JPH0440604Y2 - - Google Patents

Description

[Detailed description of the invention] [Technical field] This invention is a gas that is heated downward by a burner located at the top and used to grill grilled meat, fish, etc. placed on a receiving net at the bottom. It is related to pottery.

[Background Art] Generally, in this type of gas grill, an infrared burner with the bottom surface serving as the combustion surface is placed at the top.
It consists of a receiving net placed at the bottom, and the meat is placed in the receiving net.
Grilled foods such as fish are placed on it, and the roasted foods are fired using infrared rays radiated downward from an infrared burner. However, the infrared rays emitted from the combustion surface of an infrared burner are mainly called near-infrared rays, which have short wavelengths, and are easily reflected by the surface of the object to be fired, making it difficult for them to penetrate into the inside of the object. Need to bake for an hour. For this reason, if the item to be baked is baked in a high temperature atmosphere for a long time, there will be a lot of drips flowing out and the taste will be lost, the meat will become hard, the surface will burn black and the appearance will deteriorate, and the inosinic acid will fly away. However, there was a problem that the taste was reduced by half.

[Purpose of the invention] This invention was made in view of the above points, and the purpose of the invention is to heat the inside of the pottery with far infrared rays quickly, and to bake the pottery in a short time. To provide a gas grilling device which can grill deliciously by preventing the outflow of drips and which does not cause the surface to become black and lose its appearance and taste.

[Disclosure of the invention] The gas grilling device of the present invention has a burner 1 at the bottom that heats downward, and a receiving net 3 on which a pottery 2 can be placed at the bottom. A far-infrared emitting ceramic plate 4 that emits infrared rays is placed below the combustion surface 5 of the burner 1 at intervals, and the fitting part 17 of the mounting bracket 16 is fitted onto the outer periphery of the burner 1, and the fitting part 17 of the mounting bracket 16 is fitted onto the outer periphery of the burner 1. U-shaped holding parts 19 are provided on both sides of the joining part 17 via spacer parts 18, and the edges of the far-infrared emitting ceramic plate 4 are fitted into the holding parts 19, and the structure is as described above. This solves the drawbacks of the conventional example. In other words, the far-infrared emitting ceramic plate 4, which emits far-infrared rays when heated, is placed on the combustion surface 5 of the burner 1.
By arranging them at intervals below, the far-infrared emitting ceramic plate 4 is heated by combustion on the combustion surface 5 of the burner 1 and is irradiated with a large amount of far-infrared rays, so that the far-infrared rays penetrate into the inside of the pottery 2. The inside of the pot can be baked in a short time, and since the inside of the pot is baked in a short time, there is no leakage of drips and the product can be baked deliciously.Furthermore, the surface of the pottery 2 is not black and burnt and has a good appearance. At the same time, inosinic acid increases, making it delicious.

The present invention will be explained in detail below with reference to examples.

The far-infrared emitting ceramic used in this invention emits a large amount of infrared rays (wavelength 5.6-1000 microns), which has the longest wavelength in the infrared region (wavelength 0.76-1000 microns) when heated. Although any suitable material can be used, it is preferable to use the material provided in Japanese Patent Publication No. 47-25010 (Patent No. 790172). That is, this material is a mineralizer consisting of 60% ZrO ₂ /SiO ₂ by weight, at least one metal oxide selected from the group consisting of oxides of iron, cobalt, nickel, and chromium, and manganese oxide. It is a black zirconia-based ceramic obtained by firing a base mixture consisting of up to 15% clay and the remainder clay at at least the porcelain forming temperature. The main components of this ceramic are ZrO ₂ and SiO ₂ , and manganese oxide is an important component of the mineralizing agent used to prepare this ceramic. If manganese oxide is not used, the product will not be black and will not have sufficient radiation properties as a black body. However, it is also not suitable if the mineralizer consists only of manganese oxide. In other words, the ceramics obtained in that case are black only on the surface and not black on the inside. Therefore, as a mineralizing agent, at least one of oxides of iron, cobalt, nickel and chromium is used.
It is desirable to use seeds together with manganese oxide,
If these compositions change, the color of the ceramic produced will change; for example, if iron oxide is used in combination, a large amount will produce a blue-black product, whereas a small amount of iron oxide will produce a brown-black product. of products are obtained. From an economic point of view, it is desirable that this mineralizing agent consists of manganese oxide and iron oxide, and if necessary, one or more other metal oxides may be used as part or all of the iron oxide. It is better to use it instead. Mineralizing agent accounts for 15% of the total (weight%, same below)
It is best to use manganese oxide in an amount of up to 10%. The remaining component of the green mixture is clay. Clay is not necessarily an essential component, and the ceramics used in the present invention can be made only from ZrO ₂ and SiO ₂ as mineralizers.
However, in order to increase the plasticity of the base mixture and improve its moldability, it is desirable to use clay. The ceramics are manufactured by molding and firing a mixture of these base components in a conventional manner. In other words,
The mixture is kneaded with an appropriate amount of water, shaped by various means, dried, and fired. Firing is carried out by heating to at least the porcelain temperature, but generally 1260
A temperature of about 1,450°C, particularly 1,280 to 1,380°C is preferred. Firing can be carried out in a normal porcelain firing atmosphere. The optimal usage amounts of each of these base ingredients are as described above, but in general, when ZrO ₂ / SiO _{2 is} 60% or less, clay is used at 30% or more, or mineralizer is used at 15% or more, the fire resistance of the product is or the firing temperature range decreases, making it impossible to obtain good ceramics. Within the above specified amount range, by increasing ZrO ₂ / SiO ₂ and decreasing the clay content or mineralizing agent, the firing temperature can be increased, and the product usage temperature can also be increased. . The ceramics obtained as described above have a number of desirable characteristics compared to ordinary porcelain or white zircon porcelain. First, it has the unique property of emitting a large amount of long-wavelength infrared rays, that is, far infrared rays, when heated. Second, although it varies slightly depending on the ingredients, firing conditions, etc.,
It is to exhibit a black color such as gray-black, blue-black, pure black, etc. This means that it absorbs heat well and efficiently converts it into far infrared rays. Thirdly, it has higher hardness and bending strength than ordinary porcelain or white zircon porcelain (at least mechanical strength is greater than quartz), and has high wear resistance.
Moreover, it is a good conductor of heat and has the characteristic of not easily accumulating heat.

