JPH0531918Y2 - - Google Patents

Description

[Detailed explanation of the idea] (Industrial application field) The present invention relates to improvements in popcorn containers.

(Prior Art) Conventionally, a popcorn container is known which is constructed by storing popcorn ingredients in the inner bottom of a dish-shaped container made of a heat-resistant material and covering the upper open part of the dish-shaped container with an inflatable metal cover. ing. The above-mentioned container is heated by direct heating, and the popcorn sequentially bursts due to the heating, and the pressure inside the container increases due to the steam generated from the popcorn, so that the metal cover covering the upper opening of the above-mentioned dish-shaped container is heated. The mechanism is such that it expands.

In addition, in the above-mentioned container, a ventilation hole is provided in the metal cover in order to prevent the metal cover from bursting due to an increase in the pressure inside the container due to the steam generated from the popcorn during heating. There is.
This technology is disclosed in US Pat. No. 3,110,233 and others. However, the prior art discloses only holes having a certain area as ventilation holes, and simply providing such holes causes the following problems.

That is, when heating a container at home, etc., the degree of heating generally varies depending on the heating device used, the cook's method, etc. In this regard, if the metal cover is provided with ventilation holes of a certain size in advance, as in the prior art, in order to prevent the metal cover from bursting even if the degree of heating is strong, the ventilation holes are It needs to be enlarged to some extent. This is because a bursting of the metal cover is a dangerous and serious problem, such as burns to the cook. However, when actually heating at home, etc., the degree of heating may be weak, and in this case, the container of the prior art has too many holes, so the internal pressure of the container does not increase, and the metal cover allows sufficient expansion. popcorn may not cook properly. In other words, conventional popcorn containers had a problem in that popcorn could only be cooked well under limited heating conditions.

(Problems to be Solved) The purpose of the present invention is to solve the above-mentioned problems of the conventional method and to provide a popcorn container that allows popcorn to be cooked safely and well regardless of the degree of heating. be.

(Means for Solving the Problems) The present invention was made to achieve the above object, and consists of storing popcorn raw material in the inner bottom of a dish-shaped container made of a heat-resistant material, and A popcorn container is constructed by covering an open part with an inflatable metal cover, and the metal cover is provided with a hole having a certain area, and the hole is covered with a synthetic resin film, and the metal cover is covered with an inflatable metal cover. The object of the present invention is to provide a popcorn container characterized by having a ventilation hole formed by intersecting two or more cut lines or by surrounding a hole having a certain area with cut lines.

Hereinafter, the present invention will be explained in detail based on the drawings.

Figure 1-a is a perspective view showing the popcorn container of the present invention before heating, and Figure 1-b is a perspective view of the popcorn container of the present invention before heating.
FIG. 1-a is a sectional view taken in the C1-C2 direction, and FIG. 2 is a perspective view showing the state of the container shown in FIG. 1-a after heating.

In the drawings, reference numeral 1 denotes a dish-shaped container made of a heat-resistant material such as aluminum, and a popcorn raw material (not shown) is stored in the inner bottom of the dish-shaped container 1. Further, the upper open portion of the dish-shaped container 1 is covered with an inflatable metal cover 2 made of aluminum foil or the like. The metal cover 2 is normally folded before heating (see Figures 1-a and 1-b), and gradually expands as heating progresses (see Figure 2). Note that it is particularly desirable that the metal cover 2 is made of aluminum foil with a thickness of 5 μm to 20 μm so that the metal cover 2 expands well during cooking. The container 1 is provided with a handle 4 for gripping during cooking.

In the present invention, a hole 3 having a constant area is provided in the metal cover 2 of the container 10 having the above structure.
Examples of the shape of the hole 3 include a circle, a substantially circle, a square, a substantially rectangle, and a triangle. The size of the hole 3 is preferably the same as the maximum size when the ventilation hole 8 provided in the synthetic resin film 7 opens along the cut line, or is appropriately larger than this.
For example, it can be about 10 to 200 ^mm2 . Hole 3
By setting the above-mentioned size, the vent hole 8 can be opened to an appropriate size according to the increase in the internal pressure of the container during cooking. Further, the hole 3 can be provided at any location in the metal cover 2, and usually the hole 3 is provided in the metal cover 2.
It can be provided in the center of the

The above hole 3 is covered with a synthetic resin film 7, and the synthetic resin film 7 is provided with two or more cut lines in an intersecting manner, or the cut line is provided around a hole having a certain area. A ventilation hole 8 is provided.

Specifically, examples of the material of the synthetic resin film 7 include films such as polyethylene, polyester, polypropylene, and cellophane, and laminate films thereof. A material obtained by laminating a paper material onto the above-mentioned synthetic resin film or a material obtained by vapor-depositing aluminum onto a synthetic resin film may also be used. In addition, it is particularly desirable to use polyester from the viewpoint of closing the vent hole 8 when unheated and smoothly opening the vent hole 8 as the internal pressure of the container increases during cooking, and from the viewpoint of heat resistance. Further, in order to satisfactorily achieve the above-mentioned functions, the thickness of the synthetic resin film 7 is preferably about 30 to 70 μm in the case of polyester, for example.

Vent holes 8 are formed by intersecting two or more cut lines provided in the synthetic resin film 7.
Examples of the shape include an X-shape, an H-shape, a substantially X-shape, or a substantially H-shape (see FIGS. 3 to 6, which are plan views showing the shapes of the ventilation holes). In addition, a ventilation hole 8 is formed by arranging a cut line around a hole having a certain area.
For example, a hole 5 having a circular, substantially circular, rectangular, substantially rectangular, or triangular shape is formed with 2 to 8 cutting lines 6 radially circumferentially around it (a plan view showing the shape of the ventilation hole). (See Figures 7 to 11). The shape of the ventilation hole 8 is not limited to the illustrated one, and for example, the shape of the ventilation hole 8
The cut line forming the hole 5 may be curved, and the cut line 6 may be provided at any arbitrary location of the hole 5.

