JP6839441B2 - Heat generation sheet for IH cooker - Google Patents

Description

The present invention relates to an IH cooker heating sheet used for cooking with an IH cooker.

In recent years, cooking cookers called electromagnetic cookers have become widespread in place of gas stoves and the like. This electromagnetic cooker, also called an IH cooker, generates a high-frequency magnetic field by an electromagnetic induction heating coil provided inside, and Joule heat is generated by an eddy current induced in a cooking container placed on the cooker. This heats the foodstuff contained in the cooking container or the object to be heated such as water.
Since such an electromagnetic cooker can be cooked without using a flame, it is highly safe, easy to wipe off dirt, has excellent cleanliness, and is more economical than a conventional cooker. Are better.

However, in principle, the cooking utensils that can be used for an electromagnetic cooker are limited, and a special utensil made of a magnetic material typified by iron must be used. For this reason, recently, many cooking utensils or cooking containers made of materials other than magnetic materials have been proposed and put into practical use. For example, Patent Document 1 discloses a heating cooker for an IH cooker in which a heating sheet made of a metal foil such as aluminum foil is attached to a plastic container, and the heating sheet includes a metal foil such as aluminum foil. A laminated heat generating sheet in which a layer of a thermoplastic resin such as an olefin resin is laminated is also proposed.

The heat-generating sheet is not fixed only by placing it on the bottom of the plastic container, and causes inconveniences such as the heat-generating sheet moving during cooking (cooking). Is fixed by. Therefore, the layer of the thermoplastic resin laminated on the metal foil needs to have a heat-sealing property with respect to the bottom of the plastic container.

The heat-generating sheet as described above is not suitable for disposable use because it needs to be fixed to the bottom of the container. Further, since a manufacturing process for fixing to the bottom of the plastic container is required, there is a problem that it is difficult to manufacture at low cost.

The applicant has further developed the function of the heat-generating sheet, and has previously proposed a heat-generating sheet for an IH cooker, which is a laminated sheet of a conductive sheet (metal foil) and a resin sheet formed of an olefin resin or the like. The heat-generating sheet is patented (Patent Document 2). This heat-generating sheet can be folded into a container shape, and a container (heat-generating container) formed by folding the heat-generating sheet is inserted into a container-shaped holder made of thermoplastic resin, and the heat-generating container is inserted. Water and ingredients to be cooked are put inside the container, and cooking is performed by an IH cooker in this state.

The heat-generating sheet as described above has an advantage that it is not fixed to a container-shaped thermoplastic resin holder by a heat seal but is suitable for disposable use. By folding this sheet, it is possible to cook by heating such as boiling. A container suitable for the above is formed, and this is placed in an induction heating part of an IH cooker, and heat is generated by induction heating to perform cooking.

The heat-generating sheet has a certain degree of heat resistance, but when cooking at a high temperature such as cooking of fried food in which the object to be heated is cooking oil, a resin sheet having higher heat resistance is applied to one surface of the metal foil. It is necessary to provide it.
Therefore, in order to impart high heat resistance to the heat-generating sheet, the applicant is a heat-resistant laminated sheet formed of a conductive sheet and a silicone resin layer having a thickness of 20 μm or more formed on one surface of the conductive sheet. The silicone resin layer is composed of a silicone sheet and a silicone coating layer, and the silicone coating layer is formed on the conductive sheet side, and a heat-resistant laminated sheet used as a heat-generating sheet for an IH cooker has been proposed. A heat-resistant laminated sheet has also been patented (Patent Document 3).

However, the container formed by folding the heat-generating sheet as described above (sometimes referred to as a folding heat-generating container) is held by a holder made of thermoplastic resin placed in the induction heating part of the IH cooker. When cooking such as fried food, there is a problem that the foodstuff is partially burnt due to direct heat transfer by the conductive sheet. Further, there is also a problem that the increase in heat generation of the conductive sheet is detected by a sensor provided in the induction heating section of the IH cooker, the temperature control by the IH cooker becomes high, and the temperature control becomes difficult.

