KR20120044114A - Wind-protection panel with increasing thermal-efficiency and decreasing the emission of carbon for gas range - Google Patents

Abstract

PURPOSE: A wind-protection panel of a gas range is provided to reduce discharges of carbon dioxide, incomplete combustion materials because a height of the wind-protection panel is different and the wind-protection pane is formed into a laminated structure. CONSTITUTION: A wind-protection panel of a gas range comprises an inner wind block panel(510), an outer wind block panel(520), and a s receiving space(530). The inner wind block panel has an empty space in center to be formed on a circumference of ignited fire. The inner wind block panel is formed like a block panel surrounds with a consistent height from the ground. The outer wind block panel and the inner wind block panel are separated with a certain distance. The outer wind block panel is formed like surrounding the inner wind block panel with the consistent height from the ground. The receiving space is located between the outer wind block panel and the inner wind block panel. The receiving space forms a receiver space of a constant volume.

Description

Wind-protection panel with increasing thermal-efficiency and decreasing the emission of carbon for gas range}

The present invention aims to reduce the carbon dioxide emitted when the gas is burned in the stove, such as forming a windshield panel with an overlapping structure inside and outside around the stove burner and forming different heights thereof. It is to propose a heat-efficient low-carbon gas stove windshield to reduce the greenhouse gas emissions in each household by reducing the carbon energy by increasing the heat efficiency by preventing the heat of the stove fire to be released to the outside. In addition, the gas stove windshield blocks the wind blowing from the outside that can be commonly encountered in the use of the stove in the open air also serves to prevent the light off.

A typical cooking appliance for home use is a gas range. It is easy to use and clean, and has pushed out the existing briquettes and has loved housewives for decades. Nowadays, electric ranges are attracting consumers' attention, but gas ranges are still the leading cooker.

Due to the convenience of gas, a simple gas range using butane gas is also widely used. Butane gas ranges are conveniently used in home and outdoor situations where the gas hose can be removed from the constraints of connecting gas hoses.

Important issues related to the use of gas ranges are the ease of cooking and the safety of use due to the increased efficiency of the fire.

Korean public utility model No. 1998-035592 'Gas glenji with a shielding film' is one of the related arts related to increasing the thermal power or cooking efficiency in the use of the gas range, Figure 11 is the Republic of Korea Utility Model No. 1998-035592 is a view showing a gas grease with a barrier film.

Such a conventional utility model No. 1998-035592 'gas grille with a shielding film' is a great 14, the cooking vessel containing the heating object, as shown in Fig. 11, the burner 20 for heating the heating material And, in the gas grill is formed grill portion for cooking fish, etc., the support jaw 12 is formed integrally with the Great 14, the one side is formed with a blocking film 30 to block the wind It is to prevent the burn out by the wind during the combustion by turning the great portion toward the direction of the wind blowing portion formed by the blocking film.

Another conventional technique related to increasing the firepower or cooking efficiency in the use of the gas range is the Republic of Korea Utility Model No. 260643, 'cooking equipment with a flame barrier on the side of the outer bottom of the cooking zone', 12 is a view showing the Republic of Korea Utility Model Registration No. 260643 'cooking utensil made of a flame collection film on the side of the outer bottom surface of the cooking utensil'.

As shown in Fig. 12, the conventional utility model 'cooking tool having a flame collection film on the side of the outer bottom surface of the cooking utensil' has a cylindrical and polygonal cylindrical film on the bottom surface of the cooking utensil so that the flame that is turned on in the stove is cooked. When it touches the bottom surface, the fire is generated evenly over the entire bottom of the cooking zone. In the conventional cooking utensil without membrane, the flame spread to the cylindrical side of the side beyond the bottom, but it controls the cylinder and It has a polygonal barrier.

As a result, the conventional cooking utensils are mainly arc-shaped or flat, and when cooking using a gas stove, the fire of the stove is spread not only to the bottom but also to the cylindrical surface, and there is no film around it. There was a problem that the flame spreads or heat loss occurs a lot. Therefore, in order to solve these problems, the prevention of heat loss and the prevention of fire and explosion accidents, and even in the form of energy consumption, as the combustion of gas produces carbon dioxide, the reduction of carbon dioxide emission causes the greenhouse gas emission, which is the main culprit of global warming. There is a demand for the development of related products that can reduce the risk.

