KR100702992B1 - Control method for dryer - Google Patents

Abstract

The present invention relates to a control method of a dryer, and more particularly, to a control method of a dryer for controlling the drying operation to minimize the drying time when clogging the lint filter and to prevent damage to the cloth due to temperature rise. The present invention monitors the blower rotational speed that is variably controlled during the drying operation, and detects clogging of the lint filter and the exhaust pipe. When the blockage of the lint filter and the exhaust pipe is detected, the rotation RPM of the blower is increased to a higher value than the reference value to control the air flow in the drum to increase. In addition, by controlling the heating value of the heater variable so as not to reach the off temperature of the heater by preventing the increase of drying time.

Description

Control method for dryer             

1 is an exploded perspective view showing the main configuration of a dryer according to a general technique,

2 is a side cross-sectional view of the dryer according to the present invention;

3 is a plan view of the dryer according to the present invention;

4 is an operation flowchart for detecting a blockage of a lint filter in a dryer according to the present invention;

5 is a relationship characteristic diagram between the control RPM of the blower and the rising RPM according to the blockage of the lint filter;

6 is a relationship characteristic diagram of the degree of clogging of the exhaust pipe and the rotational RPM of the blower;

7 is a characteristic diagram of the degree of clogging and drying time of the exhaust pipe;

8 is a temperature characteristic diagram in a drum for explaining the present invention,

9 and 10 are control configuration diagrams of the heater,

11 is a control block diagram of a dryer according to the present invention.

Explanation of symbols on the main parts of the drawings

30: blower assembly 31: blower                 

32,48: Temperature sensor 34: Exhaust duct

36: lint filter 38: electrode sensor

42: heater 44: drum

50: inverter board 52: main board

54 drum belt 52a: control unit

52b: speed sensor 52c: heater driving unit

52d: blower drive unit

The present invention relates to a control method of a dryer, and more particularly, to a control method of a dryer for controlling the drying operation to minimize the drying time when clogging the lint filter and to prevent damage to the cloth due to temperature rise.

1 is an exploded perspective view showing a main configuration of a dryer according to the prior art. According to this, the drum 1 is installed inside a cabinet (not shown) constituting the exterior of the dryer. The drum 1 has a cylindrical groove formed at both ends thereof, and a belt groove 2 around which a belt (not shown) driven by a separate driving source is wound. 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 inside the drying chamber 5 when the drum 1 is rotated.

The front head 7 and the rear head 9 are installed to correspond to the front and rear ends of the drum 1, respectively. Here, the front head 7 and the rear head 9 form a drying chamber 5 by blocking the open portion of the drum 1 and serve to support the front and rear ends of the drum 1, respectively. In this case, a sealing member 10 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 for controlling the supply of gas. Reference numeral 23 is a gas pipe.

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. A spark plug 26 is installed at the tip of the mixing tube 24 to generate sparks 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 is ignited and burned by the spark plug 26.

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.

However, the prior art having the configuration as described above has the following problems.

Air absorbing moisture in the drying chamber 5 passes through the outlet assembly 13 in the drying chamber 5 through the lint duct 14 by driving the blower 17 and passes through the lint filter 14. Is passed to (15). In this process, foreign substances mixed with the air, that is, seams or dusts, are filtered by the lint filter 14. Therefore, when a large amount of foreign material is caught in the lint filter 14, the flow of air flowing from the drying chamber 5 to the lint duct 15 is not smooth.

However, in the related art, in order to check the degree of clogging of the lint filter 14, the user had to pull out the lint filter 14 directly from the lint duct 15 and check it. Therefore, in the related art, the degree of clogging of the lint filter 14 cannot be easily confirmed by the user, and the dryer may be operated while the lint filter 14 is almost blocked. As such, when the dryer is operated while the lint filter 14 is blocked, a problem occurs that the drying of the air through the drying chamber 5 is not performed smoothly.

In addition, when the lint filter 14 is blocked, the temperature inside the drum 1 rises rapidly without the smooth flow of air. Therefore, a problem occurs that the laundry being dried is damaged by the elevated temperature. And the normal drying operation is not made, the drying time is increased, thereby causing a problem of increased energy consumption.

