JP6624960B2 - Stove burner - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a stove burner in which a mixed gas flows out of a flame formed around a burner head and ignites using a spark plug.

  A stove burner provided in a gas stove includes a burner body that mixes fuel gas and primary air to generate a mixed gas, and a burner head that is mounted on the burner body. An annular tubular wall projects downward from the outer edge of the burner head, and a groove (flame port) penetrating from the inside to the outside of the tubular wall is formed in the lower end surface of the tubular wall. A plurality of grooves are formed. When the burner head is mounted on the burner body, the bottom surface of the cylindrical wall comes into contact with the mounting surface, and the outer peripheral side surface of the cylindrical wall has a plurality of flame opening grooves. The locations where these flame hole grooves are opened on the outer peripheral side face become the flame ports, and the mixed gas flowing out of the flame ports burns to form a flame around the burner head.

  The ignition of the mixed gas is performed using an ignition plug provided on the side of the burner head. That is, the burner head is provided with an ignition flame opening toward the ignition plug, and an ignition target projects from the burner head toward the ignition plug above the ignition flame. Then, at the time of ignition, the mixed gas is caused to flow out from the plurality of flame ports while performing spark discharge from the ignition plug toward the ignition target. Then, first, the mixed gas flowing out of the ignition flame is ignited by the spark discharge from the spark plug, the flame is transferred to an adjacent flame, and the mixed gas flowing out of the flame is ignited. Then, the flame burns to the next flame outlet. In this way, the mixed gas flowing out from all the flame openings can be ignited by successively transferring the fire.

  In recent years, even when a small-diameter cooking vessel is used, the flow rate of the mixed gas at the time of ignition tends to be set to a small flow rate so that the flame at the time of ignition does not overflow from the bottom of the cooking vessel. If the flow rate of the mixed gas at the time of ignition is set to a small flow rate, the mixed gas flowing out of the ignition flame becomes easy to be diluted before being ignited by the spark plug, so that ignition is difficult. Therefore, by providing a projection protruding toward the ignition plug on the side of the outer peripheral side of the burner head facing the ignition plug, and forming an ignition flame port on the projection, the ignition flame port is connected to the ignition plug. There has also been proposed a stove burner approaching (2). In such a stove burner, it is possible to prevent the mixed gas flowing out of the ignition flame from being diluted before ignition, so that it is possible to avoid a situation in which ignition becomes difficult.

JP 2013-221668 A

  However, if the flow rate of the mixed gas at the time of ignition is set to a small flow rate, there is a problem that it becomes difficult to stably ignite even if a slight crosswind exists at the time of ignition. This is because, if a cross wind is received during ignition, the mixed gas flowing out of the ignition flame port flows, and it is difficult to reach the ignition target.

  SUMMARY OF THE INVENTION The present invention has been made in response to the above-described problems of the conventional technology, and has as its object to provide a stove burner that can stably ignite even under a situation where cross wind is received at the time of ignition. .

In order to solve the above-described problem, the stove burner of the present invention employs the following configuration. That is,
A burner head for discharging a mixed gas of fuel gas and primary air from a plurality of flame ports provided on an outer peripheral side surface, a burner body on which the burner head is mounted , and a spark directed toward an ignition target of the burner head; And a spark plug for igniting the mixed gas by performing discharge.
On the side of the outer peripheral side of the burner head facing the ignition plug, a plurality of ignition flame outlets for allowing the mixed gas to flow toward the ignition plug, and from the upper side of the ignition flame toward the ignition plug. And an eave portion protruding to a position outside the outer peripheral wall of the burner body,
On the lower surface side of the eaves portion, the ignition target protruding downward is formed at a position outside the outer peripheral wall of the burner body,
The plurality of ignition flame ports are formed side by side in the circumferential direction of the outer peripheral side surface,
A protruding wall protruding from the outer peripheral side surface of the burner head toward the ignition plug is formed between the adjacent ignition flame ports ,
The projecting length of the protruding wall is set to a length that reaches a position outside the outer peripheral wall of the burner body but does not reach the ignition target .

