Gasket for heat dissipation and anti-skid of glass container with magnetic property

By setting heat-insulating cotton and a perforated gasket at the bottom of the magnetic glass container, the problems of detachment, wear, discoloration, and vibration during heating of the magnetic glass container are solved, resulting in a longer service life and more uniform heat dissipation.

CN224387192UActive Publication Date: 2026-06-23BRIGHT TIME HUBEI IND LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BRIGHT TIME HUBEI IND LTD
Filing Date
2025-06-27
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing magnetic glass containers have issues with the magnetic sheet coming into contact with food during heating, which can affect food quality. The magnetic sheet is also prone to falling off or wearing out, discoloration, and overheating, which can cause the glass container to crack and generate electromagnetic vibrations, thus affecting its lifespan.

Method used

Design a gasket body that is fitted onto the bottom of a magnetically conductive glass container, with heat-insulating cotton placed between the gasket body and the magnetically conductive glass container, and through holes provided at the bottom and inside of the gasket body. It is made of high-temperature resistant material to enhance the heat insulation effect and buffer electromagnetic vibration, and the bottom of the gasket body has an annular thread to increase friction.

Benefits of technology

To prevent the magnetic layer from detaching or wearing off due to prolonged contact with the induction cooker, this method enhances heat insulation, prevents glass containers from sliding, extends service life, ensures even heat dissipation, promptly removes moisture, and buffers electromagnetic vibrations.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224387192U_ABST
    Figure CN224387192U_ABST
Patent Text Reader

Abstract

The utility model discloses a kind of gasket for magnetic glass container heat dissipation and antiskid, including the gasket body of being sleeved in the bottom of magnetic glass container, the gasket body is set to bowl type, and heat insulation cotton is arranged between gasket body and magnetic glass container.The utility model is simple in structure, the gasket body of being set, avoid the magnetic layer long-term direct contact induction cooker to cause to fall off or wear and tear, prevent the collision when magnetic glass container moves and the sliding when heating;The heat insulation cotton of being set, enhance the heat insulation effect, protect the discoloration of magnetic layer, further prevent the magnetic layer from falling off or wear and tear, slow down the aging of gasket body, prolong its service life, buffer electromagnetic induction oscillation.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of gasket technology, specifically to a gasket for heat dissipation and anti-slip of a magnetically conductive glass container. Background Technology

[0002] In existing technologies, magnetic glass containers often employ magnetic sheets placed inside or outside the glass container for direct heating on an induction cooker. However, this presents several problems: 1) The magnetic sheets inside the glass container come into direct contact with the food, affecting food quality, appetite, and health; 2) The magnetic sheets outside the glass container are prone to detachment or wear under mechanical friction and discoloration under high-temperature heating, affecting the container's appearance; 3) Direct contact with a high-temperature heat source can lead to localized overheating, preventing moisture from escaping and causing the container to slip and break, thus affecting its lifespan; 4) The large electromagnetic induction vibrations generated between the induction cooker and the magnetic glass container can easily cause damage to the glass container.

[0003] Therefore, it is necessary to design a heat dissipation and anti-slip pad for a magnetically conductive glass container. Summary of the Invention

[0004] To address the aforementioned technical problems, this utility model provides a heat dissipation and anti-slip pad for a magnetically conductive glass container.

[0005] The technical solution provided by this utility model is as follows:

[0006] A heat dissipation and anti-slip pad for a magnetically conductive glass container includes a pad body fitted onto the bottom of the magnetically conductive glass container. The pad body is shaped like a bowl, and heat insulation cotton is provided between the pad body and the magnetically conductive glass container.

[0007] Furthermore, the bottom of the gasket body is provided with multiple annular threads.

[0008] Furthermore, the bottom surface inside the gasket body is provided with a plurality of first through holes at equal intervals, and the sidewall inside the gasket body is provided with a plurality of second through holes at equal intervals.