However, while these conventional technologies are trying to increase the heating power or cooking efficiency in the use of the gas range, there are still problems with the use of the gas range, and in particular, the approach in terms of greenhouse gas emission reduction is not attempted at all. Not even.

That is, the conventional Republic of Korea Utility Model No. 1998-035592 'gas grill with a shielding film' of Figure 11, the support jaw 12 is formed integrally with the Great 14, to block the wind to one side Although the purpose of forming the barrier film 30 is to prevent the burn-out caused by the wind during combustion by turning the grate toward the direction of the wind blowing the portion where the barrier film is formed. It does not effectively block the wind blowing from outside to allow the gas to burn.

In addition, the Republic of Korea Utility Model No. 260643 of '12 cooking utensils made of a flame collection film on the side of the outer bottom surface of the cooking utensil ', the bottom surface of the cooking utensils are made of cylindrical and polygonal cylindrical film is turned on in the stove When the flame reaches the bottom of the cooking zone, the flame is evenly generated throughout the bottom of the cooking zone to increase the thermal power. However, although the flame itself spreads evenly on the floor, these cooking utensils are not only difficult to produce but also have beauty. They do not meet the demands, and they are removed from the gas range after cooking. It is also a major problem for secondary safety, including the risk of additional accidents.

In addition, to improve the efficiency of fire and cooking in the process of using the gas range, as well as to solve the conventional problems, as well as a new and efficient structure and technology for devices and devices that can be applied to various fields are urgently requested. There is a situation.

Therefore, an object of the present invention, the innermost plate portion is formed in the form of a hollow space in the center so as to be mounted around the ignition flame ignited in the gas range, the barrier panel is surrounded by a certain height from the ground; An outermost plate part formed to be spaced apart from the innermost plate part by a predetermined distance from the outer surface of the innermost plate part so as to surround the panel at a predetermined height; By including a receiving space portion which is located between the innermost plate portion and the outermost plate portion spaced by a certain distance to form a receiving volume of a predetermined volume; It is to provide a thermally efficient low-carbon gas stove windshield that prevents the ignition state of the gas range from the wind to increase the thermal efficiency of the gas range and reduce the emission of incomplete combustion materials including carbon based on the efficient combustion.

Through this, it is to prevent the emission of the heat of the fire ignited to the outside, and to increase the thermal efficiency of the gas range to reduce the emission of incomplete combustion materials such as carbon dioxide to save gas energy to seek the ultimate goal of reducing greenhouse gas emissions.

In addition, the present invention, the height of the innermost plate portion and the height of the outermost plate portion is formed different from the ground to increase the blocking efficiency against the wind applied from the outside; It is preferable that the height of the outermost plate portion is higher than the height of the innermost plate portion.

In addition, in the present invention, the innermost membrane portion and the outermost membrane portion is the innermost membrane at a point that constantly divides the circumference of the gas stove windscreen to mount the cooking appliances placed on the top of the gas range. It is possible to form at least one or more support protrusions projecting from the upper portion of at least one of the plate portion and the outermost plate portion with a predetermined width. And the at least one support protrusion is deformed into at least one parallel structure for supporting the cooking apparatus mounted on the upper portion of the gas range; It is possible that the upper end of the support protrusion is formed in a flat surface form in order to mount the cooking appliances mounted on the top of the gas range.

In another aspect, the present invention, at least to extend inward in the state of dividing the central portion space in a predetermined ratio inside the innermost plate portion to support the cooking apparatus located in the central portion space inside the innermost plate portion. It further comprises one or more support legs; The at least one support leg is characterized in that it is formed foldable to be able to fold or extend.

In addition, the present invention is connected to the inner side of the gas stove windshield from the outer circumference of the gas stove windshield, at least one so as to pass through the lower portion of the receiving space at the point of constantly dividing the circumference of the gas stove windshield. It is formed by further including a ball; The innermost plate part and the outermost plate part have a width spaced apart from each other; The present gas stove windshield can be formed in one of the shapes necessary for the round shape and the round shape.

In addition, it provides a detailed description of each of the configuration of the present thermally efficient low carbon gas stove windshield according to the present invention, the configuration and the description can be carried out individually or in combination with each other.

Accordingly, the present invention provides the following important effects.

