JP2019132471A - Temperature detection device for cooker - Google Patents

Abstract

To provide a temperature detection device for a cooker capable of appropriately detecting whether or not a heated material is placed on a placing part, and achieving reduction of manufacturing costs and simplification of manufacturing processes.SOLUTION: A temperature detection device 50 includes a roughly L-shaped cylindrical support body 51, a lifting body 55 supported on a top edge of one side section of the cylindrical support body, a temperature detection mechanism 62 provided with a detection part 60 and a lead wire 61, a heated material detection mechanism 68 provided with a lead switch 65, a magnet 66, and an operation part 67 for switching a state of the lead switch between a first state and a second state, and a transmission member 75, one end of which is connected to the lifting body, and the other end of which extends into the other side section of the cylindrical support body. A magnetic shield 80 located between the lead switch and the magnet, which shields the magnetic field of the magnet, is disposed at a predetermined position of the transmission member as an operation part. A glass braided tube disposed so as to cover the lead wire over at least the lifting body to the magnetic shield is used as the transmission member.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a temperature detection device, and more specifically, temperature detection for a heating cooker that is used to detect the temperature of an object to be heated (such as a cooking container such as a pan) placed on a heating cooker such as a gas stove. Relates to the device.

  The gas stove includes a gas stove including a temperature detection device that detects the temperature of the object to be heated (for example, a cooking container such as a pan) in contact with the bottom surface.

And in patent document 1, as a manufacturing method of the temperature detection apparatus for heating cookers,
(A) an L-shaped cylindrical support provided on a heating cooker in a fixed manner, wherein one side is in a standing posture and the other side is in a horizontal posture;
(B) It is possible to move up and down and return to the upper side so that it can be pushed down as the bottom of a heated object (such as a cooking container such as a pan) placed on the placing part of the heating cooker comes into contact. In the state made, the lifting body 20 (see FIG. 1 of Patent Document 1) supported by the upper end of one side of the cylindrical support,
(C) a temperature detection mechanism having a detection unit for detecting temperature and a lead wire for transmitting detection information of the detection unit;
(D) A detection unit (reed switch 43 (see FIG. 1 of Patent Document 1)) that can be switched between the first state and the second state, and a detection unit ( A heated object detection mechanism having an operation unit (magnetic shield 45 (see FIG. 1 of Patent Document 1)) for switching the reed switch 43) between the first state and the second state;
(E) The abutting portion with which the detection unit abuts the bottom of the heated object in the lifting body 20 in a state where the lead wire is disposed inside the cylindrical support body in a form extending outside the other side portion of the cylindrical support body. It is provided to detect the temperature of
(F) A transmission member (piano wire 51 (see FIG. 1 of Patent Document 1)) having one end connected to the lifting body 20 and the other end connected to the operation unit (magnetic shield 45) is L-shaped. Arranged in a cylindrical support body,
(G) An operation in which the transmission member (piano wire 51) is positioned within the other side of the transmission member (piano wire 51) with a pressing force applied when the elevating body is lowered and a tensile force applied when the elevating body is raised. The manufacturing method of the temperature detection apparatus for heating cookers comprised so that transmission to the part (magnetic shielding body 45) was described.

  And in the manufacturing method of the temperature detection apparatus of this patent document 1, the raising / lowering body 20 raises / lowers when a to-be-heated material is mounted in the mounting part (5 morals 5) or removed from a mounting part. Accordingly, the relative positional relationship between the detection unit (reed switch 43) and the operation unit (magnetic shield 45) in the axial direction of the cylindrical support is accurately changed between the proximity state and the separation state, and the detection unit ( The reed switch 43) can be appropriately switched between the first state and the second state.

  Therefore, according to the method of Patent Document 1, even when the cylindrical support is configured in a substantially L shape, the presence / absence of the placement of the object to be heated on the placement portion (5 virtues 5) is accurately detected. This makes it possible to realize a temperature detecting device that can perform the above-described purpose.

Japanese Patent Laying-Open No. 2015-94521

  However, in the temperature detection device of Patent Document 1, it is necessary to arrange the lead wire connected to the thermistor and the cord-like body (piano wire 51) in parallel in the substantially L-shaped cylindrical support body, There is a problem that the manufacturing cost increases due to the increase in the number of members and the manufacturing process becomes complicated, and there is room for improvement.

  The present invention does not require the cord-like body (piano wire) to be arranged in parallel with the lead wire as in Patent Document 1 described above, and whether or not the object to be heated is placed on the placement portion. It is an object of the present invention to provide a temperature detection device for a cooking device that can accurately detect the temperature and can realize a reduction in manufacturing cost and simplification of a manufacturing process.