The size of the ventilation hole 8 is not particularly limited, but when it is formed with intersecting cut lines, the length of the cut line is about 3 mm to 15 mm, and the cut line 6 is provided around the hole 5. In this case, the area of hole 5 should be 0.2 mm ² to 1
^mm2 , and the length of the cutting line 6 can be about 1 mm to 5 mm. Due to these, even when the heating conditions of the container 10 change, the ventilation hole 8 can sufficiently cope with the change.

When covering the hole 3 with the synthetic resin film 7 described above, make the film 7 appropriately larger than the hole 3, and place the film 7 on the metal cover 2 so that the film 7 covers the hole 3. good. The film 7 can be adhered to the metal cover 2 by dry lamination, for example, using a solvent-based or solvent-free adhesive. The method for installing the film 7 on the metal cover 2 is not limited to the above method, but any other method may be used.
In addition, when installing the synthetic resin film 7 on the metal cover 2, it is desirable that the centers of the holes 3 provided in the metal cover 2 and the ventilation holes 8 provided in the film 7 are aligned with each other.

Next, the operation when using the container 10 of the present invention having the above configuration will be explained with reference to the drawings. 1st
2 and 14 are perspective views showing the state of an X-shaped ventilation hole and a circular hole with cut lines around the circumference when the degree of heating is low, and FIGS. 13 and 15 are FIG. 2 is a perspective view showing the state of an X-shaped ventilation hole and a circular hole with cut lines around the ventilation hole when the degree of heating is high.

The container 10 in the state shown in FIG. 1 is heated by an appropriate means, such as a stove. As heating progresses,
As the popcorn is heated and bursts, water vapor is generated from the popcorn, the pressure inside the container increases, and the metal cover 2 covering the upper opening of the dish-shaped container 1 gradually expands. In this case, when the degree of heating is low or at the initial stage of heating, the amount of water vapor generated from the popcorn is small, so the pressure inside the container does not increase so much, and the ventilation holes 8 of the synthetic resin film 7 are formed along the break line. (No. 12)
), or the portion along the cut line 6 is not opened (see FIG. 14). In other words, the vent hole 8 is opened only to the minimum extent necessary, and therefore the volatilization of water vapor outside the container is suppressed as much as possible to efficiently heat the popcorn, and at the same time, the metal cover 2 can be expanded without resistance.

On the other hand, when the degree of heating is strong or in the middle to final stages of heating, the amount of water vapor generated from the popcorn is large, so the pressure inside the container increases considerably, and the vent hole 8 is wide open along the cut line. (See Figures 13 and 15). In other words, even if a large amount of water vapor is generated inside the container, the vent hole 8 is provided with a variable opening size depending on the pressure inside the container.
This allows a necessary amount of water vapor to escape from the container, preventing the container from bursting and achieving good heating of the popcorn.

(Effect of the invention) According to the popcorn container described in claim (1), by providing the vent hole having a cut line in the synthetic resin film, the vent hole can be adjusted appropriately according to the increase in the internal pressure of the container during cooking. The container opens to the desired size and the required amount of water vapor is discharged outside the container. For this reason,
Even when the degree of heating is high, the metal cover is prevented from bursting, and even when the degree of heating is low, the metal cover is sufficiently inflated. Therefore, regardless of the degree of heating, popcorn can be safely and well cooked. Further, the ventilation hole according to the present invention has a great industrial effect in that it can be easily formed without requiring particularly complicated processes or costs. According to the popcorn container according to claim (2), by specifying the shape of the vent provided in the synthetic resin film, the size of the opening can be changed more sensitively according to the pressure inside the container during cooking. . Therefore, popcorn can be cooked more stably and efficiently.

[Brief explanation of the drawing]

Figure 1-a is a perspective view showing the state of the popcorn container of the present invention before heating, and Figure 1-b is a perspective view of the popcorn container of the present invention.
FIG. 2 is a perspective view showing the state of the container shown in FIG. 1-a after heating. 3 to 11 are plan views showing the shape of the ventilation holes. 12 and 14 are perspective views showing the state of the X-shaped ventilation hole and the circular hole with cut lines around the circumference when the degree of heating is low, and FIGS. 13 and 15 are FIG. 2 is a perspective view showing the state of an X-shaped vent hole and a circular vent hole with cut lines around them when the degree of heating is high. 1...Dish-shaped container, 2...Metal cover, 3,5
... hole, 4 ... handle, 6 ... cut line, 7 ... synthetic resin film, 8 ... ventilation hole.

Claims (1)

[Scope of Claim for Utility Model Registration] (1) A popcorn constructed by storing popcorn raw material in the inner bottom of a dish-shaped container made of heat-resistant material, and covering the upper open part of the dish-shaped container with an inflatable metal cover. A hole with a certain area is provided in the metal cover of the container, and the hole is covered with a synthetic resin film, and two or more cutting lines are provided in the synthetic resin film in an intersecting manner. A popcorn container characterized by having a ventilation hole formed by arranging a cut line around a hole having an area. (2) The container according to claim (1), wherein the ventilation holes provided in the synthetic resin film are formed in an X-shape, an H-shape, a substantially X-shape, or a substantially H-shape.