KR101771083B1 - Thermal sensing protective device for gas rice cooker - Google Patents

Abstract

The present invention relates to a device for protecting a thermal sensitive portion of a gas rice cooker. More specifically, the present invention relates to a device for protecting a thermal sensitive portion of a gas rice cooker including a burner for heating a pot, a sensor for sensing the heat of the pot, and a spring elastically supporting inner and outer heat shielding plates for protecting the sensor. The inner heat shielding plate has a vertical wall surface surrounding the sensor. The outer heat shielding plate has a contact surface which is in contact with the vertical wall surface of the inner heat shielding plate. The present invention is able to solve problems of bad cooking and operation errors, such as half-cooking of rice due to premature combustion by controlling a tilting of the external heat shielding plate due to the impact and allowing the pot and the external heat shielding plate to be in close contact with each other by effective elastic restoration.

Description

TECHNICAL FIELD [0001] The present invention relates to a thermally insulated protective device,

More particularly, the present invention relates to a device for protecting a thermally sensitive portion of a gas taking-up period, which prevents a heat sensing error by blocking the direct transfer of a burner heat to a sensor for detecting a pot temperature .

The gas cooker is provided with a thermoelectric part A for detecting the heat of the cooker 11 at the center of the burner 12 of the combustion chamber 10 and detects the temperature of the cooker during the heat transfer process through the thermo part, If the actual temperature of the pot heated by the heat transfer can not be accurately detected, the fire can not be controlled and the rice is cooked or overcooked.

The heat sensing portion A includes a sensor 14 for detecting the pot temperature, a base 15, an inner heat shield 16 surrounding the outside of the base 15, a spring (not shown) surrounding the outside of the inner heat shield 16, 17 as an external heat shield plate. The sensor 14 has a structure that surrounds the sensor 14 with the outer heat shield plate 16 (18) so as to contact under the pot and to protect the sensor 14 from heat so as to detect the temperature of the cooker 11 2, the outer heat shield plate 18 is moved away from the central axis S and is inclined at an arbitrary S1 inclination, as shown in Fig. 2, when an impact of D is applied to the external heat shield plate 18 subjected to elasticity of the spring 17, It tilts.

When the outer heat shield plate 18 is inclined, the upper step 19 forms a gap with the bottom surface of the cooker 11, and the heat of the burner can be directly introduced into the sensor 14 between the gaps. The problem of the inclination of the external heat shield plate 18 can not be detected when the inside of the combustion chamber is cleaned, when the pot is placed on the heat sensing portion and docked, when the pot is inserted and removed, when the door is opened and closed, Appears when an impact is applied to the soleplate.

As shown in FIG. 3, the conventional heat-sensitive portion A is a conical shape in which the shape of the spring 17 for supporting the external heat-shielding plate 18 with elasticity is wide and narrow downward or vice versa, Spring contact points are formed only at the lower portions of the outer heat shield plate 16 and the upper portions of the outer heat shield plate 18, and spring clearances are formed throughout the springs. This causes the outer heat shield plate 18 to tilt out of the center. When the outer heat shield plate 18 is inclined away from the center, the step 19 is overlapped with the upper step of the inner heat shield plate 16, It may not be restored to the center position and may be restrained.

If the outside heat plate of the heat source part is tilted or constrained and it can not come into close contact with the bottom of the pot and the gap spreads, the heat of the burner is transferred to the heat source part, and the sensor detects the temperature of the heat of the burner flowing along the gap, . When the burner heat is directly transferred to the sensor, it is impossible to detect the temperature of the actual pot and it is possible to detect a temperature higher than the current pot temperature, or to detect the temperature of the burner line irrespective of the actual pot temperature, Causing premature digestion and malfunction of the rice.

Patent Document 1. Korean Patent Laid-Open No. 10-2011-0111672

Patent Document 2: Korean Patent Publication No. 10-2012-0061255

Patent Document 3: JP-A-07-269871

It is an object of the present invention to solve the problem of premature burnout of a burner due to a pot temperature detection error through a thermal unit.

Another object of the present invention is to prevent the outer heat shield plate which constitutes the thermosensitive part from tilting to protect the thermosensitive part.

It is still another object of the present invention to improve the operational reliability of the gas intake and the service period by preventing the heat generating portion from being affected by the heat of the burner.

According to the present invention, the above-mentioned objects can be accomplished by a heat-sensing part of a gas-taking season including a burner for heating a pot, a sensor for sensing the heat of the pot, an inner and outer heat shield for protecting the sensor, and a spring for resiliently heating the outer heat shield , The inner heat shield plate has a vertical wall surface surrounding the sensor, and the outer heat shield plate has a contact surface which is in contact with the vertical wall surface of the inner heat shield plate, do.