In order to solve the above problems, a temperature detection device for a heating cooker according to the present invention,
A cylindrical support having a substantially L shape and fixedly disposed in a heating cooker, one side extending in a substantially vertical direction and the other extending in a substantially horizontal direction from the one side And a cylindrical support body that is configured so that a boundary region between the one side part and the other side part is a bent part.
The bottom of the object to be heated placed on the placing part of the heating cooker comes into contact, moves up and down with the vertical movement of the object to be heated, and is urged to return upward. An elevating body supported by the upper end of the one side of the shaped support,
A detection unit that detects the temperature of the bottom of the object to be heated, and a lead wire that is disposed in the cylindrical support body in a manner extending outward from the other side of the cylindrical support member, and transmits detection information of the detection unit A temperature detection mechanism comprising:
A reed switch that is provided on the outer peripheral portion of the other side of the cylindrical support and can be switched between a first state and a second state by applying a magnetic field, and to face the reed switch via the other side. And a magnet disposed on the outer peripheral portion of the other side portion and the inside of the other side portion of the cylindrical support, and the reed switch is moved closer to and away from the reed switch. A heated object detection mechanism including an operation unit for switching between the first state and the second state;
One end is connected to the elevating body and the other end is disposed in the cylindrical support body in such a manner that the other end extends into the other side, and along the axial direction of the cylindrical support body as the elevating body moves up and down. A transmission member that moves within the cylindrical support;
A temperature detection device for a cooking device comprising:
A magnetic shield that shields the magnetic field of the magnet applied to the reed switch by being positioned between the reed switch and the magnet is disposed at a predetermined position of the transmission member as the operation unit. And
The transmission member is a glass braided tube disposed so as to cover at least the lead wire from the elevating body to the magnetic shield.

In the temperature detection device for the cooking device of the present invention,
The magnetic shield is a cylindrical member having an inner diameter dimension equal to or larger than the outer diameter dimension of the glass braided tube, and is externally fitted to the glass braided tube in the other side portion;
The pair of substantially cylindrical crimping fixing members having an outer diameter larger than the inner diameter of the magnetic shield are adjacent to both ends of the magnetic shield so as to be adjacent to both ends of the magnetic shield. It is preferably fixed to a glass braided tube.

Further, the magnetic shield is a cylindrical member having an inner diameter dimension equal to or larger than the outer diameter dimension of the glass braided tube, and is fitted on the glass braided tube in the other side portion,
A magnetic shield that is the cylindrical member includes: (a) a strip-like continuous connection portion that is continuous from the partial region in the circumferential direction of the axial end portion of the magnetic shield toward the outside in the axial direction; (B) a continuous crimping fixing portion continuously provided from the magnetic shield via the continuous connection portion in a mode in which the main portion is positioned with a predetermined gap between the magnetic shield and the magnetic shield; Prepared,
It is preferable that the magnetic shield is held at a predetermined position of the glass braided tube by the caulking and plastic deformation of the continuous crimping fixing portion and being fixed to the glass braided tube.

  The temperature detection device for a heating cooker according to the present invention is configured as described above, and a glass braided tube disposed so as to cover at least the lead wire from the lifting body to the magnetic shield is used as the transmission member. Therefore, as in the case of the above-mentioned Patent Document 1, it is not necessary to arrange the cord-like body (piano wire) in parallel with the lead wire, and the object to be heated on the placement portion It is possible to provide a temperature detection device for a heating cooker that can accurately detect the presence or absence of mounting, and that can reduce the manufacturing cost and simplify the manufacturing process.

  The glass braided tube has a substantially L-shaped cylindrical shape corresponding to the lifting / lowering operation of the lifting / lowering body that moves up and down when the object to be heated is placed on the placement part (Gotoku) or removed from the placement part. The support body has flexibility (deformability) capable of smoothly moving along the axial direction of the support body, and can move within the cylindrical support body by a distance corresponding to the lift distance of the lift body. By using a glass braided tube as the transmission member, the reed switch and the operation unit (magnetic shield) are not required separately as in the case of Patent Document 1 without the need for a separate cord (piano wire). (The relative positional relationship in the direction along the axial direction of the cylindrical support) is accurately changed between the proximity state and the separation state (that is, the reed switch is reliably changed between the first state and the second state). To switch to Possible to become.

  Further, the magnetic shield is a cylindrical member having an inner diameter dimension equal to or larger than the outer diameter dimension of the glass braided tube, and is fitted on the glass braided tube inside the other side, and is larger than the inner diameter dimension of the magnetic shield. When a pair of substantially cylindrical crimping fixing members having outer diameter dimensions are fixed to the glass braided tube so as to be adjacent to both ends of the magnetic shield on both ends of the magnetic shield, Even when a material that is difficult to be plastically deformed is used as the magnetic shield, the magnetic shield can be attached to an appropriate position of the glass braided tube as the transmission member, and the present invention can be made more effective. .

