KR20190045339A - Vacuum cup - Google Patents

Abstract

The vacuum cup comprises a vacuum cup body 10 including a tank 11 and an outer casing 12 arranged outside the tank 11 and an interheat insulation layer 100 formed between the tank 11 and the outer casing 12. [ A temperature indicator 20 installed on the outer casing 12 and a heat transfer structure 30 arranged inside the interheat insulation layer 100. The temperature indicator 20 is connected to the tank 20 via a heat transfer structure 30, (11) to transfer the temperature of the tank (11) to the temperature indicator (20). The vacuum cup effectively solves the problem that the outer casing of the conventional vacuum cup can not display the temperature inside the cup.

Description

Vacuum cup

The present invention relates to the field of vacuum cups, and more particularly to the type of vacuum cups.

Cups have become indispensable necessities in people's lives. Cups are generally used for drinking water, coffee, tea, and the like. Cups are generally made of plastic, glass, stainless steel and other materials. As the living standards of people improve, the demand for people's cups increases and they are interested in ease of use. The user would like to know directly whether the water in the cup is at a desired temperature.

The main object of the present invention is effectively solving the problem that the outer casing of the conventional vacuum cup can not display the temperature inside the cup.

To achieve the above object, the present invention provides a vacuum cup, which is a vacuum cup body, comprising: a vacuum cup body including a tank and an outer casing arranged outside the tank; A heat insulating layer formed between the tank and the outer casing; A temperature indicator installed on the outer casing; And a heat transfer structure arranged within the interheat layer, the temperature indicator contacting the tank via a heat transfer structure to transfer the temperature of the tank to a temperature indicator.

Further, an installation section may be provided on the outer wall of the outer casing, wherein a temperature indicator is installed.

The temperature indicator may also be constructed of a plurality of color changing materials and configured to display different colors based on different temperatures, and the vacuum cup body has a comparison label comprising an exemplary color of the color changing material.

Further, the mounting section may be a groove on the outer wall forming the outer casing, and the temperature indicator is installed inside the groove.

The first end of the heat transfer structure may also be in contact with the tank and the second end of the heat transfer structure may be in contact with the bottom of the groove and the heat transfer structure may include an upper inter- And then divided into the inter-insulation layer.

The heat transfer structure may also include a casing and a thermal section arranged within the casing.

In addition, the first and / or second ends of the heat transfer structure may be formed in a sawtooth shape such that the layer between the upper interheat interlayer and the lower insulating layer is in communication.

Further, the heat transfer structure includes an annular casing, and at the center of the annular casing, through holes for communicating the upper insulating sandwich with the lower insulating sandwich can be arranged, and the thermal section is arranged inside the annular casing.

Further, the temperature indicator may be a plurality of independent color change rings, the color change rings may be arranged side by side and installed on the outer casing, and each color change ring is made of a different color change material.

Further, the temperature indicator may be made of a plurality of independent color changing rings arranged and spaced apart in an outer casing, each color changing ring being made of a different color changing material, and the plurality of heat transferring structures One-to-one correspondence with ring.

In application of the technical solution of the present invention, water is poured into the vacuum cup. The temperature of the tank will quickly match the temperature of the water after contact. The heat transfer structure will convey the temperature of the tank to the temperature indicator and the indicator will indicate the temperature of the water in the cup. The present invention effectively solves the problem that the outer casing of the conventional vacuum cup can not display the temperature inside the cup.

The description of the accompanying drawings, which form a part hereof, is used to provide a further understanding of the invention. Embodiments of the present invention and the description thereof are used to illustrate the present invention and do not constitute an inadequate limitation of the present invention.
1 is a schematic structural view of a vacuum cup according to a first embodiment of the present invention.
Figure 2 is a partial enlarged schematic view of Figure 1;
The following reference numerals are included in the above figures.
10. Vacuum cup body; 11. Tanks; 12. outer casing; 121. Installation section; 20. Temperature indicator; 30. Heat transfer structure; 31. Casing; 32. Thermal section; 100. Insulation sandwich; 101. Upper insulation sandwich; 102. Lower insulation sandwich.

It should be noted that the embodiments of the present application and its features can be combined with one another without collision. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and embodiments.

