KR100679246B1 - A control method from wrong using of gasoven range - Google Patents

Abstract

The present invention relates to a control method according to the gas misuse of the gas oven range, and more particularly to determine the state of the gas supplied to the gas oven range, gas misuse of the gas oven range to shut off the valve in case of misuse It relates to a control method according to. According to the present invention, a reference value of carbon monoxide generated according to the use of burners, grills and ovens in a gas oven range is set in advance, and the amount of carbon monoxide and reference values generated according to the currently supplied gas according to whether burners, grills and ovens are used. In comparison, the state of carbon monoxide (normal or misused) is determined. As a result of the determination, when the gas in the gas oven range is used incorrectly, the valve is shut off during operation, and an error state of carbon monoxide is displayed and an alarm sound is output. As a result, the present invention shuts off the gas valve within a short time when the gas is misused, and notifies the outside of the misuse of the gas, thereby enabling the user to respond quickly.

Gas oven range, carbon monoxide, ideal gas

Description

A control method from wrong using of gasoven range

1 is a perspective view of a gas oven generally equipped with a hidden burner.

2 is a system configuration of a gas oven range generally equipped with a hidden burner.

3 is a state diagram showing a change amount of carbon monoxide according to gas misuse of the gas oven range.

4 is a state diagram showing a change amount of carbon monoxide according to gas misuse of the gas oven range.

Figure 5 is a flow chart of the operation of the carbon monoxide sensor microcomputer for detecting the gas misuse of the gas oven range according to the present invention.

Figure 6 is a flow chart of the operation of the hidden burner micom for detecting gas misuse of the gas oven range according to the present invention.

7 is an embodiment showing a gas state diagram until the alarm sound according to the gas misuse of the gas oven range according to the present invention.

           Explanation of symbols on the main parts of the drawings

100: oven and grill microcomputer 110: hidden burner microcomputer

120: carbon monoxide sensor microcomputer

The present invention relates to a gas oven range, and more particularly, a control method according to gas use of a gas oven range that detects the misuse of a gas supplied to the gas oven range, cuts off the supply of gas, and controls the display to the outside. It is about.

Hereinafter, the hidden burner gas oven range will be described.

1 is a perspective view of a gas oven range generally equipped with a hidden burner.

In the gas oven range, the oven unit 10, the grill unit 9, and the top burner unit 3 are all provided in one apparatus, so that various dishes may be performed at the same time. As shown in the drawing, an oven unit 10 mainly for barbecue cooking is installed by using a vertical thermal power and tropical streams, and a grilled dish of fish using tropical streams is mainly formed above the oven unit 10. The grill part 9 is provided, and the top burner part 3 is provided in the upper part of the grill part 9 so that the several burners for heating the container in which food is contained are exposed on the upper side. And the back of the device is combined with a back guard for discharging the exhaust gas generated in the oven unit 10, the grill unit 9 to the outside, the rear of the oven unit 10 barbecue motor (not shown separately) And a convection motor (not shown) are installed.

When cooking a barbecue or a room, etc., cook in the oven section (10), and when grilled brown fish such as grilled fish, cook using the grill section (9), and put food in a container to heat When cooking a general cooking using the burner of the top burner portion (3) exposed to the upper portion.

In particular, the top burner portion 3 of the gas oven range is formed in a hidden burner type. The burner type is a ceramic glass (2) which is installed on the upper opening of the outer case (1) to be placed on the food, and disposed below the ceramic glass (2) and the ceramic glass (2) A burner housing 4 coupled to the exhaust passage is formed therebetween, and a radiation burner 5 coupled to the burner housing 4 and generating a radiation wave by burning the mixed gas. When the mixed gas is supplied to the radiation burner 5 and ignition is performed, radiation heat is generated in the ceramic glass 2.

As the gas is supplied, it is determined whether the current gas is suitable for the gas oven range according to the amount of carbon monoxide generated during burner combustion. The gas oven range may use city gas (LNG) and propane gas (LPG) at the same time. When using city gas (LNG) and converting to propane gas (LPG), you need to change the nozzle on each burner. Because the nozzles have different diameters for each gas, the pressure and calorific value for each gas are different. Therefore, when the operating gas changes, the nozzles corresponding to the gas must be replaced.

In the existing products, when the nozzles for gas were not matched, the length of the flame showed that the nozzles were used incorrectly. However, since the flame was not visible in the hidden burner, an accurate judgment could not be made. Therefore, a carbon monoxide sensor was attached to detect carbon monoxide generated when other gases were used.

2 is a system configuration diagram of a gas oven with a hidden burner in general.