In the stove burner of the present invention, a plurality of flame ports are provided on the outer peripheral side surface of the burner head, and a flame is formed around the burner head by burning the mixed gas flowing out of the flame port. In addition, on the side of the outer peripheral side of the burner head facing the ignition plug, a plurality of ignition flame outlets for allowing the mixed gas to flow toward the ignition plug are formed in a state of being arranged in a circumferential direction of the outer peripheral side . Further, from the outer peripheral side surface above the plurality of ignition flame ports, an eave portion is provided to reach a position outside the outer peripheral wall of the burner body toward the spark plug, and on the lower surface side of the eave portion, An ignition target protruding downward is formed at a position outside the outer peripheral wall of the burner body. Then, by spark discharge from the spark plug toward the ignition target, the mixed gas flowing out from the ignition flame is ignited. Here, between the ignition flame port and the ignition flame port, a protruding wall is formed continuously from the outer peripheral side surface of the burner head and protrudes toward the ignition plug, and the length of the protruding wall is determined by a burner body. The length is set to reach the position outside the outer peripheral wall, but not to reach the ignition target .

In this way, even if the burner head receives a crosswind when the burner head is ignited, the mixed gas flowing out of the ignition flame outlet continuously projects from the outer peripheral side surface of the burner head at a position between the adjacent ignition flame hole. The flow does not flow any further because it is blocked by the projected wall, and flows toward the ignition target . For this reason, even in a situation where a crosswind is received, the mixed gas is supplied around the ignition target , so that it is possible to stably ignite by spark discharge from the ignition plug to the ignition target .

  In the above-mentioned stove burner of the present invention, the central ignition flame port is provided at the center of the side of the outer peripheral surface facing the ignition plug, and the left ignition flame port is located on the left side of the central ignition flame port in the direction of the ignition plug. And a right ignition flame may be provided on the right side of the center ignition flame toward the spark plug. Then, a projecting wall may be formed between the center ignition flame and the left ignition flame and between the center ignition flame and the right and left ignition flame.

  In this way, for example, when a cross wind is received from the left side, the mixed gas flowing out of the left ignition flame is directed in the direction of the ignition plug by a projecting wall provided between the left ignition flame and the central ignition flame. Can lead. Further, when a cross wind is received from the right side, the mixed gas flowing out of the right ignition flame can be guided to the direction of the ignition plug by a projecting wall between the right ignition flame and the center ignition flame. Further, when no cross wind is received, the mixed gas flowing out of the central ignition flame port can be guided toward the spark plug. Therefore, the mixed gas can be supplied around the spark plug without being affected by the wind, so that the ignition can be stably ignited using the spark plug.

  In the above-mentioned stove burner of the present invention, a notch portion in which the protruding wall is cut may be provided at the lower end of the protruding wall.

  In this way, if the mixed gas flowing out of any one of the plurality of ignition flames can be ignited, the flame generated at the ignition flame is connected to the next ignition flame through the notch. All the flames can be ignited. For this reason, it is possible to stably and easily ignite using the spark plug even in a situation where there is a crosswind.

  In the above-described stove burner of the present invention, the side of the outer peripheral surface of the burner head facing the spark plug is formed in a protruding shape protruding toward the spark plug, and a plurality of points are formed on the protruding portion. A flame port may be formed.

  In this case, the ignition flame port can be brought closer to the ignition plug by the amount of the protruding portion protruding from the outer peripheral side surface of the burner head. For this reason, it is possible to suppress the mixed gas flowing out of the ignition flame from being diluted with the surrounding air before reaching the spark plug. Can be easily ignited.

It is a perspective view showing appearance shape of gas stove 1 in which stove burner 10 of this example was carried. It is sectional drawing which shows the structure of the stove burner 10 of a present Example. FIG. 3 is an enlarged view showing a detailed shape of a burner head 14 on a side facing an ignition plug 11. FIG. 7 is an explanatory diagram showing the reason why the burner head 14 of the present embodiment can stably ignite even in the presence of a crosswind. It is explanatory drawing about the burner head 14 of a 1st modification. It is explanatory drawing about the burner head 14 of a 2nd modification.

