KR20030033894A - Ignition control device for dryer - Google Patents

Abstract

PURPOSE: A combustion control apparatus for a drier is provided to control operation of a valve for supplying gas by detecting flame from a burner, and to prevent accidents from unnecessary fuel supply and wrong operation by feeding gas only in detecting flame. CONSTITUTION: A drier heats and dries the laundry by supplying hot air to a rotary drum, and discharges air from the rotary drum. A combustion control device of the drier comprises a flame detecting unit(60) detecting presence of flame for heating air, and a heating fuel driving unit controlled by the flame detecting unit and driven to supply fuel. Power to the heating fuel driving unit is forcibly shut off in not detecting flame from the flame detecting unit in drying. Accidents from unnecessary fuel supply and wrong operation are prevented by supplying gas in detecting flame.

Description

Ignition control device for dryer

The present invention relates to a combustion control apparatus of a dryer, and more particularly, to a combustion control apparatus of a dryer that detects the presence of a flame during a combustion operation for generating thermal energy and controls the safe combustion operation to proceed. .

1 and 2 show the configuration of a conventional dryer. As shown, the drum 1 is installed inside a cabinet (not shown) constituting the exterior of the dryer. The drum 1 is formed so that both sides in the horizontal direction are opened, and a belt groove 2 around which a belt (not shown) driven by a separate driving source is wound is formed along the middle of the outer circumferential surface. The drying chamber 5 in which drying proceeds is formed in the drum 1. A plurality of baffles 6 are formed inside the drying chamber 5 to turn over the object to be dried in the drying chamber 5 when the drum 1 rotates.

The front head 7 and the rear head 9 are installed at the front and rear ends of the drum 1, respectively. Therefore, the front head 7 and the rear head 9 serve to support the front and rear ends of the drum 1, respectively. In this case, a sealing member 8 is installed between the front head 7 and the drum 1 which are relatively rotated and between the rear head 9 and the drum 1 to prevent leakage. Of course, a plurality of rollers (not shown) for supporting the drum 1 are installed at positions corresponding to the front and rear ends of the drum 1.

The front head 7 is provided with a through hole 8 for communicating the interior and exterior of the drying chamber (5). The through hole 8 is selectively opened and closed by a door (not shown).

An air supply duct 12 is installed in the rear head 9, and the air supply duct 12 serves as a passage for supplying air, more precisely, hot air, into the drying chamber 5. It communicates with the interior of the drying chamber 5.

And one side of the front head 7 corresponding to the lower end of the through hole 8 of the front head 7 is provided with an outlet assembly 12 which is a part of the air escape from the drying chamber (5). The outlet assembly 13 is provided with a lint filter 14. The lint filter 14 serves to filter foreign matter (for example, seams or dust) mixed in the air flowing out of the drying chamber 5.

The lint duct 15 is installed in communication with the outlet assembly 12, and the lint filter 13 is positioned to the inside of the lint duct 15. The blower 17 is installed to be connected to the lint duct 15 to suck the air inside the drying chamber 5 through the lint duct 15. The blower 17 is installed inside the blower housing 18. One side of the blower housing 18 communicates with the lint duct 15, and an exhaust pipe 19 is connected to the other side. Therefore, the air exiting the drying chamber 5 and passing through the lint duct 15 is discharged to the outside through the exhaust pipe 19 by the force of the blower 17.

On the other hand, the hot air duct 20 is installed to be connected to the air supply duct (12). The hot air duct 20 serves to supply hot air having a drying function in the drying chamber 5. To this end, the hot air duct 20 is provided with a configuration for generating heat energy for heating the air.

That is, a gas nozzle 22 is installed at the inlet of the hot air duct 20. The gas nozzle 22 serves to inject the supplied gas. The gas nozzle 22 is provided with a valve 25 for controlling the supply of gas. Reference numeral 23 is a gas pipe.

The valve 25 is controlled by the control of a controller (not shown), and serves to open and close the gas supplied from the gas pipe 23 to the gas nozzle 22.