It should be noted that the following detailed description is illustrative and is intended to provide further explanation of the present application. Unless otherwise stated, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

Relative spatial terms such as " on ", " above ", " on top surface ", and " top " refer to the spatial location of an apparatus or feature It is used to describe the relationship. It should be understood that the relative spatial terminology is intended to encompass different orientations of the device in use or operation as well as the orientations described in the drawings. For example, if the device in the drawing is reversed, the device described as "on another device or structure" or "on another device or structure" is located "under another device or structure" or "under another device or structure". Thus, an exemplary term " above " may include two orientations including " above " and " below ". The device can be positioned using other methods (located in 90 ° rotation or other orientations) and a description corresponding to the relative spatial terms used herein is possible.

Hereinafter, embodiments according to the present invention will be described in more detail with reference to the accompanying drawings. However, these embodiments have many different forms and should not be construed as limited to the embodiments described herein. It is to be understood that these embodiments are provided so that this thorough and complete disclosure of the present invention is possible, and will fully convey the concept of these embodiments to those skilled in the art. For the sake of clarity of the drawings, the thicknesses of the layers and regions have been increased and the same reference numerals are used to denote the same apparatus, and the description thereof will be omitted.

As shown in Fig. 1, the vacuum cup of embodiment 1 includes a vacuum cup body 10, a temperature indicator 20 and a heat transfer structure 30. As shown in Fig. The vacuum cup body 10 includes a tank 11 and an outer casing 12 arranged outside the tank 11. An interlayer insulating layer 100 is formed between the tank 11 and the outer casing 12 . The temperature indicator (20) is installed in the outer casing (12). The heat transfer structure 30 is installed inside the insulating sandwich 100 and the temperature indicator 20 contacts the tank 11 via the heat transfer structure 30 to change the temperature of the tank 11 to the temperature indicator 20. [ .

In application of the technical solution of Example 1, water is poured into a vacuum cup. The temperature of the tank 11 will quickly match the temperature of the water after contact. The heat transfer structure 30 will deliver the temperature of the tank 11 to the temperature indicator 20 and the indicator 20 will indicate the temperature of the water in the cup. The technical solution of this embodiment effectively solves the problem that the outer casing 12 of the conventional vacuum cup can not display the temperature inside the cup.

1 and 2, in the technical solution of Embodiment 1, the outer wall of the outer casing 12 is arranged to have an installation section 121, in which a temperature indicator 20 is installed. The outer wall of the outer casing 12 has an installation section 121 which on the one hand enables the easy installation of the temperature indicator 20 and on the other hand ensures the health and long life of the temperature indicator 20 .

In the technical solution of embodiment 1, as shown in Figures 1 and 2, the temperature indicator 20 is made of a plurality of color changing materials and is configured to display different colors based on different temperatures. The above-described structure is easy to arrange and process, and has a relatively low production cost. Specifically, the hue change of the temperature indicator 20 can be adjusted as needed, and the hue change temperature of the temperature indicator 20 can be changed using a different material composition, for example, at 45 or 70 degrees, Can be adjusted using different material compositions. The various color change materials ensure that the different colors displayed by the temperature indicator 20 of the vacuum cup of the embodiment correspond to different temperatures. In addition, the vacuum cup body 10 is provided with a comparison label containing an exemplary color of the color change material, so that the user can easily read the temperature of the liquid (hot water) in the vacuum cup.

In the technical solution of Embodiment 1, as shown in Figures 1 and 2, the mounting section 121 is a groove on the outer wall forming the outer casing 12, and the temperature indicator 20 is installed inside the groove. The groove structure is simple and easy to process. Specifically, since there is a gap between the bottom of the groove and the tank 11, the heat holding performance of the vacuum cup can be ensured. The grooves are set to arcuate transition, which provides a more comfortable experience and a beautiful appearance.

1 and 2, in the technical solution of embodiment 1, the first end of the heat transfer structure 30 is in contact with the tank 11 and the second end of the heat transfer structure 30 is in contact with the groove 11, And the heat transfer structure 30 divides the inter-layer insulation layer 100 into a communicated upper inter-insulation layer 101 and a lower inter-insulation layer 102. This structure ensures that the temperature of the tank 11 can be quickly transferred to the outer casing 12. [ For example, after pouring the hot water into the vacuum cup, the temperature of the hot water is immediately transferred to the tank 11, and then the temperature of the tank 11 is immediately transferred to the outer casing 12 through the heat transfer structure 30 , Which continues to deliver this temperature to the temperature indicator 20 and thereafter the temperature indicator 20 indicates the temperature of the hot water in the tank 11 through a change in its own temperature.