-The thermally efficient low carbon gas stove windshield of the present invention prevents the heat of the gas stove from being discharged to the outside of the burner to increase the thermal efficiency, thereby reducing the carbon energy emission by reducing the gas energy consumption, thereby reducing the greenhouse gas emissions, which is the main culprit of global warming.

In addition, the present invention can block the wind blowing from the outside in the outdoor use of the stove to prevent the light off phenomenon.

In addition, it ensures that combustion in the stove is performed correctly, thereby increasing the safety of the stove and reducing accidents.

It is also expected to attract attention in the industry by presenting solutions that enable efficient gas combustion.

1 is a perspective view of a thermally efficient low carbon gas stove windshield according to an embodiment of the present invention.
Figure 2 is a view showing an example in which the thermal efficiency low carbon gas stove windshield of Figure 1 is used.
Figure 3 is a cross-sectional view for explaining that the thermal efficiency low carbon gas stove windshield of Figure 1 is used.
Figure 4 is a view showing a modified form of the support projections in Figure 1 thermally efficient low carbon gas stove windshield.
5 is a view showing another modified form in preparation for the supporting projection of FIG.
FIG. 6 is a view showing an example in which a support leg is further formed on the thermally efficient low carbon gas stove windshield of FIG. 1; FIG.
7 is a view showing an embodiment showing another modified shape and the actual size for manufacturing the thermally efficient low carbon gas stove windshield of the present invention.
8 is a perspective view of a double square thermally efficient low carbon gas stove windscreen according to another embodiment of the present invention.
9 is a view showing an example in which the thermal efficiency low carbon gas stove windshield of FIG. 8 is used.
FIG. 10 is a view illustrating an example in which a support leg is further formed on the thermally efficient low carbon gas stove windshield of FIG. 8. FIG.
11 is a view showing the Republic of Korea Utility Model No. 1998-035592 'gas grille with a barrier film'.
12 is a view showing the Republic of Korea Utility Model Registration No. 260643 'cooking utensil made of a flame collection film on the side of the outer bottom surface of the cooking utensil'.

Hereinafter, with reference to the drawings will be described in detail the heat-efficient low-carbon gas stove windscreen of the present invention having a function to increase the thermal efficiency and to reduce the carbon and prevent fire off.

1 is a perspective view of a thermally efficient low carbon gas stove windshield according to an embodiment of the present invention, Figure 2 is a view showing an example of using the thermally efficient low carbon gas stove windshield Figure 1, Figure 3 is a thermally efficient low carbon gas stove windshield It is sectional drawing for demonstrating that a board is used.

As shown, the thermally efficient low carbon gas stove windscreen 50 according to an embodiment of the present invention increases the heating efficiency of a roasting plate, a frying pan, a pot, etc., which is placed on the gas range by preventing the ignition state in the gas range from the wind. At the same time, the main purpose of reducing the emission of incomplete combustion materials including carbon series such as carbon dioxide and carbon monoxide according to the efficient combustion, the innermost plate portion 510, outermost plate portion 520 and the receiving space portion ( 530 can be divided into a large configuration. In addition, the gas range used in the present embodiment is a concept including all the ranges using gas such as butane casing and grill gas range.

In addition, in the present embodiment, the test results are shown to be relatively higher than the other forms of the windscreen and thermal efficiency, the innermost plate portion 510 is circular, the outermost plate portion 520 is formed in a rectangular shape, respectively. However, as will be described later, the shapes of the innermost plate part 510 and the outermost plate part 520 may be circular, rectangular, or other forms.

First, in the thermally efficient low carbon gas stove windscreen 50, the innermost plate part 510 is formed with an empty space in the center so as to be mounted around the ignition flame ignited in the gas range, and the panel is surrounded by a certain height from the ground. It is a component that is formed in a falling shape.

Next, the outermost plate part 520 is spaced apart from the innermost plate part 510 by a predetermined distance so that the outermost plate part 510 is surrounded by a predetermined height from the ground on the outside of the innermost plate part 510.

As shown, in the thermally efficient low carbon gas stove windshield 50 of the present embodiment, the innermost membrane portion 510 and the outermost membrane portion 520 have the form of a double rectangular perimeter membrane having a thin plate (panel) structure.