  The magnetic shield is a cylindrical member having an inner diameter that is equal to or larger than the outer diameter of the glass braided tube, and is externally fitted to the glass braided tube in the other side and is a cylindrical member. (A) A strip-like continuous connection portion that is provided continuously from a partial region in the circumferential direction of the axial end portion of the magnetic shield toward the outside in the axial direction, and (b) a main portion is a magnetic shield. And a continuous crimping fixing part continuously provided from the magnetic shield via the continuous connection part, and the continuous crimping fixing part is caulked. When the magnetic shield is configured to be held at a predetermined position of the glass braided tube by being plastically deformed and fixed to the glass braided tube, the continuous crimping fixing portion is crimped to the glass braided tube. The magnetic shield is deformed when fixed While suppressing the would, it is possible to hold the magnetic shield in a predetermined position of the glass braided tube.

  That is, since the continuous crimping fixing portion and the magnetic shield are connected by the strip-like continuous connection portion, the influence of deformation of the continuous crimping fixing portion when caulking is difficult to be transmitted to the magnetic shield. It is possible to improve the reliability by suppressing the magnetic shielding function from being damaged by the deformation of the magnetic shielding body.

It is a perspective view which shows the external appearance structure of the gas stove provided with the temperature detection apparatus for heating cookers concerning one Embodiment of this invention. It is a longitudinal cross-sectional view which shows the principal part structure in the state in which the raising / lowering body is located in an upper limit position of the temperature detection apparatus for heating cookers concerning one Embodiment of this invention. It is a longitudinal cross-sectional view which shows the principal part structure in the state which the raising / lowering body fell of the temperature detection apparatus for cooking-by-heating machines concerning one Embodiment of this invention. It is a longitudinal cross-sectional view which shows the principal part structure in the intermediate process which manufactures the temperature detection apparatus for the heating cooker concerning one Embodiment of this invention. It is a figure which shows the magnetic shielding body used for the temperature detection apparatus for the heating cooker concerning one Embodiment of this invention. It is a figure which shows the principal part structure of the temperature detection apparatus for heating cookers concerning another Embodiment 1 of this invention, (a) is crimping a crimping | fixing fixing member, and before fixing a magnetic shield to a glass braided tube. State (b) is a view showing a state after crimping the crimping fixing member and fixing the magnetic shield to the glass braided tube. It is a figure which shows the principal part structure of the temperature detection apparatus for the heating cooker concerning another Embodiment 2 of this invention, (a) crimps a continuous crimping | fixing fixing part, and fixes a magnetic shield to a glass braided tube. FIG. 5B is a diagram showing a state after the caulking process is performed on the continuous crimping fixing portion and the magnetic shield is fixed to the glass braided tube. It is a perspective view which shows the magnetic shielding body used for the temperature detection apparatus for the heating cooker concerning another Embodiment 2 of this invention.

  Hereinafter, a stove with a grill according to an embodiment of the present invention will be shown and the features of the present invention will be described in detail.

  As shown in FIG. 1, a stove with a grill (heating cooker) 100 according to an embodiment of the present invention includes a case main body (a stove main body) 101 and a standard thermal power stove with a temperature sensor disposed in the case main body 101. This is a stove with a built-in grill provided with 32a, a high thermal power stove burner 32b with a temperature sensor, a small thermal power stove burner 32c with a temperature sensor, and a grill 33 used when cooking fish or the like.

  On the upper left side and upper right side of the front surface of the case main body 101, there are provided heating state adjusting parts 35a, 35b, 35c for performing operations of ignition, extinguishing, and heating power adjustment of the plurality of burners 32a, 32b, 32c, respectively. ing.

  Specifically, a heating state adjusting unit 35a for performing operations of ignition, extinguishing, and heating power adjustment of the standard thermal power stove burner 32a is disposed on the upper left side of the front surface of the case body 101, and on the upper right side. A heating state adjusting unit 35b for performing operations of ignition, extinguishing, and heating power adjustment of the high-thermal power stove burner 32b; Is arranged.

  A temperature detecting device 50 (50a, 50b, 50c) for a cooking device (hereinafter, simply referred to as a temperature detecting device) is provided for each of the stove burners 32a, 32b, 32c. Similarly, each of the three temperature detection devices 50 provided in the stove burners 32a, 32b, and 32c is used for an object to be heated (such as a cooking container such as a pan) (not shown) placed on the virtues 40, respectively. A heated object temperature detecting function for detecting temperature and a heated object detecting function for detecting whether or not the heated object is placed on the virtues 40 are provided.