A mixing tube 24 for mixing the gas injected from the gas nozzle 22 and the primary air is installed to extend from the inlet of the hot air duct 20 to the inside. Here, the inlet of the mixing tube 24 is located to correspond to the gas nozzle 22. Inside the mixing tube 24, the gas injected from the gas nozzle 22 and the external air introduced through the inlet of the mixing tube 24, that is, primary air, are mixed. The spark plug 26 is installed at the tip of the mixing tube 24 to generate spark for ignition.

It will be described that the dryer according to the prior art having such a configuration is operated.

After putting the laundry cloth to be dried into the drying chamber 5 formed in the drum 1 and closing the door, pressing the operation button, the belt wound around the belt groove 2 is driven by a separate driving source. The drum 1 is rotated.

Then, the blower 17 is operated to suck the air inside the drying chamber 5 through the lint duct 15. In this case, the outside air flows into the drying chamber 5 through the air supply duct 12.

Here, the air supplied to the air supply duct 12 becomes a relatively high temperature while passing through the hot air duct 20. That is, gas is injected into the mixing tube 24 through the gas nozzle 22, and primary air enters the inlet of the mixing tube 24, and the gas is mixed with the gas in the mixing tube 24. The air is mixed and is first burned by ignition by the spark plug 26 at the outlet of the mixing tube 24.

As such, the heat energy generated by the combustion of the gas heats the air sucked by the suction force driven by the blower 17 into the hot air duct 20 to make hot air.

The hot air is delivered to the interior of the drying chamber 5 formed inside the drum 1 through the air supply duct 12. The hot air in the drying chamber (5) absorbs the moisture contained in the laundry cloth, and then exits from the drying chamber (5) through the outlet assembly (13). At this time, the air is discharged from the drying chamber 5 through the outlet assembly 13 is made by the suction force of the blower (17). Air passing through the outlet assembly 13 is filtered through the lint filter 14 so that foreign matter such as dust or seams is filtered out.

Next, a combustion control apparatus for generating heat energy required for a drying operation in a conventional dryer will be described.

FIG. 3 shows a state when the combustion control device is in operation, and FIG. 4 shows a fire state of the combustion control device.

First, the combustion control apparatus includes coils 266, 269 and 278 for opening and closing the valve 25. As shown in FIG. The reason why the plurality of coils is provided is that the valve 25 is a valve of two or more stages connected in series. That is, it can be described that the gas is supplied through the valve 25 only when all the coils are operated.

In addition, an igniter 275 for generating salt during an initial ignition operation and a bimetal sensor 272 (for example, a radiant sensor) that is turned on and off according to the influence of temperature. And a thermostat 263 is included at the beginning of the combustion control device. The sensor 272 and the thermostat 263 are kept in an on state without heat, and are switched to an off state when a certain temperature is reached by driving a heater.

The coil 269 configured to be driven last among the coils for the operation of the valve 25 has a higher resistance value than the sensor 272. This is to allow current to be supplied first to the igniter 275 through the sensor 272 in the initial power supply state.

In such a configuration, the conventional combustion control apparatus has the sensor 272 and the thermostat 263 in the on state during the initial operation without heat, so that when the power is supplied, the sensor 272 has the on state. Current is supplied to the igniter 275 through the igniter 275 is heated.

The heat generated by the igniter 275 causes the sensor 272 to switch off. The supplied current does not pass through the off-state sensor 272 and is supplied to the coils 266, 269, and 278 configured to drive the gas valve 25, thereby controlling the valve in the open state. When the valve 25 is opened in this way, heating is continuously performed by the gas supplied, and heat energy required by a dryer is generated.

Then, when the drying operation of the dryer is completed, when the driving of the heater is to be stopped, the controller (not shown) closes the operation of the valve 25 while cutting off the current supplied to each of the coils 266, 269, and 278. To control. In this case, the gas supplied to the mixing pipe 24 is blocked while the valve 25 is closed.

