JP6517604B2 - Gas stove - Google Patents

Description

  The present invention relates to a gas stove.

  In the push-to-burn gas stove, a gas stove that can provide a click feeling with a predetermined thermal power when adjusting the thermal power has been proposed. For example, a pressing plate for supporting the operation component inserted and disposed on the operating shaft is provided, and the rotating plate in contact with the pressing plate is inserted and arranged to integrally rotate with the operating shaft, and the contact of the rotating plate A groove or protrusion containing metal balls is provided on the surface and a hole or groove is provided on the contact surface of the pressure plate, or a convex piece is provided on the outer peripheral portion of the rotating plate and a protrusion is provided on the contact surface of the pressure plate The stove which provided the protrusion which contact | abuts and locks with the edge part of piece is proposed (for example, refer patent document 1).

JP, 2008-145050, A

  In the stove described in Patent Document 1, there is a problem that it is difficult to assemble and disassemble because the structure for obtaining the click feeling is complicated.

  An object of the present invention is to provide a gas stove which has a simple structure and can provide a click feeling at a predetermined thermal power when the thermal power is adjusted.

The gas stove of the invention according to claim 1 is a gas stove provided with a thermal power adjustment device for adjusting the thermal power of the burner, wherein the thermal power adjustment device is pivotally supported by the main body portion and the main body portion, and the thermal power adjustment And a rotary plate provided integrally with the rotary shaft and rotating around the rotary shaft, and a groove or a hole provided on one side of the rotary plate. A leaf spring fixed to the main body portion and extending from the fixed portion fixed to the main body portion to the one side of the pivot plate; and a tip end portion of the leaf spring, the pivot plate being pivoted And a pin which is disposed on a pivoting locus of the groove or the hole which is rotated with the rotation, and which can be engaged with the groove or the hole when the rotating plate is rotated to a predetermined thermal position. The leaf spring is provided with the pin at the tip end of the pivot plate. Biased in serial one side, the combustion control system further while pushing the knob provided on the operating shaft in the axial direction of the operation shaft, a direction in which to adjust the heating power from the small thermal to the large thermal one It has a function to open the gas flow path to the burner by performing an ignition operation to rotate in a direction, the rotating plate is formed in a substantially fan shape centering on the operation axis, and before the ignition operation and the burner When extinguishing the fire, the pin separates from the one end on the downstream side of the one direction, which rotates with the operation shaft, of the both ends in the outer peripheral direction of the rotation plate, and from the one end on the downstream side A gap is provided on the one side, and at the time of an ignition operation, the pin runs on the one side from the one end side of the downstream side of the rotating plate rotating in the one direction, and the downstream side The other end of the upstream side opposite to the one end of the Characterized by sliding towards.

The gas stove of the invention according to claim 2 is characterized in that, in addition to the constitution of the invention according to claim 1 , a play is provided in the rotational direction of the operation shaft with respect to the operation shaft before ignition operation and at the time of extinguishment. I assume.

The gas stove of the invention according to claim 3 comprises, in addition to the constitution of the invention according to claim 1 or 2 , an urging means for urging the operating shaft on the opposite side to the direction of pushing the knob, at the time of ignition operation In the invention, the pivot plate is pivoted in a state where it is pressed together with the operation shaft.

In the gas stove according to a fourth aspect of the present invention, in addition to the configuration of the invention according to any one of the first to third aspects, the pivoting of the contact point where the tip of the pin contacts the one surface of the pivoting plate The one direction in which the plate rotates with the operation shaft is substantially opposite to the direction from the fixing portion fixed to the main body portion of the plate spring to the tip portion, and the axial direction of the pin Is characterized in that it is inclined in a direction away from the fixed portion side with respect to a direction perpendicular to the one surface of the rotating plate in the contact point.

In the gas stove according to the invention as set forth in claim 5 , in addition to the constitution of the invention as set forth in any one of claims 1 to 4 , the inner edge portion of the groove portion or the hole portion is formed in a tapered shape. I assume.

In the gas stove of the invention according to claim 6 , in addition to the constitution of the invention according to any one of claims 1 to 5 , the predetermined fire power position is a heat power position between middle heat power and small heat power. It is characterized by

  In the gas stove of the invention according to claim 1, when the user rotates the operating shaft to adjust the thermal power of the burner and the pivoting plate is rotated to the predetermined thermal position, it is provided at the tip of the plate spring. The engaged pin engages with a groove or hole provided in the pivot plate. Thereby, when adjusting the thermal power, it is possible to obtain a click feeling with a predetermined thermal power, and therefore, the thermal power adjustment can be easily performed by using the click feeling as a clue. And since it has a simple structure in which a pivoting plate is provided on the operation shaft and a plate spring provided with a pin at the tip is attached to the gas stove, the attachment is easy, maintenance such as repair and replacement is easy, and parts cost Can be kept cheap.

Moth Sukonro is, before the point fire operation, the pin provided on the distal end portion of the leaf spring, and disengaged from the rotation plate is disposed with a gap. That is, since the pivoting plate does not contact the plate spring before the ignition operation, no load is applied to the plate spring. Thereby, the durability of the plate spring can be improved.

In the gas stove of the invention according to claim 2 , in addition to the effect of the invention according to claim 1 , when the operation shaft is turned without being pushed by the user's erroneous operation before the ignition operation, the operation shaft is within the range of play Since it only rotates, no load is applied to the leaf spring even if the pivot plate contacts the leaf spring. Thereby, the durability of the plate spring can be further improved.

In the gas stove of the invention according to claim 3 , in addition to the effect of the invention according to claim 1 or 2 , when pushing the knob at the time of the ignition operation, the pin is moved in a direction moved away from one side of the rotating plate. Slide on one side of the moving plate. As a result, when the pin slides on one side of the pivot plate, the leaf spring only bends to a small extent, so it is possible to reduce the click feeling that occurs when the pin passes through the groove or the hole. Therefore, the user can perform the ignition operation time without discomfort.

In addition to the effects of the invention described in any one of claims 1 to 3 , the gas stove of the invention according to claim 4 can exhibit the following effects. If the tip end portion of the pin slides in a direction perpendicular to one side of the rotation plate, the rotation plate and the operation shaft move in one direction (substantially opposite to the direction from the fixing portion of the leaf spring to the In the case of pivoting in the direction), the leaf spring is pulled to the opposite side to the fixed part side through the pin engaged with the groove or the hole, so it easily slips out of the groove or the hole. On the other hand, when the pivoting plate pivots in the direction opposite to the one direction with the operation shaft, the leaf spring is pushed toward the fixed portion through the pin engaged with the groove or the hole, so from the groove or the hole It is hard to escape. Therefore, in the present invention, the axial direction of the pin is inclined in the direction away from the fixed portion side with respect to the direction perpendicular to one side of the rotating plate at the contact point between the tip of the pin and one side of the rotating plate. . This makes it possible to equalize the ease of removal from the groove or hole of the pin when the rotating plate rotates with the operating shaft in the direction opposite to the one direction. Therefore, the click feeling produced when the operation axis is rotated in one direction and in the opposite direction can be made uniform.