Japanese Unexamined Patent Publication No. 2014-239852 Patent No. 5788557 Patent No. 5989846

Therefore, an object of the present invention is an IH cooker heat-generating sheet that includes a conductive sheet that generates heat by induction heating and that heats and cooks using the heat generated by the conductive sheet, and when cooking such as fried food is performed. It is an object of the present invention to provide a heat generating sheet for an IH cooker, in which partial charring of foodstuffs is effectively prevented and temperature control by an IH cooker is appropriately performed.

According to the present invention, it is a heat generating sheet for an IH cooker, in which a conductive sheet and a silicone sheet are laminated on one surface of the conductive sheet, and a paint layer is formed on the other surface. A heating sheet for an IH cooker is provided, wherein each layer contains a radioactive material.

In the heat-generating sheet for an IH cooker of the present invention,
(1) The paint layer is a silicone paint layer.
(2) The radiation material is a black pigment.
(3) The black pigment is a carbon-based pigment.
(4) The radiation divergence on the paint layer side at a wavelength of 5 μm at 300 ° C. of the silicone sheet and the heat generating sheet for an IH cooker using the paint layer is 380 W · m ^-2 · μm ^-1 or more.
(5) A reinforcing dielectric piece having a strength higher than that of the silicone sheet is attached to the surface of the silicone sheet opposite to the conductive sheet so that a part of the surface of the silicone sheet is exposed. thing,
Is preferable.

According to the heat-generating sheet for an IH cooker of the present invention, it is arranged on the induction heating part of the IH cooker, and when cooking such as fried food on the heat-generating sheet is performed, the radiation of the radiator heats the food. By contributing to the above, the partial heating of the food material due to the direct heat transfer of the conductive sheet is alleviated, and the occurrence of partial charring of the food material can be effectively avoided.
Further, when the above-mentioned cooking is performed, the increase in heat generation of the conductive sheet is alleviated by the radiation of the radiator, and the temperature is appropriately controlled by the sensor provided in the induction heating section of the IH cooker.

The schematic which shows the cross-sectional structure of the heating sheet for an IH cooker of this invention. The plan view of the heating sheet of FIG. The bottom view of the heat generating sheet of FIG. FIG. 5 is a plan view showing a blank sheet used for attaching a reinforcing dielectric piece to the heat generating sheet of FIG. A semi-perspective view of a holding member on which the heat generating sheet of FIG. FIG. 3 is a schematic cross-sectional view showing a procedure for placing the heat generating sheet of FIG. 1 on a holding member. The figure which shows the distribution of the black body radiation bundle on the coating layer side at 300 degreeC of the heat generation sheet of FIG.

As shown in FIGS. 1 to 3, the heating sheet for an IH cooker of the present invention (shown as 1 as a whole, hereinafter referred to as a heating sheet) has a conductive sheet 3 as a heating element by induction heating, and the conductive sheet 3 is provided. A silicone sheet 5 is laminated on one surface of the sheet 3, and a coating layer 6 is formed on the other surface of the conductive sheet 3, both of which contain a radioactive material. Further, a reinforcing dielectric piece 7 is attached to the surface of the silicone sheet 5 opposite to the conductive sheet 3. As shown in FIG. 5 described later, the heat generating sheet 1 is folded into the form of the container A with the reinforcing dielectric piece 7 as the outer surface side, and is placed on the dielectric holding member 30. It is placed in the induction heating part of the IH cooker.

The conductive sheet 3 is formed of a metal foil typified by aluminum foil or the like, and the heat generating sheet 1 is placed on the induction heating part of the IH cooker so that the silicone sheet 5 is on the lower side, and the IH cooker is placed. When operated, the conductive sheet 3 generates heat due to the eddy current induced by the high-frequency magnetic field.