As shown in the figure, the oven and grill micom 100, the hidden burner micom 110, and the carbon monoxide sensor micom 120 are configured in the hidden burner type gas oven range, respectively. The oven and grill micom 100 performs control according to the operation of the oven and the grill. The carbon monoxide sensor microcomputer 120 performs a function of detecting the amount of carbon monoxide generated by the heating operation of the gas oven ladle. The hidden burner microcomputer 110 controls the operation of the hidden burner according to the sensing amount of carbon monoxide in accordance with the output signals transmitted from the carbon monoxide sensor microcomputer 120 and the oven and the grill microcomputer 100.

When the oven and the grill operate, a control signal is input from the P3 port of the oven and grill micom 100 to the P3 'port of the hidden burner micom 110. On the other hand, when the hidden burner or oven and the grill operates, the carbon monoxide sensor measures the amount of carbon monoxide generated by heating. When carbon monoxide is detected from the carbon monoxide sensor, a control signal is input from the P1 port of the carbon monoxide (CO) sensor microcomputer to the P1 'port of the hidden burner microcomputer 110. The control signal is input from the P2 port of the carbon monoxide (CO) sensor microcomputer to the P2 'port of the hidden burner microcomputer 110. The control signals input to the P1 'and P2' are output according to whether carbon monoxide is detected from the carbon monoxide sensor and the amount of carbon monoxide detected from the carbon monoxide sensor microcomputer 120 reaches each reference value. In this case, P1 of the carbon monoxide sensor microcomputer 120 is an output signal with respect to the first reference value, and P2 of the carbon monoxide sensor microcomputer 120 is an output signal with respect to the second reference value.

The hidden burner microcomputer 110 may grasp the state of the amount of carbon monoxide generated in the gas oven range according to whether a signal is input from P1 ', P2', and P3 'as shown.

3 is a state diagram showing the amount of change of carbon monoxide according to the gas misuse of the gas oven range, Figure 4 is a state diagram showing the amount of change of carbon monoxide according to the gas misuse of the gas oven range.

Conventionally, as the gas oven is heated, carbon monoxide is generated during the operation of a hidden burner or an oven and a grill. As shown in FIG. 3, when gas is normally supplied to the gas oven range, the amount of carbon monoxide generated during the operation of the hidden burner does not exceed the first reference value. When the gas is supplied to the gas oven range normally, the amount of carbon monoxide generated during the operation of the oven and the grill exceeds the first reference value, but does not exceed the second reference value.

However, when the gas is abnormally supplied to the gas oven range, as illustrated in FIG. 4, the amount of carbon monoxide generated during the hidden burner operation and the amount of carbon monoxide generated during the oven and grill operation respectively exceed the second reference value.

Conventionally, the reference value of the carbon monoxide according to the gas state is fixed at the first level to determine the gas supply state. That is, conventionally, carbon monoxide is attached to detect carbon monoxide generated when other gases are used. In addition, the amount of carbon monoxide generated when only the hidden burner is operated in the normal gas state does not reach the first level as shown in FIG. 3. However, when the grill and the oven are used, the first level is exceeded even in the normal gas state, thereby controlling the load to be cut off according to the carbon monoxide error. Regardless of the gas state (normal or abnormal), if the first level, which is simply the reference value for the amount of carbon monoxide, is exceeded, the load is controlled unconditionally regardless of the state of the supplied gas.

Therefore, the gas burner of the hidden burner type according to the prior art had the following problems.

Due to the characteristics of the product, the gas oven range includes different kinds of burners according to the thermal power, so that the concentration of carbon monoxide generated depending on the burner type (large burner, small burner) when gas is used is different. The degree of generation of carbon monoxide concentration also varies depending on the installation conditions (ventilation conditions). In addition, the amount of carbon monoxide is generated differently depending on the number of burners and the use of burners, grills, and ovens. However, in the related art, regardless of the burner and grill of the gas oven range, whether the oven is used and the strength of the thermal power, when a predetermined value of carbon monoxide is generated, the load is uniformly cut off. As described above, there is a problem in that the current state of carbon monoxide in the gas oven range is not accurately understood.

Therefore, the present invention detects the misuse of the gas supplied to the gas oven range according to the burner and grill, whether the oven is used, and the power of the fire, control the display of the gas oven and the gas misuse of the gas oven to control the display outside In providing a method.