  FIG. 1 is a perspective view showing an external shape of a gas stove 1 on which a stove burner 10 of the present embodiment is mounted. As shown in the figure, the gas stove 1 includes a top plate 2 made of glass or metal, a stove burner 10 protruding above the top plate 2 through an opening for a burner to be described later, which is opened in the top plate 2, and a top plate. It has a burner 3 that supports a cooking container such as a pot above the stove burner 10, and a burner ring 4 that blocks a space between the burner opening and the stove burner 10.

  The stove burner 10 includes a spark plug 11, a burner body 12, a burner head 14 mounted on the burner body 12, a wide annular burner cover 16 mounted on the burner head 14, A temperature sensor 18 and the like are provided so as to protrude from a central through hole of the burner cover 16. Note that the stove burner 10 is also provided with a thermocouple for misfire detection, but is not shown in the drawing because it has little relevance to the present invention.

  As will be described later, a mixing chamber is provided inside the burner body 12, and mixes the fuel gas and the primary air to form a mixed gas. The outer peripheral side surface of the burner head 14 is formed in a substantially cylindrical shape. The outer peripheral side surface has a main flame opening 15a which is vertically elongated in the vertical direction and through which the mixed gas flows, and which is vertically higher than the main flame opening 15a. A flame holding port 15b is formed which opens short in the direction and in which the mixed gas flows out. In the following, the main flame port 15a and the flame holding port 15b may be simply referred to as "flame port 15".

  Further, the burner head 14 is provided with an eave portion 20 protruding from an upper portion facing the ignition plug 11 toward the outside (in a direction in which the ignition plug 11 is provided). As will be described in detail later, the side surface of the burner head 14 below the eaves portion 20 is formed in a protruding shape toward the ignition plug 11, and the portion formed in this protruding shape also faces the ignition plug 11. A flame opening (ignition flame opening) is formed. Further, an ignition target 20t to be described later is provided on the lower surface side of the eave portion 20. For this reason, when the mixed gas is caused to flow out of the flame port 15 and an ignition flame port described later while performing spark discharge from the ignition plug 11 toward the ignition target 20t, the mixed gas is ignited by the spark discharge and combustion is started. be able to.

  The burner cover 16 prevents boiled juice spouted from the cooking container during cooking from entering the burner head 14 and the burner body 12. The temperature sensor 18 is configured to be urged upward by a coil spring (not shown) so as to be able to expand and contract in the vertical direction. When the cooking container is placed on the goto 3, the temperature sensor 18 is pushed down on the bottom surface of the cooking container. For this reason, the temperature sensor 18 is in a state where the upper end surface is in close contact with the bottom surface of the cooking vessel, and can accurately measure the temperature of the cooking vessel.

  FIG. 2 is an explanatory view showing the structure of the stove burner 10 by taking a cross section of the gas stove 1. The burner body 12 of the stove burner 10 is constructed by assembling two press-formed sheet metals facing each other and in an airtight state. One sheet metal forms the outer peripheral wall 12a, and the other sheet metal forms the inner peripheral wall 12b, and a mixing chamber 12c is formed between the outer peripheral wall 12a and the inner peripheral wall 12b. The upper end portion of the outer peripheral wall 12a is bent inward to form an annular mounting surface 12d that is inclined obliquely downward. The burner head 14 is mounted on the mounting surface 12d.

  The burner head 14 is a substantially annular component manufactured by a method such as casting, forging, or die casting. An annular tubular wall 14r is protruded downward at an outer edge portion, and further, an inner edge portion is formed. , A cylindrical support tube 14t is erected downward. The burner head 14 is configured such that a lower end surface (hereinafter referred to as a lower end surface) of the cylindrical wall 14r abuts on the mounting surface 12d in a state where the support cylinder 14t is fitted to the inner peripheral wall 12b of the burner body 12. 12. Further, a plurality of grooves (flame opening grooves) crossing in the radial direction of the cylindrical wall 14r are formed on the lower end surface of the cylindrical wall 14r. The flame groove is provided with a deep groove (main flame groove 14a) and a shallow groove (flame groove 14b), and the main flame groove 14a is opened on the outer peripheral side surface of the cylindrical wall 14r. Becomes the main flame opening 15a, and the portion where the flame keeping groove 14b opens becomes the flame keeping hole 15b.

