RU171893U1 - TABLE TOP WITH INTEGRATED INDUCTION STOVE - Google Patents

Abstract

The utility model relates to kitchen equipment, namely to countertops with integrated induction heating elements. The technical result is to reduce the thickness of the upper layer of the countertop while maintaining its strength characteristics, which reduces energy consumption and time for cooking. The worktop with an integrated induction cooker consists of a ceramic sheet with flat upper and lower sides and with a hob on the upper side, on which the location of the induction coils is marked with embedded ceramic paint. The ceramic sheet is glued to the carrier, in which a through cut is made in the hob area. Between the ceramic sheet and the carrier in the hob area, an aluminum sheet is installed as a radiator, in which, in order to ensure contact between the induction coils and the ceramic sheet, holes are made in the area of the induction coils in excess of the diameter of the induction coils. Between the induction coils and the ceramic sheet is a sheet of wax paper. A fiberglass mesh is glued to the bottom of the ceramic sheet in the area where the induction coils are located using heat-resistant mastic. In the center of the fiberglass mesh of each induction coil, holes are made in which thermistors are installed and fixed.

Description

The utility model relates to kitchen equipment, namely to countertops with integrated induction heating elements.

Various variants of countertops with integrated heating elements are widely known in the prior art, for example, from WO 2014108521 A1, a countertop with induction heating elements integrated in recesses on the underside of a countertop is known. Indication of the heating area occurs with a laser.

The disadvantage of this technical solution is that the place of cooking can be determined only with a working laser pointer. In addition, the countertop has a sufficiently large thickness of the top coating, which increases the energy consumption required for cooking.

The closest document is DE 102006047972 A1, which discloses a description of a countertop made in the form of a slab with an upper layer of artificial stone with a thickness of 10 mm or more, with recesses on the bottom of which are made of induction heating elements.

The disadvantage of the closest analogue is the lack of indicators of the places of heating, as well as a sufficiently large thickness of the top cover of the countertop.

Thus, the objective of the claimed utility model is to eliminate the disadvantages of the prior art.

The technical result to which the claimed utility model is directed is to reduce the thickness of the top layer of the countertop while maintaining its strength characteristics, which reduces energy consumption and cooking time, as well as the exact marking of the installation sites for cooking utensils, since inaccurate installation of dishes also affects power consumption and cooking time.

The task and the claimed technical result are fully achieved by a set of features of an independent paragraph of the claimed formula of the utility model.

The worktop with an integrated induction cooker consists of a ceramic sheet with flat upper and lower sides and with a hob on the upper side, on which the location of the induction coils is marked with embedded ceramic paint. The ceramic sheet is glued to the carrier, in which a through cut is made in the hob area. Between the ceramic sheet and the carrier in the hob area, an aluminum sheet is installed as a radiator, in which, in order to ensure contact between the induction coils and the ceramic sheet, holes are made in the area of the induction coils in excess of the diameter of the induction coils. Between the induction coils and the ceramic sheet is a sheet of wax paper. A fiberglass mesh is glued to the bottom of the ceramic sheet in the area where the induction coils are located using heat-resistant mastic. In the center of the fiberglass mesh of each induction coil, holes are made in which thermistors are installed and fixed.

The thickness of the aluminum sheet is from 0.5 to 2 mm.

The aluminum sheet is glued to the ceramic sheet using heat-resistant adhesive.

As a heat-resistant adhesive, Neopur 2911 and Adiflex 2681 hardener can be used.

The claimed tabletop contains a controller that is programmed in such a way as to prevent overheating of the upper layer of the ceramic sheet.

The hole in the aluminum sheet in diameter exceeds the diameters of the induction coils by about 2 mm.

The marking of the locations of the induction coils coincides with the areas of the location of the dishes for cooking, applied to the ceramic sheet by injecting ceramic paint into the upper layer of the ceramic sheet.

The carrier may be made of plywood.

The carrier may be made of chipboard.

Further, the claimed utility model is explained in more detail by the drawings, in which:

Figure 1 is a General view of the claimed countertops.