Using far-infrared emitting ceramics constructed as described above, a gas pottery appliance is constructed as shown in FIGS. 1 and 2. The receiving tray 6 having an open upper surface is formed in the shape of a rectangular plate, and the receiving net 3 is removably placed in the upper opening. A leg part 7 is provided protruding from the lower surface side of the receiving net 3, and the leg part 7 is installed therein. A stand-up rod 8 is provided projecting above one end of the tray 6, and one end of a casing 9 disposed above the tray 6 is attached to the upper end of the stand-up rod 8. This housing 9 is open at the bottom, and inside the housing 9
A burner 1 whose lower surface is a combustion surface 5 is installed inside. The burner 1 in this embodiment is an infrared burner, and a combustion surface 5 made of porous ceramics is provided on the lower surface of the mixing chamber 10. A governor 11 is provided at the base of the burner 1, and a gas supply pipe 12 is introduced into the governor 11.
When gas is supplied from 2, air is sucked in from the primary air hole 13 and mixed in the mixing chamber 10. By igniting the mixed gas ejected from the combustion surface 5 with an ignition device (not shown), It is designed to burn and generate infrared rays while taking in secondary air. A far-infrared emitting ceramic plate 4 made of the above-mentioned far-infrared emitting ceramic is mounted below the combustion surface 5 of the burner 1 at a distance from the combustion surface 5. In this embodiment, the far-infrared emitting ceramic plate 4 is a rectangular flat plate, as shown in FIG. can be,
A through hole 15 is bored in the center as required. This far-infrared emitting ceramic plate 4 is mounted using a mounting bracket 16 as shown in FIG. The fitting 16 is formed by bending a metal plate having spring properties, and has a fitting part 1 that can be fitted to the outer periphery of the burner 1.
7, a U-shaped spacer portion 18 integrally extending from the lower end of the fitting portion 17, and a U-shaped holding portion 19 integrally extending from the spacer portion 18. The fitting part 17 of this fitting 16 is fitted onto the burner 1, and a spacer part 1 is attached to the bottom side of the combustion surface 5.
The end edge of the far-infrared emitting ceramic plate 4 is fitted to the holding portion 19 via the far-infrared ray emitting ceramic plate 4 . At this time, a distance of 5 to 15 mm is maintained between the combustion surface 5 and the far-infrared emitting ceramic plate 4 by the spacer part 18, and by changing the height of the spacer part 18, the combustion surface 5 and the far-infrared emitting ceramic plate 4 can be separated. It is now possible to change the spacing between. In this embodiment, the far-infrared emitting ceramic plate 4 was attached using the mounting bracket 16, but a spacer may be interposed between the combustion surface 5 and the far-infrared emitting ceramic plate 4 and the far-infrared emitting ceramic plate 4 may be suspended with a wire. The radiant ceramic plate 4 and the combustion surface 5 may be attached by any means as long as they can be attached while maintaining a constant distance between them. In the above embodiment, an infrared burner is used as the burner 1, but any burner that heats downward may be used. In addition, reflectors 20 are provided on both sides of the housing 9.
is installed.