  And about the temperature detection apparatus 50 (50c) with which the small thermal power stove burner 32c is provided, since it needs to arrange | position above the grill exhaust pipe (not shown) connected to the exhaust port 91, it installs in an up-down direction. Since the space is narrow, the temperature detection device according to the present invention is used.

  It goes without saying that the temperature detection device according to the present invention can also be used for the temperature detection devices 50 (50a, 50b) of the standard thermal power burner 32a and the high thermal power control burner 32b.

<Characteristic configuration>
Hereinafter, a temperature detection device for a heating cooker according to an embodiment of the present invention will be described with reference to FIGS.

The temperature detection device 50 (50c) for the heating cooker according to this embodiment, as described below,
(A) a cylindrical support 51 having a substantially L-shape;
(B) an elevating body 55 supported by the upper end of one side 51a of the cylindrical support 51;
(C) A detection unit (temperature detection unit) 60 that detects the temperature of the bottom of an object to be heated (for example, a cooking container such as a pan), and a lead wire 61 that transmits detection information of the detection unit 60 to a control unit (not shown). A temperature detection mechanism 62 comprising:
(D) A reed switch 65 disposed on the outer peripheral portion of the other side portion 51b and a magnet 66 disposed on the outer peripheral portion of the other side portion 51b so as to face the reed switch 65 via the other side portion 51b. A heated object detection mechanism 68 including an operation unit 67 for switching the reed switch 65 between the first state and the second state;
(E) One end is connected to the elevating body 55 and the other end is disposed in the cylindrical support body 51 so as to extend into the other side 51b of the cylindrical support body 51. And a transmission member 75 that moves in the cylindrical support 51.

  Further, a magnetic shield 80 that shields the magnetic field from being applied to the reed switch 65 so that the magnetic field from the magnet 66 is not applied to the reed switch 65 is disposed at a predetermined position of the transmission member 75 and is configured to function as the operation unit 67 described above. Yes.

  And in the temperature detection apparatus 50 concerning this embodiment, this magnetic shielding body 80 is comprised by the coil spring formed by winding a magnetic body (this embodiment magnetic steel wire) around the transmission member 75. FIG. The magnetic shield 80 is configured to be positioned inside the cylindrical support 51. The coil spring (magnetic shield) 80 has flexibility and is configured to be easily elastically deformed.

  Below, the temperature detection apparatus 50 (50c) for the heating cooker of this embodiment is demonstrated in more detail, referring FIGS. 1-5.

  The above-described cylindrical support 51 provided in the temperature detection device 50 of the present embodiment is a hollow cylindrical member having a substantially L shape, as shown in FIGS. Part 51a and the other side part 51b extending in the substantially horizontal direction from one side part 51a, and the boundary region between the one side part 51a and the other side part 51b is configured to be a bent part 51c. Yes.

  Further, one side 51a of the substantially L-shaped cylindrical support 51 is fixed in the case main body 101 of the stove 100 with a grill by a fixing means (not shown). However, you may comprise so that the other side part 51b may be fixed in the case main body 101 by a fixing means.

  Moreover, the raising / lowering body 55 supported by the upper end part of the one side part 51a of the cylindrical support body 51 is a to-be-heated object (for example, a pot etc.) mounted in the mounting part of the heating cooker (stove with a grill) 100. The bottom portion of the cooking container (not shown) is in contact with it, and is configured to move up and down as the object to be heated moves up and down. On the other hand, it is supported by the upper end part of the side part 51a.

  Moreover, the detection part 60 which comprises the temperature detection mechanism 62 is provided with the heat collection body 60a and thermistor 60b which contact | abut to the bottom part of to-be-heated material. The temperature detection mechanism 62 includes a lead wire 61 that transmits detection information of the detection unit 60 to a control unit (not shown), and the lead wire 61 is connected to the thermistor 60b (see FIG. 2).

In addition, the thermistor 60b is hold | maintained at the holding | maintenance part 60c provided with the flange part, and the upper end part is contact | abutting with the heat collection body 60a.
And in this embodiment, the heat collecting body 60a is attached to the raising / lowering body 55 by crimping the peripheral part and engaging with the raising / lowering body main body 55a.
However, there are no particular restrictions on the mounting mode and mounting structure of the heat collector 60a, and other mounting modes and mounting structures can be employed.

  The lead wire 61 is inserted into the glass braided tube 75 and protected by the glass braided tube 75 (see FIG. 2).

  In this embodiment, the glass braided tube 75 functions as a protective member that protects the lead wire 61 and also functions as a transmission member.