Further, the silicone sheet 5 is a dielectric material having excellent heat resistance, and is formed to prevent direct contact between the conductive sheet 3 and the IH cooker and to moderate the heat generation of the conductive sheet 3. is there. The silicone sheet 5 is made of, for example, silicone rubber, and uses a silicone primer made of liquid silicone or the like containing acrylic alkoxysilane or other alkoxysilane as a monomer component to form a conductive sheet 3 and a reinforcing dielectric piece 7 to be described later. It is affixed to and integrated with the silicone primer.

The silicone sheet 5 integrated with the silicone primer as described above varies depending on the size of the heat generating sheet 1 and the like, but is generally a silicone primer applied on the conductive sheet 3 or on the reinforcing dielectric piece 7. The thickness is about 0.05 to 2.0 μm in terms of dry film thickness, and the thickness of the silicone sheet 5 laminated and integrated with the silicone rubber layer is 20 μm or more, preferably 20 to 1000 μm, and more preferably 50 to 200 μm. You just have to do it.

In the present invention, the above-mentioned silicone sheet 5 is dispersed with a radiant material, and when the conductive sheet 3 generates heat, the temperature rise is alleviated, and the temperature by a sensor provided in the induction heating section of the IH cooker is used. Control is done aptitude.

Further, in the paint layer 6, when the conductive sheet 3 generates heat, the radiation of the radiator contributes to the heating of the food material, and the radiant material is dispersed in order to alleviate the partial heating of the food material due to the direct heat transfer of the conductive sheet 3. Has been done.
Such a coating layer 6 is preferably formed of a silicone coating material from the viewpoint of adhesion to the conductive sheet 3 and heat resistance. This silicone paint is a paint containing liquid silicone similar to the above-mentioned silicone primer as a vehicle, and is a paint that forms a silicone coating film.
The thickness of the coating layer 6 in which such a radioactive material is dispersed is usually in the range of 1 to 50 μm. If this thickness is too thin, the food is not sufficiently heated by radiation, and charring is likely to occur. Further, if it is excessively thick, the paint layer 6 may be easily peeled off from the heat generating sheet 1.

The radioactive material blended in the silicone sheet 5 and the paint layer 6 described above is not particularly limited, but it is preferable to use known black pigments such as carbon-based black pigments and oxide-based black pigments.
For example, examples of carbon-based black pigments include carbon black, lamp black, plant black, bone black, and graphite, and examples of oxide-based black pigments include magnetite, copper-chromium composite oxide, and copper-chromium-. Examples include zinc composite oxides. In the present invention, a carbon-based black pigment, particularly carbon black, is preferably used from the viewpoint of being used especially for food applications.

The amount of the radiant material blended in the silicone sheet 5 as described above is set so as to alleviate the increase in heat generation of the conductive sheet 3 of the heat generating sheet 1, and the amount of the radiant material blended in the paint layer 6 is It is preferable that the radiation of the radiator contributes to the heating of the food material so that the partial heating of the food material due to the direct heat transfer of the conductive sheet 3 is effectively relaxed.

FIG. 7 shows the distribution of the blackbody radiation bundle on the paint layer 6 side of the heat generating sheet 1 at 300 ° C., and the radiation of the heat generating sheet 1 formed by using the silicone sheet 5 and the paint layer 6 at 300 ° C. It is a figure which shows the distribution of the divergence degree (radiant flux per unit area), and is black pigment (carbon black) in the amount that ^{the radiant divergence degree at 300 degreeC, the wavelength 5 μm becomes 380 W · m -2} · μm ^{-1 or more.} By blending, the partial charring of the ingredients was prevented.
In FIG. 7, the radiation emission degree of the blackbody is a theoretical value obtained by the following formula according to Planck's radiation law.
E (λ, T) = (2πc ² / λ ⁵ ) / (e ^{hc / λkT} -1)
In the formula, E: energy density (W / m ² · μm)
T: Blackbody temperature (Kelvin [K])
λ: Wavelength (m)
h: Planck's constant ^{(6.625 × 10 -34 [J /} s])
k: Boltzmann constant (1.38 × ^10-23 [J / K])
c: speed of light ^{(2.9979 × 10 8 [m /} s])

Further, in the present invention, various forms of cut lines X1, X2, and X3 are formed on the conductive sheet 3 in order to adjust the eddy current induced by the induction heating by the operation of the IH cooker. That is, these cut lines are formed linearly so as to penetrate the conductive sheet 3 and leave the silicone sheet 5 so that the eddy current induced in the conductive sheet 3 is completely divided (Fig.). It is formed by known means such as (see 1 and 2) and laser processing.