1 and 2, in the technical solution of Embodiment 1, the heat transfer structure 30 includes a casing 31 and a thermal section 32 set within the casing 31. [ This construction on the one hand ensures a high heat transfer rate and on the other hand ensures that there is no heat loss when the heat of the tank 11 is transferred to the outer casing 12. [ Specifically, in the technical solution of the present embodiment, the casing 31 is made of copper, and the thermal section 32 is made of a highly efficient thermally conductive liquid disposed in the casing 31.

As shown in Figures 1 and 2, in the technical solution of embodiment 1, the first end of the heat transfer structure 30 is connected to the upper inter-thermal layer 101 and the lower inter- . On the one hand the heat transfer structure 30 makes contact with the tank 11 to ensure the heat transfer function of the heat transfer structure 30 and on the other hand the heat transfer structure 30 and the tank 11 To ensure that the contact between the upper inter-insulating layer 101 and the lower inter-insulating layer 102 is continuous. In particular, the inter-insulating layer 100 is a layer of interstitial vacuum. The communication between the upper inter-insulating layer 101 and the lower inter-insulating layer 102 allows vacuuming of the vacuum cup to be completed at one time; More specifically, the vacuum hole is located at the bottom of the outer casing 12, and the communication between the upper inter-insulating layer 101 and the lower inter-insulating layer 102 is a vacuum in the outer casing 12, Lt; RTI ID = 0.0 > 101 < / RTI > Of course, those skilled in the art will appreciate that the second end of the heat transfer structure 30 can be arranged in a saw-tooth fashion, or that both the first and second ends of the heat transfer structure 30 can be arranged in a serrated manner I can understand.

1 and 2, in the technical solution of Embodiment 1, the installation section 121 is arranged at the junction between the bottom of the outer casing 12 and the wall. This structure makes it possible to quickly detect the temperature in the vacuum cup when the hot water is poured. Specifically, the vacuum cup can display the temperature of the hot water inside even when the amount of hot water in the vacuum cup is relatively small. More specifically, the grooves are at the same height of the vacuum cup. Of course, as is known to those skilled in the art, the grooves can be a continuous loop of varying heights.

The vacuum cup of Example 2 has a through hole so that the heat transfer structure 30 includes an annular casing and the center of the annular casing communicates with the upper inter-insulating layer 101 and the lower inter-insulating layer 102 And is different from the vacuum cup of Embodiment 1 in that the thermal section 32 is arranged inside the annular casing. In this manner, the upper interstitial layer 101 and the lower inter-thermal layer 102 can communicate with each other during heat transfer in the heat transfer structure 30. [

In application of the technical solution of Example 2, water is poured into a vacuum cup. The temperature of the tank 11 will quickly match the temperature of the water after contact. The heat transfer structure 30 will deliver the temperature of the tank 11 to the temperature indicator 20 and the indicator 20 will indicate the temperature of the water in the cup. The technical solution of this embodiment effectively solves the problem that the outer casing 12 of the conventional vacuum cup can not display the temperature inside the cup.

In the technical solution of the second embodiment, the outer wall of the outer casing 12 is provided with an installation section 121, to which a temperature indicator 20 is installed. The outer wall of the outer casing 12 has an installation section 121 which on the one hand enables the easy installation of the temperature indicator 20 and on the other hand ensures the health and long life of the temperature indicator 20 .

In the technical solution of embodiment 2, the temperature indicator 20 is made of a plurality of color changing materials and is configured to display different colors based on different temperatures. The above-described structure is easy to arrange and process, and has a relatively low production cost. Specifically, the hue change of the temperature indicator 20 can be adjusted as needed, and the hue change temperature of the temperature indicator 20 can be changed using a different material composition, for example, at 45 or 70 degrees, Can be adjusted using different material compositions. The various color change materials ensure that the different colors displayed by the temperature indicator 20 of the vacuum cup of this embodiment correspond to different temperatures. In addition, the vacuum cup body 10 is provided with a comparison label containing an exemplary color of the color changing material so that the user can easily read the temperature of the liquid (hot water) in the vacuum cup.

In the technical solution of Embodiment 2, the installation section 121 is a groove on the outer wall forming the outer casing 12, and the temperature indicator 20 is installed inside the groove. The groove structure is simple and easy to process. Specifically, since there is a gap between the bottom of the groove and the tank 11, the heat holding performance of the vacuum cup can be ensured. The grooves are set to arcuate transition portions; This structure provides a more comfortable experience and a beautiful appearance.