  A substantially disc-shaped burner cover 16 is attached to an upper portion of the burner head 14 by a mounting bracket (not shown). Further, a cylindrical temperature sensor 18 protrudes from a through hole formed at the center position of the burner cover 16. The temperature sensor 18 is attached to the upper end of a support pole 19 that penetrates the center of the support cylinder 14t of the burner head 14, and the upper end of the temperature sensor 18 when the cooking vessel is not placed on the gotoku 3 is the top surface of the gotoku 3. More protruding. An upper portion of the burner body 12 (a portion where the mounting surface 12d is formed) is protruded from a burner opening 2a opened in the top plate 2, and a gap between the burner body 12 and the burner opening 2a is formed. It is closed by an annular burner ring 4.

  FIG. 3 is an enlarged view showing the detailed shape of the burner head 14 on the side facing the ignition plug 11. FIG. 3A shows an enlarged view of the side where the burner head 14 faces the ignition plug 11 as viewed obliquely from above, and FIG. 3B shows an enlarged view as viewed from obliquely below. It is shown. As described above, the burner head 14 of this embodiment has the outer peripheral side surface 14s formed in a cylindrical shape, and the outer peripheral side surface 14s has a plurality of main flame ports 15a and flame holding ports 15b. As shown in FIG. 3A, the side of the burner head 14 facing the spark plug 11 is formed by projecting an outer peripheral side surface 14 s of the burner head 14 toward the spark plug 11 in an arc shape, thereby forming a convex portion 22. The eaves 20 extend from the upper part of the convex part 22 toward the spark plug 11. Further, on the lower end surface of the convex portion 22, a flame opening groove (ignition flame groove) is formed which traverses the convex portion 22 in the radial direction from the center of the burner head 14. An ignition flame port is formed at a portion that opens to the outer peripheral surface. In addition, the convex portion 22 corresponds to the “portion in which the outer peripheral side surface is formed in a protruding shape” in the present invention. Further, on the outer peripheral wall 12a of the burner body 12, a portion below the convex portion 22 has a shape depressed in a direction away from the ignition plug 11, and a concave portion 12e is formed in this portion.

  FIG. 3B is an enlarged view of the protrusion 22 of the burner head 14 as viewed from a diagonally lower direction indicated by an arrow P in FIG. 3A. As shown in FIG. 3 (b), in the burner head 14 of the present embodiment, a central ignition flame port 24a is formed at the top (the part closest to the spark plug 11) of the convex part 22 projecting in an arc shape. An ignition target 20t is formed above the central ignition flame port 24a so as to protrude downward from the lower surface of the eave portion 20. A left ignition flame port 24b is formed on the left side of the center ignition flame port 24a when viewed from the burner head 14 side (right side on the paper surface of FIG. 3B), and is viewed from the burner head 14 side. A right ignition flame 24c is formed on the right side of the center ignition flame 24a (left side on the paper surface of FIG. 3B). In the following, the center ignition flame 24a, the left ignition flame 24b, and the right ignition flame 24c may be collectively referred to as "ignition flame 24". Further, a projecting wall 21 protruding outward (in the direction of the ignition plug 11) is formed between the center ignition flame port 24a and the left ignition flame port 24b. A protruding wall 21 protruding outward is also formed between the protruding wall 21 and the mouth 24c. The upper ends of these protruding walls 21 extend to the locations on the lower surface of the eaves portion 20 where the ignition targets 20t protrude.

  In such a stove burner 10 of the present embodiment, the protruding wall 21 is formed between the center ignition flame 24a and the left ignition flame 24b or between the center ignition flame 24a and the right ignition flame 24c. Therefore, it is possible to stably ignite using the spark plug 11 even in a situation where a crosswind exists. The reason will be described in detail with reference to FIG.