In the gas stove of the invention according to claim 5 , in addition to the effect of the invention according to any one of claims 1 to 4 , thereby, the pin can be smoothly engaged and disengaged from the groove portion or the hole portion. You can get a sense of clicks.

In the gas stove according to the invention according to claim 6 , in addition to the effect of the invention according to any one of claims 1 to 5 , for example, when squeezing the fire power from middle fire power to small fire power in cooking of boiled food etc. It is possible to prevent the fire from disappearing because it is too narrow.

FIG. 1 is a perspective view of a gas stove 1; FIG. 2 is a perspective view of a thermal power adjustment device 20. FIG. 6 is a right side view of the thermal power adjustment device 20. FIG. 2 is a left side view of a thermal power adjustment device 20; FIG. 2 is a front view of a thermal power adjustment device 20. FIG. 6 is a cross-sectional view taken along line I-I in FIG. FIG. 6 is a front view of a rotating plate 60. FIG. 7 is a side view of a plate spring 70. It is a front view (at the time of ignition) of the thermal-power-control apparatus 20. FIG. FIG. 6 is a front view of the thermal power adjustment device 20 (during medium thermal power). It is a front view of the thermal-power-control apparatus 20 (at the time of a click generation | occurrence | production). It is a front view (at the time of small thermal power) of the thermal power adjustment apparatus 20. FIG. It is a figure (at the time of ignition) which shows the physical relationship of rotation board 60 and leaf spring 70. It is a figure (at the time of click generating) showing the physical relationship of rotation board 60 and leaf spring 70. It is a figure (at the time of large thermal power) which shows the physical relationship of rotation board 60 and leaf spring 170. It is a figure (at the time of click generating) showing the physical relationship of rotation board 60 and leaf spring 170.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Although the gas stove 1 shown in FIG. 1 is a grilled table stove equipped with push-and-push type knobs 11 to 13, it may be a grilleless table stove or a built-in stove installed on a counter top of a kitchen. In the following description, upper and lower, right and left, and front and back indicated by arrows in the drawings are used.

  The external structure of the gas stove 1 will be described with reference to FIG. The gas stove 1 is provided with a horizontally long substantially rectangular parallelepiped appliance 2. The right stove 5 is provided on the right side of the top surface 4 of the appliance 2 and the left stove 6 is provided on the left side. An exhaust port 9 is provided behind the top surface of the top surface 4. The exhaust port 9 is provided with a slit-like cover 9A. The exhaust port 9 communicates with the inside of a grill storage (not shown) provided in the appliance 2. A grille opening (not shown) provided at the front of the grill storage is provided at the center of the front of the appliance 2. At the grill opening, a grill door 10 is provided movably in the front-rear direction. When the grille door 10 is pulled out to the front side, a saucer (not shown) and a grill connected to the lower rear of the grille door 10 can be simultaneously taken out from the grill storage.

  On the right side of the grille door 10 at the front of the appliance 2, knobs 11 and 12 are provided. A knob 13 is provided on the left side of the grille door 10. The knobs 11 to 13 are push and turn type. When the burner 11 of the right stove 5 (hereinafter simply referred to as a burner) is ignited, the knob 11 is pushed and rotated approximately 90 ° counterclockwise in a front view. After ignition, the thermal power is adjusted from large thermal power to small thermal power by turning clockwise. When the knob 11 is returned to the pre-ignition position, the burner is extinguished. Although not described in detail, the operation method of the knobs 12 and 13 is the same as that of the knob 11. The knob 12 is pushed and rotated when the grill burner (not shown) in the grill storage is ignited, and the knob 13 is pushed and rotated to ignite the burner of the left stove 6.

  In the present embodiment, when rotating the knobs 11 to 13 for adjusting the thermal power of various burners, when the thermal power of various burners switches from middle thermal power to small thermal power, a light catching feeling (so-called "click feeling") , 11-11 can be applied. The mechanism of the click feeling will be described later.

  A thermal power adjustment device 20 (see FIG. 2) is provided on the front side inside the device 2 and at each position corresponding to the knobs 11 to 13, respectively. For example, the thermal power adjustment device 20 corresponding to the right stove 5 drives an igniter (not shown) for igniting the burner of the right stove 5 according to the pressing operation of the knob 11, and the gas supplied to the burner of the right stove 5 Adjust the amount. A battery box 15 is provided on the left side of the knob 13. The battery box 15 stores a dry battery (not shown) for supplying power to the gas stove 1.

  The structure of the thermal power adjustment device 20 will be described with reference to FIGS. Since all the thermal power control devices 20 corresponding to various burners have the same structure, the structure of the thermal power control device 20 corresponding to the burners of the right stove 5 will be described here. The thermal power adjustment device 20 includes a valve body 21, an airframe 22, an operation mechanism 23, and the like. The valve body 21 is provided in the lower part of the thermal power adjustment device 20, and is formed in a substantially cylindrical shape extending substantially horizontally. The valve body 21 is a main body of the thermal power adjustment device 20, and adjusts the amount of gas supplied to the burner of the right stove 5 by the rotation of the operation shaft 50 described later of the operation mechanism 23. The airframe 22 is placed on the top of the valve body 21 and fixed by two left and right screws 81 (see FIGS. 2 to 4). A substantially cylindrical gas discharge portion 37 is provided on the upper portion of the machine body 22. The airframe 22 discharges the gas flowing from the valve body 21 from the gas discharge unit 37 toward the burner of the right stove 5. The operating mechanism 23 is provided on the front side of the valve body 21. The operating mechanism 23 drives an igniter (not shown) provided in the vicinity of the burner of the right stove 5 by pushing and turning the knob 11 (see FIGS. 3 and 4) fitted to the front end of the operating shaft 50. The amount of gas flowing in the valve body 21 is adjusted.

