CN218960511U - Honeycomb temperature sensing color-changing pot - Google Patents

Abstract

The utility model provides a honeycomb thermochromic pot, which comprises a pot body with an inner surface, wherein the pot body comprises: raised lines arranged on the inner surface; the temperature sensing area is arranged on the inner surface and is coated with a thermochromic coating; the raised grains comprise raised grains of the temperature sensing area, which are arranged in the temperature sensing area, and the raised grains of the temperature sensing area at least have raised structures with two different shapes. According to the utility model, the raised structures with two different shapes are arranged in the temperature sensing area, so that the density of the raised lines can be reasonably adjusted according to the requirements when the raised lines in the temperature sensing area are designed. Compared with the traditional design, the convex grain design emitted from the center to the outside can obtain a better convex density design mode through the matching mode.

Description

Honeycomb temperature sensing color-changing pot

Technical Field

The utility model belongs to the field of cookware, and particularly relates to a honeycomb thermochromic pot.

Background

In the existing cooking appliances, cooking appliances having a plurality of different uses are produced according to different use performances. In order to monitor the oil temperature in real time after pouring the oil into the cookware capable of frying and frying food, a temperature sensing coating is generally coated on the inner surface of the cookware, so that the color of the inner surface of the cookware changes after the temperature of the cookware rises due to heating, and the heated temperature of the cookware is deduced; in addition, in the design of the cookware, the inner surface of the cookware is usually smooth, or some raised patterns are designed, so that the cookware with the design has the following problems.

1. If patterns are not arranged on the inner surface of the cooker or the arranged patterns are sparse, the temperature sensing coating is only arranged on the inner surface of the cooker, after the temperature of the cooker is increased, the color change can be only formed on the inner surface of the cooker, and in actual cooking, the consumers are easy to judge intuitively because the reference formed by the patterns is lack, and the patterns are easy to be blocked by lampblack.

2. If very dense patterns are arranged on the inner surface of the cooker, although very obvious color-changing patterns can be formed on the inner surface of the cooker after the color changes due to temperature sensing, the color-changing paint is difficult to adhere to the inner surface of the cooker in production and is easy to cause the paint on the inner surface of the cooker to fall off in use; meanwhile, if the inner surface of the cooker has complicated patterns, the turner and the inner surface of the cooker have larger friction resistance when cooking is performed, so that the turner is difficult to turn over.

In the prior art, no good solution is provided for the problems, most cookers are provided with the patterns on the inner surface, when the patterns on the inner surface of the cookers are designed, the cookers are etched in a divergent manner from the center of the inner surface of the cookers to the periphery, the etching process is simple to operate, but the patterns on the center part of the cookers are very dense, and the patterns on the inner surface of the cookers are gradually sparse along the radial direction of the cookers; therefore, the pattern design mode of the inner surface of the pot body is performed by diverging from the center to the periphery, so that the sparseness degree of the pattern of the inner surface of the pot body is difficult to balance; if the design of the patterns of the central area on the inner surface of the pot body is reasonable, the edge area of the central part becomes thinner and thinner.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides the honeycomb thermochromic pot with a reasonable temperature-sensing area structure design.

In order to achieve the above purpose, the utility model provides a honeycomb thermochromic pot, comprising a pot body with an inner surface, wherein the pot body comprises:

raised lines arranged on the inner surface;

the temperature sensing area is arranged on the inner surface and is coated with a thermochromic coating;

the raised grains comprise raised grains of the temperature sensing area, which are arranged in the temperature sensing area, and the raised grains of the temperature sensing area at least have raised structures with two different shapes.

According to the utility model, the raised structures with two different shapes are arranged in the temperature sensing area, so that the density of the raised lines can be reasonably adjusted according to the requirements when the raised lines in the temperature sensing area are designed. Compared with the traditional design, the convex grain design emitted from the center to the outside can obtain a better convex density design mode through the matching mode.

Optionally, the temperature sensing area protrusion lines comprise a plurality of strip-shaped protrusions and dot-shaped protrusions matched with the strip-shaped protrusions.

Optionally, the dot-shaped protrusions are located in a space surrounded by the plurality of strip-shaped protrusions.

Optionally, a gap is formed between two adjacent strip-shaped protrusions.

Optionally, the strip-shaped protrusions are connected end to end in sequence to enclose a polygonal space.

Optionally, the length range of the strip-shaped protrusion is set to be 0.6-1 mm, and the width of the strip-shaped protrusion is set to be 0.25-0.4 mm.