  FIG. 4 shows the flow of the mixed gas flowing out of the ignition flame port 24 at the time of ignition when the burner head 14 is viewed from the lower surface side. The dashed arrows shown in the figure indicate the flow of the mixed gas flowing out of the ignition flame port 24. In the absence of wind, as shown in FIG. 4A, the mixed gas flowing out of the central ignition flame 24a goes straight toward the ignition target 20t and the ignition plug 11. Further, the mixed gas is supplied to the periphery of the ignition target 20t and the ignition plug 11 also from the left ignition flame 24b and the right ignition flame 24c on the left and right of the center ignition flame 24a. Therefore, in a windless condition, the mixed gas can be stably ignited by spark discharge from the ignition plug 11 toward the ignition target 20t.

  On the other hand, FIG. 4B shows a case where a cross wind is received from the right side of the burner head 14. Since FIG. 4 shows the burner head 14 viewed from below, the cross wind received from the right side of the burner head 14 is represented by an arrow from the left in the drawing. As indicated by the dashed arrows in the figure, when a cross wind is received from the right side, the mixed gas flowing out of each ignition flame port 24 is bent leftward (rightward in the figure). However, for the mixed gas flowing out of the right ignition flame 24c, since the protruding wall 21 is provided between the right ignition flame 24c and the center ignition flame 24a, bending in the traveling direction due to the cross wind is suppressed. . As a result, the mixed gas can be supplied around the ignition target 20t and the ignition plug 11, so that the spark discharge from the ignition plug 11 (see FIG. 3) toward the ignition target 20t stabilizes the mixed gas. It can be ignited reliably.

  The same description applies when the burner head 14 receives a cross wind from the left side. FIG. 4C shows a case where the burner head 14 receives a cross wind from the left side (from the right side in the drawing). When a cross wind is received from the left side, the traveling direction of the mixed gas flowing out of the ignition flame port 24 is bent rightward (leftward in the figure) as indicated by a broken arrow in the figure. However, with respect to the mixed gas flowing out from the left ignition flame port 24b, the protruding wall 21 provided between the left ignition flame port 24b and the central ignition flame port 24a suppresses the bending in the traveling direction. The mixed gas can be supplied to around 20t and around the ignition plug 11. Therefore, even when a cross wind is received from the left side, it is possible to stably ignite by spark discharge from the spark plug 11 (see FIG. 3) toward the ignition target 20t.

  In addition, in the stove burner 10 according to the present embodiment, the plurality of ignition flames 24 (here, the center ignition flame 24a, the left ignition flame 24b, and the right ignition flame 24c) project outward in an arc shape. It is formed on the provided convex portion 22. For this reason, since the distance from the ignition flame 24 to the ignition target 20t and the ignition plug 11 is shorter than when the ignition flame 24 is provided on the outer peripheral side surface 14s, the ignition flame 24 flows out from the ignition flame 24. Until the mixed gas reaches the periphery of the ignition target 20t and the spark plug 11, the mixed gas can be suppressed from being diluted with air. As a result, the concentration of the mixed gas in the vicinity of the ignition target 20t and the ignition plug 11 can be maintained at a concentration that allows easy ignition even under the condition of receiving a crosswind, so that the spark discharge from the ignition plug 11 It is possible to stably ignite.

  There are a plurality of modifications of the stove burner 10 of the present embodiment described above. Hereinafter, these modified examples will be briefly described focusing on differences from the present embodiment.

  In the above-described embodiment, as shown in FIG. 3B, the upper end of the protruding wall 21 is extended to reach the lower surface of the eaves portion 20, and the lower end of the protruding wall 21 is formed in an arc shape. The description has been made assuming that the projection 22 extends to the lower surface of the protruding projection 22. Therefore, the space outside the center ignition flame port 24a and the space outside the left ignition flame port 24b are in a state of being separated by the projecting wall 21 projecting therebetween. Further, the space outside the center ignition flame port 24a and the space outside the right ignition flame port 24c are also separated by the projecting wall 21. However, a cutout portion 21c is provided in a part of the protruding wall 21 to partially communicate the space outside the central ignition flame port 24a with the space outside the left ignition flame port 24b. And a space outside the right ignition flame port 24c may be partially communicated.

