JP2019027659A - Gas cooking stove - Google Patents

Abstract

To provide a gas cooking stove which can display a fire power with a simple configuration.SOLUTION: A fuel supply device 20 adjusts a fire power of a burner by rotationally operating an operation knob 14. The fuel supply device 20 is attached to a back surface of a panel body 50 of a panel device 9B, and the operation knob 14 is exposed on a front surface of a decorative panel 80 through a through hole 53. On an upper outer periphery of the through hole 53, a plurality of cylindrical light guide parts 54 are aligned in a peripheral direction. An LED 61 are provided in a cylindrical hole 55 of the light guide part 54. A flanged cylindrical part 70 is provided in the through hole 53, and shields the light of the LED 61 with a flange part provided on a front side of the light guide part 54. The flanged cylindrical part 70 rotates along with the operation knob 14. The flange part has a notch-like light passing part. The flanged cylindrical part 70 changes the light guide part 54 in which the light of the LED 61 can pass through the light passing part according to a rotational position. The panel device 9B illuminates the light of the LED 61 that has passed through the light passing part on a front surface of the decorative panel 80 and displays the fire power.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a gas stove.

  The gas stove includes a fuel supply device that supplies gas to the stove burner. For example, the combustion amount adjusting body described in Patent Document 1 has a push / push mechanism that can be rotated, and is projected or accommodated from the front surface of the stove body by a pushing operation. At the time of protrusion, the controller performs an ignition process for the combustor. The controller detects the amount of rotation of the combustion amount adjusting body by a position sensor, and drives the motor according to the detected amount to adjust the amount of gas supplied to the burner. Further, the controller performs light emission control of the LED that displays the thermal power according to the detection amount of the position sensor.

JP 2015-36593 A

  However, in order to reduce the cost, if the controller, position sensor, and other devices and parts are omitted, and the ignition process of the burner and the adjustment of the gas supply amount are performed with a mechanical configuration such as a cam, Since the amount of rotation operation is not known, it is difficult to display the thermal power by turning on the LED.

  The objective of this invention is providing the gas stove which can perform a thermal power display with a simple structure.

  The gas stove of the invention according to claim 1 of the present invention is a casing in which a stove burner is disposed at an upper portion, and is disposed in a front portion in the casing, and supplies gas to the stove burner, and is connected to the stove burner. A gas stove comprising: a fuel supply device including an operation unit that performs gas supply and shutoff operations; and a panel device that is fixed to the housing in front of the fuel supply device and indicates an operation state of the operation unit. The operation part of the fuel supply device is in a state of projecting from the front surface of the panel device at least when supplying gas, and the supply amount of gas supplied to the burner can be adjusted by a turning operation. An operation knob, and the panel device is fixed to the casing in front of the fuel supply device, penetrates in the front-rear direction, and has a through-hole in which the operation knob is disposed; A light emitting portion that emits light by being provided in a region in a predetermined range along the circumferential direction outside the through hole in the radial direction on the back surface of the panel body, and a cylindrical shape. Present in the through-hole, and a main body portion rotatably disposed in the outer peripheral surface of the main body portion, projecting radially outward in at least a part of the circumferential direction, and disposed on the front side of the light-emitting portion A flange portion that blocks light from the light emitting portion, a light passage portion that is formed in a hole shape or a notch shape in a part of the circumferential direction of the flange portion, and allows the light from the light emitting portion to pass through; and the operation portion And a hooked cylindrical portion having an engaging portion that rotates the main body portion in response to a turning operation of the operation knob, and a front portion of the panel main body, and the through hole and the front and rear Opening at a position overlapping in the direction, the opening where the operation knob is disposed, and the opening. A decorative panel having a translucent part provided around the part in a position overlapping with the light emitting part in the front-rear direction, the light emitting part being emitted and transmitting the light that has passed through the light passing part. It is characterized by that.

  A gas stove according to a second aspect of the present invention is the gas stove according to the first aspect, in addition to the configuration of the first aspect, the flange portion is formed in a bowl shape on the entire outer surface of the main body portion excluding the light passage portion. It is characterized by that.

  A gas stove according to a third aspect of the present invention is the gas stove according to the first or second aspect, wherein the panel body has a hole portion through which light passes in the front-rear direction, and is surrounded around the through hole. A plurality of light guides arranged in a direction are provided, and the light emitting unit emits light toward the surface side of the panel body through the plurality of light guides.

  The gas stove of the invention according to claim 4 is characterized in that, in addition to the configuration of the invention according to claim 3, the light guide portion is formed in a cylindrical shape extending in the front-rear direction.

  A gas stove according to a fifth aspect of the present invention is the gas stove according to the third or fourth aspect, wherein the light emitting section includes a plurality of light sources corresponding to the arrangement positions of the plurality of light guide sections. Features.

  A gas stove according to a sixth aspect of the present invention is the gas stove according to any one of the third to fifth aspects, wherein the plurality of light guides are arranged at equal intervals in a circumferential direction of the through hole, The width of the light passage part in the circumferential direction of the flange part is 1 time or more and less than 2 times the arrangement interval of the plurality of light guide parts.

  A gas stove according to a seventh aspect of the present invention is the gas stove according to any one of the first to sixth aspects, wherein the light emitting portion is disposed along a circumferential direction at an upper portion of the through hole, When there are a plurality of fuel supply devices arranged side by side at the front of the housing, the through holes of the panel body corresponding to the adjacent fuel supply devices are arranged in the respective through holes. The flanged portions of the flanged tube portion are formed at positions where the flange portions overlap in the front-rear direction, and the flange portion is located on the counterclockwise side when divided in half in the circumferential direction with respect to the light passage portion. The first part and the second part located in the clockwise direction are formed at positions that are stepped in the front-rear direction, and one of the flanges among the two flanged tubular parts respectively disposed in the adjacent through holes. The flange in the flange portion of the attached tube portion In part, with respect to the second portion in the flange portion of the other of the flanged tubular portion, characterized in that it is disposed at a position overlapping in the longitudinal direction.