On the other hand, after the fire extinguishing operation, the sensor 272 is kept open as shown in FIG. 4 due to the latent heat remaining inside the hot air duct 20 for a predetermined time (several seconds).

Therefore, when the user applies a command to perform the drying operation in this operation state again or when the voltage is supplied to the combustion control device due to a malfunction of the control unit, a current is supplied to the igniter 275 through the open sensor 272. If not, it will immediately flow to the coil (266, 269, 278) driven for the opening and closing operation of the gas valve (25).

In this case, the gas supply state is controlled without confirming whether combustion is normally performed at the outlet side of the mixing pipe 24 at the control unit side controlling the combustion control device. As a result, by supplying gas unnecessarily in a state in which the combustion operation by the drying operation is not normally performed, not only does it generate fuel waste, but also normal drying operation cannot be performed.

In addition, when the valve 25 is controlled to be opened for a predetermined time or more in a state where there is no flame, the gas supplied from the gas pipe 23 and injected into the mixing pipe 24 through the gas nozzle 22 performs normal combustion. Something left to do is not done. If the ignition operation by the spark plug 26 occurs in the state that the unburned gas remains in the mixing tube 24, the risk of explosion is generated by the amount of gas filled in the mixing tube 24. .

In other words, the conventional dryer is a case where the gas is supplied in the absence of a flame, this is a problem that not only lowers the reliability of the product but also the user's safety.

Accordingly, an object of the present invention is to provide a combustion control apparatus for a dryer capable of detecting the presence of flame in a dryer and controlling a safe combustion operation.

1 is an exploded perspective view showing the main configuration of a dryer according to the prior art;

Figure 2 is a plan view showing the configuration of a gas combustion device for a dryer according to the prior art.

3 and 4 is an operating state diagram of a combustion control apparatus according to the prior art,

5 is a configuration diagram of a combustion control apparatus of a dryer according to the present invention;

6 is a principle diagram for salt detection.

Explanation of symbols on the main parts of the drawings

22 gas nozzle 23 gas pipe

24: mixing tube 25: valve

26: spark plug 60: salt detection sensor

63: thermostat 66,69,78: coil

72: radiant sensor 75: igniter

A combustion control apparatus for a dryer according to the present invention for achieving the above object is a dryer configured to supply heated air into a rotating drum to heat dry laundry and to discharge air in the rotating drum to the outside: for air heating Salt detection means for detecting the presence of a flame to be formed; And a heated fuel driving means which is driven to control the salt detecting means and is supplied to supply a heated fuel. When the salt is not detected in the salt detecting means while a drying operation is in progress, the heated fuel It is characterized by forcibly cutting off the power supply of the driving means.

The heating fuel drive means of the present invention is configured by connecting two or more valves in series, characterized in that configured to have a time difference in the operation time of each valve.

The present invention includes an igniter connected in parallel with the heating fuel driving means, the igniter being operated faster than the heating fuel driving means during initial ignition to generate salt; It is characterized by opening and closing the current path of the igniter through a sensor having an on state in the absence of heat.

Hereinafter, a combustion control apparatus of a dryer according to the present invention will be described in detail with reference to the accompanying drawings.

5 is a block diagram of a combustion control apparatus in the dryer according to the present invention. And the configuration of the dryer in the present invention will be described with reference to Figs.

In the present invention, the combustion control apparatus of the dryer is controlled by the operation of the salt detection sensor 60 capable of detecting the presence of a flame in the mixing tube 24.

The principle of the salt detection sensor 60 is the same as FIG. The salt detection sensor 60, as shown, is a switching sensor that is operated when detecting the presence of salt in the salt detection rod 50 configured to directly detect the flame generated by the burner 56.

The signal detected by the salt detection rod 50 is configured to be transmitted to the salt detection unit 54 through a signal line, and is converted into an electrical signal in the salt detection unit 54 and then input to the control unit 58. . Therefore, when salt is detected in the salt detection rod 50, the salt detection sensor 60 maintains an on state, but when salt is not detected, it maintains an off state.

