An energy-concentrating component and a gas stove

By designing a rotatable support component for the energy-concentrating assembly, the problem of poor boiler size adaptability in the existing technology has been solved, achieving stable support and efficient heating.

CN224434491UActive Publication Date: 2026-06-30IWATANI GAS APPLIANCES (ZHUHAI) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
IWATANI GAS APPLIANCES (ZHUHAI) CO LTD
Filing Date
2025-06-06
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing energy-concentrating components cannot adapt to boilers of different sizes, resulting in problems such as high heat loss or unstable boiler placement.

Method used

Design an energy-concentrating assembly comprising a base, a windproof ring, and a rotatable support. The rotation of the support adapts to different boiler sizes, provides stable support, and improves heating efficiency through a double-layer energy-concentrating structure of inner and outer rings.

Benefits of technology

It achieves stable support and uniform heating for boilers of different sizes, reduces heat loss, and improves heating efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses an energy-concentrating component and a gas stove. The energy-concentrating component includes: a base with an upward-facing cavity; a windproof ring connected to the bottom side of the base, with the top side of the windproof ring located below the top side of the base; and a bracket connected to the bottom side of the base. The bracket is equipped with a rotatable support member, with the top surface of the support member serving as the support surface. The support surface can rotate downwards to enter the windproof ring or upwards to protrude from the windproof ring. Multiple brackets are arranged around the windproof ring. This utility model adapts to different boiler sizes by rotating multiple support members, providing stable support for the boiler. Furthermore, the double-layer energy-concentrating structure of the inner and outer rings provides a uniform heating environment for the boiler, which helps reduce heat loss and improve heating efficiency.
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Description

Technical Field

[0001] This utility model relates to the field of stove technology, and in particular to an energy-concentrating component and a gas stove. Background Technology

[0002] The heat-concentrating component is a crucial structural element of a gas stove, comprising a heat-concentrating ring for wind deflection and heat loss reduction, and supports for the boiler. Currently, heat-concentrating components typically involve multiple supports directly fixed to the heat-concentrating ring, collectively supporting the boiler. However, in practice, because the positions of the supports and the heat-concentrating ring are relatively fixed, when the boiler is small and the distance between the boiler and the heat-concentrating ring is large, the ring's wind deflection and heat concentration are poor, resulting in significant heat loss. When the boiler is large, exceeding the space limit that the supports can accommodate, the boiler cannot be placed or is placed unstable. Therefore, there is an urgent need for a heat-concentrating component that can better accommodate different boiler sizes to improve the versatility of gas stoves. Utility Model Content

[0003] The purpose of this utility model is to provide an energy-concentrating component and a gas stove to solve one or more technical problems existing in the prior art, and at least provide a beneficial option or create conditions.

[0004] An energy-concentrating component according to a first aspect embodiment of the present invention includes:

[0005] The base is enclosed to form an upward-facing cavity;

[0006] A windproof ring is connected to the bottom side of the base, and the plane on the top side of the windproof ring is located below the plane on the top side of the base;

[0007] A bracket is connected to the bottom side of the base. The bracket is provided with a rotatable support member with the top surface of the support member as the support surface. The support surface can rotate downward to enter the windproof ring or rotate upward to protrude from the windproof ring. The bracket is provided with multiple such members around the windproof ring.

[0008] This technical solution has at least the following beneficial effects: The base is installed inside an external gas stove, forming a cavity for internal ignition and heating. The sidewalls of the base itself form an outer ring within the cavity that can block wind and concentrate energy. A windproof ring is installed on the bottom side of the base and forms an inner ring within the base that can block wind and concentrate energy. In use, the boiler is placed on multiple supports, with the supports abutting against the boiler for support. When the boiler is small, the multiple supports rotate downwards into the fireproof ring, and the boiler presses down against the multiple supports. At this time, the multiple support surfaces are inclined against the outside of the boiler to provide limiting support, and the supports themselves can... The direct heat transfer to the boiler is increased, and the inner ring formed by the fireproof ring can directly block wind and concentrate energy around the boiler, effectively improving the heating efficiency of the boiler. When the boiler is large, multiple support components rotate upwards until their support surfaces protrude beyond the fireproof ring. The boiler presses down on the multiple support components, at which point the multiple support surfaces abut against the bottom side of the boiler to provide support. The outer ring formed by the bottom support sidewall can block wind and concentrate energy around the boiler. In this way, the rotation of multiple support components can adapt to different boiler sizes, providing stable support for the boiler. Furthermore, the double-layer energy-concentrating structure of the inner and outer rings can provide a uniform heating environment for the boiler, which helps to reduce heat loss and improve heating efficiency.