  A gas stove according to an eighth aspect of the present invention is the gas stove according to any one of the first to seventh aspects, wherein the decorative panel has an annular shape and an inner diameter is larger than an outer diameter of the operation knob. An annular portion disposed in the opening is provided.

  According to the gas stove of the invention according to claim 1, the flanged cylindrical portion blocks light emitted from the light emitting portion by the flange portion. The light passage part of the flange part is formed in a part of the flange part, thereby allowing a part of the light from the light emitting part to pass therethrough. Since the flanged tube portion rotates according to the turning operation of the operation knob, the light from the light emitting portion irradiates the front of the panel device at the position where the light passage portion is arranged according to the turning position of the operation knob. Is done. In other words, the gas stove can indicate the thermal power display corresponding to the rotation position of the operation knob by the light that has passed through the light passage portion. Thereby, for example, the rotation position of the operation knob can be detected by an encoder or the like, and the thermal power display can be performed without using various parts and the like that are necessary for indicating the detected position by an LED or the like, thereby reducing the production cost. Can be reduced. In addition, the light passage portion allows light from the light emitting portion to pass through only a predetermined portion corresponding to the rotation position of the operation knob. In other words, only the portion of the light transmitting portion corresponding to the current thermal power shines pinpoint. Therefore, the gas stove excellent in the recognizability of the thermal power display can be provided with a simple configuration.

  According to the gas stove of the invention according to claim 2, in addition to the effect of the invention according to claim 1, the entire circumference of the flange portion excluding the light passage portion is formed in a bowl shape. Therefore, the flange portion can reliably block light from the light emitting portion even if there is some dimensional error in the arrangement of the light emitting portion, etc. It is possible to prevent leakage to the front side of the panel.

  According to the gas stove of the invention according to claim 3, in addition to the effect of the invention according to claim 1 or 2, the portion of the light emitted from the light emitting portion that is irradiated forward by the plurality of light guide portions is limited. Furthermore, only the light that has passed through the light guide portion located at a predetermined portion where the light passage portion is arranged according to the rotation position of the operation knob among the light that has passed through the plurality of light guide portions reaches the light transmitting portion. , Only the part corresponding to the current firepower is shining pinpoint. The light that displays the thermal power in the light-transmitting part is in the shape of the hole of the light guide part, so that the recognizability of the thermal power display can be further enhanced.

  According to the gas stove of the invention according to claim 4, in addition to the effect of the invention according to claim 3, the light from the light emitting part can pass through the hole (cylinder hole) of the cylindrical light guide part. The light that can be produced is limited to light that travels forward. Therefore, the light that displays the thermal power in the translucent portion is suppressed from spreading and has a clear outline, so that the recognizability of the thermal power display can be further enhanced.

  According to the gas stove of the invention according to claim 5, in addition to the effect of the invention according to claim 3 or 4, the light passing through the light passage part and reaching the light transmission part corresponds to each of the plurality of light guide parts. Therefore, the intensity of light is higher than that of diffused light from a single light source. Therefore, since the light for displaying the thermal power in the light transmitting portion is relatively bright, the recognizability of the thermal power display can be further enhanced.

  According to the gas stove of the invention according to claim 6, in addition to the effect of the invention according to any one of claims 3 to 5, no matter which position the operation knob rotates, one or two light passing portions are provided. Two light guides are exposed. Therefore, in the gas stove, the light passage part is located between the two light guide parts, the flange part closes all the light guide parts, all the light from the light emitting part is blocked, and the thermal power display is not made. Can be prevented.

  According to the gas stove of the invention according to claim 7, in addition to the effect of the invention according to any one of claims 1 to 6, when the fuel supply devices are arranged side by side, the flanged cylinder arranged in the adjacent through hole Since the through holes are formed apart from each other so that the flange portions do not interfere with each other, the panel device needs to ensure a large lateral width. As described above, the panel device can be formed with the through-holes close to the left and right by reducing the width by arranging the flanges so as not to interfere even if they are arranged at positions where the flanges overlap in the front-rear direction. be able to. In addition, since the fuel supply device can be disposed close to the left and right in the housing, the space occupied by the fuel supply device in the housing can be reduced, and the freedom of the layout in the housing can be increased.

  According to the gas stove of the invention according to claim 8, in addition to the effect of the invention according to any one of claims 1 to 7, when light from the light emitting part passes through the light transmitting part, the diffused reflection causes the opening in the opening part. May head. The annular portion can prevent the light leaking from the light transmitting portion from illuminating the inside of the opening, and can enhance the recognizability of the thermal power display.

  In the present invention, the invention-specific matters of claims 1 to 8 may be arbitrarily combined.

1 is a perspective view of a gas stove 1. 2 is a perspective view of a fuel supply device 20. FIG. It is a disassembled perspective view of the panel apparatus 9B. 4 is a perspective view of an upper portion 52 of the panel body 50. FIG. It is a perspective view of the collar part 70 with a collar. 3 is an exploded perspective view of a decorative panel 80. FIG. It is a front view of the panel apparatus 9B which removed the decorative panel 80. FIG.

  Embodiments of the present invention will be described below. The structure of the apparatus described below is merely an illustrative example, and is not intended to be limited to that unless otherwise specified. The drawings are used to explain technical features that can be adopted by the present invention. In the following description, left, right, front, back, and top and bottom indicated by arrows in the figure are used.