  The internal structure of the valve body 21 and the airframe 22 will be described with reference to FIG. The valve body 21 has a gas flow passage inside. The gas flow path extends in the axial direction of the valve body 21. The valve body 21 includes a spindle 25, a main valve 26, a safety valve 27, a gas inlet 29, an outlet 31, a gas passage 32 and the like. The spindle 25 is inserted into the gas flow path of the valve body 21 and can move back and forth along the flow path. The front end portion of the spindle 25 is connected to the rear end portion of the operation shaft 50 of the operation mechanism 23 described later. The spindle 25 is pushed back together with the operation shaft 50 by the pushing operation of the knob 11 fitted to the front end portion of the operation shaft 50. The main valve 26 is fixed to the spindle 25 and opens and closes a gas flow path to the discharge port 31 described later by pushing and turning the knob 11. The safety valve 27 is of a magnet type, and is pushed backward by the pushing operation of the knob 11 at the time of ignition to open the gas flow path, and is held in the open state by the thermoelectromotive force at the burner combustion of the right stove 5.

  The gas inlet 29 is provided in the vicinity of the main valve 26. The gas inlet 29 opens downward to allow the gas to flow into the gas flow path in the valve body 21. The discharge port 31 is provided on the inner peripheral surface of the gas flow passage in the valve body 21 and on the downstream side of the main valve 26. The discharge port 31 changes the amount of gas discharged toward the gas flow path 32 depending on the overlapping area with the spindle 25 that rotates with the operation shaft 50. The gas flow path 32 extends upward from the discharge port 31, and the outlet thereof is provided at the top of the valve body 21.

  The airframe 22 includes gas flow paths 33 to 35 inside. The outlet of the gas flow passage 32 provided in the upper part of the valve body 21 communicates with the inlet of the gas flow passage 33 provided in the lower part of the airframe 22. The gas flows through the gas flow paths 33 to 35 in order, and is discharged from the gas discharge unit 37 toward the burner of the right stove 5.

  The structure of the operation mechanism 23 will be described with reference to FIGS. The operation mechanism 23 includes an operation shaft 50, a support member 40, a rotation plate 60, a plate spring 70, a first spring locking member 51 (see FIGS. 3 and 4), and a second spring locking member 52 (see FIGS. 3 and 4). 4), a return spring 53 (see FIGS. 3 and 4), a drive switch 55 (see FIG. 4), and the like.

  The operating shaft 50 will be described with reference to FIG. The operation shaft 50 is disposed substantially horizontally so as to extend in the front-rear direction, and the rear end side is inserted into the gas flow path from an opening (not shown) provided at the front end of the valve body 21 and the front end is frontward from the opening (See Figs. 2 and 3). A cross section orthogonal to the axial direction of the operation shaft 50 is formed in a substantially rectangular shape. The front end of the operation shaft 50 projects forward from between the left end of the right front wall 43 of the support member 40 described later and the notch 44A provided on the right end of the left front wall 44 (see FIG. 2, see Figure 5). The knob 11 is fitted to the front end of the operation shaft 50. The rear end of the operating shaft 50 is connected to the front end of the spindle 25 in the gas flow path. The operating shaft 50 can be rotated together with the spindle 25 and can be advanced and retracted in the front-rear direction, and the spindle 25 is pushed rearward by pushing and rotating the knob 11.

  The structure of the support member 40 will be described with reference to FIGS. As shown in FIG. 2, the support member 40 is formed in a substantially inverted U shape opened downward in a side view by bending a sheet metal, and is fixed to the front end portion of the valve body 21. The support member 40 includes a main body 41, an upper wall 42, a right front wall 43, a left front wall 44, and the like. The main body portion 41 is formed in a substantially rectangular shape that is vertically long in a front view, and has a substantially circular opening (not shown) at the approximate center thereof. The main body 41 is fixed to the front end of the valve body 21 by two screws 84 and 85. Inside the opening of the main body 41, an operation shaft 50 projecting forward from the front end of the valve body 21 is inserted so as to be able to move forward and backward. At a substantially central position in the vertical direction of the left end of the main body 41, a support 41A (see FIG. 4) extending backward is provided. A drive switch 55 described later is fixed to the support portion 41A. The upper wall portion 42 is formed in a substantially rectangular shape in a plan view, and is folded back from the upper end portion of the main body portion 41 and extends.

  As shown in FIGS. 2 and 5, the right front wall 43 extends vertically downward from the right side at the front end of the upper wall 42 and is formed in a substantially rectangular shape in a front view. At the lower left corner of the right front wall 43, a circular arc notch 43A is provided. The notch 43A avoids interference with a pin 78 provided at the tip of a plate spring 70 described later. At an upper portion of the right front wall 43, a fixing hole (not shown) for fixing a plate spring 70 described later with a screw 82 is provided. A pair of engagement holes 43B and 43C are provided above the fixing holes with a gap in the left-right direction. A pair of locking pieces 75 (see FIGS. 4 and 8) of the plate spring 70, described later, lock in the pair of engagement holes 43B and 43C.

  The left front wall portion 44 is provided on the left side at the front end portion of the upper wall portion 42, extends vertically downward from a position extending forward of the position of the left front wall portion 44, and is formed in a substantially rectangular shape in front view . Therefore, the left front wall 44 is disposed forward of the right front wall 43. The lower right corner of the left front wall 44 is provided with an arc-shaped notch 44A. The notch 44A avoids interference with the knob 11 (see FIG. 3) fitted to the front end of the operation shaft 50.

  The shape of the rotating plate 60 will be described with reference to FIGS. 2 and 7. As shown in FIG. 2, the pivot plate 60 is fixed to the front end side of the operation shaft 50 projecting forward from the front end portion of the valve body 21. The pivot plate 60 is disposed at substantially the same position as the right front wall 43 in the front-rear direction (see FIG. 3). The rotation plate 60 rotates integrally with the operation shaft 50 around the operation shaft 50. As shown in FIG. 7, the rotating plate 60 includes a disk portion 61 and a sliding portion 62 and is formed in a generally fan-like shape in a front view. The disk portion 61 is formed in a substantially circular shape in a front view, and a substantially rectangular insertion hole 65 is provided in a substantially central portion thereof. The operating shaft 50 is inserted into the insertion hole 65.

  The sliding portion 62 is formed in a substantially fan shape in a front view, and is provided along the outer peripheral portion of the disc portion 61. On the front surface of the sliding portion 62, a pin 78 provided at the tip of a plate spring 70, which will be described later, slides as the pivoting plate 60 pivots. When the sliding portion 62 is viewed from the front, the sliding portion 62 includes one end 67 on the downstream side in the counterclockwise direction about the insertion hole 65 and the other end 68 on the upstream side. The one end portion 67 is provided with a concave portion 67A recessed in an arc shape. The recess 67 </ b> A is located on the trajectory of the pin 78 sliding on the front surface of the sliding portion 62. Furthermore, an engagement hole 66 is provided on the trajectory of the pin 78 in the sliding portion 62 and in the vicinity of the recess 67A. The tip end of a pin 78 sliding on the front surface of the sliding portion 62 can be engaged with the engagement hole 66 in a hanging manner. The engagement hole 66 is formed in a substantially elliptical shape slightly longer in the direction orthogonal to the trajectory of the pin 78 on the front surface of the sliding portion 62. The inner edge portion of the engagement hole 66 is formed in a tapered shape so as to be tapered from the front side to the back side of the sliding portion 62 (see FIG. 13).