The first end of the heat transfer structure 30 is in contact with the tank 11 and the second end of the heat transfer structure 30 is in contact with the bottom of the groove and the heat transfer structure 30 ) Divides the inter-insulating layer 100 into a communicably-communicating upper inter-insulating layer 101 and a lower inter-insulating layer 102. This structure ensures that the temperature of the tank 11 can be quickly transferred to the outer casing 12. [ For example, after pouring the hot water into the vacuum cup, the temperature of the hot water is immediately transferred to the tank 11, and then the temperature of the tank 11 is immediately transferred to the outer casing 12 through the heat transfer structure 30 , The outer casing 12 continues to deliver this temperature to the temperature indicator 20 and then the temperature indicator 20 displays the temperature of the hot water in the tank 11 through a change in its own temperature.

In the technical solution of the second embodiment, the heat transfer structure 30 includes a casing 31 and a thermal section 32 set within the casing 31. This construction on the one hand ensures a high heat transfer rate and on the other hand ensures that there is no heat loss when the heat of the tank 11 is transferred to the outer casing 12. [ Specifically, in the technical solution of the present embodiment, the casing 31 is made of copper, and the thermal section 32 is made of a highly efficient thermally conductive liquid disposed in the casing 31.

In the technical solution of the second embodiment, the installation section 121 is arranged at the junction between the bottom and the wall of the outer casing 12. [ This structure makes it possible to quickly detect the temperature in the vacuum cup when the hot water is poured. Specifically, the vacuum cup can display the temperature of the hot water inside even when the amount of hot water in the vacuum cup is relatively small. More specifically, the grooves are at the same height of the vacuum cup. Of course, as is known to those skilled in the art, the grooves can be a continuous loop of varying heights.

The vacuum cup of Example 3 is characterized in that the temperature indicator 20 is made of a plurality of independent color change rings and the color change rings are arranged side by side in the outer casing 12 each of which is made of a different color change material Which is different from the first embodiment. These color change rings are independent of each other, so that the temperature indication of the temperature indicator 20 on the vacuum cup is more reliable.

In the technical solution of Example 3, water is poured into a vacuum cup. The temperature of the tank 11 will quickly match the temperature of the water after contact. The heat transfer structure 30 will deliver the temperature of the tank 11 to the temperature indicator 20 and the indicator 20 will indicate the temperature of the water in the cup. The technical solution of this embodiment effectively solves the problem that the outer casing 12 of the conventional vacuum cup can not display the temperature inside the cup.

In the technical solution of the third embodiment, the outer wall of the outer casing 12 is provided with an installation section 121, to which a temperature indicator 20 is installed. Providing the outer wall of the outer casing 12 with the installation section 121 allows for easy installation of the temperature indicator 20 on the one hand and on the other hand provides the good life of the temperature indicator 20 and the long life .

In the technical solution of embodiment 3, the temperature indicator 20 is made of a plurality of color changing materials and is configured to display different colors based on different temperatures. The above-described structure is easy to arrange and process, and has a relatively low production cost. Specifically, the hue change of the temperature indicator 20 can be adjusted as needed, and the hue change temperature of the temperature indicator 20 can be changed using a different material composition, for example, at 45 or 70 degrees, Can be adjusted using different material compositions. The various color change materials ensure that the different colors displayed by the temperature indicator 20 of the vacuum cup of this embodiment correspond to different temperatures. In addition, the vacuum cup body 10 is provided with a comparison label containing an exemplary color of the color changing material so that the user can easily read the temperature of the liquid (hot water) in the vacuum cup.

In the technical solution of the third embodiment, the installation section 121 is a groove on the outer wall forming the outer casing 12, and the temperature indicator 20 is installed inside the groove. The groove structure is simple and easy to process. Specifically, since there is a gap between the bottom of the groove and the tank 11, the heat holding performance of the vacuum cup can be ensured. The grooves are set to arcuate transition portions; This structure provides a more comfortable experience and a beautiful appearance.

The first end of the heat transfer structure 30 is in contact with the tank 11 and the second end of the heat transfer structure 30 is in contact with the bottom of the groove and the heat transfer structure 30 Is divided into an upper inter-insulating layer 101 and a lower inter-insulating layer 102 which communicate the inter-insulating layer 100. This structure ensures that the temperature of the tank 11 can be quickly transferred to the outer casing 12. [ For example, after pouring the hot water into the vacuum cup, the temperature of the hot water is immediately transferred to the tank 11, and then the temperature of the tank 11 is immediately transferred to the outer casing 12 through the heat transfer structure 30 , The outer casing 12 continues to deliver this temperature to the temperature indicator 20 and then the temperature indicator 20 displays the temperature of the hot water in the tank 11 through a change in its own temperature.