  The gas stove 1 will be described with reference to FIG. The gas stove 1 is a built-in stove. The gas stove 1 includes a housing 2 and a top plate 3. The housing 2 is open at the top, and the top plate 3 is installed at the opening. In the top 3, a right burner 4 is provided on the right front side, a left burner 5 is provided on the left front side, and a back burner 6 is provided on the center rear side. An exhaust port 7 of a grill device (not shown) installed in the housing 2 is provided at the rear portion of the top plate 3.

  A grill door 8 is provided in the approximate center of the front surface of the gas stove 1. The grill door 8 opens and closes a front opening portion of a grill cabinet (not shown) provided in the grill device. In the area on the right side of the grill door 8, two operation knobs 11 and 12 having a circular shape in front view are provided side by side in the horizontal direction. In the left region of the grill door 8, two operation knobs 13 and 14 having the same shape are provided side by side in the same height position as the operation knobs 11 and 12. The operation knobs 11 to 14 are operated to ignite, extinguish, and adjust the thermal power of the right burner 4, the grill burner (not shown) in the grill cabinet, the back burner 6, and the left burner 5, respectively. The operation knobs 11 to 14 are respectively attached to the front end portion of the fuel supply device 20 (see FIG. 2).

  The fuel supply device 20 will be described with reference to FIG. The gas stove 1 includes a right burner 4, a left burner 5, a back burner 6, and four fuel supply devices that supply gas to the grill device. Among them, the fuel supply device 20 that supplies gas to the right burner 4, the left burner 5, and the back burner 6 is a device having the same configuration including a known push-push mechanism 24. A fuel supply device (not shown) for supplying gas to the grill device includes a push-push mechanism similar to that of the fuel supply device 20, but a gas flow rate is adjusted by an electromagnetic valve. ) Is provided separately. Hereinafter, the fuel supply device 20 that supplies gas to the left burner 5 will be described as an example, and description of the fuel supply device that supplies gas to the right burner 4, the back burner 6, and the grill device will be omitted. Note that the fuel supply device that supplies gas to the right burner 4 and the fuel supply device that supplies gas to the back burner 6 have the same configuration as the fuel supply device 20, and therefore, for convenience, the same reference numerals are attached for the sake of convenience. Called device 20.

  As shown in FIG. 2, the fuel supply device 20 is a device that performs ignition and extinguishing of the left burner 5 and adjustment of the amount of gas supplied to the left burner 5 by pushing and rotating the operation knob 14. The pushing operation is an operation of pushing the front surface of the operation knob 14 rearward and pushing the operation knob 14 inward from the front surface of the gas stove 1. The rotation operation is an operation of gripping the side surface of the operation knob 14 and rotating around the axis in the front-rear direction (axial center AX). The fuel supply device 20 includes an operation unit 21, a gas flow path unit 22, a thermal power adjustment cam 26, a flow rate adjustment unit 31, and the like.

  The operation unit 21 includes an operation knob 14, a push / push mechanism 24, and a connecting member 25. The connecting member 25 will be described later. The operation knob 14 is formed in a substantially cylindrical shape. The operation knob 14 is moved toward each position of the standby position, the push-in position, and the operation position by being pushed and moved toward the rear of the gas stove 1. The standby position is a position where the front end surface of the operation knob 14 is substantially flush with the front surface of the gas stove 1. In the standby position, the front end surface of the operation knob 14 may be positioned slightly rearward from the front surface of the gas stove 1 or may be positioned slightly forward. In the fuel supply device 20 shown in FIG. 2, the operation knob 14 is located at the standby position. The pushing position is a position where the front end surface of the operation knob 14 is pushed backward from the front surface of the gas stove 1. The operation knob 14 is located behind the standby position at the push-in position. The operation position is a position where the front end surface of the operation knob 14 protrudes from the front surface of the gas stove 1. The operation knob 14 is positioned in front of the standby position at the operation position. When in the operation position, the operation knob 14 is rotatable (rotatable) about the axis AX along the front-rear direction.

  The push-push mechanism 24 positions the operation knob 14 at each of the standby position, the push-in position, and the operation position, and maintains a main valve (not shown) described later in an open state or a closed state according to each position. Inside the push-push mechanism 24, a slider (not shown) that moves in the front-rear direction in accordance with the pushing operation of the operation knob 14, a spring that urges the slider forward, and a valve drive that drives the main valve A portion (not shown) is provided. A known cam mechanism (not shown) is provided on the slider. Each time the operation knob 14 is pushed in, the slider repeats an operation of moving the operation knob 14 from the standby position to the operation position via the push position and an operation of moving from the operation position to the standby position via the push position. The valve drive unit performs an operation of opening and maintaining the main valve in conjunction with the operation of the operation knob 14 moving from the standby position to the operation position, and the operation knob 14 moves from the operation position to the standby position. In conjunction with the operation, the main valve is closed and maintained in the closed state.

  The gas flow path portion 22 is connected to the rear side of the push / push mechanism 24. A first gas passage (not shown) is formed inside the gas flow path portion 22. The first gas passage circulates the gas supplied from a gas supply pipe (not shown) connected to the introduction port 23 opened in the lower part to the flow rate adjusting unit 31. A safety valve (not shown) and a main valve (not shown) are provided in the first gas passage. The safety valve is an electromagnetically operated valve that is elastically biased to a closed state that closes the first gas passage. The main valve is a valve that opens and closes the first gas passage in accordance with the pushing operation of the operation knob 14. Since the main valve and the safety valve are both known, detailed description of the operation is omitted.

  The flow rate adjusting unit 31 is provided above the push / push mechanism 24 and the gas flow path unit 22. A second gas passage (not shown) is formed inside the flow rate adjusting unit 31. The second gas passage circulates the gas supplied from the gas flow path portion 22 and supplies the gas to the left burner 5 via a gas supply pipe (not shown) connected to the outlet 32 that opens to the top. A hole 30 communicating with the second gas passage is formed at the front end of the flow rate adjusting unit 31 and the needle valve 28 is inserted therein. The needle valve 28 is disposed such that the front end side is exposed to the outside from the hole 30 and the rear end side is movable in the front-rear direction in the second gas passage. A pin 29 extending in the vertical direction is provided at the front end of the needle valve 28. The lower end portion of the pin 29 engages with a cam groove 27 (described later) of the heating power adjustment cam 26.

