of the controller, which is close to the outer glass.

Further preferably, the door frame and the sealing strip are both made of PVC materials.

Still further preferably, the upper molding, the lower molding and the extrusion molding are all made of injection molding.

Still further preferably, the temperature display screen and the touch screen are both electrically connected to the controller.

The beneficial effects of the utility model are as follows:

according to the utility model, the touch screen and the multilayer hollow cavity are arranged, and inert gas is filled in the hollow layer, so that the transparency and transparency of glass when light is sufficient are ensured, the touch screen can customize pictures, play advertisements or propaganda videos according to the demands of customers, meanwhile, the condition that the light is insufficient and the inside of a cabinet is not opened at night is met, the perspective view in the cabinet is ensured, the condition that the cabinet applying the glass is 2 ℃ in the cabinet and 35 ℃ outside the cabinet and the relative humidity is 85% is ensured, the condensation phenomenon is not generated on the outer surface of the glass, and the products in the cabinet are always clearly visible outside the cabinet; the heat transfer coefficient of the wine cabinet using the glass is reduced to 0.7W/m.k, so that the refrigeration energy consumption of the compressor of the wine cabinet can be effectively reduced.

Drawings

The accompanying drawings, which constitute a part of this specification, are included to provide a further understanding of the application and are not to be construed as unduly limiting the application.

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic cross-sectional view of the present utility model;

FIG. 3 is a schematic view of a double-layer transparent screen according to the present utility model;

in the figure, 1-outer layer glass; 2-a touch screen; 3-door frame; 31-finishing strips; 32-extruding a strip; 4-a temperature display screen; 5-a controller; 6-front glass; 7-rear glass; 8, sealing strips; 9-a first hollow cavity; 10-a second hollow cavity; 11-soft bars.

Detailed Description

The specific implementation mode of the multi-layer hollow cavity touch control cabinet door applied to the wine cabinet is further described with reference to the accompanying drawings and the embodiment.

As shown in fig. 1, a multi-layer hollow cavity touch control cabinet door applied to a wine cabinet comprises a cabinet door body, wherein the cabinet door body comprises a door frame 3, and an outer layer glass 1 is fixedly arranged at the front end of the door frame 3; the door frame 3 includes an upper decorative strip 31 at the top, a lower decorative strip at the bottom, and extrusion strips 32 at the left and right sides of the door frame 3, which are assembled together to form a frame structure of the door frame 3. The controller 5 is installed and fixed in the upper decorative strip 31; the double-layer transparent screen is extruded and fixed at the middle positions of the upper decorative strip, the lower decorative strip and the extrusion strip through the sealing strip 8. Preferably, the door frame and the sealing strip are made of PVC materials; the upper decorative strip, the lower decorative strip and the extrusion strip are all made of injection molding strips.

Specifically, the double-layer transparent screen comprises a front glass 6 and a rear glass 7 which are identical in size and are arranged in parallel, and four end surfaces of the front glass 6 and the rear glass 7 are fixedly connected through a tooth-shaped soft strip 11; specifically, two ends of the front glass 6 and the rear glass 7 are respectively placed in grooves at corresponding positions of the soft strip 11, then contact surfaces of the soft strip 11 and the front glass 6 and the rear glass 7 are sealed through sealant, and in order to further improve the sealing effect, secondary sealing is carried out on the outer surface of the soft strip 11 through sealant. Similarly, the junction between the outer glass 1 and the door frame 3 is sealed with a sealant. At this time, a first hollow cavity 9 is formed between the outer glass 1 and the front glass 6; a second hollow cavity 10 is formed between the front glass 6 and the rear glass 7 as shown in fig. 2-3.

Preferably, in order to prevent condensation of the glass surface due to the temperature difference between the inside and the outside of the cabinet, which affects the visibility in the cabinet, 96% of inert gas is also filled into the first hollow cavity 9 and the second hollow cavity 10.

Still preferably, the touch screen 2 is attached to the inner side of the outer layer glass 1, so that required advertisements, videos or customized patterns can be put in according to the requirements of customers, and the visual sense and experience of users are met. A temperature display screen 4 is arranged in the upper decorative strip 31 of the door frame 3 (the side close to the outer layer glass 1), so that a user can know and control the temperature in the wine cabinet conveniently. It should be noted that, the touch screen 2 and the temperature display screen 4 are controlled by the controller 5.