  When the pivoting plate 60 is attached to the operating shaft 50, as described above, since the pivoting plate 60 is formed in a fan-like shape in a front view, the front end portion of the operating shaft 50 projecting forward of the support member 40 is rotated By inserting the rotary plate 60 into the insertion hole 65 of the moving plate 60 and pushing it back as it is, the rotary plate 60 is not interfered with the notch portion 44A provided at the right end of the left front wall portion 44. It can be arranged at approximately the same position as Therefore, the mounting operation of the pivot plate 60 is easy. The portion in which the operation shaft 50 is inserted into the insertion hole 65 is fixed by a fixing washer 58 substantially C-shaped in a front view. Thus, the pivot plate 60 is fixed to the operation shaft 50.

  The structure of the plate spring 70 will be described with reference to FIGS. 2 and 8. As shown in FIG. 2, the leaf spring 70 is fixed to the front of the right front wall 43 of the support member 40. The plate spring 70 is formed by bending an elongated sheet metal extending downward from above, and extends from the portion fixed to the front surface of the right front wall 43 by the screw 82 to the front side of the pivot plate 60. As shown in FIG. 8, the plate spring 70 includes, in order from the top, the fixing portion 71, the inclined portion 72, the pin support portion 73, the pin 78, and the like.

  The fixing portion 71 is a portion fixed along the front surface of the right front wall portion 43 of the support member 40, and extends in the vertical direction. The fixing portion 71 is formed in a substantially rectangular shape that is vertically long in a front view, and includes a fixing hole (not shown), a pair of locking pieces 75, a positioning portion 76, and the like. The fixing hole is provided substantially at the center of the fixing portion 71. A screw 82 is inserted into the fixing hole, and is fastened to a fixing hole (not shown) provided on the right front wall 43 of the support member 40. The pair of locking pieces 75 (only one side is shown in FIG. 8) protrudes rearward from a position slightly above the fixing hole at both end portions of the fixing portion 71 in the left-right direction, and is formed in a substantially semicircular shape in side view There is. The pair of locking pieces 75 respectively lock in a pair of engagement holes 43B and 43C (see FIG. 2) provided in the right front wall 43 of the support member 40. Therefore, in the present embodiment, it is possible to prevent the positional deviation of the right front wall 43 of the plate spring 70 in the left-right direction. The positioning portion 76 is folded back and protrudes from the upper end portion of the fixing portion 71 and is formed in a substantially semicircular shape. The positioning portion 76 is locked to the upper surface of the upper wall portion 42 of the support member 40. Therefore, in the present embodiment, the positioning of the right front wall 43 of the plate spring 70 in the vertical direction can be facilitated.

  The inclined portion 72 is slightly bent to the front side from the lower end portion of the fixed portion 71 and extends obliquely downward. The inclined portion 72 is formed in a substantially rectangular shape that is longitudinally long in a front view (see FIGS. 2 and 5). The pin support portion 73 is slightly bent rearward from the tip end of the inclined portion 72 and extends obliquely downward. The pin support portion 73 is formed in a substantially rectangular shape that is vertically long in a front view (see FIGS. 2 and 5). The tip end portion of the pin support portion 73 is formed in a substantially arc shape.

  The pin 78 is made of metal and is supported by the pin support 73. The pin 78 coaxially has a base 78A and a conical portion 78B. The rear end face of the base 78A is fixed to the back of the pin support 73 by a rivet 77. The conical portion 78B is a tip portion of the pin 78 and is formed in a substantially conical shape. In a state in which the plate spring 70 is fixed to the front surface of the right front wall 43 of the support member 40, the pin 78 is disposed in the vicinity of the notch 43 A of the right front wall 43. The tip end portion of the pin 78 is located on the rotation locus of the engagement hole 66 of the rotation plate 60 which rotates with the operation shaft 50. Therefore, with the rotation of the rotation plate 60, the tip end portion of the pin 78 rides on and slides on the front surface of the rotation plate 60, and falls into the engagement hole 66. When the pivot plate 60 further pivots, the tip of the pin 78 comes out of the engagement hole 66. As will be described later, the axial direction of the pin 78 is in the direction away from the fixed portion 71 side with respect to the direction perpendicular to the front surface of the rotary plate 60 at the contact point where the tip of the pin 78 contacts the front surface of the rotary plate 60 It is inclined (see FIG. 13). In addition, the effect by making the axial direction of the pin 78 incline is mentioned later.

  The other members will be described with reference to FIGS. 3 and 4. The first spring locking member 51 is a substantially cylindrical member made of resin. The first spring locking member 51 is mounted on the operation shaft 50 and fixed to the back side of the pivot plate 60. The first spring locking member 51 includes a locking portion 51A and a biasing portion 51B. The locking portion 51A is formed in a substantially cylindrical shape, and is mounted on the operation shaft 50. The axial direction one end side of a substantially cylindrical return spring 53 mounted on the operation shaft 50 is engaged with the engagement portion 51A. The biasing portion 51B is formed in an arm shape, and protrudes leftward from the left side portion of the locking portion 51A. The tip end portion of the biasing portion 51B abuts on the operation element 56 of the drive switch 55 described later from below, and biases it upward (see FIG. 4).

  The second spring locking member 52 is also a substantially cylindrical member made of resin similar to the first spring locking member 51. The second spring locking member 52 is mounted on the operation shaft 50 and fixed to the front side of the main body 41 of the support member 40. The other axial end of the return spring 53 is engaged with the second spring engagement member 52. The first spring locking member 51 and the second spring locking member 52 are separated from each other in the front-rear direction between the front surface of the main body portion 41 of the support member 40 and the rear surface of the pivot plate 60. The return spring 53 is mounted on the operation shaft 50 in a state of being compressed between the first spring locking member 51 and the second spring locking member 52.