  The thermal power adjustment cam 26 is formed in a substantially semi-cylindrical shape, and is provided so as to be rotatable around the axis AX so as to cover the upper part of the front end side of the push-push mechanism 24. The thermal power adjustment cam 26 is restricted from moving in the front-rear direction. A cam groove 27 is provided on the outer peripheral portion of the thermal power adjustment cam 26. The cam groove 27 is formed in a spiral shape centered on the axis AX. The cam groove 27 engages with a lower end portion of a pin 29 provided on the needle valve 28. When the heating power adjustment cam 26 rotates, the cam groove 27 guides the pin 29 and moves the needle valve 28 in the front-rear direction.

  The thermal power adjustment cam 26 includes an extending portion (not shown) extending forward, and has a tooth portion 35 (see FIG. 3) protruding inward at a front end portion of the extending portion. The tooth portion 35 meshes with a tooth portion 38 (described later) of the connection member 25 when the operation knob 14 is in the operation position, and the thermal power adjustment cam 26 is rotated around the shaft center AX together with the operation knob 14 via the connection member 25. To do. An LED operation member 36 is fixed to the outer peripheral surface of the extending portion of the thermal power adjustment cam 26. The LED operation member 36 has an engagement piece 37 extending forward. The LED operation member 36 is engaged with a flanged cylinder part 70 (described later), and rotates the flanged cylinder part 70 around the axis AX together with the heating power adjusting cam 26.

  The connecting member 25 of the operation unit 21 extends forward from the slider of the push / push mechanism 24 and engages with a shaft body (not shown) having the shaft center AX as an axis. The connecting member 25 is fixed to the operation knob 14 integrally at the front end, and is provided so as to be rotatable around the axis AX together with the operation knob 14. The connecting member 25 has a tooth portion 38 that meshes with the tooth portion 35 of the heating power adjustment cam 26 on the outer peripheral surface of the rear end portion. When the operation knob 14 is in the operation position, the tooth portion 38 of the connecting member 25 meshes with the tooth portion 35 of the heating power adjustment cam 26 to connect the operation knob 14 and the heating power adjustment cam 26. When the operation knob 14 is not in the operation position, the tooth portion 35 of the heating power adjustment cam 26 is positioned in front of the tooth portion 38 of the connecting member 25 and does not mesh, and the connection state of the operation knob 14 and the heating power adjustment cam 26 is changed. To release.

  Next, the ignition and extinguishing and the adjustment of the thermal power by rotating the operation knob 14 will be described. When the left burner 5 is extinguished, the operation knob 14 is in the standby position. In the process in which the user pushes the operation knob 14 and the operation knob 14 moves to the pushing position, the safety valve and the main valve are opened, and the left burner 5 is ignited by an igniter (not shown). When the user releases the operation knob 14, the operation knob 14 is moved to the operation position by the bias of the spring. The safety valve and the main valve are kept open. The operation knob 14 and the heating power adjustment cam 26 are connected by the connecting member 25.

  When the operation knob 14 is rotated while the operation knob 14 is in the operation position, the heating power adjustment cam 26 rotates around the axis AX together with the operation knob 14. When the thermal power adjustment cam 26 rotates, the pin 29 of the needle valve 28 is guided by the cam groove 27 and moves in the front-rear direction. Thereby, since the needle valve 28 moves in the front-rear direction, the flow rate of the gas flowing through the second gas passage is adjusted according to the position of the needle valve 28, and the heating power of the left burner 5 is changed.

  In the process where the user pushes the operation knob 14 and the operation knob 14 moves to the pushing position, the safety valve and the main valve are closed. The left burner 5 is extinguished. When the user releases the operation knob 14, the operation knob 14 moves to the standby position by the bias of the spring. The safety valve and the main valve are kept closed.

  As described above, the fuel supply device 20 adjusts the flow rate of the gas flowing through the second gas passage of the flow rate adjusting unit 31 by the thermal power adjusting cam 26 moving the needle valve 28 in accordance with the turning operation of the operation knob 14. Adjust steplessly. That is, the heating power of the left burner 5 changes linearly according to the rotation amount of the operation knob 14. The same applies to the operation knobs 11 and 13 corresponding to the right burner 4 and the back burner 6, respectively. The gas stove 1 includes a thermal power display function in the panel devices 9A and 9B provided on the front surface in order to perform thermal power display according to the rotation amounts of the operation knobs 11, 13, and 14, respectively.

  As shown in FIG. 1, the gas stove 1 is provided with a right burner 4 and a panel device 9 </ b> A for displaying the thermal power of the grill device in the right region of the grill door 8, and the left burner 5 in the left region of the grill door 8. A panel device 9B for displaying the thermal power of the back burner 6 is provided.

  The fuel supply device of the grill device includes a plurality of switches (not shown) that are turned on and off according to the rotation position of the operation knob 12. The flow rate adjusting unit of the grill device adjusts the heating power of the grill burner by switching the open / close state of the plurality of solenoid valves according to the on / off states of the plurality of switches. Therefore, the thermal power display of the grill device is performed by stepwise switching the lighting / extinguishing state of the LEDs provided on the panel device 9A in accordance with the on / off states of the plurality of switches.