In the thermally efficient low carbon gas stove windscreen 50 of the present embodiment, the innermost plate portion 510 and the outermost plate portion 520 have the present thermally efficient low carbon gas stove windscreen for mounting cookers placed on top of the gas range. At least one support protrusion (510s, 520s) protruding at a predetermined width from one or more of the innermost plate portion 510 and the outermost plate portion 520 is formed at a point where the circumference of the plate is constantly divided. .

In the present embodiment, the support protrusions 510s and 520s are formed in the middle portions of the inner side plate parts 510 and the outermost plate parts 520, respectively, and the support protrusions 510s and 520s are shown. Will support cooking equipment such as grilled meat plates, frying pans, pots, etc., which are raised for cooking in the stove.

In addition to forming one support protrusion (510s, 520s) in the middle portion of each side as in this embodiment, it is also possible to form two or three ..., or more at a certain interval Do. In addition, the deformation of the support protrusions (510s, 520s) will be described later.

In addition, in the thermally efficient low carbon gas stove windshield 50 of the present embodiment, the height of the innermost plate portion 510 and the outermost plate portion 520 of the outer surface of the outermost plate portion 520 may be increased so as to increase the blocking efficiency against the wind applied from the outside. Although the height may be different from each other, in the present thermally efficient low carbon gas stove windshield 50, the outermost plate portion 520 is formed higher than the innermost plate portion 510, which is more generally implemented in this embodiment. The explanation focuses on being.

This is generally related to cookware such as yakiniku, fry pan, pot, etc., which is formed mostly in the form of lower center than the outer edge of the center portion, and the outermost plate part 520 blocks the wind blowing from the outside. It is also associated with the gas flame to be burned in the central portion of the back plate portion 510 to be burned well in a straight state without being scattered in the wind.

In the present embodiment, the receiving space portion 530 is a receiving volume of a predetermined volume which is formed between the innermost plate portion 510 and the outermost plate portion 520 spaced apart by a predetermined distance.

That is, as shown in the receiving space portion 530, the innermost plate portion 510 and the outermost membrane spaced a predetermined distance by connecting the lower end position between the innermost plate portion 510 and the outermost plate portion 520 to each other. The plate part 520 naturally becomes a receiving space. Of course, in the present embodiment, the innermost plate part 510 and the outermost plate part 520 may have a variable width spaced apart from each other.

In addition, the thermally efficient low carbon gas stove windshield 50 of the present embodiment is connected to the inside of the thermally efficient low carbon gas stove windscreen seen from the outer circumference of the thermally efficient low carbon gas stove windscreen as shown, It is also possible to further include at least one or more holes 540 to communicate with the lower portion of the receiving space 530 at a point that constantly divides the circumference of the.

In addition, one of various expected forms will be described later, but the thermally efficient low carbon gas stove windshield 50 of the present embodiment may be variously modified based on the above-described form. In addition, when the combustion in the gas range using the heat-efficient low-carbon gas stove windshield 50 of the present embodiment, efficient combustion is achieved, thereby reducing emissions of incomplete combustion materials including carbon series such as carbon dioxide or carbon monoxide. .

4 is a view showing a modified form of the support protrusion in the thermally efficient low carbon gas stove windshield according to an embodiment of the present invention, Figure 5 is a view showing another modified form in comparison to the support protrusion of Figure 4;

In the thermally efficient low carbon gas stove windscreen 50 of the present embodiment, the innermost plate portion 510 and the outermost plate portion 520 are thermally efficient low carbon gas stove windscreens for mounting cookers placed on top of the gas range. At least one of the innermost plate part 510 and the outermost plate part 520 is formed at a point that divides the circumference of at least one of the at least one support protrusion protruding with a predetermined width.

The support protrusions 510s and 520s formed in each of the innermost plate part 510 and the outermost plate part 520 may be modified in various forms. The support protrusions 510s and 520s of the type as shown in FIG. 5 will be described.

First, in the thermally efficient low carbon gas stove windshield 50 of the present embodiment, the support protrusion is deformed and formed in at least one or more parallel structure to support the cooking apparatus mounted on the upper portion of the gas range.

As an example of this case, as shown in FIG. 4, the structures of the support protrusions 510s and 520s of the thermally efficient low carbon gas stove windscreen 50 are deformed in a dual form, which is the support protrusions 510s of the innermost plate part 510. ) And the support protrusion 520s of the outermost plate part 520 may each have a dual structure. Therefore, the thermally efficient low carbon gas stove windscreen 50 as a whole, any one of the support protrusions 510s of the innermost plate portion 510 and the support protrusions 520s of the outermost plate portion 520 may be modified or both. It may be modified.