[0009] According to some embodiments of the present invention, the top of the bracket is provided with an arc-shaped convex corner on the side near the center of the base, and the bottom side of the support member is provided with a connecting groove. The arc-shaped convex corner is rotatably connected to the connecting groove. When the support member is rotated upward to protrude from the windproof ring, the bottom side of the support member abuts against the top side of the bracket.

[0010] According to some embodiments of the present invention, the bracket is connected to the base at a position outside the windproof ring, and the windproof ring is provided with a clearance hole for avoiding the support member.

[0011] According to some embodiments of the present invention, the base has a supporting boss at its bottom corner, and multiple supporting bosses are arranged around the base, with multiple brackets respectively connected to the top side of the multiple supporting bosses.

[0012] According to some embodiments of the present invention, the plurality of brackets and the plurality of supporting bosses are detachably connected.

[0013] According to some embodiments of the present invention, the bottom side of the windproof ring is provided with a plurality of supporting ribs, the plurality of supporting ribs abutting against the bottom side of the base, and the plurality of supporting ribs abutting against the side of the plurality of supporting bosses near the center of the base.

[0014] According to some embodiments of the present invention, the bracket has an upwardly protruding limiting portion formed on the side away from the center of the base.

[0015] According to some embodiments of the present invention, the limiting part is provided with a limiting concave corner near the center of the base.

[0016] According to some embodiments of the present invention, a plurality of locking teeth are provided on the top side of the support surface along the length direction of the support surface.

[0017] A gas stove according to a second aspect of the present invention includes a furnace body and the aforementioned energy-concentrating component, wherein the base is connected to the furnace body.

[0018] The technical solution has at least the following beneficial effects: When the furnace body is ignited and burning, due to the energy-concentrating components mentioned above in the furnace body, the rotation of multiple support components can adapt to different boiler sizes, providing stable support for the boiler. Furthermore, the double-layer energy-concentrating structure of the inner and outer rings can provide a uniform heating environment for the boiler, which helps to reduce heat loss and improve heating efficiency.

[0019] Additional aspects and advantages of this invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. Attached Figure Description

[0020] To more clearly illustrate the technical solutions in the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly explained below. Obviously, the described drawings are only a part of the embodiments of this utility model, and not all of them. Those skilled in the art can obtain other design schemes and drawings based on these drawings without creative effort.

[0021] Figure 1 This is a schematic diagram of the overall exploded structure of the gas stove of this utility model.

[0022] Figure 2 This is a three-dimensional view of the gas stove of this utility model after assembly.

[0023] Figure 3 This is a top view of the gas stove of this utility model.

[0024] Figure 4 yes Figure 3 A schematic diagram of the AA cross-sectional structure.

[0025] Figure 5 This is a schematic diagram showing the switching of the usage status of the support components on the bracket.

[0026] In the attached diagram: 100-bottom support, 110-cavity, 120-support boss, 200-windproof ring, 210-avoidance hole, 220-support rib, 300-bracket, 310-support component, 311-tooth, 320-arc-shaped convex corner, 330-limiting part, 331-limiting concave corner, 400-furnace body. Detailed Implementation

[0027] The embodiments of this utility model are described in detail below. Examples of these embodiments are shown in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and are only used to explain this utility model, and should not be construed as limiting this utility model.

[0028] In the description of this utility model, it should be understood that the directional descriptions, such as up, down, front, back, left, right, etc., indicate the directional or positional relationship based on the directional or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.

[0029] In the description of this utility model, "several" means one or more, "multiple" means two or more, "greater than," "less than," and "exceeding" are understood to exclude the stated number, while "above," "below," and "within" are understood to include the stated number. If "first" or "second" is used in the description, it is only for the purpose of distinguishing technical features and should not be construed as indicating or implying relative importance, or implicitly indicating the number of indicated technical features, or implicitly indicating the order of the indicated technical features.