[0009] Furthermore, both the first through hole and the second through hole are configured to be circular, elliptical, square, or triangular.

[0010] Furthermore, the plurality of first through holes are arranged in a star-shaped, cross-shaped, or ring-shaped pattern.

[0011] Furthermore, the gasket body is made of a high-temperature resistant material.

[0012] The beneficial effects of this utility model are:

[0013] 1) This utility model has a simple structure. The gasket body is designed to prevent the magnetic layer from being in direct contact with the induction cooker for a long time, which could lead to it falling off or being worn. It also prevents the magnetic glass container from colliding when moving and from sliding during heating.

[0014] 2) The insulation cotton added enhances the heat insulation effect, protects the magnetic layer from discoloration, further prevents the magnetic layer from falling off or wearing, slows down the aging of the gasket body, extends its service life, and buffers electromagnetic induction vibration.

[0015] 3) The multiple first and second through holes on the gasket body allow for uniform heat dissipation and facilitate the timely discharge of moisture, which has promising prospects for widespread application. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of the magnetic glass container, insulation cotton, and gasket body. Figure 1 ;

[0017] Figure 2 This is a schematic diagram of the overall structure of the magnetic glass container, insulation cotton, and gasket body. Figure 2 ;

[0018] Figure 3 This is a schematic diagram of the overall structure of the magnetic glass container, insulation cotton, and gasket body. Figure 3 ;

[0019] Figure 4 This is a schematic diagram of the structure in embodiment 3. Figure 1 ;

[0020] Figure 5 yes Figure 4 Side view;

[0021] Figure 6 This is a schematic diagram of the overall structure of the magnetic glass container, insulation cotton, and gasket body. Figure 4 ;

[0022] Figure 7 This is a schematic diagram of the bottom structure of the gasket body in Embodiment 4;

[0023] Figure 8 yes Figure 7 Side view.

[0024] In the diagram: 1. Gasket body; 2. First through hole; 3. Second through hole; 4. Annular thread; 5. Insulation cotton; 6. Magnetic glass container; 7. Magnetic layer. Detailed Implementation

[0025] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.

[0026] It should be noted that in the description of this utility model, the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicating the orientation or positional relationship are based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model. Example

[0027] like Figure 1 As shown, a heat dissipation and anti-slip pad for a magnetically conductive glass container includes a pad body 1 fitted onto the bottom of the magnetically conductive glass container 6. The pad body 1 is shaped like a bowl, and heat insulation cotton 5 is provided between the pad body 1 and the magnetically conductive glass container 6.

[0028] In this embodiment, the magnetically conductive glass container 6 is a glass container with a magnetically conductive layer 7 coated on the bottom to avoid direct contact with food, which could affect food quality, appetite, and health. The magnetically conductive layer 7 allows the glass container to be heated on an induction cooker. The pad body 1 is located at the bottom of the magnetically conductive glass container 6 and wraps the magnetically conductive layer 7 within it, preventing the magnetically conductive layer 7 from falling off or wearing out due to long-term direct contact with the induction cooker. It also prevents the magnetically conductive glass container 6 from colliding during movement and sliding during heating. The thickness of the magnetically conductive layer 7 is set to 0.01 mm. The thickness of the heat insulation cotton 5 is set to 2~10 mm, the temperature resistance is 650℃, and the density is 200±20 kg / m³. 3 This enhances the heat insulation effect, protects the magnetic layer 7 from discoloration, further prevents the magnetic layer 7 from falling off or wearing out, slows down the aging of the gasket body 1, extends its service life, and buffers electromagnetic induction vibration.

