A door leaf door flower glass packaging structure for preventing fogging

Abstract

The utility model discloses a prevent the door leaf door flower glass packaging structure of fogging, include: door leaf board, door flower subassembly and glass board, the middle part of door leaf board is provided with the inlay frame, door flower subassembly sets up in inlay frame, the inboard and the outside of door flower subassembly all are provided with glass board, the both side edges of door flower subassembly and the both side edges of glass board with inlay frame all are provided with glass sealant seal layer between, through the setting glass sealant seal layer between door flower subassembly, glass board and inlay frame formed a close sealing barrier, this can effectively prevent the outside water vapor from entering the space between glass board and door flower subassembly, when outside water vapor cannot enter, just from the root reduced the possibility of glass fogging, keep glass always clear and transparent, guarantee the overall aesthetic degree of door and the light transmittance and sight line permeability through glass.

Description

Technical Field

[0001] This utility model belongs to the field of door panel structure technology, and specifically relates to a door panel glass encapsulation structure to prevent fogging. Background Technology

[0002] Early front door designs were relatively simple, primarily focused on functionality, and often featured a monotonous, flat design. While these doors provided basic security and protection, they lacked aesthetic appeal and decoration, failing to meet people's demands for personalized and aesthetically pleasing homes. Therefore, modern front doors utilize a combination of decorative patterns and glass to transform the traditional, monotonous appearance. These patterns can be customized to different design styles, such as Chinese-style floral, bird, fish, and insect motifs, or European-style scrollwork and geometric patterns. The interplay of these patterns with the transparent texture of the glass makes the front door a highlight of the home décor, elevating the overall taste and sophistication of the home.

[0003] The door decorations and glass structure on the entrance door are usually sandwiched between double-glazed windows. This prevents dust from accumulating on the complex door decoration surface, reduces the difficulty of cleaning, and ensures the sound insulation and heat insulation performance of the door through the double-glazed structure.

[0004] However, the existing door panel and glass combination structure has poor sealing performance. With temperature changes, external humid air can easily enter the double-layer glass structure, causing water vapor on the glass and even mold growth in severe cases. Therefore, this application provides a door panel glass encapsulation structure to prevent fogging, aiming to provide a door panel glass encapsulation structure with good sealing performance and to prevent fogging inside the glass interlayer. Utility Model Content

[0005] This utility model provides a door panel glass encapsulation structure to prevent fogging, aiming to solve the problems pointed out in the background art.

[0006] To solve the above-mentioned technical problems, the present invention adopts the following technical solution:

[0007] A door panel and door decoration glass encapsulation structure to prevent fogging includes: a door panel, a door decoration component, and a glass plate;

[0008] A frame is provided in the middle of the door panel, the door flower assembly is set in the frame, and glass plates are provided on both the inner and outer sides of the door flower assembly.

[0009] A glass sealant layer is provided between the two sides of the door flower assembly and the two sides of the glass panel and the inlay frame.

[0010] Furthermore, the door panel includes several splicing plates, which are welded together to form the door panel. The edge of the inlay frame surrounds several splicing plates, and adjacent splicing plates are welded together to form a first welding layer. A first sealing layer is provided on the surface of the first welding layer.

[0011] Furthermore, the door flower assembly includes an outer frame and a decorative element, wherein the decorative element is disposed inside the outer frame and welded to the outer frame.

[0012] Furthermore, the outer frame is welded to the inlay frame to form a plurality of second welding layers, the second welding layers covering the first welding layer, and adjacent second welding layers are spaced apart.

[0013] Furthermore, the first sealant layer is positioned to avoid the outer frame.

[0014] Furthermore, a second sealing layer is provided between the two side edges of the outer frame and the glass plate, and a third sealing layer is provided on the outer edge of the glass plate.

[0015] Furthermore, the first sealant layer is configured to cooperate with the edge of the glass plate, the second sealant layer, and the third sealant layer.

[0016] Compared with the prior art, the present invention has the following technical effects:

[0017] 1. The door panel and door flower glass sealing structure described in this utility model forms a tight sealing barrier between the door flower component, the glass panel and the inlay frame by setting a glass sealant layer. This can effectively prevent external moisture from entering the space between the glass panel and the door flower component. When external moisture cannot enter, the possibility of glass fogging is reduced from the root, keeping the glass clear and transparent at all times, ensuring the overall aesthetics of the door as well as the light transmittance and visual transparency through the glass. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the outer surface of a door panel glass encapsulation structure for preventing fogging, as described in this utility model.