Optionally, the inner surface is further provided with a non-temperature-sensing area, the protrusion lines are formed in the non-temperature-sensing area and consist of a plurality of connecting protrusions and protruding points, and the space area enclosed by the connecting protrusions in the non-temperature-sensing area is larger than the space area enclosed by the strip-shaped protrusions; the temperature sensing area is positioned at the center of the non-temperature sensing area.

Optionally, the temperature-sensing area and the non-temperature-sensing area have a boundary; the parting line is composed of partition convex grains, and the partition convex grains comprise a plurality of convex rings and a plurality of partition convex arranged in two convex rings which are concentrically arranged.

Optionally, the thermochromic coating is further coated with at least a non-stick layer.

Optionally, the pan body is sequentially coated with a primer layer, a temperature sensing color-changing coating and a non-sticky layer in the temperature sensing area; the inner surface of the pot body is sequentially coated with a primer layer and a non-stick layer.

In summary, the present utility model has the following advantages over the prior art.

First, through setting up the arch of two kinds of structures in the temperature sensing area, design the density of decorative pattern in the temperature sensing area rationally.

Secondly, the density of the patterns can be reasonably arranged by closing the dot-shaped protrusions by the strip-shaped protrusions, and the density is mainly adjusted by adjusting the closing area of the strip-shaped protrusions and the diameter of the dot-shaped protrusions.

Thirdly, when the strip-shaped protrusions are closed to form a polygonal space, the strip-shaped protrusions are not connected with each other, so that the distance between the strip-shaped protrusions can be adjusted, and the pattern density can be better adjusted.

Fourth, the temperature sensing area and the non-temperature sensing area are provided with convex dividing lines, so that when corresponding paint is coated, the area to be coated can be defined by the dividing lines, and the paint can be finished better.

Fifth, the temperature sensing area and the non-temperature sensing area are divided through annular protrusions, so that consumers can intuitively see the non-temperature sensing area and the temperature sensing area, and the positions of the temperature sensing areas can be accurately found during cooking.

Sixthly, the area enclosed by the connecting protrusions in the non-temperature-sensing area is larger, namely the pattern density in the non-temperature-sensing area is smaller than that in the temperature-sensing area, so that more dense patterns can be obtained in the temperature-sensing area, and the color-changing area and the patterns can be enabled to show a more stereoscopic effect when color development is performed; the patterns of the non-temperature-sensing area are sparse, so that more paint attaching effects can be obtained, and the paint of the non-temperature-sensing area is prevented from falling off; meanwhile, the area of the non-temperature-sensing area is larger, the patterns of the non-temperature-sensing area are fewer, and the resistance of the turner during turning can be reduced.

Drawings

FIG. 1 is a top view of the inner surface of the present utility model.

Fig. 2 is an enlarged view of the temperature sensing region and a portion of the non-temperature sensing region of fig. 1.

Fig. 3 is an enlarged view of a boundary portion of the temperature sensing region and the non-temperature sensing region of fig. 1.

Fig. 4 is a top view of the utility model with gaps between the inner surface strips.

Fig. 5 is a top view of the inner surface of the present utility model with the strip-like projections end to end.

Detailed Description

In order to enable those skilled in the art to better understand the present utility model, the following description will make clear and complete descriptions of the technical solutions in the embodiments of the present utility model with reference to the accompanying drawings in the embodiments of the present utility model.

As shown in figures 1-5, a honeycomb thermochromic cooker includes a cooker body having a bottom and a sidewall extending upwardly from the bottom, the sidewall and bottom defining a cooking cavity for cooking food. The style of the pot body can be a commercially available pan, a frying pan, a soup pot, a hot pot, a steamer and a milk pot, and different cookers can be changed by adjusting the styles of the bottom and the side wall.

The inner surface 1a is formed on the pot body 1, and the inner surface 1a is used for contacting food, and the inner surface 1a is a surface of the inner wall of the cooking cavity.

The inner surface 1a is divided into a temperature sensing area 101 and a non-temperature sensing area 102, the temperature sensing area 101 is arranged in the central area of the inner surface 1a of the pot body 1, and meanwhile, the temperature sensing area 101 is arranged in the central area of the non-temperature sensing area 102. In the present embodiment, the temperature sensing region 101 is provided in a circular shape, and in the remaining embodiments, the temperature sensing region 101 may be provided in the remaining shape.