In another modified form, in the thermally efficient low carbon gas stove windshield 50 of the present embodiment, the upper end of the support portion for mounting the cooking appliances mounted on the upper portion of the gas range is provided with a flat surface. .

As an example of this case, as shown in FIG. 5, the support protrusions 510s and 520s formed on the top of the membrane panel 500p are deformed to have the extended support surfaces 510sa and 520sa so that the support portions are wider.

FIG. 6 is a view illustrating additionally forming a support leg on a thermally efficient low carbon gas stove windshield according to an embodiment of the present invention.

As shown, the heat-efficient low-carbon gas stove windshield 50 of the present embodiment is to support the cooking appliances located in the central portion space inside the innermost plate portion 510, the innermost plate portion 510 of the It is possible to further form at least one or more support legs 550 extending inwardly in a state of dividing the central space at a predetermined ratio from the inside.

The support leg 550 may be formed in a shape necessary to be able to fold or fold in a folding manner. In this embodiment, even if the size of the various cooking appliances placed on the gas range may be folded to the innermost plate portion 510 so that all of them can be used, or to spread to the empty space in the center of the innermost plate portion 510. It is also possible to form in a foldable form, this embodiment will be described with a focus. However, the support leg 550, which is additionally formed, may be designed in various forms such as a fixed type.

In addition, the thermally efficient low carbon gas stove windshield 50 of the present embodiment, in addition to forming a rectangular shape as described above, the innermost plate portion 510 and the outermost plate portion 520 are circular, hexagonal, octagonal and other polygonal shapes. It is possible to form, in this case, the support protrusion is formed in a position where the interval is jumped to some extent so as to be a position that can support a variety of cooking apparatus placed on the gas range well.

The thermally efficient low carbon gas stove windshield 50 of the present embodiment is generally formed by casting a molten metal into a mold and casting it into a mold casting, that is, die casting. It is also possible to form a metal by tapping or rolling and cutting other iron metals.

In addition, various cooking appliances placed on the gas range are also preferably formed in accordance with the technology and shape of the thermally efficient low carbon gas stove windshield 50 of this embodiment.

For example, as shown in FIGS. 2 and 3, it is preferable to form a plurality of insertion grooves 600h in the lower portion of the grill plate 60 so that the support protrusions 510s and 520s can be safely inserted or inserted. Therefore, there is also a variety of cooking appliances mounted on the upper portion of the gas range using the thermally efficient low carbon gas stove windscreen 50 of the present embodiment.

In addition, as will be understood from the description so far, the thermally efficient low carbon gas stove windshield 50 of the present embodiment effectively prevents wind from the outside, so that combustion in the gas range is efficiently performed without scattering around. Ensuring that combustion is done properly has many additional effects, such as increasing the safety of the stove and reducing accidents.

7 is a view showing an embodiment showing another modified shape and the actual size for manufacturing the thermally efficient low carbon gas stove windshield of the present invention.

As illustrated, the thermally efficient low carbon gas stove windshield 50 of the present embodiment is deformed in a state in which the support legs 550 are formed in a ring at the top, unlike in the previous embodiments, and the number is five.

The length of one side of the thermally efficient low carbon gas stove windscreen 50 is 220 mm in the shape of a rounded corner, and the innermost plate part 510 formed in a circular shape has a diameter of 180 mm.

Unlike the above, there is no support protrusion of the innermost plate part 510, and the outermost plate part 520 has a height of 37 mm and a height of the support protrusion 520 s is about 54 mm.

This embodiment is just one of the various deformable forms of the present thermally efficient low carbon gas stove windshield 50 described above, the technical purpose intended in the present invention is applied.

In addition to the embodiments or contents of the other modifications will be described later, the heat-efficient low-carbon gas stove windshield 50 can be mounted on the burner pedestal (trivet) of all existing gas stoves, which are the most used these days In addition to the five can be installed directly on top of the existing product, there are additional effects to use this product by providing alternative five to three, four or six.

8 is a perspective view of a double square thermally efficient low carbon gas stove windshield according to another embodiment of the present invention, Figure 9 is a view showing an example in which the thermally efficient low carbon gas stove windshield of Figure 8 is used, Figure 10 8 is a view showing an example in which the supporting leg is further formed on the thermally efficient low carbon gas stove windshield.