[0030] In the description of this utility model, unless otherwise explicitly defined, terms such as "setting," "installation," and "connection" should be interpreted broadly, and those skilled in the art can reasonably determine the specific meaning of the above terms in this utility model in conjunction with the specific content of the technical solution.

[0031] Reference Figures 1 to 5According to a first aspect of the present invention, an energy-concentrating component includes a base 100, a windproof ring 200, and a support 300. The base 100 forms an upward-facing cavity 110. In practical applications, an opening is provided at the center of the bottom side of the base 100 for inserting the burner into the cavity 110 for combustion when installed in an external gas stove. The windproof ring 200 gradually increases in inner diameter from bottom to top, forming a trumpet-shaped structure. The windproof ring 200 is connected to the bottom side of the base 100. The plane on the top side of the windproof ring 200 is located below the plane on the top side of the base 100; the bracket 300 is connected to the bottom side of the base 100, and the bracket 300 is provided with a rotatable support member 310, with the top surface of the support member 310 as the support surface. The support surface can rotate downward to enter the windproof ring 200 or rotate upward to protrude from the windproof ring 200. Multiple brackets 300 are provided around the windproof ring 200. For example, the number of brackets 300 can be three, four or five, etc.

[0032] As described above, the base 100 is used to install inside an external gas stove, and its enclosure forms a cavity 110 for internal ignition and heating. The sidewall of the base 100 itself forms an outer ring within the cavity 110 that can block wind and concentrate energy. A windproof ring 200 is installed on the bottom side of the base 100 and forms an inner ring within the base 100 that can block wind and concentrate energy. In use, the boiler is placed on multiple supports 300, and the support members 310 on the supports 300 abut against the boiler to provide support. When the boiler is small, the multiple support members 310 rotate downwards to enter the fireproof ring, and the boiler is pressed down to abut against the multiple support members 310. At this time, the multiple support surfaces are inclined against the outside of the boiler to provide limiting support, and through the support... The component 310 itself can increase the direct heat conduction to the boiler, while the inner ring formed by the fireproof ring can directly block the wind and concentrate energy on the outside of the boiler, effectively improving the heating efficiency of the boiler. When the boiler is large, multiple support components 310 rotate upwards until their support surfaces protrude out of the windproof ring 200. The boiler presses down on multiple support components 310. At this time, multiple support surfaces abut against the bottom side of the boiler to provide support. The outer ring formed by the side wall of the bottom support 100 can block the wind and concentrate energy on the outside of the boiler. In this way, the rotation of multiple support components 310 can adapt to different boiler sizes, providing stable support for the boiler. Furthermore, the double-layer energy-concentrating structure of the inner and outer rings can provide a uniform heating environment for the boiler, which helps to reduce heat loss and improve heating efficiency.

[0033] There are several ways to rotatably connect the support member 310 to the bracket 300. For example, the support member 310 can be rotatably connected to the bracket 300 by a hinge. In this embodiment, as shown... Figure 5As shown, the top of the bracket 300 is provided with an arc-shaped protrusion 320 on the side near the center of the base 100. The arc-shaped protrusion 320 is a protrusion structure on the top corner of the bracket 300, and the shape of the protrusion structure is arc-shaped to accommodate the rotation of the support. The bottom side of the support member 310 is provided with a connecting groove, and the arc-shaped protrusion 320 is rotatably connected in the connecting groove. When the support member 310 rotates upward to protrude from the windproof ring 200, the bottom side of the support member 310 abuts against the top side of the bracket 300. The support member 310 is rotatably connected to the arc-shaped convex corner 320. One end of the support member 310 protrudes from the bracket 300, while the other end is located on the bracket 300. In use, when a small boiler is placed directly on the support member 310, the boiler can directly abut against the part of the support member 310 that protrudes from the bracket 300, causing the support member 310 to rotate downward. When a large boiler is placed on the support member 310, the bottom side of the boiler can abut against the part of the support member 310 located on the top side of the bracket 300. At this time, the support member 310 will not rotate, that is, it will remain rotated upward until the support surface protrudes from the windproof ring 200. At this time, the bottom side of the support member 310 abuts against the top side of the bracket 300, which can provide stable support for the support member 310, thereby ensuring the stability of the boiler placement.