The heat-generating sheet 1 is usually circular as a whole, but when folded, the conductive sheet 3 side is the inner surface, the central circular region is the bottom portion 10, and the annular region around the periphery is the circumferential side wall portion 13. A (see FIG. 5 described later) can be formed. That is, the size of the container A thus formed is usually about the same as that of a pot used for cooking at home.

The conductive sheet 3 of the portion (annular region) that becomes the peripheral side wall portion 13 of the container formed by folding has a first radially extending portion starting from the portion that becomes the center O of the bottom portion 10 (central circular region). A large number of cut lines X1 are formed at equal intervals (see FIG. 2). The first cut line X1 reduces or blocks the induction of eddy currents flowing through the conductive sheet 3 of the peripheral side wall portion 13 of the container formed by folding, and prevents excessive heat generation of the peripheral side wall portion 13. Not only can it be cooked (boiled) at an appropriate temperature, but also damage caused by heating of the dielectric holding member 30 (see FIGS. 5 and 6 described later) in contact with the peripheral side wall portion 13 is damaged. It can be effectively prevented.

The number of such first cut lines X1 that can reduce or cut off the eddy current induced by the high frequency magnetic field during cooking may be appropriately selected according to the size of the container formed by folding. Generally, it is 2 or more, preferably 3 to 40. Further, in FIG. 2, the first cut line X1 extends radially, but may be formed in a curved shape or another shape as long as the eddy current can be reduced or cut off.

Further, as shown in FIG. 2, it is preferable to form a plurality of concentric second cut lines X2 centered on the bottom center O in the region serving as the bottom 10 of the container thus formed. is there. That is, the cut line X2 divides the eddy current flowing through the conductive sheet 3 corresponding to the bottom 10 of the container A formed by folding into each region, and boil at an appropriate temperature in order to prevent excessive heat generation of the bottom 10. It is effective in performing cooking such as. The number of such second cut lines X2 is not particularly limited, but usually may be several.

Further, as shown in FIG. 2, in the region surrounded by the minimum diameter cut line of the second cut line X2, a third cut line extending to the minimum diameter cut line of the second cut line X2 X3 is formed. That is, the third cut line X3 reduces or cuts off the eddy current induced in the central portion of the bottom 10, and effectively causes bumping by partial heating of the central portion of the bottom 10 during cooking (cooking). It is to prevent.
Such a third cut line X3 may extend in a direction of reducing or blocking the induced eddy current, that is, in the minimum diameter cut line of the second cut line X2. For example, in FIG. 2, FIG. Although it is formed in an arc shape, it may be formed in a straight line, and the number thereof is not limited.

The first cut line X1 is not in contact with the maximum diameter cut line of the second cut line X2, and the second cut line X2 is formed in an endped shape, that is, in an arc shape. Further, the third cut line X3 is not in contact with the second cut line X2. Such a pattern has an advantage that damage to the silicone sheet 5 that occurs particularly when forming a cut line can be reliably prevented.