The control method according to the gas misuse of the gas oven range according to the present invention for achieving the above object, the first reference value for the amount of carbon monoxide generated during the operation of the hidden burner and is generated more during the operation of the hidden burner, oven and grill Setting a second reference value for the amount of carbon monoxide, determining whether the hidden burner, the oven, and the grill are in operation; Counting the holding time, determining that the generation state of carbon monoxide is abnormal when the counted time passes a predetermined holding time, and stopping the hidden burner, oven, or grill operation according to the determination result. It is configured to include.
When only the hidden burner is in operation, when the amount of carbon monoxide exceeds the second reference value and the holding time is counted and the counted time passes a predetermined holding time, the generation of carbon monoxide is determined to be abnormal. To stop.
In addition, when only the hidden burner is in operation, when the amount of carbon monoxide exceeds the first reference value and the holding time is counted and the counted time passes a predetermined holding time, it is determined that the generation state of carbon monoxide is abnormal. To stop.
In addition, the amount of carbon monoxide generated by the currently supplied gas is different depending on whether the hidden burner, the grill, or the oven is used.

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Hereinafter, a control method according to gas misuse of a gas oven range according to the present invention will be described with reference to FIGS. 1 to 4 with respect to a perspective view of a gas oven range, and a normal gas state and an abnormal gas state.

5 is an operation control flowchart of the carbon monoxide sensor microcomputer 120 for detecting the gas misuse of the gas oven range according to the present invention.

First, when the heating signal is input, the gas oven is driven (step 500). When it is determined that the gas oven range is being driven according to the heating signal input in step 500 (operation 510), the carbon monoxide sensor detects carbon monoxide generated by driving the gas oven range. At this time, the resistance value is used to detect the amount of carbon monoxide, and the resistance value changed due to the increase of carbon monoxide is converted into a voltage value and input to the carbon monoxide sensor microcomputer 120. The carbon monoxide sensor microcomputer 120 calculates the amount of carbon monoxide currently input according to the input voltage value (step 520). In this case, a reference value of carbon monoxide is preset in the carbon monoxide sensor microcomputer 120. That is, the first level and the second level are separately designated and are reference values for determining whether the amount of carbon monoxide is increased to reach a predetermined value. In an embodiment of the present invention, the first level is 100 ppm and the second level is 235 ppm.

Accordingly, the carbon monoxide sensor microcomputer 120 detects the amount of carbon monoxide generated by heating the gas oven range, and calculates whether the amount of carbon monoxide detected exceeds the first reference value (operation 530).

If the amount of carbon monoxide does not exceed the first reference value, the ports P1 and P2 of the carbon monoxide sensor microcomputer 120 are in an OFF state and remain low (step 540). However, when the first reference value is exceeded, the carbon monoxide sensor microcomputer 120 controls the high signal to be output through the P1 port, while maintaining the low state by maintaining the P2 port (step 550). Accordingly, the high signal output through the P1 port is input to the P1 'port of the hidden burner microcomputer 110. As a result, the hidden burner microcomputer 110 determines that the current amount of carbon monoxide exceeds the first reference value.

On the other hand, after step 550, the amount of carbon monoxide continues to increase, and if the amount of carbon monoxide detected from the carbon monoxide sensor exceeds the second reference value (step 560), the P2 port as well as the P1 port of the carbon monoxide sensor microcomputer 120 are turned on. The transition is made (step 570). Accordingly, the high signal is input to the P1 'and P2' ports of the hidden burner microcomputer 110 through the P1 and P2 ports.

As described above, the carbon monoxide sensor microcomputer 120 outputs a high signal through the P1 and P2 ports in comparison with a preset reference value according to the amount of carbon monoxide detected from the carbon monoxide sensor. As a result, the hidden burner microcomputer 110 receiving the high signal may determine the current state of carbon monoxide.

Figure 6 is a flow chart of the operation of the hidden burner micom for detecting gas misuse of the gas oven range according to the present invention.

The hidden burner micom 110, according to the signal received from the P1, P2 port of the carbon monoxide sensor microcomputer 120, the hidden burner microcomputer 110 detects the amount of carbon monoxide. As described above, the hidden burner microcomputer 110 controls the operation of the hidden burner while determining the current carbon monoxide state according to signals transmitted from P1 and P2 of the carbon monoxide sensor microcomputer 120 during the hidden burner operation.

As such, during operation of the hidden burner (step 600), it is detected whether a high signal is output from the P3 port of the oven and the grill microcomputer 100 to the P3 ′ port of the hidden burner (step 610). When the high signal of the ON state from the P3 port of the oven and grill micom 100 is input to the P3 'port of the hidden burner micom 110, the hidden burner micom 110 is the oven and grill micom 100 It is determined that the vehicle is in operation (step 620).