Further, according to the embodiment of the present invention, the upper portion of the inner heat shield plate has a bent step toward the sensor.

Further, according to the embodiment of the present invention, the upper portion of the outer heat shield plate has a bent stepped portion facing the vertical wall surface of the inner heat shield plate.

Further, according to the embodiment of the present invention, the stepped portion bent on the outer heat shield plate may include a bent surface bent to extend downward.

Further, according to the embodiment of the present invention, the external heat shield plate itself includes the housing for inducing the engagement of the spring, thereby preventing the spring from coming off.

In addition, according to the embodiment of the present invention, the spring includes a conical spring formed of an extension portion that forms a clearance that widens along the vertical wall surface of the inner heat shield plate.

Further, according to the embodiment of the present invention, the spring includes a two-stepped spring composed of a tight contact portion contacting the vertical wall surface of the inner heat shield plate and an extension portion forming a clearance and a clearance.

Further, according to the embodiment of the present invention, the length of the contact portion of the two-stage spring preferably has a length that is positioned at least one-half of the vertical wall surface of the inner heat sink.

According to the apparatus for protecting a thermally conductive part during the gas-taking period according to the embodiment of the present invention, the external heat shield plate can be prevented from being inclined due to external impact acting on the thermally- It is possible to prevent premature burnout of the burner, thereby preventing the rice from being saved.

Further, the present invention has the effect of safely protecting the heat-sensitive portion from the heat of the burner, effectively detecting the heat of the burner transmitted to the sensor, and reliably detecting the temperature of the pot.

In addition, the present invention has the effect of solving the problems such as gas-fired power control and premature fire extinguishment, solving operational error problems such as cooking rice during cooking, and improving operating reliability of the gas taking-off period.

Fig. 1 is a schematic view of the gas intake period.
Fig. 2 is a diagram illustrating the configuration and operation of the conventional heat exchanger of the conventional gas intake type.
Fig. 3 shows the shape of the spring constituting the thermally-conductive portion of the conventional gas-taking season.
FIG. 4 is a photograph showing an example in which a gap is formed between the thermosensitive part of the conventional gas absorption type and the pot.
Fig. 5 is an illustration of an external heat shield plate constituting a thermosensitive part of a gas intake half period according to an embodiment of the present invention.
6 is an illustration of a two-stage spring of a thermal head applied in accordance with an embodiment of the present invention.
FIG. 7 is an explanatory diagram of a thermal part to which a conical spring according to an embodiment of the present invention is applied, wherein (a) is a state in which no impact is transmitted to the external heat shield plate, (b) Is the external heat plate displacement at.
FIG. 8 is an explanatory view of a thermal part to which a two-stage spring according to an embodiment of the present invention is applied, in which (a) is a state in which no impact is transmitted to the external heat shield plate, (b) Is the external heat plate displacement in the state.
9 is an explanatory diagram of a heat flow control state to which a thermal protection unit according to an embodiment of the present invention is applied.
10 is a photograph showing an example in which the temperature sensor and the pot are closely contacted according to the embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

Fig. 4 is a photograph showing an example of a gap formed between the thermosensitive part and the pot in the gas reservoir. As can be seen in the photograph of FIG. 4, there is a latching phenomenon between the upper end of the thermally conductive portion and the bottom surface of the pot in the gas intake period due to the spring clearance, so that the spring restoring force is not applied to the external heat- . When the gap is formed, the heat of the burner coming from the bottom is directly transmitted to the sensor to detect the actual temperature of the cooker, and the operation temperature of the burner is detected by detecting the temperature of the burner. Causing problems to occur.

The thermally conductive part of the gas-taking / half period includes a burner 110 for heating the pot 120, a sensor 130 for sensing the heat of the pot 120, an inner and outer heat shielding plates 140 and 150 for protecting the sensors, And a spring 160 for resiliently urging the spring 150.

5 is an illustration of an external heat shield plate constituting a protective device for a heater unit during a gas-taking season according to an embodiment of the present invention.

5, the inner heat shield plate 140 has a vertical wall surface 141 surrounding the sensor 130, and the outer heat shield plate 150 has a vertical wall surface 141 of the inner heat shield plate 140, As shown in FIG. Reference numeral 151 denotes a vertical wall surface of the outer heat sink.

Here, the inner heat shield plate 140 and the outer heat shield plate 150 are similar to a cylinder having an empty space therein, and surround the contactor so that the heat of the burner can not come into contact with the contactor 130. A spring is supported between the opposed vertical wall surfaces supported by the lower base plate 170.

6 is an illustration showing a two-stage spring that can be applied to a thermal unit according to an embodiment of the present invention.

FIGS. 7 to 8 show a displacement state of the thermal type according to an embodiment of the present invention. FIG. 7 shows a conical spring application example, and FIG. 8 shows an example of a two- (B) shows a state in which the external heat plate is displaced in a state where a one-directional impact is transmitted to the external heat plate.