Specifically, the first cut line X1 does not extend to the position of the maximum diameter cut line of the second cut line X2, and the end portion X1a and the second cut line X2 of the first cut line X1. There is a clearance α between the cut line and the maximum diameter cut line. Further, the maximum diameter cut line of the second cut line X2 is not completely endless, and ends X2a and X2a are formed in an arc shape with a part missing, and between the ends. Clearance α is present. Similarly, the third cut line X3 does not extend to the position of the minimum diameter cut line of the second cut line X2, and the end portion X3a of the third cut line X3 and the minimum diameter of the second cut line X2. There is a clearance α between the cut line and the cut line.
That is, the cut lines X1 to X3 penetrating the conductive sheet 3 are formed by processing by laser irradiation (laser processing), but the laser processing is performed repeatedly at the portion where these cut lines come into contact with each other. The heat generated by the heated material (conductive sheet: metal foil such as aluminum foil) tends to cause inconveniences such as damage to the underlying silicone sheet 5 at this portion and holes. This is also the case when the line is formed in a completely circular shape (endless shape) as in the second cut line X2. This is because the laser machining is repeated at the end of the line formed by the laser machining in order to make it completely endless.

However, in the aspect of FIG. 2, the first to third cut lines X1 to X3 are not in contact with each other, a constant clearance α is formed between them, and the second cut line X2 is also formed. A part is cut out to form a clearance α. As a result, it is possible to prevent excessive heating due to repeated laser processing, and it is possible to effectively prevent damage to the silicone sheet 5 due to laser processing.

As the clearance α as described above becomes larger, the above-mentioned effect of the cut lines X1 to X3 decreases. Therefore, this clearance α should have an appropriate size, and is generally preferably about 0.5 to 1.0 mm.

Further, in the clearance α at the maximum diameter cut line of the second cut line X2, a short leakage prevention cut line Y is formed from the extension line of the cut line to the outside. As a result, it is possible to further suppress the reduction of the eddy current in the maximum diameter cut line (leakage to the outer circumference) or the reduction of the blocking effect. On the other hand, in the clearance α at the minimum diameter cut line of the second cut line X2, a short leakage prevention cut line Y is formed from the extension line of the cut line toward the inside. As a result, the eddy current induced in the minimum diameter cut line can be reduced or cut off, and sudden boiling due to partial heating of the central portion can be more effectively prevented during cooking (cooking).
The length of the leakage prevention cut line Y is preferably about 0.5 to 2.0 mm from the extension line of the cut line.

In the heat generating sheet 1 having the above-mentioned basic structure, in the present invention, as shown in FIG. 1, the surface of the silicone sheet 5 (the surface opposite to the conductive sheet 3) is used for reinforcement. It is preferable that the dielectric piece 7 is attached.
That is, when the heat-generating sheet 1 is formed by the two-layer structure of the conductive sheet 3 and the silicone sheet 5 described above, if foodstuffs or the like are put into the container A formed by folding the heat-generating sheet 1, the container loses its shape. Often occurs. For example, as shown in FIG. 6, when a container A formed by folding the heat-generating sheet 1 is placed in the holder 30 to put foodstuffs and cooked by an IH cooker, the container A is held. It may not be possible to set the ingredients 30 according to the shape of the ingredients or to set them in a stable state, which may make cooking difficult.
However, in the present invention, since the reinforcing dielectric piece 7 is provided on the surface of the silicone sheet 5, the container A having a stable shape is formed by folding the reinforcing dielectric piece 7 on the outer surface side. Can be done. That is, when the container A is formed by folding or the like, reinforcing dielectric pieces 7 (a plurality of projecting pieces 23 to be described later) can be present on each of the adjacent fold surfaces, whereby the container A can be formed. The morphology is stably maintained.

Therefore, according to the present invention, when a container A formed by folding is placed in the holder 30 to put foodstuffs and cooked by an IH cooker, the container A is placed along the shape of the holder 30. It can be set or set in a stable state, and cooking with an IH cooker can be performed stably.

The reinforcing dielectric piece 7 is formed of a non-energized material like the silicone sheet 5, but must have higher strength than the silicone sheet 5. If the reinforcing dielectric piece 7 is formed of a material having a strength lower than that of the silicone sheet 5, the reinforcing effect becomes insufficient, and the shape-retaining property of the container A formed by folding becomes insufficient.
Therefore, the reinforcing dielectric piece 7 is formed of a high-strength material that is not energized, and may be formed of a polyester resin such as PET or PEN depending on the strength of the silicone sheet 5, but is generally used. It is best made of paper because it is inexpensive.