  On the other hand, in displaying the thermal power of the right burner 4 in the panel device 9A and the thermal power of the left burner 5 and the back burner 6 in the panel device 9B, the fuel supply device 20 rotates the operation knobs 11, 13, and 14. Does not include an encoder that detects the amount. Therefore, the panel devices 9A and 9B do not perform control for switching the on / off state of the LEDs according to the rotation positions of the operation knobs 11, 13, and 14. In this embodiment, panel device 9A, 9B permeate | transmits the LED light of the position corresponding to the rotation position of the operation knobs 11, 13, and 14, and displays a thermal power display by shielding the LED light of another position.

  The panel device 9B will be described with reference to FIGS. In addition, the structure of the part which concerns on the thermal power display of the right burner 4 in the panel apparatus 9A is the same as the structure of the part which concerns on the thermal power display of the left burner 5 and the back burner 6 in the panel apparatus 9B. Therefore, the configuration of the panel device 9A is similar to the configuration of the panel device 9B, and the description thereof is omitted.

  The panel device 9 </ b> B includes a panel body 50, a display substrate 60, a flanged cylinder 70, and a decorative panel 80. The panel main body 50 is assembled to the front end of the housing 2. As shown in FIGS. 3 and 4, the lower portion 51 of the panel body 50 is formed in a box shape and accommodates an operation panel (not shown). The upper part 52 of the panel main body 50 protrudes in a plate shape from the lower part 51 upward. In the upper portion 52, two through holes 53 penetrating in the front-rear direction are formed side by side in the left-right direction. The inner diameter of the through hole 53 is larger than the outer diameter of the operation knobs 13 and 14. The fuel supply devices 20 of the left burner 5 and the back burner 6 are fixed to the upper part 52 of the panel body 50 from the rear side in a state where they are arranged side by side. The connecting members 25 and the operation knobs 13 and 14 of the two fuel supply apparatuses 20 are disposed in the two through holes 53, respectively.

  A plurality of light guide portions 54 are arranged in the circumferential direction on the upper outer peripheral portion of the two through holes 53, respectively. The light guides 54 are cylindrical bodies extending in the front-rear direction, and seven light guides are provided in this embodiment. The cylindrical holes 55 of the respective light guide portions 54 are formed independently of each other.

  A display substrate 60 is fixed to the rear surface of the upper portion 52. The lower end of the display substrate 60 is formed in a double arc shape so as not to interfere with the through hole 53. A plurality of LEDs 61 are mounted on the front surface of the display substrate 60, and are arranged in two arcs along the lower end. In the present embodiment, seven LEDs 61 are provided along two arcs. Each LED 61 is provided at a position corresponding to a position where each tube hole 55 of each light guide portion 54 is formed. Thereby, the intensity | strength of the light which passes the cylinder hole 55 of the light guide part 54 can be ensured in intensity | strength stronger than the case where it diffuses from one light source. When the display substrate 60 is fixed to the panel main body 50, the rear opening of each cylindrical hole 55 of the light guide portion 54 is closed by the front surface of the display substrate 60. The plurality of LEDs 61 are disposed in the respective cylindrical holes 55 of the light guide unit 54. Since the light guide part 54 extends in the front-rear direction, the light of the LED 61 that can pass through the cylindrical hole 55 of the light guide part 54 is limited only to the light traveling forward, and the spread of the light is suppressed.

  As shown in FIGS. 2 and 5, the flanged tube portion 70 includes a main body portion 71 and a flange portion 76. The main body 71 has a cylindrical shape extending in the front-rear direction. The outer diameter of the main body 71 is smaller than the inner diameter of the through hole 53 of the panel main body 50, and the inner diameter is larger than the outer diameters of the operation knobs 11, 13, and 14 (see FIG. 3). The main body 71 has two hook portions 72 and 73 formed in a cutout shape from the rear end to the front and three engaging portions 74 at three locations in the circumferential direction. In each of the hook portions 72 and 73, a hook piece 75 that is hooked on the rear surface of the through hole 53 of the panel main body portion 50 is provided. The flanged portion 76 that abuts the front surface of the through hole 53 and the hook piece 75 prevent the flanged tube portion 70 from being detached in a state in which the main body 71 is disposed in the through hole 53, and the shaft in the through hole 53. It is held rotatably about the center AX. The engagement portion 74 engages with the engagement piece 37 of the LED operation member 36. In the main body 71, the portions sandwiching the engaging portion 74 from both sides in the circumferential direction extend rearward and make it difficult for the engaging piece 37 to come off.

  The flange portion 76 is formed in a hook shape radially outward at the front end portion of the main body portion 71. The flange portion 76 includes a light passage portion 77, a rear side flange portion 78, and a front side flange portion 79. The light passage portion 77 is a portion formed in a notch shape in the flange portion 76. Although details will be described later, the light passage part 77 is formed wider than the cylindrical hole 55 of the light guide part 54. The flange portion 76 is formed on the entire circumference in the circumferential direction excluding the light passage portion 77. The rear side flange portion 78 is a portion located on the clockwise side when the flange portion 76 is divided substantially in half in the circumferential direction with the light passage portion 77 as a reference. The front side flange portion 79 is a portion located on the counterclockwise side when the flange portion 76 is divided substantially in half in the circumferential direction with the light passage portion 77 as a reference. The rear side collar part 78 and the front side collar part 79 are formed at positions that are stepped in the front-rear direction. The front side collar part 79 is provided in front of the rear side collar part 78.

  As shown in FIG. 2, the fuel supply device 20 for the left burner 5 and the fuel supply device 20 for the back burner 6 are arranged side by side. In the panel main body 50, the through hole 53 for the left burner 5 and the through hole 53 for the back burner 6 are slightly larger than the radial length of the flange portion 76 of the flanged cylinder portion 70 in the left-right direction. Formed apart. Therefore, when the flanged cylinder part 70 for the left burner 5 and the flanged cylinder part 70 for the back burner 6 are assembled in the corresponding through holes 53, the flanges 76 are arranged at overlapping positions. Here, as described above, the rear side collar part 78 and the front side collar part 79 are formed at positions that are stepped in the front-rear direction. Therefore, since the front side flange portion 79 of the flanged cylinder portion 70 for the back burner 6 is arranged at a position overlapping the rear flange portion 78 of the flanged cylinder portion 70 for the left burner 5, each flange portion 76 is Do not interfere with each other. With this configuration, the fuel supply device 20 for the left burner 5 and the fuel supply device 20 for the back burner 6 can be arranged close to the left and right in the housing 2.