[0029] To further verify the effect of the insulation cotton 5 in protecting the magnetic conductive layer 7 from discoloration, the following comparative experiment was conducted:

[0030] 1) The magnetic glass container 6 without insulation cotton 5 was placed on an induction cooker for heating. The specific results are shown in Table 1:

[0031] Table 1 Heating results of magnetic glass containers without insulation cotton

[0032] Induction cooker power Weight of glass container + water Bottom filled with bubbles time Bubbles are rising in large quantities, indicating the water is about to boil. When the water first boils Boiling time of water Does it have insulation cotton? Does the applied magnetic coating change color? 800W 2.3kg 3 minutes 20 seconds 10 minutes 14 minutes 15 minutes 20 seconds none Slight yellowing 1000W 2.3kg 2 minutes and 10 seconds 7 minutes and 35 seconds 10 minutes and 15 seconds 10 minutes and 40 seconds none Slight yellowing 1200W 2.3kg 2 minutes 8 minutes 9 minutes and 40 seconds 10 minutes and 30 seconds none Turn yellow

[0033] 2) The magnetic glass container 6 with insulation cotton 5 was placed on an induction cooker for heating. The specific results are shown in Table 2:

[0034] Table 2 Heating results of magnetically conductive glass containers with insulation cotton

[0035] Induction cooker power Weight of glass container + water Bottom filled with bubbles time Bubbles are rising in large quantities, indicating the water is about to boil. When the water first boils Boiling time of water Does it have insulation cotton? Does the applied magnetic coating change color? 800W 2.3kg 2 minutes 7 minutes 9 minutes and 30 seconds 10 minutes have Not turned yellow 1000W 2.3kg 1 point 5 minutes and 35 seconds 6 minutes and 40 seconds 7 minutes have Not turned yellow 1200W 2.3kg 3 minutes 9 minutes and 20 seconds 10 minutes and 30 seconds 11 minutes and 10 seconds have Not turned yellow

[0036] As shown in Tables 1 and 2, the color of the magnetic layer 7 coated on the bottom of the glass container with added heat insulation cotton 5 remains unchanged. Heat insulation cotton 5 enhances the heat insulation effect and protects the magnetic layer 7 from discoloration. Example

[0037] like Figure 2 As shown, a heat dissipation and anti-slip pad for a magnetically conductive glass container includes a pad body 1 fitted onto the bottom of a magnetically conductive glass container 6. The pad body 1 is bowl-shaped, and heat insulation cotton 5 is provided between the pad body 1 and the magnetically conductive glass container 6. The bottom of the pad body 1 is provided with multiple annular threads 4.

[0038] Based on Example 1, this embodiment further increases friction by providing multiple annular threads 4 at the bottom of the gasket body 1, thereby preventing the magnetic glass device 6 and the gasket body 1 from sliding as a whole. Example

[0039] like Figures 3 to 5 As shown, a heat dissipation and anti-slip pad for a magnetically conductive glass container includes a pad body 1 fitted onto the bottom of a magnetically conductive glass container 6. The pad body 1 is bowl-shaped, and heat insulation cotton 5 is provided between the pad body 1 and the magnetically conductive glass container 6. The bottom surface inside the pad body 1 is provided with a plurality of first through holes 2 at equal intervals, and the side wall inside the pad body 1 is provided with a plurality of second through holes 3 at equal intervals.

[0040] In this embodiment, the magnetically conductive glass container 6 is a glass container with a magnetically conductive layer 7 coated on the bottom. The magnetically conductive layer 7 allows the glass container to be heated on an induction cooker. The gasket body 1 is set at the bottom of the magnetically conductive glass container 6 to wrap the magnetically conductive layer 7 within it, preventing the magnetically conductive layer 7 from directly contacting the induction cooker for a long time, which could lead to it falling off or wearing out. It also prevents the magnetically conductive glass container 6 from colliding when moving or sliding during heating. The thickness of the gasket body 1 is set to 0.5~3mm, and it is made of high-temperature resistant materials such as silicone or plastic to prevent the magnetically conductive glass container 6 from aging due to long-term heating, thus extending the service life of the gasket body 1. The thickness of the magnetically conductive layer 7 is set to 0.01mm. The heat insulation cotton 5 is set to enhance the heat insulation effect, protect the magnetically conductive layer 7 from discoloration, further prevent the magnetically conductive layer 7 from falling off or wearing out, slow down the aging of the gasket body 1, extend its service life, and buffer electromagnetic induction vibration. The first through hole 2 and the second through hole 3 are both circular. Multiple first through holes 2 are arranged in a cross shape and multiple second through holes 3 are arranged in a ring shape to dissipate heat evenly and facilitate the timely discharge of water vapor.