  As shown in FIG. 4, the drive switch 55 is fixed to a support portion 41A provided at the left end of the main body portion 41 of the support member 40 with a screw 86. The drive switch 55 is a switch for driving the igniter of the right stove 5. An arm-shaped operator 56 is provided on the bottom side of the drive switch 55. The proximal end side of the operator 56 is pivotally supported, and the distal end side extending forward is rotatable in the vertical direction. The biasing portion 51B of the first spring locking member 51 abuts on the tip end portion of the operating element 56 from below. When the tip of the operating element 56 is urged upward, a micro switch (not shown) provided on the bottom of the drive switch 55 is pushed upward by the operating element 56 to be turned off. On the other hand, when the first spring locking member 51 is rotated together with the operation shaft 50 by the push-and-turn operation of the knob 11, the biasing portion 51B is moved downward, so that the tip of the operating element 56 is also moved downward. At this time, the microswitch (not shown) is turned on.

  Next, a state prior to the ignition operation of the thermal power adjustment device 20 (during extinction) will be described. As shown in FIG. 1, the portion gripped by the hand of the knob 11 before the ignition operation is in the state of facing vertically. As shown in FIG. 4, the biasing portion 51 B of the first spring locking member 51 mounted on the operation shaft 50 contacts the lower end portion of the operating element 56 of the drive switch 55 from below and biases it upward. Do. The microswitch on the bottom of the drive switch 55 is pushed upward and is in the off state.

  As shown in FIGS. 2 and 5, the one end portion 67 of the rotating plate 60 is disposed with a gap in the clockwise direction with respect to the pin 78 of the plate spring 70. As shown in FIGS. 3 and 4, since the pivoting plate 60 is biased forward by the return spring 53, it is disposed at substantially the same position as the right front wall 43 of the support member 40. In this state, as shown in FIG. 5, the pin 78 is not in contact with the one end portion 67 of the rotating plate 60. Therefore, in the state before the ignition operation, no load is applied to the leaf spring 70, so that the durability of the leaf spring 70 can be improved.

  Furthermore, in the state before the ignition operation, the operating shaft 50 does not rotate inside the valve body 21 unless it is turned while pressing the knob 11, but a predetermined play is provided in the rotation direction There is. Therefore, even when the user erroneously rotates the knob 11 without pressing the knob 11 in the state prior to the ignition operation, the operating shaft 50 only pivots within the predetermined play range. There is no load. Thus, the durability of the plate spring 70 can be further improved.

  Next, the operation at the time of ignition operation of the thermal power adjustment device 20 will be described. In order to ignite the burner, the user performs an ignition operation of rotating the knob 11 by about 90 ° counterclockwise while pressing the knob 11. Along with the knob 11, the operating shaft 50 also pivots approximately 90 ° counterclockwise. Then, the main valve 26 in the valve body 21 shown in FIG. 6 opens and closes the gas flow path to the discharge port 31. The safety valve 27 is pushed rearward to open the gas flow path. Since the spindle 25 is rotated together with the operation shaft 50, the discharge port 31 is opened, and the gas flows toward the gas flow path 32. The gas flowing from the gas flow passage 32 to the gas flow passage 33 flows through the gas flow passages 34 and 35, and from the gas discharge portion 37 to a mixing pipe (not shown) provided in a burner main body (not shown) of the right stove 5. The gas is discharged towards. The mixed gas generated by mixing the primary air in the mixing tube is ejected from a plurality of flame ports (not shown) formed between the burner body of the right stove 5 and the burner head (not shown).

  On the other hand, together with the operation shaft 50, the first spring locking member 51 also rotates about 90 ° counterclockwise while being pushed rearward against the bias of the return spring 53. Then, as shown in FIG. 9, the biasing portion 51B of the first spring locking member 51 moves downward, so the operating element 56 of the drive switch 55 also moves downward. The drive switch 55 is turned on, and the igniter provided on the right stove 5 is driven. A flame is formed on the plurality of flame ports of the right stove 5 by being ignited by the gas ejected from the plurality of flame ports by the igniter. The safety valve 27 in the valve body 21 is held in the open state by the thermoelectromotive force at the time of the burner combustion of the right stove 5.

  Further, as shown in FIG. 5, together with the operation shaft 50, the rotary plate 60 is also turned about 90 ° counterclockwise (P direction in FIG. 5) while being pushed backward against the bias of the return spring 53. Move. At this time, the pivoting plate 60 pivots counterclockwise from a state in which it is pressed from substantially the same position as the right front wall 43 of the support member 40 to the tip of the conical portion 78B of the pin 78. Therefore, as shown in FIG. 9, the tip end portion of the pin 78 can smoothly ride on the front surface from the recess 67A of the one end portion 67 of the rotating plate 60.

  Then, as the pivoting plate 60 pivots counterclockwise, the tip end portion of the pin 78 slides from the one end side to the other end side of the front surface of the pivoting plate 60. As described above, since the pivoting plate 60 is pivoted counterclockwise in a state of being pushed backward, in a state where the tip of the pin 78 contacts the front surface of the pivoting plate 60, the plate spring 70 is a fixed portion Starting from 71, the inclined portion 72 and the pin support portion 73 only slightly bend in the direction away from the right front wall 43 in the forward direction. Therefore, since the impact when the tip of the pin 78 comes into contact with the engagement hole 66 is small, the user hardly feels a click. Therefore, this embodiment can realize a natural pushing operation of the knob 11 at the time of ignition operation by the knob 11.

  After the ignition is completed, the user releases the knob 11, so that the operation shaft 50 is biased forward by the return spring 53. Along with this, as shown in FIG. 13, the pivot plate 60 also moves forward, but the tip end of the pin 78 contacts the front surface of the pivot plate 60, so the plate spring 70 is screwed with the screw 82 of the fixed portion 71. Starting from the vicinity, the inclined portion 72 and the pin support portion 73 are bent so as to warp in a direction away from the front surface of the right front wall 43. The tip end portion of the pin 78 is pressed against the front surface of the rotating plate 60 by the elastic return force generated in the plate spring 70.

Next, the operation at the time of the thermal power adjustment of the thermal power adjustment device 20 will be described.
-From large thermal power to medium thermal power-
After the ignition is completed, the positional relationship between the pin 78 and the pivot plate 60 is as shown in FIG. The burner after the completion of ignition is adjusted to a large thermal power. In order to adjust the thermal power of the burner from the high thermal power to the medium thermal power, the user rotates the knob 11 clockwise. Then, as shown in FIG. 6, the operating shaft 50 and the spindle 25 rotate clockwise together with the knob 11. Along with this, the overlapping area of the discharge port 31 and the spindle 25 increases, so the opening area of the discharge port 31 decreases. Therefore, since the amount of gas flowing toward the gas flow path 32 is reduced, the burner of the right stove 5 is adjusted to medium heat power.