The apparatus for protecting a thermally conductive portion according to the embodiment of the present invention can prevent the temperature difference between the pot and the outer heat shield plate 150 due to the release or engagement of the spring through the outer heat shield plate 150 regardless of the application of the conical spring and the two- So that a gap is not formed between the two.

The upper portion of the inner heat shield plate 140 has a bent step 142 facing the sensor 130. The step 142 formed on the inner heat shield plate 140 is configured to be bent in the horizontal direction from the vertical wall surface 141 to face the bottom surface of the pot.

The upper portion of the outer heat shield plate 150 has a bent step 153 that faces the vertical wall surface 141 of the inner heat shield plate 140. Similarly, the step 153 formed on the outer heat sink plate 150 is configured to be bent in the horizontal direction from the vertical wall surface 151 to face the bottom surface of the pot. It is preferable that the step 153 bent in the horizontal direction is a plane which can be brought into close contact with the bottom surface of the pot 120.

In addition, the step 153, which is bent at the outer heat shield plate 150, may include a bent surface bent at an end thereof so as to extend downward. The bent surface may be a contact surface 152 to which the vertical wall surface 141 of the inner heat shield plate 140 closely contacts.

The contact surface 152 contacts the vertical wall surface 141 of the inner heat shield plate 140 when the outer heat shield plate 150 is tilted by the impact and blocks the further inclination, The upper step 153 is prevented from being caught by the inner heat shield plate 140 and safely returned to the normal position.

The edge of the boundary between the contact surface 152 of the external heat shield plate 150 and the upper step 153 is preferably formed by a rounded curved surface R. [ If the boundary between the contact surface 152 and the upper step 153 is formed by a rounded curved surface R, the locking operation may be more stable because the locking is not performed well as compared with the case where the corner is angled.

The outer heat shield plate 150 is bent at a bent step 153 extending from the end of the outer heat shield plate 150 so as to be bent downward so that even when the external heat shield plate 150 is inclined due to a shock, No further tilting is blocked and the phenomenon that the outer heat shield plate 150 is caught and constrained by the step 142 of the inner heat shield plate 140 does not appear, The heat plate 150 is maintained in an upright state close to the vertical.

The upper portion of the outer heat shield plate 150 constitutes a conical spring 160 or a housing 154 for inducing spring coupling such as a two-stage spring 160a together with the bent surface serving as the contact surface 152, It is possible to cope with problems such as separation of the outer heat shield plate 150 from the upper portion of the spring and spring constraint.

The spring may be a conical spring 160 formed of an extension extending along the vertical wall surface of the inner heat shield plate 140 to form a clearance for increasing the width.

6, the contact portion 161 contacting the vertical wall surface of the inner heat shield plate 140 and the region excluding the contact portion 161 are formed on the inner heat shield plate Stage spring 160a composed of the vertical wall surface 141 of the first spring 140 and the extension portion 162 forming the clearance.

The length of the contact portion 161 of the two-stepped spring 160a preferably has a length that is positioned at least 1/2 of the vertical wall surface 141 of the inner heat shield plate 140.

7, when the external heat shield plate 150 is impacted in the direction of the arrow in FIG. 7 (a) in which the conical spring 160 is applied to the thermal conductive portion A, A displacement in which the heat sink 150 tilts to some extent occurs, but the contact surface 152 contacts the vertical wall surface 141 of the inner heat shield plate 140, so that further displacement does not occur. Accordingly, even if the external heat shield plate 150 is tilted by impact, the spring 160 returns to its original position by elasticity when the impact disappears. Also, there is no problem that the outer heat shield plate 150 is caught by the inner heat shield plate 140 and the in-situ restoration is not performed.

8 shows an example in which the two-stage spring 160a is applied to the thermosensitive portion A. Even if a shock is transmitted to the outer heat shield plate 150 only by the conical spring 160 and the spring type as shown in FIG. 7, the contact surface 152 is in contact with the outer heat shield plate 150 even if a displacement, No further displacement occurs due to contact with the vertical wall surface 141 of the heat sink 140. When the impact is lost, the spring 160a is returned to the correct position by elasticity. Also, there is no problem that the outer heat shield plate 150 is caught by the inner heat shield plate 140 and the in-situ restoration is not performed.

6, the two-stage spring 160a has a structure in which the spring mounting portion 161 includes a close contact surface 163 contacting the outer wall 141 of the inner heat shield plate 140 And the spring clearance a1 may be partially formed only in a region other than the spring mounting portion 161 to induce the restoration of the external heat shield plate 150 to the original state. The upper step 153 of the outer heat shield plate 150 is not caught by the upper step 142 of the inner heat shield plate 140 because the two-end springs have little or no spring clearance.