When in installation, firstly, the frame structure of the door frame 3 is assembled, and the controller 5 and the temperature display screen 4 are fixed in the upper decorative strip 31 of the door frame 3; then, attaching and fixing the touch screen 2 on the inner side of the outer glass; then, fixing the side of the outer glass 1 provided with the touch screen 2 with the front end of the door frame 3; then, the front glass 6 and the rear glass 7 are placed in parallel at the grooves corresponding to the tooth-shaped soft strips 11, and the joint and the outer surface of the soft strips 11 are sealed by sealant, so that the assembly of the double-layer transparent screen is completed; after sealing and curing, drilling holes and mixing inert gas into the first hollow cavity 9 and the second hollow cavity 10; then, sealing the drilled hole again, and waiting for sealing and curing; finally, the sealed double-layer transparent screen is extruded and fixed in the door frame 3 through the sealing strip 8, and then the assembly can be completed.

The utility model adopts a multi-layer glass multi-cavity structure, combines inert gas filled in the cavity, can effectively reduce the heat transfer coefficient of the product to 0.7W/m.k, ensures that the glass surface is not condensed under the condition that the cabinet with the cabinet door is 2 ℃ in the cabinet and 35 ℃ outside the cabinet and the relative humidity is 85%, and well improves the visibility of the glass. Meanwhile, the touch screen 2 is additionally arranged, so that the visual experience of a customer is improved.

In the present utility model, the terms such as "upper", "lower", "bottom", "top", and the like refer to the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, and are merely relational terms used for convenience in describing the structural relationships of the various components or elements of the present utility model, and are not meant to designate the components or elements of the present utility model in any way, and are not meant to limit the present utility model. Terms such as "connected," "coupled," and the like are to be construed broadly and mean either permanently connected or integrally connected or removably connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the terms in the present utility model can be determined according to circumstances by a person skilled in the relevant art or the art, and is not to be construed as limiting the present utility model.

It should be understood that the above description is not intended to limit the utility model to the particular embodiments disclosed, but to limit the utility model to the particular embodiments disclosed, and that the utility model is not limited to the particular embodiments disclosed, but is intended to cover modifications, adaptations, additions and alternatives falling within the spirit and scope of the utility model.

Claims (10)

1. The multi-layer hollow cavity touch control cabinet door comprises a cabinet door body, and is characterized in that the cabinet door body comprises a door frame, and outer glass is fixedly arranged at the front end of the door frame; and a double-layer transparent screen is arranged in the door frame through a sealing strip.

2. The multi-layer hollow cavity touch control cabinet door applied to a wine cabinet according to claim 1, wherein a touch control screen is attached to one side of the outer layer glass, which is close to a door frame.

3. The multi-layer hollow cavity touch cabinet door applied to the wine cabinet according to claim 1, wherein the double-layer transparent screen comprises front glass and rear glass which are identical in size and are arranged in parallel, and four end surfaces of the front glass and the rear glass are fixedly connected through tooth-shaped soft strips; the front glass, the rear glass and the soft strip are sealed by sealant.

4. The multi-layer hollow cavity touch control cabinet door applied to a wine cabinet according to claim 2, wherein the door frame comprises an upper decorative strip at the top, a lower decorative strip at the bottom and extrusion strips at the left side and the right side; and a controller is arranged in the upper decorative strip.

5. A multi-layer hollow cavity touch control cabinet door applied to a wine cabinet according to claim 3, wherein a first hollow cavity is formed between the outer layer glass and the front glass; and a second hollow cavity is formed between the front glass and the rear glass.

6. The multi-layer hollow cavity touch control cabinet door applied to a wine cabinet according to claim 5, wherein 96% of inert gas is filled in each of the first hollow cavity and the second hollow cavity.

7. The multi-layer hollow cavity touch control cabinet door applied to a wine cabinet according to claim 4, wherein a temperature display screen is arranged on one side, close to outer glass, of the front end of the controller.

8. The multi-layer hollow cavity touch control cabinet door applied to a wine cabinet according to claim 1, wherein the door frame and the sealing strip are made of PVC materials.

9. The multi-layer hollow cavity touch control cabinet door applied to a wine cabinet according to claim 4, wherein the upper decorative strip, the lower decorative strip and the extrusion strip are all made of injection molding strips.

10. The multi-layer hollow cavity touch control cabinet door applied to a wine cabinet according to claim 7, wherein the temperature display screen and the touch control screen are electrically connected with the controller.