In the technical solution of the third embodiment, the heat transfer structure 30 includes a casing 31 and a thermal section 32 set within the casing 31. This construction on the one hand ensures a high heat transfer rate and on the other hand ensures that there is no heat loss when the heat of the tank 11 is transferred to the outer casing 12. [ Specifically, in the technical solution of the present embodiment, the casing 31 is made of copper, and the thermal section 32 is made of a highly efficient thermally conductive liquid disposed in the casing 31.

In the technical solution of embodiment 3, the mounting section 121 is arranged at the junction between the bottom of the outer casing 12 and the wall. This structure makes it possible to quickly detect the temperature in the vacuum cup when the hot water is poured. Specifically, the vacuum cup can display the temperature of the hot water inside even when the amount of hot water in the vacuum cup is relatively small. More specifically, the grooves are at the same height of the vacuum cup. Of course, as is known to those skilled in the art, the grooves can be a continuous loop of varying heights.

The vacuum cup of Example 4 is a plurality of independent color changing rings, in which a temperature indicator 20 is placed on and spaced apart from the outer casing 12, each of which is made of a different color changing material, The structure 30 is different from the first embodiment in that it has a one-to-one correspondence with the ring of the temperature indicator 20. Since these independently arranged color change rings are at different heights on the outer casing 12, the temperature at different heights of the vacuum cup can be obtained. Each color change ring is spaced apart to avoid mutual interference between the color change rings.

In application of the technical solution of Example 4, water is poured into a vacuum cup. The temperature of the tank 11 will quickly match the temperature of the water after contact. The heat transfer structure 30 will deliver the temperature of the tank 11 to the temperature indicator 20 and the indicator 20 will indicate the temperature of the water in the cup. The technical solution of this embodiment effectively solves the problem that the outer casing 12 of the conventional vacuum cup can not display the temperature inside the cup.

In the technical solution of Embodiment 4, the outer wall of the outer casing 12 is arranged to have an installation section 121, wherein a temperature indicator 20 is installed. The outer wall of the outer casing 12 with the installation section 121 allows for easy installation of the temperature indicator 20 on the one hand and on the other hand ensures the health and long life of the temperature indicator 20 .

In the technical solution of embodiment 4, the temperature indicator 20 is made of a plurality of color changing materials and is configured to display different colors based on different temperatures. The above-described structure is easy to arrange and process, and has a low production cost. Specifically, the hue change of the temperature indicator 20 can be adjusted as needed, and the hue change temperature of the temperature indicator 20 can be changed using a different material composition, for example, at 45 or 70 degrees, Can be adjusted using different material compositions. The various color change materials ensure that the different colors displayed by the temperature indicator 20 of the vacuum cup of this embodiment correspond to different temperatures. In addition, the vacuum cup body 10 is provided with a comparison label containing an exemplary color of the color changing material so that the user can easily read the temperature of the liquid (hot water) in the vacuum cup.

In the technical solution of Embodiment 4, the installation section 121 is a groove on the outer wall forming the outer casing 12, and the temperature indicator 20 is installed inside the groove. The groove structure is simple and easy to process. Specifically, since there is a gap between the bottom of the groove and the tank 11, the heat holding performance of the vacuum cup can be ensured. The grooves are set to arcuate transition portions; This structure provides a more comfortable experience and a beautiful appearance.

The first end of the heat transfer structure 30 is in contact with the tank 11 and the second end of the heat transfer structure 30 is in contact with the bottom of the groove and the heat transfer structure 30 ) Divides the inter-insulating layer 100 into a communicably-communicating upper inter-insulating layer 101 and a lower inter-insulating layer 102. This structure ensures that the temperature of the tank 11 can be quickly transferred to the outer casing 12. [ For example, after pouring the hot water into the vacuum cup, the temperature of the hot water is immediately transferred to the tank 11, and then the temperature of the tank 11 is immediately transferred to the outer casing 12 through the heat transfer structure 30 , The outer casing 12 continues to deliver this temperature to the temperature indicator 20 and then the temperature indicator 20 displays the temperature of the hot water in the tank 11 through a change in its own temperature.