  As shown in FIGS. 3 and 6, the decorative panel 80 is a plate-like body that is assembled to the front side of the upper portion 52 of the panel body 50. The decorative panel 80 includes a base 81, a panel plate 82, an annular portion 83, and a translucent member 84. The base 81 is a main body portion of the decorative panel 80, and the panel plate 82, the annular portion 83, and the light transmitting member 84 are assembled. The base body 81 has a substantially rectangular shape when viewed from the front, and includes a slide lock 85 at the upper end. When the decorative panel 80 is assembled to the upper portion 52 of the panel main body 50, the decorative panel 80 is fixed to the panel main body 50 by sliding the slide lock 85 to the right.

  In the base body 81, two openings 86 penetrating in the front-rear direction are formed side by side in the left-right direction. The inner diameter of the opening 86 is larger than the outer diameter of the operation knobs 13 and 14. Operation knobs 13 and 14 are disposed in the two openings 86, respectively. Groove portions 87 in which the translucent members 84 are positioned are formed on the upper outer peripheral portions of the two openings 86, respectively. The translucent member 84 is a member formed of, for example, a transparent resin, and supports a plurality of (seven in this embodiment) translucent portions 88 and all of the plurality of translucent portions 88 connected together. It has a rod-shaped support part 89. The translucent portion 88 is a cylindrical portion extending in the front-rear direction, and has a length substantially the same as the thickness of the base body 81. The translucent part 88 is provided at a position corresponding to each formation position of the light guide part 54 when the decorative panel 80 is assembled to the upper part 52 of the panel main body part 50. The groove portion 87 of the base body 81 is formed according to the outer shape of the light transmitting member 84, and the light transmitting member 84 is accommodated in the groove portion 87. In the groove portion 87, the light transmitting portion 88 is disposed at the position where it penetrates the base body 81 in the front-rear direction. The translucent part 88 guides the light emitted from the LED 61 and incident from the rear surface through the light guide part 54 to the front through the inside, and emits the light from the front to the front.

  The annular portion 83 has an annular shape, and the inner diameter is larger than the outer diameter of the operation knobs 13 and 14. The annular portion 83 is disposed in the opening 86 of the base body 81. Of the light emitted from the LED 61 and transmitted through the light transmitting portion 88, the annular portion 83 leaks from the light transmitting portion 88 due to irregular reflection or the like, and blocks light traveling into the opening 86.

  The panel board 82 is a decorative board which colored the back surface (back surface) of the transparent resin board, for example. The panel board 82 opens two round holes 91 at positions corresponding to the openings 86 of the base body 81. The position corresponding to each of the translucent part 88 is not colored, and can transmit the light of the LED 61. The panel plate 82 is attached to the front surface of the base 81 with an adhesive or the like after the translucent member 84 and the annular portion 83 are assembled to the base 81.

  As shown in FIG. 3, the fuel supply device 20 for the left burner 5 and the fuel supply device 20 for the back burner 6 are arranged side by side using mounting brackets 33, and the panel main body 50 of the panel device 9 </ b> B. It is fixed to the back of the screw with a screw. The engagement piece 37 of the LED operation member 36 is engaged with the engagement portion 74 of the flanged cylinder portion 70. Therefore, the flanged cylinder portion 70 rotates around the axis AX in the through hole 53 of the panel body 50 when the heating power adjustment cam 26 to which the LED operation member 36 is fixed rotates around the axis AX.

  The plurality of LEDs 61 on the display substrate 60 are all lit when the safety valve is opened. As described above, when the operation knobs 13 and 14 are in the operation position, the heating power adjustment cam 26 is connected to the operation knobs 13 and 14, and the rear burner 6 and the left burner 5 are operated according to the turning operation of the operation knobs 13 and 14. You can adjust the firepower. When the operation knobs 13 and 14 rotate, the flanged tube portion 70 rotates around the axis AX together with the heating power adjustment cam 26 via the LED operation member 36. The flange portion 76 blocks the light of the LED 61 that is irradiated forward through the tube hole 55 of the light guide portion 54, except for a position overlapping the light passage portion 77. When the operation knobs 13 and 14 are rotated and the heating power is changed, the light passage portion 77 moves in the circumferential direction around the axis AX, and the light guide portions 54 through which the light from the LEDs 61 can pass are arranged in the circumferential direction. Will be changed according to. The light of the LED 61 that has passed through the light passage part 77 is lit and displayed on the surface of the decorative panel 80 through the light transmission part 88 of the light transmission member 84 corresponding to the light guide part 54. Therefore, the panel device 9 </ b> B can perform thermal power display according to the position where the light of the LED 61 is lit on the surface of the decorative panel 80.