Accordingly, the hidden burner microcomputer 110 reads data input through the P1 and P2 ports of the carbon monoxide sensor microcomputer 120 (operation 630). In the oven and grill operation, the amount of carbon monoxide generated from the gas oven range exceeds the first reference value and exceeds the second reference value. Therefore, the high signal is input to the P1 'and P2' ports of the hidden burner microcomputer 110 through the P1 and P2 ports of the carbon monoxide sensor microcomputer 120.

Therefore, when the P2 port of the carbon monoxide sensor microcomputer 120 is turned on in step 640 and a high signal is input to P2 ′ of the hidden burner microcomputer 110, it means that the carbon monoxide has exceeded the second reference value.

When the carbon monoxide is generated and exceeds the second reference value, the time for maintaining the state where the amount of carbon monoxide exceeds the second reference value is counted (step 650). When the counted time passes the second holding time (19 seconds in the embodiment of the present invention) (step 660), the hidden burner microcomputer 110 determines that the carbon monoxide generation state is 'abnormal'.

In the case where carbon monoxide is generated by heating the gas oven range, and the gas in the gas oven range is normal, as shown in FIG. 3, the carbon monoxide generation amount does not exceed the first reference value when operating only the burner as shown in FIG. And the grill operation together, the amount of carbon monoxide generated exceeds the first reference value but does not exceed the second reference value.

However, when the gas in the gas range is misused, the amount of carbon monoxide exceeds the second reference value not only during the operation of the hidden burner but also during the operation of the oven and the grill, so that the amount of carbon monoxide increases rapidly.

As a result, the hidden burner controls the gas valve to be shut off during operation (operation 670). As a result, both the hidden burner and oven and grill operations stop. In addition, the hidden burner microcomputer 110 displays that the current carbon monoxide is in an error state and outputs an alarm sound (step 680).

Meanwhile, in operation 610, when the P2 ports of the oven and the grill microcomputer 100 are OFF, the low signal is input to the P2 ′ port of the hidden burner microcomputer 110, and the hidden burner microcomputer 110 is currently present. It is determined that only the hidden burner is in operation (step 700).

In operation 700, only the P1 port of the carbon monoxide sensor micom 120 is turned on, and the hidden burner microcomputer 110 reads data of the high signal transmitted from the P1 port (operation 720).

In the case where carbon monoxide is generated by heating the gas oven range, and the gas in the gas oven range is normal, as shown in FIG. 3, the carbon monoxide generation amount does not exceed the first reference value when operating only the burner as shown in FIG. And the grill operation together, the amount of carbon monoxide generated exceeds the first reference value but does not exceed the second reference value.

However, when the gas in the gas range is misused, the amount of carbon monoxide exceeds the second reference value not only during the operation of the hidden burner but also during the operation of the oven and the grill, thereby rapidly increasing the amount of carbon monoxide.

When only the hidden burner operates, a high signal is input to the P1 'port of the hidden burner microcomputer 110 through the P1 port of the carbon monoxide sensor microcomputer 120. Therefore, the hidden burner microcomputer 110 determines whether the P1 port of the carbon monoxide sensor microcomputer 120 is turned on and whether a high signal is input (operation 720).

As a result of the determination, when the high signal of the P1 port of the carbon monoxide sensor micom 120 is input to the P1 'port of the hidden burner micom 110, the high signal is transmitted from the P2 port of the carbon monoxide sensor micom 120 to P2 of the hidden burner micom 110. In operation 730, it is determined whether the port is input to the port. When the P2 port of the carbon monoxide sensor microcomputer 120 is turned on and a high signal is input to P2 ′ of the hidden burner microcomputer 110, it means that the carbon monoxide has exceeded the second reference value.

When the carbon monoxide is generated and exceeds the second reference value, the time for maintaining the state where the amount of carbon monoxide exceeds the second reference value is counted (step 740). When the counted time passes the second holding time (19 seconds as an embodiment of the present invention) (step 750), the hidden burner microcomputer 110 determines that the carbon monoxide generation state is 'abnormal'.

As a result, the hidden burner controls the gas valve to be shut off during operation (operation 670). As a result, the hidden burner operation stops. In addition, the hidden burner microcomputer 110 displays that the current carbon monoxide is in an error state and outputs an alarm sound (step 680).

However, in step 730, when the low signal is output from the P2 port of the carbon monoxide sensor micom 120 and the high signal is output only from the P1 port of the carbon monoxide sensor micom 120, the amount of carbon monoxide exceeds the first reference value. It means.