The combustion control apparatus of the present invention is composed of a plurality of coils 66, 69, and 78 for opening and closing the valve 25. The reason why the plurality of coils is provided is that the valve 25 is a valve of two or more stages connected in series. That is, it can be described that the gas is supplied through the valve 25 only when all the coils are operated.

In addition, the igniter 75 in the initial ignition operation, and the bimetal type sensor 72 (for example, radiant sensor) that is on / off operation in accordance with the influence of temperature. And it comprises a thermostat (63) in the next stage of the salt detection sensor (60). The sensor 72 and the thermostat 63 are kept in an on state without heat, and are switched to an off state when a certain temperature is reached by driving a heater.

The coil 69 configured to be driven last among the coils for the operation of the valve 25 is set to have a higher resistance value than the sensor 72. This is to allow the current to be supplied first to the igniter 75 through the sensor 72 in the initial power supply state.

The following describes a process in which the dryer according to the present invention having the above configuration is operated.

After putting the laundry cloth to be dried into the drying chamber 5 formed in the drum 1 and closing the door, pressing the operation button, the belt wound around the belt groove 2 is driven by a separate driving source. The drum 1 is rotated.

Then, the blower 17 is operated to suck air inside the drying chamber 5 through the lint duct 15. In this case, the outside air flows into the drying chamber 5 through the air supply duct 12.

Here, the air supplied to the air supply duct 12 becomes a relatively high temperature while passing through the hot air duct 20. That is, gas is injected into the mixing tube 24 through the gas nozzle 22, and primary air enters the inlet of the mixing tube 24, and the gas is mixed with the gas in the mixing tube 24. The air is mixed to form a flame. At the outlet of the mixing tube 24 is first ignited by the spark plug 26, after which the flame is maintained by the gas supplied.

In the ignition operation, when power is supplied to the combustion control device of the present invention, the sensor 72 and the thermostat 63 are kept in the on state during the initial operation without heat, so that the power source is in the on state. Current is supplied to the igniter 75 through the 72, and the igniter 75 is heated. In this way initial ignition is achieved.

When the igniter 75 is heated, the sensor 72 is turned off at an elevated temperature as heat is generated. At this time, the supplied current does not pass through the sensor 72 in the off state and is supplied to the coils 66, 69, and 78 configured to drive the gas valve 25, thereby controlling the valve in the open state. When the valve 25 is opened in this way, heating is continuously performed by the gas supplied, and heat energy required by a dryer is generated.

As such, the heat energy generated by the combustion of the gas heats the air sucked by the suction force driven by the blower 17 into the hot air duct 20 to generate hot air.

The hot air is delivered to the interior of the drying chamber 5 formed inside the drum 1 through the air supply duct 12. The hot air in the drying chamber (5) absorbs the moisture contained in the laundry cloth, and then exits from the drying chamber (5) through the outlet assembly (13). At this time, the air is discharged from the drying chamber 5 through the outlet assembly 13 is made by the suction force of the blower (17). Air passing through the outlet assembly 13 is filtered through the lint filter 14 so that foreign matter such as dust or seams is filtered out.

Drying operation of the dryer proceeds from the heat energy generated in this way, and when the drying operation of the dryer is completed, when the drive of the heater is to be stopped, the current supplied to each of the coils 66, 69, and 78 is blocked, and the valve The operation of 25 is controlled to the closed state. In this case, the gas supplied to the mixing pipe 24 is blocked while the valve 25 is closed. And drying operation is completed normally.

Next, an operation process according to flame detection will be described with reference to FIG. 5.

When the drying operation is performed, a flame should be formed at the outlet side of the mixing tube 24 in the normal operation process. The flame at this time is maintained while burning the gas injected into the mixing tube 24.

That is, the valve 25 controlled in the open state by the coils 66, 69, and 78 in the driving state allows gas to be supplied from the gas pipe 23 to the gas nozzle 22. At this time, the gas supplied to the gas nozzle 22 is continuously injected into the mixing tube 24 to maintain a flame for providing thermal energy.