[0034] The bracket 300 can be installed on the base 100 inside the windproof ring 200. In this embodiment, the bracket 300 is connected to the base 100 outside the windproof ring 200. The windproof ring 200 is provided with a clearance hole 210 to avoid the support member 310. The bracket 300 is connected to the bottom side of the base 100. When installing the windproof ring 200, the clearance hole 210 on the windproof ring 200 can be directly positioned with the bracket 300, and then the windproof ring 200 can be accurately connected to the base 100. At this time, the bracket 300 can limit the position of the windproof ring 200 and prevent the windproof ring 200 from rotating relative to the base 100. In use, the support member 310 can rotate downward at the clearance hole 210 and enter into the windproof ring 200, making the overall structure more compact.

[0035] When the boiler is placed on multiple support members 310, multiple brackets 300 will press down on the base 100. To improve the structural stability of the connection between the base 100 and the brackets 300, in this embodiment, a support boss 120 is formed at the bottom corner of the base 100. Multiple support bosses 120 are arranged around the base 100, and multiple brackets 300 are respectively connected to the top side of the multiple support bosses 120. The support bosses 120 form a raised structure on the base 100, which can increase the structural strength of the base 100 itself. By setting multiple brackets 300 on multiple support bosses 120, the weight of the boiler is transmitted downward to the multiple support bosses 120 through the brackets 300. The multiple support bosses 120 disperse the pressure on the base 100, thereby improving the structural stability of the base 100 during use.

[0036] After prolonged use, individual brackets 300 may experience structural damage, such as the rotatable connection structure of the support member 310 on the bracket 300 being broken. To facilitate the replacement of individual brackets 300, in this embodiment, multiple brackets 300 and multiple support bosses 120 are detachably connected. There are various ways to detach the brackets 300 and support bosses 120. For example, the brackets 300 and support bosses 120 can be connected to each other via snap-fit ​​connections; or screws or other connectors can be driven into the bracket 300 and connected to the base 100 to fix the bracket 300 to the base 100; or a connecting post can be provided on the support boss 120, and a connecting hole can be provided on the bottom side of the bracket 300. By inserting the connecting post into the connecting hole, the bracket 300 can be connected and fixed to the base 100. This allows for the removal and replacement of individual or multiple brackets 300 from the base 100 as needed, reducing overall usage and maintenance costs.

[0037] The windproof ring 200 can be connected to the base 100 via a snap fastener, or it can be placed directly on the base 100. In this embodiment, the bottom side of the windproof ring 200 is provided with multiple supporting ribs 220, which abut against the bottom side of the base 100 and against the side of the multiple supporting bosses 120 near the center of the base 100. When installing the windproof ring 200, the multiple supporting ribs 220 on the bottom side of the windproof ring 200 are aligned with the multiple supporting bosses 120, and then the windproof ring 200 is placed on the base 100. At this time, the multiple supporting ribs 220 abut against the side of the multiple supporting bosses 120 near the center of the base 100, limiting the windproof ring 200 radially. With the bracket 300 inserted into the clearance hole 210, the windproof ring 200 can be placed stably on the base 100. Because the supporting rib 220 raises the installation height of the windproof ring 200, a gap is formed between the bottom side of the windproof ring 200 and the base 100. At this time, external air can be introduced into the windproof ring 200 through the gap, which helps to form an airflow from the outside of the base 100 to the center of the base 100. Then, the heat of the windproof ring 200 is carried upward, preventing the windproof ring 200 from overheating due to the small space it encloses.

[0038] When a large boiler is placed on the support member 310, the support surface is in contact with the bottom surface of the boiler. To improve the boiler's positioning effect, in this embodiment, the bracket 300 has an upwardly protruding positioning part 330 on the side away from the center of the base 100. A concave angle can be formed between the positioning part 330 and the support surface to position the boiler. When a flat-bottomed boiler is placed on the top side of multiple support members 310, the multiple positioning parts 330 can position the side walls of the boiler, further improving the stability of the boiler placement.