When the carbon monoxide is generated and exceeds the first reference value, the time for maintaining the state where the carbon monoxide amount exceeds the first reference value is counted (step 800). When the counted time passes the first holding time (450 seconds as an embodiment of the present invention) (step 810), the hidden burner microcomputer 110 determines that the carbon monoxide generation state is 'abnormal'.

As a result, the hidden burner controls the gas valve to be shut off during operation (operation 670). As a result, the hidden burner operation stops. In addition, the hidden burner microcomputer 110 displays that the current carbon monoxide is in an error state and outputs an alarm sound (step 680).

7 is an embodiment showing a gas state diagram until the alarm sound according to the gas misuse of the gas oven range according to the present invention.

As shown in the figure, the gas is supplied to the gas oven range so that the amount of carbon monoxide increases with time. As described above, when only the hidden burner is in operation, T1 second (about 450 seconds as an embodiment of the present invention) after the amount of carbon monoxide exceeds the first reference value (100 ppm as the embodiment of the present invention). The alarm will sound when the elapsed time. This informs the user that the generation of carbon monoxide in the hidden burner state is abnormal.

On the other hand, when the oven and grill operation are performed together with the hidden burner, the carbon monoxide increases more. In order to accurately determine the gas generation according to this, it is determined whether or not the second reference value (235 ppm as an embodiment of the present invention) has been reached. When the generation amount of carbon monoxide exceeds the second reference value and the T2 time (about 19 seconds as an embodiment of the present invention) elapses, an alarm sound is generated. Thus, the user is informed that the generation of carbon monoxide generated when the hidden burner and the oven and the grill are used at the same time is abnormal.

As described above, the present invention, based on the amount of carbon monoxide generated according to the use of the hidden burner, the oven and the grill, it is basic to determine the gas state (normal / misuse) of the gas oven range compared to the preset reference value It is technical idea.

In addition, the present invention is characterized in that when the gas state is misused, shut off the gas valve and display a carbon monoxide error or output an alarm sound.

In the embodiment of the present invention, the amount of carbon monoxide generated according to the use of the burner, the oven and the grill of the gas oven range is compared with the reference value to determine the gas state (normal or misuse) supplied to the gas oven range. In addition, according to the type of burner (large burner, small burner) and the installation condition (ventilation condition), the amount of carbon monoxide supplied to the gas oven range (normal or misused) is determined by comparing with the detected amount of carbon monoxide and the reference value. It is also possible to.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Due to the control method according to the gas misuse of the gas oven range according to the present invention it can be expected the following effects.

The present invention presets the reference value of the amount of carbon monoxide generated according to the use of burners, grills and ovens in the gas oven range. The state of carbon monoxide (normal or misused) is determined by comparing the carbon monoxide generated according to the currently supplied gas and a reference value according to whether the burner, grill, or oven of the gas oven range is used. If the gas in the gas oven range is misused as a result of the determination, the valve is shut off during operation, and an error state of carbon monoxide is output as an indication and an alarm sound.

As a result, according to the present invention, the user can quickly grasp the state of the carbon monoxide in the current gas oven range, shut off the gas valve in a short time when the gas is misused, and notify the outside whether the gas is misused, Make it cope.

Claims (4)

Setting a first reference value for the amount of carbon monoxide generated during the operation of a hidden burner and a second reference value for the amount of carbon monoxide generated more during the operation of the hidden burner, the oven, and the grill; Determining whether the hidden burner, the oven, and the grill are in operation; Counting the time for which the amount of carbon monoxide generated from the gas oven range is maintained above the second reference value when the hidden burner, the oven and the grill are in operation; Determining that the generation state of carbon monoxide is abnormal when the counted time passes a predetermined holding time; The control method according to the gas misuse of the gas oven range comprising the step of stopping the operation of the hidden burner, oven, grill according to the determination result. The method of claim 1, When only the hidden burner is in operation, when the amount of carbon monoxide exceeds the second reference value and the holding time is counted and the counted time passes the predetermined holding time, it is determined that the generation state of carbon monoxide is abnormal and the operation of the hidden burner is stopped. Control method according to the gas misuse of the gas oven range characterized in that. The method according to claim 1 or 2, When only the hidden burner is in operation, when the amount of carbon monoxide exceeds the first reference value and the holding time is counted and the counted time passes the predetermined holding time, it is determined that the generation state of carbon monoxide is abnormal and the operation of the hidden burner is stopped. Control method according to the gas misuse of the gas oven range characterized in that. The method of claim 1, Control method according to the gas misuse of the gas oven range characterized in that the amount of carbon monoxide generated by the currently supplied gas occurs differently depending on the use of the hidden burner, grill, oven.

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