Thus, the flame formed on the outlet side of the mixing tube 24 is detected by the salt detection rod 50, the salt detection sensor 60 determines the presence of salt by the detected signal, the state in which the flame exists Will remain on. Therefore, the gas is injected into the mixing tube 24 while the current is continuously supplied to the coils 66, 69, and 58 through the salt detection sensor 60 in an on state. That is, in the state in which salt exists, the salt detection part 60 keeps on, and it does not affect the operation | movement which generate | occur | produces thermal energy.

Next, when the salt is not detected by the abnormal operation, it will be described the operation of FIG.

During the drying operation, the flame is extinguished on the outlet side of the mixing tube 24 due to external influence or internal influence. At this time, the salt detection rod 50 mounted to detect the flame formed on the outlet side of the mixing tube 24 does not detect the salt.

Therefore, the salt detecting unit 54 which has not received a signal from the salt detecting rod 50 outputs a signal indicating that the flame is extinguished to the controller 58, and the controller 58 recognizes that the salt is extinguished. By the salt detection support, the salt detection sensor 60 recognizes that the flame is extinguished, and switches to the off state.

At this time, in order to control the valve 25 in the open state, the current supplied to each coil (66, 69, 78) is forcibly cut off by the salt detection sensor 60 is turned off, the valve 25 Is closed. When the valve 25 is adjusted to the closed state, the gas supplied to the gas nozzle 22 through the gas pipe 23 is cut off. Therefore, the gas is no longer injected into the mixing tube 24.

In addition, even when a current is supplied to the coils 66, 69, and 78 by a separate control device, and a fire extinguishing operation is performed (a valve is controlled in a locked state, the gas supply is blocked). No more flame is generated at the outlet side of the mixing tube 24. Therefore, the salt detection sensor 60 is also switched to the off state without detecting the salt in the salt detection rod (50).

On the other hand, in the hot air duct 20, the latent heat remaining in the radiant sensor 72 is maintained in the off state for a predetermined time. Therefore, immediately after the fire is extinguished, even if power is supplied again to the combustion control apparatus of the present invention within a predetermined time range in which the radiant sensor 72 maintains the off state, the salt detection sensor 60 is switched to the off state. Current will not be supplied to the coil.

As described above, the present invention detects the presence of flame directly from the generated flame of the burner and controls the operation of the valve for gas supply. Therefore, the present invention controls the gas to be supplied to generate only the heat energy required during the drying operation so that it can be supplied only when there is a flame, thereby preventing unnecessary fuel supply and the risk of abnormal operation.

The present invention described above can obtain the following effects.

First, since it is possible to control the gas to be supplied only when there is a flame, it is possible to prevent the gas from being unnecessarily supplied in the absence of the flame.

Second, since the gas can be controlled to be supplied only when the flame is present, it is possible to prevent the uncombusted gas from remaining in the mixing tube 24 and the hot air duct 20. Therefore, when performing the redrying operation, it is possible to obtain an advantage of the risk of explosion due to the amount of gas remaining and the safety of the user.

Claims (3)

A dryer configured to supply heated air into a rotating drum to heat dry the laundry and to discharge air in the rotating drum to the outside: Salt detection means for detecting the presence of a flame formed for air heating; And a heated fuel driving means driven to supply the heated fuel under control of the salt detecting means, And when the salt is not detected in the salt detecting means while the drying operation is in progress, the supply control of the heating fuel driving means is forcibly cut off. The method of claim 1, The heating fuel driving means is configured by connecting two or more valves in series and configured to have a time difference in the operation time of each valve. The method of claim 1, An igniter connected in parallel with the heated fuel drive means, the igniter being operated faster than the heated fuel drive means during initial ignition to generate salt; The combustion control apparatus of the dryer, characterized in that for opening and closing the current path of the igniter through a sensor having an on state in the absence of heat.