As a result, the conventional dryer was not able to recognize whether the lint filter 14 was clogged by the controller itself during the drying operation, and thus did not have a control method for proper drying operation in the state where the lint filter was blocked.

Accordingly, an object of the present invention is to provide a control method of a dryer for proper drying operation control while preventing lint filter from clogging during drying operation and preventing fabric damage and increase of drying time.

The control method of the dryer according to the present invention for achieving the above object, in the dryer having a variable controlled blower for generating a flow of air circulating the drum, and a lint filter for collecting foreign substances generated during the drying operation Driving the variable controlled blower; Monitoring whether the rotation speed of the blower rises above a predetermined value from a reference set value; Detecting that a lint filter is clogged when the blower's rotational speed is increased; When the blockage of the lint filter is detected, adjusting the rotational speed of the blower relatively higher than a set value; And controlling the driving of the blower at the controlled rotational speed of the blower.

The present invention includes the steps of adjusting the on / off control temperature of the heater for supplying hot air to the drum relatively lower than the target value when detecting the clogging of the lint filter; And controlling the driving of the heater to the controlled temperature of the regulated heater.

In the present invention, the driving step of the heater is characterized in that the heating value of the heater is reduced so that the drying operation is performed at the controlled control temperature.

In addition, the present invention further comprises a control step for a drying operation, wherein each step of the paragraph is made during the drying operation.

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

2 and 3 is a block diagram of a dryer according to the present invention.

As shown, the outer case 53 forms the exterior of the dryer. And the front plate 41 is connected to the front end of the outer case 53 to form the front of the dryer. In the interior of the outer case 53, laundry is introduced into the drum 44, which is dried and rotatably installed. The drum 44 is rotated by a drum drive belt 54 surrounding its outer surface.

An exhaust port 43 is formed to correspond to an inner surface of the front plate 41 and to be opened toward the inside of the drum 44. The exhaust port 43 serves to exhaust the air in the drum 44 to the outside of the drum 44, and a lint filter 36 is installed at the inlet to remove foreign substances mixed in the air.

On one side of the exhaust port 43, an electrode sensor 38 for measuring the temperature inside the drum 44 during the drying operation is mounted. The electrode sensor 38 is a temperature sensor, and when the laundry is touched, the electrode sensor 38 senses the temperature by the difference in voltage applied to both ends of the electrode. The detected signal is output as a voltage signal.

An exhaust passage 45 is formed inside the front plate 3 to be connected to the exhaust port 43. And blower assembly 30 is installed in communication with the exhaust passage (45). The exhaust passage 45 is equipped with a temperature sensor 32 for sensing the temperature of the exhaust air.

The blower assembly 30 is connected to an exhaust duct 34 for discharging air from the exhaust passage 45 to the outside of the dryer. The blower assembly 30 is a blower for circulating and inhaling air in the drum 44 to introduce the heat of the heater 42, which will be described later, into the drum 44 and to discharge the moisture of the clothes to the exhaust port 43 ( 31) is included. The blower 31 uses a variable speed.

Meanwhile, a supply duct 46 for supplying air into the drum 44 is installed at a portion of the inside of the outer case 53 corresponding to the lower portion of the drum 44. The supply duct 46 supplies air to the inside of the drum 44 through the rear of the drum 44. The heater 42 is provided on one side of such a supply duct 46. One side of the supply duct 46 is provided with a temperature sensor 48 for sensing the temperature of the air supplied into the drum 44.

And the present invention is installed on the inner side of the outer case 53, the main board 52 for the overall control of the dryer, the inverter board 50 for the inverter control of the drive source (not shown) for generating the rotational force of the drum (inverter PCB) is installed.                     

The main board 52 includes a driving unit for driving the respective components to be electrically controlled in the dryer. That is, as shown in Fig. 11, the control unit 52a for overall control of the dryer, the heater driving unit 52c for driving the heater 42 under the control of the control unit 52a, and the control unit 52a. And a blower driving portion 52d for driving the blower 31 under the control of the control unit. The controller 52a outputs a driving signal for rotating the drum to the inverter board 50 to control the drum to be driven.