  On the other hand, as shown in FIG. 9, FIG. 10, and FIG. 13, together with the operation shaft 50, the pivot plate 60 also pivots clockwise (Q direction in the figure). Along with this, the tip end portion of the pin 78 slides in a circular arc shape from the other end 68 side to the one end portion 67 side in a state where it is pressed against the front surface of the rotary plate 60. The positional relationship between the pin 78 and the pivot plate 60 in the middle heating power is as shown in FIG.

-From middle power to small power-
In order to adjust the burner thermal power from medium thermal power to small thermal power, the user further rotates the knob 11 clockwise. Along with this, as shown in FIG. 6, since the overlapping area of the spindle 25 and the discharge port 31 is further reduced, the amount of gas flowing through the gas flow path 32 is further reduced, and the burner of the right stove 5 is adjusted to a small heating power. Be done.

  On the other hand, as shown in FIG. 10 and FIG. 11, together with the operation shaft 50, the pivoting plate 60 also pivots clockwise (Q direction in the figure). The tip of the pin 78 which has been sliding on the front surface of the rotary plate 60 until then when the power is switched from the middle power to the small power is swayed in the engagement hole 66 by the elastic return force of the plate spring 70. (See FIGS. 11 and 14). At this time, a small impact received from the pin 78 to the rotating plate 60 is applied to the user's hand as a click feeling via the operation shaft 50 and the knob 11. By using the click feeling as a clue, the user can clearly recognize the position where the medium power is switched to the low power, and therefore the operability of the power adjustment can be improved. In addition, when squeezing the fire power from middle to low heat power in cooking such as simmered food, it is possible to prevent the fire from disappearing because the heat power is excessively throttled.

-From small thermal power to fire extinguishing-
In order to further weaken the burner thermal power from the small thermal power and extinguish the fire, the user further rotates the knob 11 clockwise from the position where the click feeling is generated. Along with this, as shown in FIG. 6, the overlapping area of the spindle 25 and the discharge port 31 is further reduced, so the amount of gas flowing through the gas passage 32 is further reduced, and the power of the burner of the right stove 5 is even weaker. Become.

  On the other hand, as shown in FIG. 11 and FIG. 12, together with the operation shaft 50, the pivot plate 60 is further pivoted clockwise (Q direction in the figure). At this time, the tip end of the pin 78 engaged with the engagement hole 66 comes out to the one end 67 side along the tapered surface of the inner edge of the engagement hole 66, and climbs again on the front face of the rotary plate 60 (FIG. 12). reference). At this time, the leaf spring 70 bends again so that the inclined portion 72 and the pin support portion 73 are warped in a direction away from the front surface of the right front wall 43, with the vicinity of the screw 82 of the fixed portion 71 as a base point. The tip end portion of the pin 78 is pressed against the front surface of the rotating plate 60 by the elastic return force generated in the plate spring 70.

  Then, by further rotating the knob 11 clockwise (Q direction in the figure), the discharge port 31 is closed by the spindle 25 and the tip end of the pin 78 is a concave portion of the one end 67 It comes off counterclockwise from 67A. At this time, the biasing force of the plate spring 70 applied to the front surface of the pivoting plate 60 disappears at once, so the pivoting plate 60 and the operation shaft 50 are pushed forward by the return spring 53. The tip end portion of the pin 78 is separated from the front surface of the pivot plate 60 and is disposed in the gap between the notch 43A of the right front wall 43 and the recess 67A of the one end portion 67 of the pivot plate 60. Since the spindle 25 also moves forward with the operation shaft 50, the main valve 26 closes the gas flow path to the discharge port 31, and the safety valve 27 also moves forward to close the gas flow path. In this way, the right stove 5 is extinguished and returns to the state of FIG. In addition, since it becomes a flow contrary to the flow of the said operation | movement when adjusting from a small thermal power to a large thermal power, description is abbreviate | omitted.

  Thus, the gas stove 1 of the present embodiment can impart a click feeling to the knob 11 at a predetermined thermal position where the medium thermal power switches to the small thermal power when adjusting the thermal power of various burners. As a result, the user can finely adjust the burner thermal power with the click feeling as a clue, so the operability of thermal power regulation can be improved. And since this embodiment is a simple structure using only the rotation board 60 and the leaf | plate spring 70 provided with the pin 78, it can be easily attached to the structure of the conventional gas stove. Furthermore, since it has a simple structure, maintenance such as component replacement and repair is easy, and the cost of components can be reduced.

  The effect of tilting the axial direction of the pin 78 with respect to the front surface of the pivot plate 60 will be described with reference to FIGS. 13 to 15. The leaf spring 170 shown in FIG. 15 is adjusted so that the axial direction of the pin 78 is perpendicular to the front surface of the pivot plate 60. Since the other structure is the same as that of the plate spring 70 shown in FIG. 8, the same reference numerals will be given and described. When the tip end portion of the pin 78 is brought into contact with the front surface of the rotary plate 60 by using such a plate spring 170, the plate spring 170 uses the vicinity of the screw 82 of the fixed portion 71 as a base point. The inclined portion 72 and the pin support portion 73 are bent so as to warp in a direction away from the front surface of the right front wall 43. In this state, when the knob 11 is turned clockwise (from large thermal power to small thermal power: Q direction in FIG. 15) and counterclockwise (from small thermal power to large thermal power: R direction in FIG. 15) When the pin 78 is rotated, the strength of the click feeling produced when the pin 78 passes through the engagement hole 66 of the rotary plate 60 is different.

  For example, as shown in FIG. 16, when the knob 11 is rotated clockwise from the state where the tip of the pin 78 is engaged with the engagement hole 66 of the rotation plate 60 (from large thermal power to small thermal power) The pivot plate 60 pivots in the Q direction in FIG. The tip end portion of the pin 78 is pulled by the inner edge portion of the engagement hole 66 in the direction (S direction in FIG. 16) opposite to the fixing portion 71 side, so the plate spring 170 is pulled in the direction opposite to the fixing portion 71 side. It is ready to And since the inner edge of the engagement hole 66 is a tapered surface, the tip of the pin 78 slides out along the tapered surface so that it smoothly slips out to the one end 67 side. At this time, since the plate spring 170 is not subjected to a large stress, it can be said that the tip of the pin 78 is relatively easy to come out of the engagement hole 66. Thus, the click feeling produced when the tip of the pin 78 passes through the engagement hole 66 is reduced.