Further, the reinforcing dielectric piece 7 is located between the conductive sheet 3 and the IH cooker when the container A formed by folding the heat generating sheet 1 is placed on the IH cooker. .. Therefore, the reinforcing dielectric piece 7 does not hinder the power generation of the conductive sheet 3 by the IH cooker 7 (or the stop of power generation when the sensor overheats), and also hinders the folding into the container shape. Must not be.
Therefore, the thickness of the reinforcing dielectric piece 7 is, for example, about 0.1 to 5 mm, and at the same time, the entire surface of the silicone sheet 5 is not covered, and a part thereof is shown as shown in FIG. It is necessary to expose.

For example, as shown in FIG. 3, the reinforcing dielectric piece 7 is composed of a ring-shaped base portion 21 and a plurality of projecting pieces 23 extending radially outside the ring-shaped base portion 21. In this form, it is attached to the back surface of the silicone sheet 5 (the surface opposite to the conductive sheet 3).
The ring-shaped base portion 21 defines the bottom portion 10 of the container A when the heat-generating sheet 1 is folded to form the container A (see FIGS. 5 and 6), and the plurality of projecting pieces 23 are formed of the container A. It is located at a portion corresponding to the side wall portion 13, and extends radially from the center O (corresponding to the center of the bottom portion 10), but is not formed inside the ring-shaped base portion 21.

As can be seen from FIG. 3, in the region surrounded by the ring-shaped base 21, the surface of the silicone sheet 5 is exposed, whereby when the container A is placed on the IH cooker, the IH cooker When the conductive sheet 3 generates heat via the silicone sheet 5 due to the operation and the bottom 10 of the container A becomes abnormally high during cooking, a sensor provided in the IH cooker detects it. The movement of the IH cooker stops.

Further, the plurality of projecting pieces 23 of the reinforcing dielectric piece 7 located at the portion corresponding to the side wall portion 13 of the container A (that is, the outside of the ring-shaped base portion 21) are provided at intervals from each other. .. As a result, as shown in FIG. 5B, when the container A is formed by folding by folds or the like, the projecting pieces 23 are present on each surface of the folds of the side wall portion 13. The adjacent projecting pieces 23 overlap each other, and the shape of the container A formed by the heat generating sheet 1 can be stably maintained.
If the plurality of projecting pieces 23 of the reinforcing dielectric piece 7 are connected to each other, it is difficult to fold them into the shape of the container A. Therefore, it is important to provide them at intervals as described above.

The number of projecting pieces 23 of the reinforcing dielectric piece 7 is determined in consideration of ease of folding into the container A and shape retention. For example, if the number of projecting pieces 23 is too large, the distance between adjacent projecting pieces 23 becomes narrow, so that it becomes difficult to fold into the shape of the container A, and if the number of projecting pieces 23 is too small, the reinforcing effect is obtained. It becomes diluted and may impair the morphological retention. The specific number of projecting pieces 23 varies depending on the size of the container A formed by folding (the size of the heat generating sheet 1) and the like and cannot be unconditionally specified, but the size of the container A can be determined at home. When the size is about the same as the pot to be used, it is usually about 9 to 27 pots.

Further, in order to strengthen the shape retention of the container A, it is desirable that the number of projecting pieces 23 as described above is an odd number (in the example of FIG. 3, the number of projecting pieces 23 is 19). Is). That is, as shown in FIG. 3, assuming a virtual straight line L extending in the radial direction through the center O, when the number of projecting pieces 23 is set to an even number, this straight line L is different from the projecting pieces 23. Although it extends by contact, when the number of projecting pieces 23 is an odd number, this virtual straight line L always comes into contact with the projecting pieces 23. As can be understood from this, when the number of projecting pieces 23 is an even number, the laminated heat-generating sheet 1 is easily divided into two with the virtual straight line L as a polygonal line. Therefore, such a polygonal line is obtained before cooking. Is formed accidentally, and as a result, the shape-retaining property of the container A is lowered. On the other hand, when the number of projecting pieces 23 is set to an odd number, the virtual straight line L comes into contact with the projecting pieces 23 as shown in FIG. The formation can be prevented, and the morphological retention of the container A can be further enhanced.