  One end of the glass braided tube (transmission member) 75 is connected to the elevating body 55 (specifically, the lower end side of the holding portion 60c holding the thermistor 60b, the upper end of which is formed in a flange shape), and the like. The glass braided tube (transmission member) 75 is L-shaped as the elevating body 55 is moved up and down. The inside of the cylindrical support body 51 having a shape, specifically, the inside of the other side portion 51b is configured to move along the axial direction.

  That is, the glass braided tube 75 moves inside the cylindrical support body 51 along the axial direction of the cylindrical support body 51 as the lifting body 55 moves up and down, so that the object to be heated is placed on the virtues 40. The vertical movement of the elevating body 55 caused by being placed or removed from the top of the virtues 40 is transmitted to the heated object detection mechanism 68 (the operation unit 67 thereof).

  In addition, the glass braided tube 75 corresponds to the raising / lowering operation of the raising / lowering body 55 which raises / lowers when a to-be-heated object is mounted in the mounting part (Gotoku 40) or removed from the mounting part (Gotoku 40). It has flexibility (deformability) that can move smoothly along the axial direction in the substantially L-shaped cylindrical support body 51, and a distance corresponding to the lifting distance of the lifting body 55. The position of the reed switch 65 and the operation unit (magnetic shield) 80 is relatively long (on the axis of the cylindrical support 51). The relative position relationship in the direction along the direction is accurately changed between the proximity state and the separation state, and the reed switch 65 can be reliably switched between the first state and the second state.

  That is, the glass braided tube 75 has moderate flexibility and moves smoothly along the axial direction in the cylindrical support body 51 so that the ascending / descending of the elevating body 55 is appropriately detected. Since it can be transmitted to the mechanism 68, as in the case of the above-mentioned Patent Document 1, a reed switch 65 is not required as a transmission member, but a separate cord (piano wire) is required, and the reed switch 65 is moved up and down. And the operation unit (magnetic shield) 80 can be accurately changed between the proximity state and the separation state, and the reed switch 65 can be reliably switched between the first state and the second state.

  Further, as described above, the heated object detection mechanism 68 includes the reed switch 65 disposed on the outer peripheral portion of the other side portion 51b and the other side portion so as to face the reed switch 65 via the other side portion 51b. A magnet 66 disposed on the outer periphery of 51b, and an operation unit 67 disposed inside the cylindrical support 51 for switching the reed switch 65 between the first state and the second state, and a transmission member A magnetic shield (coil spring) 80 disposed at a predetermined position 75 for shielding a magnetic field applied from the magnet 66 to the reed switch 65 is configured to function as the operation unit 67 described above.

  And it is comprised so that the presence or absence of mounting of a to-be-heated material can be detected by switching the reed switch 65 to ON (1st state) and OFF (2nd state) as mentioned above. ing.

  The lead wire 61 connected to the thermistor 60b is disposed in the cylindrical support 51, extends outward from the other side 51b of the cylindrical support 51, and is connected to a control unit (not shown). The temperature information of the bottom of the object to be heated (for example, a cooking container such as a pan) detected by the thermistor 60b through the heat collector 60a constituting the detection unit 60 is the control unit outside the cylindrical support 51. (Not shown).

  In the present embodiment, as described above, the glass braided tube having moderate flexibility is configured to function as the transmission member 75, and the glass braid is compared with the lead wire 61 connected to the thermistor 60b. Since the tube (transmission member) 75 is difficult to bend, the glass braided tube 75 and the magnetic shield (coil spring) 80 disposed (fixed) on the glass braided tube 75 corresponding to the raising and lowering of the lifting body 55 with high accuracy are appropriately used. Since it moves in the other side part 51b, the 1st state and 2nd state of the reed switch 65 are switched reliably, and mounting and non-mounting of the to-be-heated material on the virtues 40 are detected appropriately.

  In the present embodiment, as described above, the coil spring (magnetic shield) 80 made of magnetic steel wire is positioned in the other side 51b of the cylindrical support 51 of the glass braided tube (transmission member) 75. Corresponding to the vertical movement of the lifting and lowering body 55, close to the region between the reed switch 65 and the magnet 66 in the other side 51 b, or between the reed switch 65 and the magnet 66. By separating from the sandwiched area, the reed switch 65 is configured to function as an operation unit in the present invention that switches between the first state and the second state (FIG. 2).

  Further, as shown in FIG. 5, the coil spring (magnetic shield) 80 is integrally provided with a crimped reduced diameter portion 80a on one end side thereof. Then, after the glass braided tube (transmission member) 75 is inserted into the crimped reduced diameter part 80a, the crimped reduced diameter part 80a is crimped and plastically deformed so that the crimped reduced diameter part 80a is glass braided. While being fixed at a predetermined position in the other side 51b of the tube (transmission member) 75, the coil spring (magnetic shield) 80 is also in a predetermined position in the other side 51b of the glass braided tube (transmission member) 75. It is fixed to.