  On the other hand, when the knob 11 is turned counterclockwise from the state where the tip of the pin 78 is engaged with the engagement hole 66 of the rotation plate 60 (from small thermal power to large thermal power), the rotation plate 60 rotates in the R direction in FIG. The tip end portion of the pin 78 is pushed toward the fixed portion 71 (direction T in FIG. 16) by the inner edge portion of the engagement hole 66, but the flat spring 170 is inclined since the fixed portion 71 is fixed by the screw 82. The portion 72 and the pin support portion 73 are compressed between the pin 78 and the screw 82. In this case, since the plate spring 170 is subjected to a large stress, it can be said that the pin 78 is relatively difficult to disengage from the engagement hole 66. Therefore, the click feeling produced when the tip of the pin 78 passes through the engagement hole 66 is increased. As described above, the ease of removal of the pin 78 from the engagement hole 66 is different depending on the difference in the rotation direction of the rotation plate 60, so the click feeling generated when the tip of the pin 78 passes the engagement hole 66 Make a difference.

  Therefore, the present embodiment is provided with the following features in order to make the click feeling generated when the pin 78 passes through the engagement hole 66, even when the rotation plate 60 is rotated in any direction. . As shown in FIG. 13, the tip of the pin 78 contacts the front surface of the pivot plate 60 at the contact point A shown in FIG. The direction in which the rotary plate 60 at the contact point A rotates counterclockwise with the operation shaft 50 is the R direction shown in FIG. The R direction is substantially opposite to the direction from the fixing portion 71 fixed to the front surface of the right front wall portion 43 of the support member 40 of the plate spring 70 toward the tip end portion of the pin support portion 73.

  In such a configuration, the axial direction of the pin 78 is inclined to the side away from the fixing portion 71 with respect to the direction (K direction in FIG. 13) perpendicular to the front surface of the rotating plate 60 at the contact point A. Thereby, as shown in FIG. 14, when the tip end of the pin 78 is engaged with the engagement hole 66, the tapered surface of the end of the engagement hole 66 on the side of the one end 67 The tapered surfaces come to face each other. Thereby, when the knob 11 is rotated clockwise and the rotation plate 60 is rotated in the Q direction in FIG. 14, the tapered surface of the conical portion 78B of the pin 78 is one end portion 67 of the engagement hole 66. As it is strongly caught by the tapered surface on the side, it is possible to make it somewhat difficult to remove as compared with the plate spring 170.

  On the other hand, the tapered surface of the conical portion 78 </ b> B of the pin 78 is disposed more inclined to the tapered surface on the other end 68 side of the engagement hole 66. Thereby, when the knob 11 is turned counterclockwise and the turning plate 60 is turned in the R direction in FIG. 14, the tapered surface of the conical portion 78B of the pin 78 is the corner on the front side of the engagement hole 66 Since it slips out to the other end 68 side so as to slide the portion 66A, it can be slightly easier to remove than the plate spring 170. As a result, since the click feeling can be made uniform between the case where the knob 11 is rotated from the large thermal power to the small thermal power and the case where the knob 11 is rotated from the small thermal power to the large thermal power, more natural rotation of the knob 11 Can provide the operation.

  As described above, the gas stove 1 of the present embodiment includes the thermal power adjustment device 20 that adjusts the thermal power of the burner of the right stove 5. The thermal power adjustment device 20 includes an operation shaft 50, a rotating plate 60, and a plate spring 70. The operating shaft 50 is pivotally supported by a valve body 21 which is a main body of the thermal power adjustment device 20, and is rotationally operated to adjust the thermal power. The rotating plate 60 is provided integrally with the operating shaft 50 and rotates around the operating shaft 50. An engagement hole 66 is provided on the front surface of the pivot plate 60. The plate spring 70 is fixed to the valve body 21 through the support member 40 and extends from the fixed portion 71 fixed to the front surface of the right front wall 43 of the support member 40 to the front side of the pivot plate 60. A pin 78 is provided at the tip of the plate spring 70. The pin 78 is disposed on the rotation trajectory of the engagement hole 66 which is rotated as the rotation plate 60 is rotated. The plate spring 70 urges the tip end portion provided with the pin 78 to the front side of the rotating plate 60. When the pivoting plate 60 is pivoted to a position where it switches to a predetermined thermal power, the pin 78 comes into engagement with the engagement hole 66. An impact generated when the pin 78 engages with the engagement hole 66 is transmitted as a click feeling to the user's hand via the operation shaft 50. By using the click feeling as a clue, the user can use it as an indicator of the thermal power adjustment, so the operability of the thermal power adjustment can be improved. In addition, since it has a simple structure in which the pivot plate 60 is provided on the operation shaft 50 and the plate spring 70 fixing the pin 78 is simply attached, attachment, component replacement, repair, etc. are easy, and the component cost is suppressed inexpensively. Be

  Further, the thermal power adjustment device 20 of the above embodiment performs the ignition operation to turn counterclockwise while pushing the knob 11 provided on the operation shaft 50 in the axial direction of the operation shaft 50, thereby making the gas to the burner It has a function to open the flow path. The counterclockwise direction is the direction when adjusting the thermal power from small thermal power to large thermal power. Further, the rotating plate 60 is formed in a substantially fan-like shape with the operation shaft 50 as a center. Furthermore, before the ignition operation and at the time of extinguishing the burner, the pin 78 separates from the one end 67 on the downstream side in the counterclockwise direction, which rotates with the operation shaft 50, of both ends in the outer peripheral direction of the rotating plate 60, And, it is disposed with a gap in one direction from one end portion 67. At the time of the ignition operation, the pin 78 rides on the front surface from the one end portion 67 side, and slides toward the other upstream end portion 68 opposite to the one end portion 67. As described above, before the ignition operation of the knob 11, the pin 78 provided at the tip of the plate spring 70 is separated from the rotating plate 60 and is disposed with a gap. Thereby, the load can not be applied to the plate spring 70 before the ignition operation, so that the durability of the plate spring 70 can be improved.

  Further, in the above embodiment, since the play is provided in the rotation direction of the operating shaft 50 with respect to the operating shaft 50 before the ignition operation and at the time of the fire extinguishing, the user does not press the knob 11 by the erroneous operation before the ignition operation. Since the operation shaft 50 only rotates within the range of play when it is turned, the load on the plate spring 70 is not applied even if the pivot plate 60 contacts the plate spring 70. Thereby, the durability of the plate spring 70 can be improved.

  Moreover, the said embodiment is equipped with the return spring 53 which biases the operation shaft 50 on the opposite side to the direction which pushes in the knob 11. As shown in FIG. Furthermore, at the time of the ignition operation, the pivot plate 60 pivots in a state of being pushed in with the operation shaft 50. Thereby, when the knob 11 is pushed around at the time of ignition operation, the pin 78 moves in the direction away from the front surface of the rotary plate 60, so that the click feeling obtained when passing through the engagement hole 66 can be relaxed. Therefore, the user can operate the knob 11 without discomfort at the time of the ignition operation.