In the technical solution of the fourth embodiment, the heat transfer structure 30 includes a casing 31 and a thermal section 32 set within the casing 31. This construction on the one hand ensures a high heat transfer rate and on the other hand ensures that there is no heat loss when the heat of the tank 11 is transferred to the outer casing 12. [ Specifically, in the technical solution of the present embodiment, the casing 31 is made of copper, and the thermal section 32 is made of a highly efficient thermally conductive liquid disposed in the casing 31.

In the technical solution of the fourth embodiment, the installation section 121 is arranged at the junction between the bottom and the wall of the outer casing 12. [ This structure makes it possible to quickly detect the temperature in the vacuum cup when the hot water is poured. Specifically, the vacuum cup can display the temperature of the hot water inside even when the amount of hot water in the vacuum cup is relatively small. More specifically, the grooves are at the same height of the vacuum cup. Of course, as is known to those skilled in the art, the grooves can be a continuous loop of varying heights.

It is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the embodiments according to the present application. As used herein, the singular forms are intended to include the plural forms unless the context clearly indicates otherwise; the terms " comprise " and / or " contain " Acts, devices, components, and / or combinations thereof.

It is noted that the terms " first ", " second ", etc. in the description and claims of the present invention and in the foregoing attached drawings are intended to distinguish similar objects and are not necessarily to be construed as a description of a specific sequence or order do. It should be understood that the data so used may be interchangeable where appropriate, so that the embodiments of the invention described herein may be implemented in a different order than, for example, shown or described herein. It is also to be understood that the terms " comprises " and " including ", and any variations thereof, are intended to encompass non-exclusive inclusion, such that a process, method, system, Is not necessarily limited to the steps or units listed herein and may include other steps or units that are not inherently or explicitly listed in the process, method, system, product, or apparatus.

The foregoing is merely a preferred embodiment of the present invention and is not intended to limit the present invention. The invention may be varied and varied by one skilled in the art. Any modifications, equivalents, improvements, etc. within the spirit and principles of the present invention are intended to be included within the scope of protection of the present invention.

Claims (10)

A vacuum cup,
As the vacuum cup body 10 including the tank 11 and the outer casing 12 arranged outside the tank 11, a layer of interlaminar insulation 100 is formed between the tank 11 and the outer casing 12 A vacuum cup body 10;
A temperature indicator (20) arranged on the outer casing (12); And
And a heat transfer structure (30) set within the interlaminar layer (100)
The temperature indicator 20 contacts the tank 11 via the heat transfer structure 30 and conveys the temperature of the tank 11 to the temperature indicator 20. 2. Vacuum cup according to claim 1, characterized in that the outer wall of the outer casing (12) is provided with an installation section (121) and the temperature indicator (20) is installed inside the installation section (121). The vacuum cup according to claim 1, wherein the temperature indicator (20) is made of a plurality of color changing materials, the temperature indicator (20) is configured to display different colors based on different temperatures, Characterized in that a comparison label is provided which comprises an exemplary color of the vacuum cup. 3. Vacuum cup according to claim 2, characterized in that the mounting section (121) is a groove on the outer wall forming the outer casing (12) and the temperature indicator (20) is installed inside the groove. 5. The heat transfer structure (30) of claim 4 wherein the first end of the heat transfer structure (30) contacts the tank (11), the second end of the heat transfer structure (30) And the upper inter-insulating layer (101) and the lower inter-insulating layer (102) which communicate the inter-insulating layer (100). 6. Vacuum cup according to claim 5, characterized in that the heat transfer structure (30) comprises a casing (31) and a thermal section (32) arranged inside the casing (31). 7. The heat transfer structure according to claim 6, characterized in that the first and / or second ends of the heat transfer structure (30) are formed in a sawtooth shape so as to communicate the upper insulating layer (101) and the lower insulating layer (102) Vacuum cup. The heat transfer structure (30) according to claim 6, wherein the heat transfer structure (30) includes an annular casing, a through hole is arranged at the center of the annular casing to communicate the upper insulating sandwich (101) and the lower insulating sandwich (102) 32) are arranged inside the annular casing. The method according to claim 1, wherein the temperature indicator (20) is a plurality of independent color change rings, the color change rings are arranged side by side on the outer casing (12), each color change ring Wherein the vacuum cup is a vacuum cup. The method of claim 1, wherein the temperature indicator (20) is a plurality of independent color change rings that are mounted and spaced on the outer casing (12), each color change ring is made of a different color change material, Wherein the heat transfer structure (30) corresponds one-to-one with the ring of the temperature indicator (20).

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