The pot body 1 is provided with raised grains, the raised grains are arranged on the inner surface 1a of the pot body 1, and the raised grains are arranged on the pot body 1 by an etching process. After the etching is completed, a primer layer (non-stick paint) is coated on the pot body 1, after the primer is dried, a thermosensitive primer layer 401 is coated, after the thermosensitive primer layer 401 is dried, a thermochromic coating 402 is coated, and after the thermochromic coating 402 is dried, a non-stick layer (non-stick paint) is coated.

Wherein the primer layer and the non-stick layer cover the whole pot body, the thermochromic base coating 401 covers the whole thermochromic region 101, and the thermochromic coating 402 covers part of the thermochromic base coating 401.

Specifically, in the present embodiment, the thermochromic coating 402 is provided in a ring shape, and the thermochromic base coating 401 is provided on the inner side and the outer side of the ring-shaped thermochromic coating 402, respectively, so that the thermochromic coating 402 can form a distinct ring-shaped color change region after the color change. In the process flow, the annular thermochromic coating 402 is coated on the thermochromic coating 401, and at normal temperature, the thermochromic coating 402 and the thermochromic coating 401 have chromatic aberration, so that the thermochromic coating 401 is shown to be disposed on the inner side and the outer side of the annular thermochromic coating 402, respectively. Of course, in other embodiments, the thermochromic coating 402 may take on other settings.

The raised grains are patterns formed on the inner surface of the pot body, and in order to enable the color-changing coating to form a good temperature sensing effect by means of the raised grains after the temperature changes, the design mode of the raised grains is as follows.

The convex grains comprise a temperature-sensing area convex grain 201 and a non-temperature-sensing area convex grain 202, the temperature-sensing area convex grain 201 comprises a strip-shaped bulge 21 and a dot-shaped bulge 22, wherein the dot-shaped bulge 22 is positioned in a space enclosed by the strip-shaped bulges 21; in this embodiment, six strip-shaped protrusions 21 enclose a regular hexagonal space, and the dot-shaped protrusions 21 are located at the middle position of the hexagonal space.

It is envisioned that in other embodiments, the space enclosed by the strip-shaped protrusions 21 may be other shapes, and the number of strip-shaped protrusions 21 enclosing multiple spaces may be other numbers. As shown in fig. 2, the space enclosed by the strip-shaped protrusions 21 may be open, and a gap is formed between every two adjacent strip-shaped protrusions 21. As shown in fig. 5, the space enclosed by the strip-shaped protrusions 21 may be closed, and every two adjacent strip-shaped protrusions 21 are connected end to end.

Further, in order to facilitate control of the dense and sparse structure of the patterns in the temperature sensing area, all the strip-shaped protrusions 21 are independent of each other, and adjustable gaps are formed between the adjacent strip-shaped protrusions 21.

Further, in order to form a reasonably dense convex grain in the temperature sensing area 101, the range of the strip-shaped convex is set to be 0.6-1 mm, and the width of the strip-shaped convex is selected to be 0.25-0.4 mm.

In some embodiments, the length of the strip-shaped protrusion 21 is selected to be 0.78mm and the width is selected to be 0.28mm.

In some embodiments, the length of the strip-shaped protrusion 21 is selected to be 0.6mm and the width is selected to be 0.25mm.

In some embodiments, the length of the strip-shaped protrusion 21 is selected to be 1mm and the width is selected to be 0.4mm.

In some embodiments, the length of the strip-shaped protrusion 21 is selected to be 0.8mm and the width is selected to be 0.33mm.

Further, the diameter of the dot-shaped protrusion 22 is in the range of 0.4 to 0.6mm.

In some embodiments, the dot-shaped protrusion 22 has a diameter of 0.44mm.

In some embodiments, the dot-shaped protrusion 22 has a diameter of 0.4mm.

In some embodiments, the dot-shaped protrusion 22 has a diameter of 0.6mm.

In some embodiments, the dot-shaped protrusion 22 has a diameter of 0.5mm.

Further, a gap is provided between the adjacent strip-shaped projections 21, the width of the gap is 0.6 to 1.2mm, and the distance between the strip-shaped projections 21 and the dot-shaped projections 22 is 0.8 to 1.5mm.

In some embodiments, the width of the gap is 0.8mm and the distance between the bar-shaped protrusions 21 and the dot-shaped protrusions 22 is 1.14mm.