Figure 2 - the claimed countertop in a longitudinal vertical section.

The worktop with an integrated induction cooker consists of a ceramic sheet (1) with flat upper and lower sides, without additional mechanical damage (milling). On the upper side of this ceramic sheet (1) with a thickness of about 6 mm there is a marking (10) of the zones of the induction coils (4). The ceramic sheet (1) is glued to the carrier (11) (for example, to a sheet of chipboard, plywood, etc.). To install the induction cooker under the ceramic sheet (1) in the carrier (11), a through cut (2) is made, and also between the ceramic sheet (1) and the carrier (11) an aluminum sheet (3) with a thickness of 0.5 to 2 mm, used to remove heat shock from the ceramic sheet (1) and evenly distribute heat. The aluminum sheet (3) is glued to the ceramic sheet (1) using heat-resistant adhesive, as an option, it is heat-resistant adhesive Neopur 2911 and hardener Adiflex 2681 to it. Heat-resistant adhesive is at least 300 ° C.

In the aluminum sheet (3) above each induction coil (4), holes (7) are made, their diameters slightly exceeding the diameters of the induction coils (4) by about 2 mm. This allows free contact of the induction coils (4) with the ceramic sheet (1) and facilitates the process of energy passing through the ceramic, respectively, saving it.

To increase the strength, the lower part of the ceramic sheet (1) in the area of the induction coils (4) is glued with a fiberglass mesh (6), which is glued to heat-resistant mastic. The heat resistance of fiberglass mesh (6) and mastic is at least 300 ° C.

In the center of the fiberglass mesh (6) of each induction coil (4), holes for installing thermistors (5) measuring the temperature of the ceramic sheet (1) are made. Thermistors (5) are attached to the underside of the ceramic sheet (1). Moreover, the controller (not shown in FIG.) Of the induction cooker is programmed in such a way as to prevent overheating of the upper layer of the ceramic sheet. After heating the surface to 200 ° C, the controller automatically reduces the heating power from 100% to 60%; when the stove is heated to 220 ° C, the operation of induction coils (4) completely stops.

Thermistors take into account a temperature difference of 10-15 ° C on the upper and lower surfaces of the ceramic sheet (1) in the region of one induction coil (4). For example, since the ceramic sheet (1) is designed for a heating temperature of not more than 220 ° C, when the temperature on the inner surface reaches about 205 ° C, induction coils (4) automatically turn off. An increase in the temperature of the upper surface of the ceramic sheet (1) above 220 ° C can lead to the destruction of the ceramic sheet (1) and the countertop as a whole.

A decrease in the thickness of the ceramic sheet (1) leads to a decrease in energy consumption during cooking and to a reduction in the time of its preparation. Ceramic sheet (1) has a minimum thickness of 3 mm and a maximum of 50 mm. The mechanical strength is ensured by gluing the ceramic sheet (1) to the carrier (11), and in the area of the induction plate due to the fact that the fiberglass mesh is glued to the ceramic sheet (1). The ceramic sheet retains its mechanical strength due to the absence of surface damage - milling, indicating the location of the induction coils.

It was experimentally established that the thickness of a ceramic sheet of 5–7 mm is optimal in terms of strength / energy consumption.

 An increase in the thickness of the ceramic sheet will entail an increase in energy consumption to overcome it, as well as an increase in cooking time.

The locations of the induction coils (4) are marked on the upper surface of the ceramic sheet (1) by marking the zones of the induction coils (4) with ceramic paint injected into the ceramic sheet (1) of the countertop during production. Paint sticking makes the drawing durable and resistant to high temperatures and the appearance of cracks and scratches.

Paints are applied to the ceramic sheet in a thin layer. During firing, fluxes (special low-melting glasses that are introduced into the composition of ceramic paint to fix the dye during the firing process on the surface and to give the paint a shine) soften, and the paint is deposited on the surface of the ceramic sheet. The paint is fired as follows: at the first stage, the temperature in the furnace rises to 645 ° C within one hour; in the second stage, the temperature cools to 300 ° C for 3 hours; In the third stage, the oven opens and the paint cools naturally. The marking injected in this way is durable and resistant to temperature changes, as well as to scratches.