As shown in the drawing, another embodiment of the thermally efficient low carbon gas stove windshield 50 of the present invention is a case where both the innermost membrane portion 510 and the outermost membrane portion 520 are formed in a rectangular shape. In this embodiment, the innermost plate part 510 is formed in a rectangular shape, and the effective part such as reducing the efficiency of combustion or the emission of incomplete combustion materials including carbon series such as carbon dioxide or carbon monoxide is improved. And there is no big difference.

Finally, the present invention has been described with reference to some specific embodiments, but the present invention is not limited to these embodiments, and the present invention in the claims and the detailed description of the present invention together with the embodiments simply applied in combination with the known art. Not only can various modifications be made by those skilled in the art, but these various implementations will belong to the scope of the present invention.

50: thermally efficient low carbon gas stove windshield
510: innermost plate part
510s: Supporting protrusion 510sa: Extended support surface
520: outermost plate part
520s: Supporting protrusion 520sa: Extended support surface
530: receiving space
540: tong
550: support leg
60: roasted meat 600h: insertion groove

Claims (11)

In the device for preventing wind in the gas range,
An innermost membrane portion formed in a shape such that an empty space is formed at the center so as to be mounted around the ignition flame ignited in the gas range, and the membrane panel is surrounded by a predetermined height from the ground;
An outermost plate part formed to be spaced apart from the innermost plate part by a predetermined distance from the outer surface of the innermost plate part so as to surround the panel at a predetermined height;
By including a receiving space portion which is located between the innermost plate portion and the outermost plate portion spaced by a certain distance to form a receiving volume of a predetermined volume;
The thermally efficient low carbon gas stove windshield of the gas range to prevent the ignition state from the wind to increase the thermal efficiency of the gas range and reduce the emission of incomplete combustion materials including carbon-based according to the efficient combustion.
The method according to claim 1,
The heat-efficient low-carbon gas stove windscreen is characterized in that the height of the innermost plate portion and the height of the outermost plate portion is formed different from the ground to increase the efficiency against the wind applied from the outside.
The method according to claim 1,
A thermally efficient low carbon gas stove windscreen is characterized in that the height of the outermost plate portion is formed higher than the height of the innermost plate portion.
The method of claim 1, wherein the innermost plate portion and the outermost plate portion
Protruding from the top of any one or more of the innermost plate portion and the outermost membrane plate portion at a point where the circumference of the gas stove windshield plate is regularly divided to mount the cookers mounted on the upper portion of the gas range. A thermally efficient low carbon gas stove windscreen, characterized by forming at least one support protrusion.
The method according to claim 4, wherein the at least one support protrusion is
Thermally-efficient low-carbon gas stove windshield, characterized in that formed in at least one support structure for mounting the cooking apparatus mounted on the top of the gas range in parallel.
The method according to claim 4, wherein the at least one support protrusion is
A thermally efficient low carbon gas stove windscreen, characterized in that the upper end of the support protrusion is formed in a flat surface to mount the cooking appliances mounted on the top of the gas range.
The method of claim 1, wherein the innermost plate portion and the outermost plate portion
A thermally efficient low carbon gas stove windshield, characterized in that the width is spaced apart from each other can be formed.
The method according to claim 1,
At least one support leg extending inwardly in a state of dividing the central portion space at a predetermined ratio from the inside of the innermost sheet portion to support the cooking apparatuses located in the central portion space inside the innermost sheet portion. A thermally efficient low carbon gas stove windshield further comprising a further formed.
The method of claim 8, wherein the at least one leg
A thermally efficient low carbon gas stove windscreen, characterized in that it is formed to be folded so that it can be folded or unfolded.
The method according to claim 1,
At least one or more passages are connected to the inside of the gas stove windshield from the outer circumference of the thermally efficient low carbon gas stove windshield, and to pass to the lower portion of the receiving space at a point that constantly divides the circumference of the gas stove windshield. Thermally efficient low carbon gas stove windshield, characterized in that it is formed.
The method according to claim 1, wherein the gas stove windshield,
A heat-efficient low-carbon gas stove windshield, characterized in that the overall form can be formed into one of the necessary shapes, round and square.

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