Further, in the present invention, the projecting piece 23 as described above preferably has an appropriate distance D from the ring-shaped base portion 21, and is set to a distance of about 1.0 to 20 mm. If this interval D is too small, breakage or deformation is likely to occur when the reinforcing dielectric piece 7 is manufactured by punching or the like, or when the reinforcing dielectric piece 7 is attached to the surface of the silicone sheet 5. .. Further, if this interval D is too large, the reinforcing effect such as buckling of the heat generating sheet 1 may be reduced.

Further, from the viewpoint of ease of folding the heat generating sheet 1, it is desirable that the projecting pieces 23 are not connected to the outer peripheral edge of the ring-shaped base portion 21, but all the projecting pieces 23 are separated from the ring-shaped base portion 21. When the reinforcing dielectric piece 7 is attached to the surface of the silicone sheet 5, the ring-shaped base 21 and the plurality of projecting pieces 23 must be attached separately in a separated state. Therefore, it is preferable to have a structure in which a part of the projecting pieces 23 is connected to the ring-shaped base portion 21 by a thin connecting portion 25. With such a structure, the projecting piece 23 and the ring-shaped base 21 are integrated on the surface of the silicone sheet 5 without impairing the ease of folding the heat generating sheet 1 into the container A and the shape retention of the container A. Can be pasted. Incidentally, in the example of FIG. 3, three projecting pieces 23 out of 19 are connected to the ring-shaped base portion 21.

The reinforcing dielectric piece 7 can be attached to the surface of the silicone sheet 5 by using an adhesive as appropriate depending on the material, but usually, the silicone sheet 5 is attached to the conductive sheet 3. Similar to dressing, it is preferable to use a silicone primer (curable silicone resin, particularly an oligomer of acrylic silicone resin) as an adhesive to integrate them.

In the present invention, for the heat generating sheet 1 having the above-described form, for example, a blank sheet B for forming the reinforcing dielectric piece 7 having the form shown in FIG. 4 is prepared, and this blank sheet B is used. Can be easily manufactured.
As shown in FIG. 4, this blank sheet B was created by punching out a dielectric sheet such as paper, and the punched-out portion 27 was attached with the reinforcing dielectric piece 7. It corresponds to the surface portion of the silicone sheet 5 that is sometimes exposed. In the blank sheet B of this form, the outer end portion of the projecting piece 23 is continuously held by the peripheral edge portion 29, and the ring-shaped base portion 21 is connected and held by the connecting portion 25 to a part of the projecting piece 23. There is.
That is, a long dielectric sheet is punched out, and a large number of punched portions 27 as described above are formed in a row to form a blank sheet B.

Then, while winding a long conductive sheet with a roll, an adhesive (for example, a silicone primer) is appropriately applied to one surface, and a paint (black paint) containing a radiation material (black pigment) is sequentially applied to the other surface. It is applied and a long silicone sheet (for example, a silicone rubber sheet) is laminated on the adhesive surface. The above blank sheet B is continuously attached to the silicone sheet surface of the long laminate produced in this manner. At this time, an adhesive such as a silicone primer is appropriately attached to the affixed surface of the blank sheet B. Is applied. In this way, a long laminate to which the blank sheet B is attached is obtained, appropriately pressure-bonded under heating to firmly bond the silicone sheet and the blank sheet B, and finally cut to a predetermined size. The target heat generating sheet 1 can be obtained.

In the heat generating sheet 1 produced as described above, it is preferable that the surface portion of the exposed silicone sheet 5 of the punched portion 27 has a reduced adhesive force. If this surface portion is sticky, it is difficult to fold the heat-generating sheet 1 into the container A, or when the heat-generating sheet 1 is loaded, the heat-generating sheets 1 adhere to each other, which hinders storage and sales. S.
Such a decrease in adhesive strength can be performed by, for example, a blasting treatment or a roughening treatment such as crimping a rough surface roll, and an anti-blocking agent such as silica particles is blended in the silicone sheet 5. This can also reduce the adhesive strength.