  FIG. 5 is an explanatory diagram of a first modified example in which a cutout portion 21c is provided in a part of the protruding wall 21. In the example shown in FIG. 5A, a notch 21 c is provided at the lower end of the protruding wall 21. In this way, the flame can be transferred between the central ignition flame 24a and the left ignition flame 24b or between the central ignition flame 24a and the right ignition flame 24c via the cutout 21c. it can. For this reason, if any one of the mixed gas of the center ignition flame 24a, the left ignition flame 24b, and the right ignition flame 24c can be ignited and ignited, the mixed gas of all the ignition flames 24 can be ignited. As a result, it is possible to stably ignite even under conditions of receiving a crosswind. The position where the notch 21c is provided is not limited to the lower end of the protruding wall 21. For example, as shown in FIG. 5B, it may be provided at the upper end of the protruding wall 21. Even in this case, if any one of the mixed gas of the center ignition flame 24a, the left ignition flame 24b, and the right ignition flame 24c is ignited, the mixed gas of all the ignition flames 24 can be ignited. Thus, it is possible to stably ignite even under the condition of receiving a cross wind.

  Further, in the above-described embodiment or the modification, the ignition flame port 24 includes the central ignition flame port 24a facing the ignition target 20t and the ignition plug 11, the left ignition flame port 24b provided on the left side of the ignition flame port 24b, and the right side. The description has been given as having at least three flames of the right ignition flame 24c provided. However, it is sufficient that the ignition flame port 24 is provided in a state where a plurality of flame ports are arranged. Therefore, the central ignition flame port 24a directly facing the ignition target 20t and the ignition plug 11 does not necessarily have to be provided. .

  FIG. 6 does not have the central ignition flame 24a facing the ignition target 20t and the ignition plug 11, and therefore, the ignition flame 24 is formed by two of the left ignition flame 24b and the right ignition flame 24c. It is explanatory drawing about the 2nd modified example. Note that FIG. 6 also shows the burner head 14 viewed from the lower surface side, similarly to FIG. 4 described above. Therefore, the left and right sides are shown upside down in the drawing. Further, in the example shown in FIG. 6, the left ignition flame port 24b and the right ignition flame port 24c are formed not on the convex portion 22 but on the outer peripheral side surface 14s. Similarly to 14, the protrusion 22 may be formed with a left ignition flame port 24b and a right ignition flame port 24c. In the burner head 14 of the second modification, a projecting wall 21 is provided between the left ignition flame 24b and the right ignition flame 24c toward the ignition target 20t. Also in the second modified example, the ignition can be stably performed using the ignition plug 11 without being affected by the crosswind for the following reasons.

  First, in a windless condition, as indicated by broken arrows in FIG. 6 (a), the mixed gas flowing out of the left ignition flame port 24b and the right ignition flame port 24c is mixed with the ignition target 20t and the ignition target 20t. The vehicle goes straight toward the periphery of the spark plug 11. Therefore, by performing spark discharge from the ignition plug 11 toward the ignition target 20t, the mixed gas can be ignited stably.

  When the burner head 14 receives a crosswind from the right side, the mixed gas flowing out of the left ignition flame port 24b and the right ignition flame port 24c travels as indicated by a broken arrow in FIG. 6B. The direction is bent to the left. In FIG. 6, since the burner head 14 is viewed from the lower surface side, the left and right sides are shown upside down in the drawing. However, since the protruding wall 21 protrudes between the right ignition flame port 24c and the left ignition flame port 24b, the mixed gas flowing out of the right ignition flame port 24c is blocked by the protruding wall 21, The bending in the traveling direction due to the cross wind is suppressed. As a result, the mixed gas from the right ignition flame port 24c can be supplied to the periphery of the ignition target 20t and the ignition plug 11, so that a spark discharge from the ignition plug 11 toward the ignition target 20t reduces cross wind. It is possible to stably ignite the air-fuel mixture even under the receiving condition.