When cooking, the grilled food 2 such as meat or fish is placed on the receiving net 3 and the burner 1 is ignited. Then, it burns on the combustion surface 5 of the burner 1, the far-infrared ray emitting ceramic plate 4 is heated by this heat, and the pottery 2 is irradiated with far-infrared rays. Heat is absorbed into the inside of the pottery 2 by this far-infrared irradiation, and the heat reaches the inside of the pottery 2 quickly.
is fired. At this time, if the reflector 20 is present, the far infrared rays are reflected downward and are concentrated on the pottery 2 without escaping to the pottery 2. Furthermore, if the distance between the combustion surface 5 and the far-infrared emitting ceramic plate 4 is set to 5 to 15 mm, the combustion surface 5 of the burner 1
Combustion is carried out stably and heat is effectively transferred to the far-infrared emitting ceramic plate 4.
In other words, if the gap is less than 5 mm, the secondary air will not be smoothly supplied to the combustion surface 5 and stable combustion will not occur, and if the gap is more than 15 mm, the far-infrared emitting ceramic plate 4 will not be heated. Poor transmission efficiency. In addition, a through hole 1 is provided in the far infrared ceramic plate 5.
5, a part of the infrared rays from the direct combustion surface 5 is irradiated onto the pottery 2, resulting in a burnt and appetizing appearance.

[Effects of the invention] As described above, in the present invention, far-infrared emitting ceramic plates that emit far-infrared rays when heated are arranged at intervals below the combustion surface of the burner. The far-infrared emitting ceramic plate is heated and irradiated with a large amount of far-infrared rays, and the far-infrared rays penetrate into the inside of the pottery and fire it in a short time. By being burned over a period of time, there is no leakage of drips, making it possible to bake deliciously and tenderly.Furthermore, the surface of the pottery becomes black and does not burn, making it look better, and the amount of inosinic acid increases, making it more delicious. Since it is fired by irradiating infrared rays, the pottery does not have a mesh or burnt black like those that are fired from below, and it has a better appearance.Furthermore, since it is heated using a burner as a heat source, Compared to using an electric heater, etc., a large amount of heat can be obtained and a large amount of far-infrared rays can be irradiated, so baking can be done quickly in a shorter time, and the energy cost can be lowered. The fitting part of the mounting bracket is fitted onto the outer periphery of the burner, and U-shaped holding parts are provided on both sides of the fitting part of the mounting fitting via spacer parts, and the edge of the far-infrared emitting ceramic plate is attached to the holding part. Even if the burner heats downward, the far-infrared emitting ceramic plate can be easily attached below the burner using the mounting bracket, and the far-infrared rays can be emitted at a predetermined distance below the burner. The radiant ceramic plate can be attached to it, and by preparing multiple types of mounting brackets with different spacing between the spacer parts, it is easy to change the spacing between the far-infrared radiating ceramic plate and the burner by replacing the mounting bracket. It is possible.

[Brief explanation of the drawing]

Fig. 1 is a schematic sectional view of one embodiment of the present invention;
The figure is a perspective view of the same as above, Fig. 3 is a front sectional view of the main part of the above, Fig. 4 is a side sectional view of the main part of the same as above, and Fig. 5 shows the far-infrared emitting ceramic plate with the mounting bracket attached. FIG. 6 is a perspective view of the far-infrared emitting ceramic plate shown above, and FIG. 7 is a perspective view of the mounting fittings shown above. 1 is a burner, 2 is a pottery, 3 is a receiving net, and 4 is a far-infrared radiation Ceramic plate 5, combustion surface 16 is a fitting, 17 is a fitting part, 18 is a spacer part,
19 is a holding section.

Claims (1)

[Claims for Utility Model Registration] [1] A gas pottery device that has a burner in the upper part that heats downward and a receiving net in the lower part on which the pottery can be placed, which emits far infrared rays when heated. Far-infrared emitting ceramic plates are placed below the burner at intervals, and the fitting part of the mounting bracket is fitted to the outer periphery of the burner.
A gas pottery appliance comprising a U-shaped holding part provided on both sides of a fitting part of the mounting fitting via a spacer part, and an end edge of the far-infrared emitting ceramic plate being fitted into the holding part. [2] The gas grilling appliance according to claim 1, which has reflective plates on both sides of the burner. [3] The gas roasting appliance according to claim 1 or 2, wherein the distance between the combustion surface of the burner and the far-infrared emitting ceramic plate is 5 to 15 mm. [4] The gas pottery appliance according to claim 1, 2, or 3 of the utility model registration claim, wherein the far-infrared ceramic plate has through holes.