  Next, the operation of the heated object detection mechanism 68 will be described. As shown in FIG. 2, in a state where an object to be heated (for example, a cooking container such as a pan) is not placed on the virtues 40, a magnetic material (in this embodiment, magnetic steel) is placed on a glass braided tube (transmission member) 75. A coil spring (magnetic shield) 80, which is an operation portion formed by winding a wire), is positioned between the reed switch 65 and the magnet 66, and is applied from the magnet 66 to the reed switch 65. In order to shield the magnetic field, the reed switch 65 is turned to the second state.

  On the other hand, in the state where the object to be heated is placed on the virtues 40, the coil spring (magnetic shield) 80 moves to the end side (right side) of the other side 51b as shown in FIG. When the coil spring (magnetic shield) 80 is not positioned between the reed switch 65 and the magnet 66, the magnetic field applied from the magnet 66 to the reed switch 65 is not shielded by the coil spring (magnetic shield) 80. Therefore, the magnetic field of the magnet 66 is applied to the reed switch 65, and the reed switch 65 is turned on.

  Note that the temperature detection device 50 according to the present invention used in the gas stove with a grill according to the present embodiment winds a magnetic body around the glass braided tube (transmission member) 75 as the magnetic shield 80 as described above. The coil spring formed by doing so is used, and the coil spring has flexibility and can be easily elastically deformed.

  Therefore, as shown in FIG. 2, each member (insertion member) of the lead wire 61, the glass braided tube (transmission member) 75, and the magnetic shield 80 is inserted into the L-shaped cylindrical support 51. When manufacturing the temperature detecting device 50 having the above structure, it can be efficiently manufactured by the method described below.

  For example, first, a straight tube member is prepared, and this tube member is bent to form the cylindrical support 51 having an L shape.

  Then, as shown in FIG. 4, each member of the lead wire 61, the glass braided tube (transmission member) 75, and the coil spring (magnetic shield) 80 fixed at predetermined positions of the glass braided tube (transmission member) 75. The (insertion member) is inserted into the cylindrical support 51 from the end of the one side 51a of the cylindrical support 51.

  At this time, since the coil spring (magnetic shield) 80 has flexibility and can be easily elastically deformed, the coil spring (magnetic shield) 80 is connected to the lead wire 61 and the glass braided tube ( Along with the transmission member 75, it can pass through the bent portion 51c of the cylindrical support 51 to reach the other side 51b. In addition, since the lead wire 61 and the glass braided tube (transmission member) 75 have appropriate flexibility and have a smaller radial dimension than the coil spring, the bent portion of the cylindrical support 51 can be easily formed. 51c can be passed through.

  Therefore, since the cylindrical support body 51 having an L-shape can be constituted by a single pipe member, the material cost can be reduced compared to the case where the cylindrical support body is constituted by three pipe members as in the prior art. In addition to being able to reduce the number of steps in the manufacturing process, the manufacturing cost can be reduced.

  In addition, when a cylindrical support body having an L-shape is formed by bending one tube member, the lead wire 61, the magnetic shield 80, and the glass braided tube (transmission member) 75 are formed on the tube member. Since it is possible to perform bending (processing for making an L shape) in a hollow state before inserting each member (insertion member), the L-shaped cylindrical support body 51 can be easily configured. Is possible. As a result, the manufacturing process can be simplified and productivity can be improved without impairing reliability.

  In this embodiment, as shown in FIG. 5, the main part of the magnetic shield (coil spring) 80 is a magnetic body constituting the coil spring (that is, a magnetic body adjacent to each other) (magnetic steel in this embodiment). Line) It is comprised by the close_contact | adherence coil spring which has a structure where two mutually contact | adhered.

  Since the main part of the magnetic shield (coil spring) 80 is constituted by the close contact coil spring in this way, the magnetic body (magnetic steel wire) is in close contact with the main part of the magnetic shield (coil spring) 80. When the object to be heated is not placed on 40, the magnetism can be shielded more appropriately, and the non-placement of the object to be heated on the virtues 40 can be detected more reliably.

  However, in the present invention, a coil spring in which adjacent magnetic bodies are not in close contact can be used as the magnetic shield. In that case, the magnetic shielding ability is somewhat lower than when a close coil spring is used, but by using a reed switch whose characteristics are selected in anticipation of this, temperature detection that has an effect equivalent to the case of the above embodiment is achieved. It is possible to configure the device.