  As shown in FIG. 7, the circumferential width A of the light passage portion 77 of the flanged tube portion 70 is larger than the circumferential width B of the tube hole 55 of the light guide portion 54. In addition, the reference | standard of the width | variety A and the width | variety B shall be the center position of the cylinder hole 55 in the radial direction of axial center AX. Further, the width A is larger than the width C between the central positions of the cylindrical holes 55 of the adjacent light guide portions 54. The width A is the circumferentially clockwise end of the cylindrical hole 55 of one light guide 54 and the circumferential counterclockwise direction of the cylindrical hole 55 that is two circumferentially clockwise away from the cylindrical hole 55. The width D between the side ends is substantially the same. Since the width A of the light passage portion 77 satisfies each of the above conditions, the light passage portion 77 exposes one or more and two or less tube holes 55 regardless of the position where the flanged tube portion 70 rotates. In other words, no matter which position the flanged cylinder part 70 rotates, the light passage part 77 always exposes one cylinder hole 55, so that it is possible to reliably display the thermal power. And although the light passage part 77 may expose the two cylindrical holes 55 depending on the rotation position of the flanged cylindrical part 70, the three or more cylindrical holes 55 are not exposed. Thereby, the light of LED61 arrange | positioned in the cylinder hole 55 exposed according to the rotation position of the flanged cylinder part 70 is irradiated to the front of the gas stove 1 through the translucent part 88 of the decorative panel 80. That is, the panel device 9B pinpoints one or two translucent portions 88 of the gas flow rate adjusted by the heating power adjustment cam 26 according to the rotation amount of the operation knobs 13 and 14, that is, the portion corresponding to the heating power. Can shine. The same applies to the thermal power display corresponding to the rotation amount of the operation knob 11 of the panel device 9A.

  As described above, the flanged cylinder part 70 blocks the light emitted from the LED 61 by the flange part 76. The light passage portion 77 of the flange portion 76 is formed in a part of the flange portion 76, thereby allowing a part of the light from the LED 61 to pass therethrough. Since the flanged tube portion 70 rotates in accordance with the turning operation of the operation knobs 11, 13, and 14, the light passing portion 77 is arranged for the light from the LED 61 according to the turning position of the operation knobs 11, 13, and 14. The light is irradiated forward of the panel devices 9A and 9B at the position where the light is applied. That is, the gas stove 1 can indicate the thermal power display corresponding to the rotation positions of the operation knobs 11, 13, and 14 by the light that has passed through the light passage portion 77. Thereby, for example, the rotation position of the operation knobs 11, 13, and 14 can be detected by an encoder or the like, and the thermal power display can be performed without using various parts and the like necessary for indicating the detected position by an LED or the like. Production cost can be reduced. In addition, the light passage unit 77 allows light from the LED 61 to pass through only a predetermined portion corresponding to the rotation position of the operation knobs 11, 13, and 14. That is, the translucent part 88 shines only at a point corresponding to the current thermal power. Therefore, the gas stove 1 excellent in the recognizability of the thermal power display with a simple configuration can be provided.

  The entire circumference of the flange portion 76 except for the light passage portion 77 is formed in a bowl shape. Therefore, since the flange portion 76 can reliably block the light from the LED 61 even if there is some dimensional error in the arrangement of the LED 61, the light from the LED 61 is excluded from the decorative panel except for the position of the light passage portion 77. It is possible to prevent leakage to the front side of 80.

  The portion of the light emitted from the LED 61 that is irradiated forward by the plurality of light guides 54 is limited. Further, out of the light that has passed through the plurality of light guides 54, the light passed through the light guide 54 located at a predetermined portion where the light passage 77 is arranged according to the rotation position of the operation knobs 11, 13, and 14. Only the light reaches the translucent part 88, and only the part corresponding to the current fire power is made to shine pinpoint. Since the light that displays the thermal power in the light transmitting portion 88 is in the shape of the cylindrical hole 55 of the light guide portion 54, the recognizability of the thermal power display can be further enhanced.

  Of the light from the LED 61, the light that can pass through the cylindrical hole 55 of the cylindrical light guide 54 is limited only to the light traveling forward. Therefore, the light that displays the thermal power in the translucent portion 88 is suppressed from spreading and has a clear outline, so that the recognizability of the thermal power display can be further enhanced.

  Since the light that passes through the light passage portion 77 and reaches the light transmission portion 88 is light from the LED 61 that is an independent light source provided corresponding to each of the plurality of light guide portions 54, diffusion from a single light source Light intensity is stronger than light. Therefore, since the light for displaying the thermal power in the light transmitting portion 88 is relatively bright, the recognizability of the thermal power display can be further enhanced.

  Regardless of the position of the operation knobs 11, 13, and 14, the light passage portion 77 exposes one or two light guide portions 54. Therefore, in the gas stove 1, the light passage part 77 is located between the two light guide parts 54, the flange part 76 blocks all the light guide parts 54, all the light from the LEDs 61 is blocked, and the thermal power display is not performed. Can be prevented.

  When the fuel supply devices 20 are arranged side by side, the through holes 53 are formed so as to be separated from each other so that the flange portions 76 of the flanged cylinder portions 70 arranged in the adjacent through holes 53 do not interfere with each other. The device 9B needs to ensure a large lateral width. As described above, the panel device 9 </ b> B can be formed with the through holes 53 close to the left and right by being configured so as not to interfere even if the flange portions 76 are arranged at positions where the flange portions 76 overlap in the front-rear direction. Can be reduced. Further, since the fuel supply device 20 can be disposed close to the left and right in the housing 2, the space occupied by the fuel supply device 20 in the housing 2 can be reduced, and the layout of the housing 2 can be freely set. Can be improved.

  When the light from the LED 61 passes through the light transmitting portion 88, it may go into the opening 86 due to irregular reflection. The annular portion can prevent light leaking from the light transmitting portion 88 from illuminating the inside of the opening 86, and can enhance the recognizability of the thermal power display.

  In addition, this invention is not limited to the said embodiment, A various change is possible. Although seven light guides 54 are provided around the upper side of the through hole 53, the number is not limited to seven. Although seven LEDs 61 of the display substrate 60 are provided in accordance with the number of light guides 54, the number of LEDs 61 may not necessarily match the number of light guides 54, for example, less than the number of light guides 54. May be. In this case, for example, the light path may be formed of a transparent resin or the like, or a light diffusing plate may be used to distribute the light of one LED 61 to the plurality of light guides 54. The light source is not limited to the LED, and other light sources such as an organic EL may be used. The light guides 54 are arranged at equal intervals in the circumferential direction. However, for example, the light guides 54 may be arranged such that the intervals increase as the heating power increases. Moreover, the light guide part 54 does not need to be cylindrical, for example, the light path may be formed of a transparent resin or the like.