[0019] Figure 2 This is a schematic diagram of the door panel structure of the door panel with a door leaf glass encapsulation structure for preventing fogging, as described in this utility model.

[0020] Figure 3 This is a schematic diagram of the door flower component structure of the door leaf and door flower glass encapsulation structure for preventing fogging, as described in this utility model.

[0021] Figure 4 This is a schematic diagram of the splicing plate welding joint of the door leaf and door flower glass encapsulation structure for preventing fogging, as described in this utility model.

[0022] Figure 5 This is a schematic diagram of the outer frame and the inlay frame of a door leaf and door flower glass encapsulation structure for preventing fogging, as described in this utility model.

[0023] Figure 6 This is a utility model Figure 1 A partial schematic diagram of the cross-sectional view at point AA.

[0024] In the picture:

[0025] 1. Door panel; 101. Inlay frame; 102. Splicing panel; 103. First welding layer; 104. First sealing layer;

[0026] 2. Door flower assembly; 201. Outer frame; 202. Decorative parts; 203. Second welding layer;

[0027] 3. Glass plate; 4. Second sealant layer; 5. Third sealant layer. Detailed Implementation

[0028] To make the objectives, technical solutions, and advantages of this utility model clearer, the technical solutions of this utility model will be clearly and completely described below with reference to specific embodiments of this application and the accompanying drawings.

[0029] like Figure 1-2 and Figure 6 As shown, a door panel glass encapsulation structure to prevent fogging includes: a door panel 1, a door panel assembly 2, and a glass panel 3;

[0030] A frame 101 is provided in the middle of the door panel 1, and the door flower assembly 2 is provided in the frame 101. Glass plates 3 are provided on both the inner and outer sides of the door flower assembly 2.

[0031] A glass sealant layer is provided between the two sides of the door flower component 2 and the two sides of the glass plate 3 and the inlay frame 101.

[0032] Traditional door panel glass sealing only involves filling the outer edge of the glass panel 3 with silicone sealant. When the temperature changes, there is a pressure difference between the air between the two glass panels 3 and the outside air. Outside air can easily enter the internal space of the glass panel 3 through the gaps in the door panel 1, bringing in moisture and causing water vapor to appear on the inner surface of the glass panel 3. In severe cases, mold may develop. Therefore, this application uses silicone sealant layers on both the inner and outer sides to form a tight sealing barrier between the door panel component 2, the glass panel 3, and the inlay frame 101. This effectively prevents outside moisture from entering the space between the glass panel and the door panel component. When outside moisture cannot enter, the possibility of glass fogging is reduced from the root, keeping the glass clear and transparent at all times, ensuring the overall aesthetics of the door and the light and visual transparency through the glass.

[0033] like Figure 2 and Figure 4 As shown, the door panel 1 includes several splicing plates 102, which are welded together to form the door panel 1. The edge of the inlay frame 101 surrounds several splicing plates 102, and adjacent splicing plates 102 are welded together to form a first welding layer 103. A first sealing layer 104 is provided on the surface of the first welding layer 103.

[0034] Traditional door panels are assembled by spot welding several splicing plates 102. In this application, the welding joints of the inlay frame 101 are fully welded to form a first welding layer 103, thereby preventing air from entering the glass interlayer inside the door panel. Since the splicing plates 102 are relatively thin, it is not possible to ensure that the thickness of the welding layer is completely consistent during the welding process, and local thinning is likely to occur. Therefore, a first sealant layer 104 is used to protect the first welding layer 103 and fill any possible minor breaks to prevent air from entering the glass interlayer. The first sealant layer 103 can also serve as a protective layer, isolating the welded parts from contact with the external environment and preventing damage such as oxidation and corrosion. Especially in humid or corrosive environments, the sealant layer can effectively protect the welded parts, extend the service life of the door panel, and maintain the structural integrity and performance stability of the door panel.

[0035] like Figure 3 As shown, the door flower component 2 includes an outer frame 201 and a decorative element 202. The decorative element 202 is disposed inside the outer frame 201 and is welded to the outer frame 201.