[Another embodiment 1]
FIG. 6 is a diagram illustrating a configuration of a main part of a temperature detecting device 50 for a heating cooker according to another embodiment 1 of the present invention, and (a) is a state before the magnetic shield 80 is fixed to the glass braided tube 75. State (b) is a view showing a state after the magnetic shield 80 is fixed to the glass braided tube 75.

  Although the case where the magnetic shield 80 is configured by a coil spring has been described in the above embodiment, the magnetic shield 80 may be configured by a member other than the coil spring in the present invention. Hereinafter, a description will be given with reference to FIGS.

  In this alternative embodiment 1, the magnetic shield 80 is formed as a cylindrical structure made of ferrite having an inner diameter dimension equal to or larger than the outer diameter dimension of the glass braided tube (transmission member) 75. The magnetic shield 80 is externally fitted to a glass braided tube (transmission member) 75 as shown in FIGS. 6A and 6B in the other side 51b.

  In addition, as shown in FIG. 6B, the magnetic shield 80 has a predetermined position of the glass braided tube (transmission member) 75 by a pair of crimping fixing members 81 disposed on both ends of the magnetic shield 80. Is held in.

  Specifically, a pair of pressure-bonding and fixing members 81 formed separately from the magnetic shield 80, and a tubular pressure-fixing and fixing member 81 having an outer diameter larger than the inner diameter of the magnetic shield 80 is a magnetic shield. The glass braided tube (transmission member) 75 is externally fitted so as to be in contact with both ends of 80 (see FIG. 6A), and the pair of crimping fixing members 81 are caulked at that position, so that FIG. As shown, the pair of crimping fixing members 81 are deformed (the diameter is reduced) and fixed to the glass braided tube (transmission member) 75, and the magnetic shield 80 is interposed between the pair of crimping fixing members 81. It is held and fixed at a predetermined position.

  In the case of the configuration of the other embodiment 1, even when a material that is difficult to be plastically deformed, for example, ferrite, is used as the magnetic shield 80, a material made of a material suitable for caulking is used for the crimping fixing member 81. Therefore, by crimping the crimping fixing member 81, the magnetic shield 80 can be easily and reliably attached to an appropriate position of the glass braided tube 75 as a transmission member, and the manufacturing process can be rationalized. Can be planned.

  Further, when a cylindrical structure made of a material such as ferrite that is not elastically deformed is used as the magnetic shield 80, the magnetic shield 80 is inserted into the cylindrical support 51 after being processed into an L shape. However, in this case, for example, before the cylindrical support 51 is bent into an L shape, a glass braided tube to which the magnetic shield 80 is attached is inserted. be able to.

[Another embodiment 2]
7 (a) and 7 (b) are diagrams showing a main configuration of a temperature detection device 50 for a heating cooker according to another embodiment 2 of the present invention, and FIG. The state before being fixed to 75, (b) is a diagram showing the state after the magnetic shield 80 is fixed to the glass braided tube 75. FIG. 8 is a perspective view showing a configuration of a magnetic shield 80 used in the temperature detection device 50 for a heating cooker according to the second embodiment. In FIG. 8, the thickness of the magnetic shield 80 is omitted.

  In this second embodiment, as shown in FIGS. 7A and 8, the magnetic shield 80 has an inner diameter dimension equal to or larger than the outer diameter dimension of the glass braided tube 75, and in the other side 51b, It is configured as a cylindrical member made of a magnetic material such as iron and fitted on the braided tube 75.

  In addition, the magnetic shield 80 that is a cylindrical member includes: (a) a strip-like continuous connection that extends from a partial region in the circumferential direction of the axial end of the magnetic shield 80 toward the outside in the axial direction. And (b) the continuous crimping provided continuously from the magnetic shield 80 via the continuous connection portion 82a in such a manner that the main part is positioned with a predetermined gap 82c between the magnetic shield 80 and the main part 82b. And a fixing portion 82b.

  Then, as shown in FIG. 7A, the cylindrical support 51 and the continuous crimping fixing portion 82b are externally fitted to the glass braided tube (transmission member) 75 as shown in FIG. 7B. In addition, the continuous crimping fixing portion 82 b is caulked and plastically deformed and fixed to the glass braided tube 75 so that the magnetic shield 80 is held at a predetermined position of the glass braided tube 75. Yes.

  In the case of the configuration of the second embodiment, the glass braiding is suppressed while the magnetic shield 80 is prevented from being deformed when the continuous crimping fixing portion 82b is fixed to the glass braided tube 75 by caulking. The magnetic shield 80 can be disposed at a predetermined position of the tube 75. As a result, it is possible to improve the reliability by suppressing the magnetic shielding function from being damaged by the deformation of the magnetic shielding body 80.