In some embodiments, the width of the gap is 0.6mm and the distance between the bar-shaped protrusions 21 and the dot-shaped protrusions 22 is 0.8mm.

In some embodiments, the width of the gap is 1.2mm and the distance between the strip-shaped protrusions 21 and the dot-shaped protrusions 22 is 1.5mm.

In some embodiments, the width of the gap is 0.9mm and the distance between the strip-shaped protrusions 21 and the dot-shaped protrusions 22 is 1.18mm.

Further, the structure of the non-temperature-sensing-area convex grain 202 provided in the non-temperature-sensing area 102 is as follows.

The non-temperature-sensing region grain 202 includes a plurality of connection protrusions 221, and a plurality of spaces are separated by the plurality of connection protrusions 221 in the non-temperature-sensing region 102, and the spaces may be hexagonal, so that a typical honeycomb-shaped pot body is formed in the non-temperature-sensing region 102 through the non-temperature-sensing protrusion grain. Meanwhile, a plurality of protruding points 222 are also provided in the space surrounded by the connection protrusion 221. The space enclosed by the connecting protrusions 221 may be closed, and each two adjacent connecting protrusions 221 are connected end to end, such as a typical honeycomb type pattern. The space enclosed by the connecting protrusions 221 may be open, with a gap between every two adjacent connecting protrusions 221, such as the pattern of the PRO pattern of an open cell pot.

Further, the length of the connection protrusion 221 is greater than the length of the bar-shaped protrusion 21.

Further, there is a boundary between the non-temperature-sensing region 102 and the temperature-sensing region 101, which is formed by a partition convex grain including a plurality of convex rings 301 and a plurality of partition convex points 302 provided in two adjacent convex rings 301.

In this embodiment, two raised rings 301 are provided, and a uniform circumferential array of dividing bumps 302 is provided in the annular space enclosed by the two raised rings 301.

It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present utility model without making any inventive effort, shall fall within the scope of the present utility model.

Claims (10)

1. A honeycomb thermochromic pot, characterized by, including having the pot body of internal surface, the pot body includes:

raised lines arranged on the inner surface;

the temperature sensing area is arranged on the inner surface and is coated with a thermochromic coating;

the raised grains comprise raised grains of the temperature sensing area, which are arranged in the temperature sensing area, and the raised grains of the temperature sensing area at least have raised structures with two different shapes.

2. The honeycomb thermochromic cooker of claim 1, wherein the raised pattern of the temperature-sensing region comprises a plurality of strip-shaped protrusions and dot-shaped protrusions which are mutually matched with the plurality of strip-shaped protrusions.

3. A honeycomb thermochromic pot according to claim 2, wherein the dot-like projections are located in spaces surrounded by the plurality of strip-like projections.

4. A honeycomb thermochromic pot according to claim 3, wherein a gap is provided between two adjacent strip-like protrusions.

5. A honeycomb thermochromic pot according to claim 3, wherein a plurality of the strip-shaped protrusions are connected end to end in sequence to enclose a polygonal space.

6. A honeycomb thermochromic pot according to claim 3, wherein the length of the strip-shaped protrusion is set to be 0.6-1 mm, and the width of the strip-shaped protrusion is set to be 0.25-0.4 mm.

7. A honeycomb thermochromic cooker according to claim 3, wherein the inner surface is further provided with a non-temperature-sensing region, the raised grains are formed with non-temperature-sensing region raised grains in the non-temperature-sensing region, the non-temperature-sensing region raised grains are composed of a plurality of connecting protrusions and raised points, and the space area enclosed by the connecting protrusions in the non-temperature-sensing region is larger than the space area enclosed by the strip-shaped protrusions; the temperature sensing area is positioned at the center of the non-temperature sensing area.

8. The cellular thermochromic cooker of claim 7, wherein said temperature-sensitive region and said non-temperature-sensitive region have demarcations; the parting line is composed of partition convex grains, and the partition convex grains comprise a plurality of convex rings and a plurality of partition convex arranged in two convex rings which are concentrically arranged.

9. A honeycomb thermochromic cooker according to any of claims 1-6, wherein the thermochromic coating is further coated with at least a non-stick layer.

10. The honeycomb thermochromic pot of any one of claims 1-6, wherein the pot body is coated with a primer layer, a thermochromic coating and a non-stick layer in the temperature sensing region in sequence; the inner surface of the pot body is sequentially coated with a primer layer and a non-stick layer.

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