  In the above embodiment, the counterclockwise direction (R direction in FIG. 13) in which the pivot plate 60 at the contact point where the tip of the pin 78 contacts the front surface of the pivot plate 60 pivots with the operation shaft 50 The direction is substantially opposite to the direction from the fixing portion 71 fixed to the support member 40 of the spring 70 toward the tip end portion. The axial direction of the pin 78 is inclined in the direction away from the fixed portion 71 with respect to the direction (direction K in FIG. 13) perpendicular to the front surface of the rotary plate 60 at the contact point with the tip of the pin 78. There is. This makes it possible to equalize the ease of removal of the pin 78 from the engagement hole 66 when the rotating plate 60 rotates clockwise and counterclockwise with the operation shaft 50. Therefore, it is possible to make the click feeling generated when the operation shaft 50 is rotated clockwise and counterclockwise.

  Further, in the above-described embodiment, the inner edge portion of the engagement hole 66 provided in the rotating plate 60 is formed in a tapered shape. Thus, the tip end of the pin 78 smoothly engages with and disengages from the engagement hole 66, so that a smooth click feeling can be obtained.

  Further, in the above embodiment, the click feeling is given at the position of the thermal power between the middle thermal power and the small thermal power, so for example, when squeezing the thermal power from middle thermal power to small thermal power in cooking, It is possible to prevent the fire from disappearing because it is too narrow.

  In addition, this invention is not limited to the said embodiment, A various change is possible. In the above embodiment, the position of the engagement hole 66 of the rotating plate 60 is determined so that the click feeling is given at the fire power position between the middle heat power and the small heat power. It may be given. For example, the click feeling may be given at the thermal position between the large thermal power and the middle thermal power. In the above embodiment, one engagement hole 66 is provided in the pivot plate 60. However, by providing a plurality of engagement holes 66, click feeling may be provided at a plurality of thermal power positions.

  Moreover, although the engagement hole 66 penetrated in the plate | board thickness direction is provided in the rotation plate 60 of the said embodiment, it is not necessary to penetrate and it is dented and formed in concave shape from the front side to the back side. It may be a groove. Also, instead of the engagement hole 66, a convex portion that protrudes to the front side may be provided. Even such a thing can give a click feeling.

  Further, in the above embodiment, the turning direction of the knob 11 at the time of the ignition operation, at the time of the thermal power adjustment or the like may be reverse. For example, at the time of ignition operation, the knob 11 may be pushed clockwise, and when adjusting from a large thermal power to a small thermal power, the knob 11 may be rotated counterclockwise.

  Moreover, the structure in the valve body 21 is not limited to the said embodiment. Moreover, the shape of the rotation plate 60 may be, for example, a circle other than the substantially fan-like shape as in the above embodiment, or may be a substantially fan-shape having an obtuse central angle.

  Further, in the above embodiment, the arrangement direction of the plate spring 70 with respect to the rotation plate 60 is arranged to extend downward from the fixing portion 71 fixed by the screw 82, for example, the tip of the pin 78 is The contacts in contact with the front surface of the pivot plate 60 may be arranged laterally or obliquely.

  In the above embodiment, the return spring 53 is used as biasing means for biasing the operation shaft 50 in the direction opposite to the direction in which the knob 11 is pushed, but an elastic member other than a spring may be used. An elastic member such as a spring, rubber, or resin may be used. In addition, the return spring 53 may not be attached to the operation shaft 50.

1 Gas Stove 5 Right Stove 11 Knob 20 Fire Power Regulator 21 Valve Body 40 Support Member 50 Operation Shaft 53 Return Spring 60 Rotating Plate 66 Engaging Hole 67 One End 68 Other End 70 Leaf Spring 71 Fixing Part 78 Pin A Contact

Claims (6)

In the gas stove equipped with a thermal power control system to control the thermal power of the burner,
The thermal power controller is
Body part,
An operating shaft rotatably supported on the main body and rotated for adjusting the thermal power;
A rotary plate provided integrally with the operation shaft and rotating around the operation shaft;
A groove or a hole provided on one side of the rotating plate;
A plate spring fixed to the main body and extending from the fixed part fixed to the main body to the one side of the pivot plate;
It is provided at the tip of the plate spring, and is disposed on the rotation locus of the groove or the hole which is rotated with the rotation of the rotation plate, and the rotation plate is rotated to a predetermined thermal power position. And a pin engageable with the groove or the hole when moved.
The leaf spring biases the tip end provided with the pin to the one side of the rotating plate ,
The thermal power controller may further
By pressing the knob provided on the operating shaft in the axial direction of the operating shaft, an ignition operation is performed to rotate the thermal power in one direction which is a direction when adjusting the thermal power from small thermal power to large thermal power, to the burner Has a function to open the gas flow path,
The pivoting plate is formed in a substantially fan shape centered on the operation axis,
Before the ignition operation and at the time of extinguishment of the burner, the pin is separated from the one end on the downstream side of the one direction which is rotated with the operation shaft among the both ends in the outer peripheral direction of the rotating plate A gap is provided from the one end on the downstream side to the one side,
At the time of ignition operation, the pin runs on the one side from the downstream one end side of the rotating plate rotating in one direction, and the other side of the upstream side opposite to the one end on the downstream side A gas cooker characterized by sliding toward the end . Gas stove according to claim 1, with respect to the operating axis of the ignition operation before and extinguishing, characterized in that a play in the rotational direction of the operating shaft. Biasing means for biasing the operating shaft is provided on the side opposite to the direction in which the knob is pushed,
The gas stove according to claim 1 or 2 , wherein at the time of ignition operation, the pivoting plate pivots in a state of being pushed in with the operation shaft. The one direction in which the pivot plate rotates with the operation shaft at the contact point where the tip of the pin contacts the one surface of the pivot plate is from the fixed portion fixed to the main body of the leaf spring Substantially opposite to the direction towards the tip,
The axial direction of the said pin inclines in the direction away from the said fixing | fixed part side with respect to the direction perpendicular | vertical to the said single side | surface of the said rotating plate in the said contact point, The any one of Claim 1 to 3 characterized by the above-mentioned. Gas stove described in one. The gas stove according to any one of claims 1 to 4 , wherein an inner edge of the groove or the hole is formed in a tapered shape. The gas stove according to any one of claims 1 to 5 , wherein the predetermined heating position is a heating position between middle heating power and small heating power.

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