  The same description applies when the burner head 14 receives a cross wind from the left side. That is, as shown in FIG. 6C, when the burner head 14 receives a cross wind from the left side (from the right side in the drawing), the traveling direction of the mixed gas flowing out from the left ignition flame port 24b and the right ignition flame port 24c. Is bent rightward (leftward in the figure). However, with respect to the mixed gas flowing out of the left ignition flame port 24b, since the bending in the traveling direction is suppressed by the projection wall 21, the mixed gas can be supplied around the ignition target 20t and the ignition plug 11. Therefore, even when a cross wind is received from the left side, it is possible to stably ignite the mixed gas using the ignition plug 11.

  Although the present embodiment and various modifications have been described above, the present invention is not limited to the above-described embodiment and modifications, and can be implemented in various modes without departing from the gist thereof. .

  For example, in the above-described embodiment and the modified example, the case where the number of the ignition flame ports 24 is two or three has been described. However, it is sufficient if the number of ignition flame ports 24 is plural, and it is possible to increase the number to four or more. When four or more ignition flames 24 are provided, it is not always necessary to provide the protruding wall 21 between the adjacent ignition flames 24. The projecting wall 21 may not be provided between the two. Even in this case, the mixed gas flowing out of the ignition flame port 24 provided with the protruding wall 21 is supplied to the ignition target 20t and the ignition plug 11 even under the condition of receiving a crosswind. Therefore, it is possible to stably ignite the mixed gas by the above-described mechanism.

1 ... gas stove, 2 ... top plate, 2a ... opening for burner,
3 ... Gotoku, 4 ... Burner ring, 10 ... Stove burner,
11: spark plug, 12: burner body, 12a: outer peripheral wall,
12b: inner peripheral wall, 12c: mixing chamber, 12d: mounting surface,
12e: recess, 14: burner head, 14a: main flame groove,
14b: flame holding groove, 14r: cylindrical wall, 14s: outer peripheral side surface,
14t: support cylinder, 15: flame outlet, 15a: main flame outlet,
15b: flame holding port, 16: burner cover, 18: temperature sensor,
19: support pole, 20: eaves, 20t: ignition target,
21: Projecting wall, 21c: Notch, 22: Convex,
24: ignition flame, 24a: central ignition flame, 24b: left ignition flame,
24c: Right ignition flame outlet.

Claims (4)

A burner head for allowing a mixed gas of fuel gas and primary air to flow out from a plurality of flame ports provided on the outer peripheral side surface; a burner body on which the burner head is mounted ; and a spark directed toward an ignition target of the burner head. And a spark plug for igniting the mixed gas by performing discharge.
On the side of the outer peripheral side of the burner head facing the ignition plug, a plurality of ignition flame outlets for allowing the mixed gas to flow toward the ignition plug, and from the upper side of the ignition flame toward the ignition plug. And an eave portion protruding to a position outside the outer peripheral wall of the burner body,
On the lower surface side of the eaves portion, the ignition target protruding downward is formed at a position outside the outer peripheral wall of the burner body,
The plurality of ignition flame ports are formed side by side in the circumferential direction of the outer peripheral side surface,
A protruding wall protruding from the outer peripheral side surface of the burner head toward the ignition plug is formed between the adjacent ignition flame ports ,
The stove burner is characterized in that a length of the projecting wall protruding reaches a position outside the outer peripheral wall of the burner body but does not reach the ignition target . The stove burner according to claim 1,
The plurality of ignition ports are a central ignition port formed in the center, a left ignition port formed on the left of the central ignition port toward the direction of the ignition plug, and a direction of the ignition plug. And a right ignition flame formed right next to the central ignition flame toward
The stove wall is formed between the center ignition flame and the left ignition flame and between the center ignition flame and the right ignition flame. In the stove burner according to claim 1 or 2,
A stove burner, wherein a cutout portion formed by cutting out the protruding wall is formed at a lower end of the protruding wall. In the stove burner according to any one of claims 1 to 3,
A side of the outer peripheral side of the burner head facing the spark plug is formed in a protruding shape protruding toward the spark plug,
The stove burner, wherein the plurality of ignition flame ports are formed in a portion of the outer peripheral side surface formed in the protruding shape.

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