In addition, in the present invention, the main board 52 includes a configuration for detecting the blockage of the lint filter 36 due to the rotational speed of the blower 31. Accordingly, the control unit 52a in the main board 52 blows the blower 31 from a speed sensor (for example, a photo encoder) 52b which is mounted on the motor shaft of the blower 31 for sensing the rotation speed. ) Can be applied to the speed signal.

That is, the main board 52 receives the rotation speed from the photo encoder for detecting the rotation speed of the blower 31 to recognize the rotation speed of the blower 31. When the recognized rotational speed of the blower 31 is increased by a predetermined value from the reference value, it is determined that the rotation RPM of the blower 31 is increased by clogging the lint filter 36.

The rotational speed of the blower 31 is increased by the clogging of the lint filter 36 because the flow of air circulated in and out of the drum is formed by the blower 31. Therefore, when the lint filter 36 is blocked, the air volume of the air circulating in the drum 44 is reduced while the pressure applied to the rotary blade of the blower 31 is reduced. For this reason, as the load on the blower 31 motor becomes small, the RPM of the motor is automatically raised. Therefore, when the blower 31 which is variably controlled exceeds a predetermined value than the rotation RPM which is set, it may be determined to be due to the blockage of the lint filter 36.

From this configuration, the main board 52 of the present invention monitors the rotation RPM of the blower 31, and detects the blockage of the lint filter 36 when it rises by a predetermined amount from the set reference value. In addition, the control unit 52a in the main board 52 of the present invention performs control to prevent an increase in drying time and damage to the cloth when detecting the blockage of the lint filter 36 during the drying operation. .

Next will be described the operation process for drying in the dryer of the present invention having the above configuration.

4 is an operation process diagram for controlling a drying operation when the lint filter is blocked in the dryer according to the present invention.

First, laundry for drying is put into the drum 44. When the user inputs a drying operation signal, the signal is input to the controller 52a in the main board 52. The controller 52a outputs a driving signal to the inverter board 50, and then the drum belt 54 is rotated while the driving source is driven by the control of the inverter board 500 so that the drum 44 rotates ( Step 100).

The control part 52a outputs a drive signal to the blower drive part 52d. Therefore, when the blower assembly 30 is operated and the blower 31 is driven, air in the drum 44 is discharged to the exhaust duct 34 through the lint filter 36 (step 110).

In addition, before and after the air is discharged in the drum 44, the controller 52a outputs a driving signal to the heater driver 52c. In this way, the heater driving unit 52c operates the heater 42.

Therefore, when the air inside the drum 44 is discharged in step 110, the outside air is sucked into the drum 44 through the supply duct 46, which is located at the inlet of the supply duct 46. The air is heated by the heat generated by the heater 42 to reach a predetermined temperature and is supplied into the drum 44. As such, the air sucked by the suction force driven by the blower 31 is heated by the heater 42 to be supplied into the drum 44.

The air supplied into the drum 44 absorbs moisture in the laundry and flows to the exhaust passage 45 through the exhaust port 43 by driving the blower assembly 30. The exhaust passage 45 is discharged to the outside through the blower assembly 30 through the exhaust duct 34. At this time, the air is discharged from the drum 44 through the exhaust port 43 is made by the suction force of the blower (31).

At this time, the air passing through the exhaust port 43 is purified by the lint filter 36 so that foreign substances (for example, seams or lint of laundry) mixed in the air are not transmitted to the blower assembly 30. It plays a role.

On the other hand, the control unit 52a in the main board 52 presets the detection value of the electrode sensor 38 according to the type and degree of drying of the building. Therefore, when the drying operation is started, the detection value according to the type of dry matter is recognized based on the preset value. Then, the operation of the heater 42 is controlled to generate heat. After the heater 42 generates heat, external inflow air sucked into the drum 44 through the supply duct 46 is generated by the heat generated by the heater 42 at the inlet of the supply duct 46. Is heated to a predetermined temperature and is supplied into the drum 44.