For printing a ceramic sheet, ceramic paints are used - these are colored mineral compounds of metals with quartz, feldspar, kaolin or with ceramic masses and glazes formed as a result of interaction at high temperatures. The intensity and color of the paint depends on the firing temperature. Coloring substances (dyes) in ceramic paints are pigments - salt oxides, highly dispersed powders of various colors, insoluble in water and binders. The pigment determines the color, the tint component changes the hue of the color. In addition to pigments (dyes), ceramic paints contain fluxes. It is possible to burn paint in a similar way at a temperature of 600-800 ° C.

The following oxides are used for the manufacture of paints:

Co2O3 - blue and cyan;

Ni2O3 - brown and purple;

Fe2O3 - yellow, red and brown;

CuO - green and blue-green;

MnO2 - brown, purple and pink;

UO3 is yellow;

TiO2 - yellow;

Cr2O3 - green and red;

Au is red;

Pt is gray;

Jr2O3 is black.

Ceramic paints have the following properties:

- resistant to high temperatures during the firing process and to the dissolving effect of fluxes and glazes;

- have high resistance to light and aggressive environment;

- easily applied to ceramics, do not exhibit toxic properties during operation (including when heated).

On the upper surface of the ceramic sheet (1), a plate control unit (8) is installed.

This ensures a decrease in the thickness of the top layer (ceramic sheet) of the countertop while maintaining its strength characteristics, which reduces energy consumption and cooking time.

In addition, the location of the precise marking of the places where dishes are installed (the locations of induction coils) for cooking also significantly save energy and reduce cooking time, as it allows the user to accurately place dishes above induction coils for maximum energy transfer from coils to the product, since inaccurate installation cookware negatively affects energy consumption and cooking time. At the same time, the applied marking does not reduce the strength characteristics of the countertop.

Claims (9)

1. A worktop with an integrated induction cooker, characterized in that it consists of a ceramic sheet with flat upper and lower sides and with a hob on the upper side, on which the location of the induction coils is marked with embedded ceramic paint, and the ceramic sheet is glued to the carrier in which a through cut is made in the hob area, in addition, an aluminum sheet is installed as a radiator between the ceramic sheet and the carrier in the hob area, in which, in order to ensure contact between the induction coils and the ceramic sheet in the area where the induction coils are located, holes are made that exceed the diameter of the induction coils, a waxed paper sheet is located between the induction coils and the ceramic sheet; A fiberglass mesh is glued to the bottom of the ceramic sheet in the area of the induction coils using heat-resistant mastic, and holes are made in the center of the fiberglass mesh of each induction coil, in which thermistors are installed and fixed. 2. A worktop with an integrated induction cooker according to claim 1, characterized in that the thickness of the aluminum sheet is from 0.5 to 2 mm. 3. A worktop with an integrated induction cooker according to claim 1, characterized in that the aluminum sheet is glued to the ceramic sheet using heat-resistant adhesive. 4. A worktop with an integrated induction cooker according to claim 3, characterized in that Neopur 2911 and Adiflex 2681 hardener can be used as heat-resistant adhesive. 5. A worktop with an integrated induction cooker according to claim 1, characterized in that it contains a controller that is programmed so as to prevent overheating of the upper layer of the ceramic sheet. 6. A worktop with an integrated induction cooker according to claim 1, characterized in that the hole in the aluminum sheet is larger than the diameter of the induction coils by about 2 mm. 7. A worktop with an integrated induction cooker according to claim 1, characterized in that the marking of the locations of the induction coils coincides with the locations of the dishes for cooking and is applied to the ceramic sheet by injecting ceramic paint into the upper layer of the ceramic sheet. 8. A worktop with an integrated induction cooker according to claim 1, characterized in that the carrier is made of plywood. 9. A worktop with an integrated induction cooker according to claim 1, characterized in that the carrier is made of chipboard.

Images