With reference to FIGS. 5 and 6, the above-mentioned laminated heat generating sheet 1 is folded into the form of the container A (see FIG. 5 (b)), for example, a dielectric holding shown in FIG. 5 (a). It is used by being placed in the induction heating part of the IH cooker in a state of being placed in the member 30.

In the present invention, the holding member 30 is also formed of a dielectric material like the silicone sheet 5 and the reinforcing dielectric piece 7 described above. In particular, from the viewpoint of moldability and the like, it is formed of a thermoplastic resin, particularly an olefin resin, and most preferably polypropylene.

As shown in FIGS. 5A and 6, the holding member 30 is formed of an annular wall 31 having a tapered shape having a large diameter at the upper end and a smaller diameter toward the lower end, and is formed at the lower end of the annular wall 31. Is formed with a circumferential flange 33 protruding inward, and a handle 34 is formed at the upper end thereof.

The container A formed from the heat generating sheet 1 of the present invention is housed inside the annular wall 31 of the holding member 30 as described above, and is subjected to cooking by an IH cooker in a stably held state. The annular wall 31 is set to a size capable of accommodating the container A inside the annular wall 31.

In particular, as shown in FIG. 6, the container A formed by folding the heat-generating sheet 1 has a reinforcing dielectric piece 7 by inserting the heat-generating sheet 1 into the annular wall 31 of the holding member 30. The projecting piece 23 rises from the ring-shaped base 21, and the container A in which the heat generating sheet 1 composed of the conductive sheet 3, the silicone sheet 5, and the reinforcing dielectric piece 7 is folded is formed and housed inside the annular wall 31 of the holding member 30. To.
Next, the heat medium and the food material 50 are placed in the container A, and in this state, cooking is performed by an IH cooker.

Although the shape of the heat generating sheet 1 of the present invention has been described above by taking a circular shape as an example, this shape may be rectangular as long as it can be folded into the shape of a container, and the reinforcing dielectric piece 7 may be formed. The shape of the endless second cut line X2 formed on the ring-shaped base 21 or the conductive sheet 3 may also be rectangular, and the planar shape of the annular wall 31 of the holding member 30 is also rectangular. You can.

1: Heat-generating sheet 3: Conductive sheet 5: Silicone sheet 6: Paint layer 7: Reinforcing dielectric piece 10: Bottom 13: Circumferential side wall 21: Ring-shaped base 23: Projection piece 25: Connecting part 27: Punched part 30 : Holding member 31: Circular wall 33: Inner flange 35: Circumferential step portion A: Container B: Blank sheet X1: First cut line X2: Second cut line X3: Third cut line

Claims (5)

It is a heating sheet for IH cookers,
A conductive sheet and a silicone sheet are laminated on one surface of the conductive sheet, and a paint layer is formed on the other surface.
The paint layer is a silicone paint layer,
A heat-generating sheet for an IH cooker, wherein both the silicone sheet and the paint layer contain a radiant material. The heat-generating sheet for an IH cooker according to claim 1 , wherein the radiant material is a black pigment. The heat-generating sheet for an IH cooker according to claim 2 , wherein the black pigment is a carbon-based pigment. According to claim 2 or 3 , the degree of radiation divergence on the paint layer side at a wavelength of 5 μm at 300 ° C. of the silicone sheet and the heat generating sheet for an IH cooker using the paint layer is 380 W · m-2 · μm-1 or more. The heat-generating sheet for an IH cooker described. Claim 1 in which a reinforcing dielectric piece having a strength higher than that of the silicone sheet is attached to the surface of the silicone sheet opposite to the conductive sheet so that a part of the surface of the silicone sheet is exposed. The heat-generating sheet for an IH cooker according to any one of 4 to 4.