[0036] like Figure 5 As shown, the outer frame 201 is welded to the inlay frame 101 to form a plurality of second welding layers 203. The second welding layers 203 cover the first welding layer 103, and adjacent second welding layers 203 are spaced apart.

[0037] The second welding layer 203 covers the first welding layer 103, which is equivalent to secondary reinforcement at the critical welding points of the splicing plate 102. The first welding layer 103 itself has already connected several splicing plates 102 into an inlay frame 101, but there may still be weak points in some areas of stress concentration. The coverage of the second welding layer 203 can further enhance the strength of these parts, disperse stress, and prevent cracking or damage to the welded parts due to stress concentration during use, thereby improving the overall reliability of the door leaf. The adjacent second welding layers 203 are spaced apart to minimize the number of welding points while ensuring connection strength, thereby reducing the possibility of breakage on the intact surface of the splicing plate 102 during the welding process.

[0038] In one specific embodiment, the first sealant layer 104 is positioned to avoid the outer frame 201, facilitating welding and fixing of the outer frame 201 to the inlay frame 101.

[0039] like Figure 6 As shown, a second sealing layer 4 is provided between the two sides of the outer frame 201 and the glass plate 3, and a third sealing layer 5 is provided on the outer edge of the glass plate 3.

[0040] In one specific embodiment, the first sealing layer 104 is configured to cooperate with the edge of the glass plate 3, the second sealing layer 4, and the third sealing layer 5.

[0041] The second sealing layer 4 is disposed between the two sides of the outer frame 201 and the glass plate 3, and the third sealing layer 5 is disposed on the outer edge of the glass plate 3. Combined with the first sealing layer 104 and the edge of the glass plate, a multi-layer sealing structure is formed. This effectively prevents air from entering the interlayer space of the glass plate 3, thus effectively preventing water vapor from appearing on the interlayer surface of the glass plate 3. Figure 6 As shown in the figure, the glass plate 3 and the door flower component 2 are relatively close. The second sealant layer 4 is directly set at the adjacent position of the glass plate 3 and the outer frame 201. When the thickness of the decorative component 202 is large and the glass plate 3 and the outer frame 201 are far apart, the outer frame 201 and the glass plate 3 can be strengthened by setting an auxiliary plate. The second sealant layer 4 is located at both ends of the auxiliary plate.

[0042] The above description is only a preferred embodiment of the present utility model. It should be noted that for those skilled in the art, several modifications and improvements can be made without departing from the inventive concept of the present utility model, and these all fall within the protection scope of the present utility model.

Claims

1. A door panel / door glass encapsulation structure to prevent fogging, characterized in that, include: Door panel (1), door flower assembly (2), and glass panel (3); The door panel (1) is provided with an inlay frame (101) in the middle, and the door flower assembly (2) is provided in the inlay frame (101). The inner and outer sides of the door flower assembly (2) are provided with glass plates (3). A glass sealant layer is provided between the two sides of the door flower component (2) and the two sides of the glass plate (3) and the inlay frame (101); The door flower assembly (2) includes: an outer frame (201) and a decorative element (202), wherein the decorative element (202) is disposed inside the outer frame (201) and welded to the outer frame (201); A second sealing layer (4) is provided between the two sides of the outer frame (201) and the glass plate (3), and a third sealing layer (5) is provided on the outer edge of the glass plate (3).

2. The anti-fogging door panel glass encapsulation structure according to claim 1, characterized in that, The door panel (1) includes several splicing plates (102), which are welded together to form the door panel (1). The edge of the inlay frame (101) surrounds several splicing plates (102), and adjacent splicing plates (102) are welded together to form a first welding layer (103). The surface of the first welding layer (103) is provided with a first sealing layer (104).

3. The anti-fogging door panel glass encapsulation structure according to claim 2, characterized in that, The outer frame (201) is welded to the inlay frame (101) to form a plurality of second welding layers (203), the second welding layers (203) covering the first welding layer (103), and adjacent second welding layers (203) are spaced apart.

4. The anti-fogging glass encapsulation structure for door panels and door patterns according to claim 2, characterized in that, The first sealant layer (104) is positioned to avoid the outer frame (201).

5. The anti-fogging door panel glass encapsulation structure according to claim 4, characterized in that, The first sealing layer (104) is configured to cooperate with the edge of the glass plate (3), the second sealing layer (4) and the third sealing layer (5).

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