  The panel device 9B displays the thermal power corresponding to each of the two fuel supply devices 20, but one fuel supply device 20 may be assembled alone to display the thermal power, or three or more fuel supply devices 20 may be displayed. It may be assembled to display the thermal power. The flange portion 76 of the flanged cylinder portion 70 is provided in a bowl shape around the entire circumference except for the light passage portion 77, but may not be provided around the circumference. Although the light passage portion 77 is formed in a notch shape, it may be formed as a hole portion opened in the flange portion 76, for example. The translucent member 84 of the decorative panel 80 includes the seven translucent portions 88 according to the light guide portion 54, but may not be provided with a plurality of translucent portions 88 and may be, for example, a single transparent plate.

  In the above description, the right burner 4, the left burner 5, and the back burner 6 are examples of the “combustor” of the present invention. The display substrate 60 is an example of the “light emitting portion” in the present invention. The cylindrical hole 55 is an example of the “hole” in the present invention. The LED 61 is an example of the “light source” in the present invention. The front side flange portion 79 is an example of the “first portion” in the present invention. The rear side flange portion 78 is an example of the “second portion” in the present invention.

DESCRIPTION OF SYMBOLS 1 Gas stove 2 Housing | casing 4 Right burner 5 Left burner 6 Back burner 9A, 9B Panel apparatus 11, 13, 14 Operation knob 20 Fuel supply apparatus 21 Operation part 50 Panel main-body part 53 Through-hole 54 Light guide part 55 Cylindrical hole 60 Display board 61 LED
70 Cylindrical cylinder part 71 Main body part 74 Engagement part 76 Flange part 77 Light passage part 78 Rear side collar part 79 Front side collar part 80 Decorative panel 83 Annular part 86 Opening part 88 Translucent part

Claims (8)

A casing in which a stove burner is arranged at the top;
A fuel supply device that is disposed at a front portion in the housing and includes an operation unit that supplies gas to the stove burner and supplies and shuts off gas to the stove burner;
A panel device fixed to the housing in front of the fuel supply device and showing an operation state of the operation unit;
A gas stove equipped with
The operation portion of the fuel supply device is in a state of projecting from the front surface of the panel device at least when supplying gas, and an operation knob capable of adjusting a supply amount of gas supplied to the conoburner by a turning operation. Including
The panel device
A panel body fixed to the housing in front of the fuel supply device, penetrating in the front-rear direction, and having a through hole in which the operation knob is disposed;
A light emitting portion that emits light on a back surface of the panel body, is provided in a predetermined range along the circumferential direction outside the through hole in the radial direction, and emits light toward the surface side of the panel body;
A main body having a cylindrical shape and rotatably disposed in the through-hole, and projecting in a radially outward manner in at least a part of the outer circumferential surface of the main body in the circumferential direction, on the front side of the light emitting unit A flange portion arranged to block light from the light emitting portion, a light passage portion that is formed in a hole shape or a notch shape in a part of the circumferential direction of the flange portion, and allows light from the light emitting portion to pass through; A hooked cylinder portion having an engagement portion that engages with the operation portion and rotates the main body portion in accordance with a turning operation of the operation knob;
Mounted on the front part of the panel body and opening at a position overlapping the through hole in the front-rear direction, and an opening part where the operation knob is arranged, and a position overlapping the light-emitting part around the opening part in the front-rear direction A decorative panel having a light-transmitting part that is emitted from the light-emitting part and transmits light that has passed through the light-passing part;
A gas stove characterized by comprising: 2. The gas stove according to claim 1, wherein the flange portion is formed in a bowl shape on the outer peripheral surface of the main body portion except for the light passage portion. The panel body includes a plurality of light guide portions that have holes that allow light to pass in the front-rear direction and are arranged in a circumferential direction around the through-holes,
The gas stove according to claim 1 or 2, wherein the light emitting unit irradiates light toward the surface side of the panel body through the plurality of light guide units.   The gas stove according to claim 3, wherein the light guide portion is formed in a cylindrical shape extending in the front-rear direction.   The gas stove according to claim 3 or 4, wherein the light emitting unit includes a plurality of light sources corresponding to the arrangement positions of the plurality of light guide units. The plurality of light guides are arranged at equal intervals in the circumferential direction of the through hole,
The gas stove according to any one of claims 3 to 5, wherein the width of the light passage portion in the circumferential direction of the flange portion is not less than 1 and less than 2 times the arrangement interval of the plurality of light guide portions. . The light emitting part is arranged along the circumferential direction at the upper part of the through hole,
When there are a plurality of the fuel supply devices and they are arranged side by side at the front of the casing, the through holes of the panel body corresponding to the adjacent fuel supply devices are respectively connected to the through holes. The flange portions of the flanged tubular portion to be disposed are formed at positions where the flange portions overlap in the front-rear direction,
The flange portion is located at a position where the first portion located on the counterclockwise side and the second portion located on the clockwise side are stepped in the front-rear direction when half divided in the circumferential direction with respect to the light passage portion. Formed,
Of the two flanged tube portions respectively disposed in the adjacent through holes, the first portion of the flange portion of one of the flanged tube portions is the flange portion of the other flanged tube portion. The gas stove according to any one of claims 1 to 6, wherein the gas stove is arranged at a position overlapping with the second portion in the front-rear direction.   The gas stove according to any one of claims 1 to 7, wherein the decorative panel has an annular shape, and has an annular portion that is disposed in the opening and has an inner diameter larger than an outer diameter of the operation knob. .

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