The length L1 of the spring mounting portion 161 is set to be at least a half or more of the height of the outer wall 141 of the inner heat shield plate 140 so that the spring clearance a1 is limited to the upper portion It can be freely designed. Even if the outer heat shield plate 150 is tilted in one direction by the impact, the spring clearance space a1 concentrated on the upper portion does not develop into the one directional deflection but only a part of the upper clearance space is displaced, The external heat shield plate 150 is restored to the center axis S without being caught by the internal heat shield plate 140 by acting in a balanced manner on the heat sink 150. [

The two-stepped spring 160a includes the bent portion P whose boundary between the mounting portion 161 and the receiving portion 162 is bent so that the mounting portion 161 which is the spring lower portion is located on the vertical outer wall of the inner heat shield plate 140 141 and the upper side support portion 162 stably supports the upper step 153 of the external heat shield plate 150. As shown in FIG.

The two-stage spring 160a is configured such that the spring clearance a1 formed between the inner heat shield plate 140 and the outer heat shield plate 150 is at least 1/2 of the height of the outer wall 141 of the inner heat shield plate 140, Or more, it is advantageous to reduce the spring clearance to the outer heat shield plate 150 and to prevent the overlapping of the outer heat shield plate 150 against the external shock.

The shape of the receiving portion 162 of the two-end spring 160a is formed such that the upper portion is wide and the lower portion is gradually narrowed with respect to the point P, So that the outer heat shield plate 150 can be stably supported and supported while the external heat shield plate 150 can be restored to its original position with respect to an external shock.

As described above, according to the present invention, the spring for providing an elastic force for restoring the outer heat shield plate 150 in the thermally conductive portion A of the gas-absorbing half-period is formed of an inner heat shield plate 140 And a conical spring 160 or a two-stepped spring 160a may be installed along the housing 154 between the outer heat shield plate 150 and the outer heat shield plate 150 to form a spring clearance space.

Accordingly, even if the external heat shield plate 150 moves from the center axis S due to the impact and tilts to an arbitrary tilt axis, the spring restoring force is immediately applied to the external heat shield plate 150 in contact with the upper step 151 of the external heat shield plate 150 The gap between the outer heat shield plate 150 and the bottom surface of the cooker 120 can be eliminated by correcting the position of the central axis S of the cooking utensil 152 by adjusting the inclination to the center axis S. [

9 is an explanatory diagram of a heat flow control state to which a thermal protection unit according to an embodiment of the present invention is applied.

9, no gaps are formed between the pot 120 and the external heat shield plate 150 of the heat-sensing portion A in the combustion chamber 100 of the gas-taking season, so that the heat of the burner flows into the gap, Thereby preventing premature burning of the burner due to the actual temperature detection error of the pot generated in contact with the burner 130.

10 is a photograph showing an example in which the outer heat shield plate of the thermoelectric part according to the embodiment of the present invention is closely contacted with the pot without forming a gap therebetween.

Since the tilting of the outer heat shield plate can be stably restored by the spring elasticity against the external impact and the stator can be stably restored, it is possible to effectively heat the transfer of the burner heat to the sensor, The sensor is protected from the burner heat and the temperature of the pot is reliably detected to solve problems such as the problem of gas-fired power control abnormality, for example, premature fire extinguishment, etc., thereby preventing operation errors .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of illustration, .

100: combustion chamber 110: burner
120: cooker 130: sensor
140: inner heat sink plate 141: vertical wall surface
142: upper step 150: outer heat sink plate
151: vertical wall surface 152: contact surface (bending surface)
153: upper step 160: conical spring
160a: two-stage spring 161:
162; The receiving portion 163:
170: Base plate A:

Claims (7)

A sensor for sensing the heat of the pot, an inner and outer heat shielding plates for protecting the sensor, and a spring for restoring the outer heat shielding plate,
Wherein the inner heat shield plate has a vertical wall surface surrounding the sensor,
Wherein the upper surface of the outer heat shield plate has a contact surface facing the vertical wall surface of the inner heat shield plate so as to face the upper end of the vertical wall surface of the inner heat shield plate,
Wherein the upper portion of the inner heat shield plate has a bent step toward the sensor. delete delete The method according to claim 1,
Wherein the stepped portion of the outer heat shield plate includes a curved surface that is bent to extend downward. The method according to claim 1,
Wherein the external heat shield plate includes a housing for guiding the engagement of the spring. The method according to claim 1,
Wherein the spring has an extension extending along a vertical wall surface of the inner heat shield plate so as to have a larger width. The method according to claim 1,
Wherein the spring comprises a two-stage spring including a tight contact portion contacting the vertical wall surface of the inner heat shield plate and an extension portion forming a vertical wall surface and a clearance except for the tight contact portion.

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