[0039] Furthermore, the limiting part 330 is provided with a limiting concave corner 331 near the center of the base 100. When a larger boiler needs to be placed, the boiler can be placed within the limiting concave corners 331 of the multiple limiting parts 330. At this time, the multiple limiting concave corners 331 are used directly to limit and support the boiler, further improving the overall versatility.

[0040] To improve the stability of the support surface in limiting the boiler when the support member 310 is tilted, in this embodiment, a plurality of locking teeth 311 are provided on the top side of the support surface along the length of the support surface. When placing a small boiler, the support member 310 rotates, and the locking teeth 311 can lock into the bottom surface of the boiler near the corner, thereby further improving the stability of the boiler placement.

[0041] A gas stove according to a second aspect embodiment of the present invention includes a furnace body 400 and the aforementioned energy-concentrating component, wherein the base 100 is connected to the furnace body 400. Naturally, a burner is provided inside the furnace body 400, and the base 100 has an opening in the middle for the burner to extend upwards, thereby allowing heating to occur within the cavity 110.

[0042] In this gas stove, when the furnace body 400 is ignited and burning, the aforementioned energy-concentrating components inside the furnace body 400, through the rotation of multiple support members 310 to adapt to different boiler sizes, provide stable support for the boiler, and through the double-layer energy-concentrating structure of the inner and outer rings, can provide a uniform heating environment for the boiler, which helps to reduce heat loss and improve heating efficiency.

[0043] The preferred embodiments of the present invention have been described in detail above. However, the present invention is not limited to the embodiments described. Those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present invention. All such equivalent modifications or substitutions are included within the scope defined by the claims of this application.

Claims

1. An energy-concentrating component, characterized in that: include: The base (100) is surrounded by an upward-facing cavity (110); A windproof ring (200) is connected to the bottom side of the base (100), and the plane on the top side of the windproof ring (200) is located below the plane on the top side of the base (100); A bracket (300) is connected to the bottom side of the base (100). The bracket (300) is provided with a rotatable support member (310). The top surface of the support member (310) is used as the support surface. The support surface can be rotated downward to enter the windproof ring (200) or rotated upward to protrude from the windproof ring (200). The bracket (300) is provided with multiple supports around the windproof ring (200).

2. The energy-concentrating component according to claim 1, characterized in that: The bracket (300) has an arc-shaped protrusion (320) on the side near the center of the base (100) at the top. The support member (310) has a connecting groove on its bottom side. The arc-shaped protrusion (320) is rotatably connected to the connecting groove. When the support member (310) rotates upward to protrude from the windproof ring (200), the bottom side of the support member (310) abuts against the top side of the bracket (300).

3. The energy-concentrating component according to claim 2, characterized in that: The bracket (300) is connected to the base (100) located outside the windproof ring (200), and the windproof ring (200) is provided with a clearance hole (210) to avoid the support member (310).

4. The energy-concentrating component according to claim 3, characterized in that: The base (100) has a support boss (120) at its bottom corner. Multiple support bosses (120) are arranged around the base (100), and multiple brackets (300) are respectively connected to the top side of the multiple support bosses (120).

5. The energy-concentrating component according to claim 4, characterized in that: The plurality of brackets (300) and the plurality of support bosses (120) are detachably connected.

6. The energy-concentrating component according to claim 4, characterized in that: The bottom side of the windproof ring (200) is provided with a plurality of supporting ribs (220), the plurality of supporting ribs (220) abut against the bottom side of the base (100) respectively, and the plurality of supporting ribs (220) abut against the side of the plurality of supporting bosses (120) near the center of the base (100) respectively.

7. The energy-concentrating component according to claim 2, characterized in that: The bracket (300) has an upwardly protruding limiting part (330) on the side away from the center of the base (100).

8. The energy-concentrating component according to claim 7, characterized in that: The limiting part (330) has a limiting concave corner (331) at the apex near the center of the base (100).

9. The energy-concentrating component according to claim 2, characterized in that: The top side of the support surface is provided with multiple locking teeth (311) along the length direction of the support surface.

10. A gas stove, characterized in that: Includes a furnace body (400) and an energy-concentrating component as described in any one of claims 1 to 9, wherein the base (100) is connected within the furnace body (400).