[0041] As a further technical solution of this embodiment, both the first through hole 2 and the second through hole 3 are set in the shape of a square or a triangle, so as to realize the diversity of the shape of the first through hole 2 and the second through hole 3 and meet the customer's choice.

[0042] As a further technical solution of this embodiment, the multiple first through holes 2 are arranged in a star-shaped or ring-shaped manner, which further facilitates the rapid evaporation and discharge of water vapor and improves the heat dissipation rate. Example

[0043] like Figures 6 to 8 As shown, a heat dissipation and anti-slip pad for a magnetically conductive glass container includes a pad body 1 fitted onto the bottom of a magnetically conductive glass container 6. The pad body 1 is bowl-shaped. Insulating cotton 5 is provided between the pad body 1 and the magnetically conductive glass container 6. Multiple first through holes 2 are evenly spaced on the bottom surface inside the pad body 1. Multiple second through holes 3 are evenly spaced on the sidewall inside the pad body 1. Multiple annular threads 4 are provided on the bottom of the pad body 1.

[0044] Based on embodiment 3, this embodiment further increases friction by providing multiple annular threads 4 at the bottom of the gasket body 1, thereby preventing the magnetic glass device 6 and the gasket body 1 from sliding as a whole.

[0045] The working principle of this utility model:

[0046] The insulating cotton is placed inside the gasket body and aligned with the magnetic layer of the magnetic glass container, so that the insulating cotton covers the magnetic layer; the gasket body is then placed on the bottom of the magnetic glass container; the magnetic glass container with the gasket body is placed on an induction cooker for heating; the insulating cotton enhances the heat insulation effect, protects the magnetic layer from discoloration, further prevents the magnetic layer from falling off or wearing, slows down the aging of the gasket body, extends its service life, and buffers electromagnetic induction vibrations; the multiple first and second through holes on the gasket body allow for uniform heat dissipation and facilitate the timely discharge of moisture, showing promising application potential.

[0047] The embodiments described above are merely preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model. Various modifications and improvements made to the technical solutions of the present utility model by those skilled in the art without departing from the principles and essence of the present utility model should fall within the protection scope defined by the claims of the present utility model.

Claims

1. A heat dissipation and anti-slip pad for a magnetically conductive glass container, comprising a pad body (1) fitted onto the bottom of a magnetically conductive glass container (6), characterized in that, The gasket body (1) is bowl-shaped, and heat insulation cotton (5) is provided between the gasket body (1) and the magnetic glass container (6).

2. The heat dissipation and anti-slip pad for a magnetically conductive glass container according to claim 1, characterized in that, The bottom of the gasket body (1) is provided with multiple annular threads (4).

3. A heat dissipation and anti-slip pad for a magnetically conductive glass container according to claim 1 or 2, characterized in that, The bottom surface of the gasket body (1) is provided with multiple first through holes (2) at equal intervals, and the side wall of the gasket body (1) is provided with multiple second through holes (3) at equal intervals.

4. The heat dissipation and anti-slip pad for a magnetically conductive glass container according to claim 3, characterized in that, The first through hole (2) and the second through hole (3) are both arranged in a circular, elliptical, square or triangular shape.

5. A heat dissipation and anti-slip pad for a magnetically conductive glass container according to claim 3, characterized in that, Multiple first through holes (2) are arranged in a star-shaped, cross-shaped, or ring-shaped pattern.

6. The heat dissipation and anti-slip pad for a magnetically conductive glass container according to claim 1, characterized in that, The gasket body (1) is made of high temperature resistant material.