  Further, as in the case of the second embodiment, also when a cylindrical structure made of a magnetic material such as iron is used as the magnetic shield 80, the cylindrical support 51 after being processed into an L shape. In this case, for example, before bending the cylindrical support 51 into an L shape, the glass braided tube 75 to which the magnetic shield 80 is attached is attached. This can be handled by inserting it.

  The present invention is not limited to the above-described embodiment or other embodiments 1 and 2, and various modifications can be made within the scope of the present invention.

32a Standard thermal power stove burner 32b High thermal power stove burner 32c Small thermal power stove burner 33 Grill 35a Standard thermal power stove burner heating state adjustment unit 35b High thermal power stove burner heating status adjustment unit 35c Small thermal power stove burner heating status control unit 40 (50a, 50b, 50c) Temperature detection device for cooking device 51 Cylindrical support 51a One side of the cylindrical support 51b The other side of the cylindrical support 51c Bending part of the cylindrical support 55 Lifting body 55a Lifting Body body 60 detector (temperature detector)
60a Heat collector 60b Thermistor 60c Holding part provided with flange part 61 Lead wire 62 Temperature detection mechanism 65 Reed switch 66 Magnet 67 Operation part 68 Heated object detection mechanism 75 Transmission member (glass braided tube)
80 Magnetic shielding body 80a Reduced diameter portion for caulking 81 A pair of crimping fixing members 82a A continuous strip-shaped connection portion 82b A continuous crimping fixing portion 82c Gap 91 Exhaust port 100 Grilled stove (heating cooker)
101 Case body (stove body)

Claims (3)

A cylindrical support having a substantially L shape and fixedly disposed in a heating cooker, one side extending in a substantially vertical direction and the other extending in a substantially horizontal direction from the one side And a cylindrical support body that is configured so that a boundary region between the one side part and the other side part is a bent part.
The bottom of the object to be heated placed on the placing part of the heating cooker comes into contact, moves up and down with the vertical movement of the object to be heated, and is urged to return upward. An elevating body supported by the upper end of the one side of the shaped support,
A detection unit that detects the temperature of the bottom of the object to be heated, and a lead wire that is disposed in the cylindrical support body in a manner extending outward from the other side of the cylindrical support member, and transmits detection information of the detection unit A temperature detection mechanism comprising:
A reed switch that is provided on the outer peripheral portion of the other side of the cylindrical support and can be switched between a first state and a second state by applying a magnetic field, and to face the reed switch via the other side. And a magnet disposed on the outer peripheral portion of the other side portion and the inside of the other side portion of the cylindrical support, and the reed switch is moved closer to and away from the reed switch. A heated object detection mechanism including an operation unit for switching between the first state and the second state;
One end is connected to the elevating body and the other end is disposed in the cylindrical support body in such a manner that the other end extends into the other side, and along the axial direction of the cylindrical support body as the elevating body moves up and down. A transmission member that moves within the cylindrical support;
A temperature detection device for a cooking device comprising:
A magnetic shield that shields the magnetic field of the magnet applied to the reed switch by being positioned between the reed switch and the magnet is disposed at a predetermined position of the transmission member as the operation unit. And
The temperature detection device for a heating cooker, wherein the transmission member is a glass braided tube disposed so as to cover at least the lead wire from the elevating body to the magnetic shield. The magnetic shield is a cylindrical member having an inner diameter dimension equal to or larger than the outer diameter dimension of the glass braided tube, and is externally fitted to the glass braided tube in the other side portion;
The pair of substantially cylindrical crimping fixing members having an outer diameter larger than the inner diameter of the magnetic shield are adjacent to both ends of the magnetic shield so as to be adjacent to both ends of the magnetic shield. The temperature detection device for a heating cooker according to claim 1, wherein the temperature detection device is fixed to a glass braided tube. The magnetic shield is a cylindrical member having an inner diameter dimension equal to or larger than the outer diameter dimension of the glass braided tube, and is externally fitted to the glass braided tube in the other side portion;
The magnetic shield that is the cylindrical member includes: (a) a strip-like continuous connection portion that is continuous from a partial region in the circumferential direction of the axial end of the magnetic shield toward the outside in the axial direction; (B) a continuous crimping fixing portion continuously provided from the magnetic shield via the continuous connection portion in a mode in which the main portion is positioned with a predetermined gap between the magnetic shield and the magnetic shield; Prepared,
The continuous crimping fixing portion is caulked and plastically deformed and fixed to the glass braided tube, whereby the magnetic shield is held at a predetermined position of the glass braided tube. The temperature detection apparatus for heating cookers of Claim 1.

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