In this operation, the electrode sensor 38 detects the temperature of the dry matter in the air circulating inside the drum 44, and transmits the detected signal to the controller as a voltage signal. At this time, the electrode sensor 38, when the building is touched by the sensor, senses the temperature by using the difference in the voltage value applied to both ends of the electrode. The sensed temperature is then output as a voltage signal.

The detection value of the electrode sensor 38 is continuously input to the control unit 52a, and the control unit 52a determines the current drying degree by the change of the voltage value detected by the electrode sensor 38.

Air absorbing moisture in the drum 44 in this process passes through the exhaust port 43 from the drum 44 by the blower 31 and passes through the lint filter 36 to the lint duct. Delivered. In this process, foreign matter mixed with the air, that is, seams or dust, is filtered by the lint filter 36. Therefore, when a lot of foreign material is caught in the lint filter 36, the flow of air flowing into the lint duct in the drum 44 is not smooth.

At this time, the blower 31 for generating a suction force so that the air is circulated in and out of the drum 44 is to smoothly control the air flow by increasing the rotation speed because the air flow is not smooth.

That is, when the lint filter 36 is blocked, the amount of air flowing into the blower 31 decreases, and the pressure applied to the blades of the blower 31 decreases, thereby lowering the load on the motor. In this way, while the load on the blower 31 motor is lowered, the rotation RPM of the motor is automatically raised.

On the other hand, the speed sensor 52b mounted on one side of the blower 31 motor continuously applies the rotational speed of the blower 31 to the controller 52a. The controller 52a recognizes the rotational speed of the blower 31 by the signal applied in this way.

At this time, the RPM of the blower 31 is increased as shown in FIG. 5 according to the degree of clogging of the lint filter 36. That is, in the normal driving state, the rotational speed of the blower 31 is controlled by being set to 1300 RPM. When the lint filter 36 rises above a predetermined range (about 230 RPM) due to the blockage of the lint filter 36, it is determined that the blockage of the lint filter is blocked. will be. In addition, when the rotational speed of the blower 31 rises to about 300 RPM or more in a state where 1700 RPM is a reference, it is determined that the lint filter is clogged.

Therefore, the controller 52a in the main board 52 monitors the detection value of the speed sensor 52b, and if the rotational speed of the blower 31 is automatically increased to a predetermined range or more than the reference value (step 120). In operation 130, it is determined that the lint filter is clogged.

In addition, although not shown in the drawings, it will be briefly described that the rotation RPM of the blower 31 used for detecting clogging of the lint filter can also be used to detect clogging of the exhaust pipe inside the dryer.

As shown in FIG. 1, a blower 17 is installed to be connected to the lint duct 15, and sucks air inside the drum 1 through the lint duct 15. One side of the blower housing 18 in which the blower 17 is installed is in communication with the lint duct 15, but the other side is connected to the exhaust pipe 19. 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.

Therefore, even when the exhaust pipe 19 is blocked by foreign matter, the rotation RPM of the blower 17 is increased. This is because the air passing through the blower 17 does not escape to the outside even if the exhaust pipe 19 is blocked by foreign matters, and the circulation of the air inside and outside the drum 1 is not smoothly performed.

6 shows the degree of clogging of the exhaust pipe 19 in units of inches. The exhaust pipe 19 is unable to effectively discharge as the length of the extension pipe is increased. In the drawing, 2.5 inches means a case in which the length of the extension tube is extended to 20m, 3.5 indicates a case in which the length of the extension tube is extended to 10m. Therefore, it can be seen that the rotation RPM of the blower also increases as the length of the extension tube increases.

Accordingly, the rotational RPM of the blower 17 is also increased according to the degree of clogging of the exhaust pipe 19, and thus the rotational RPM of the blower 17 is used as basic information for determining the clogging force of the exhaust pipe 19. It is possible.

7 shows a relationship with the roughness time according to the degree of clogging of the exhaust pipe. That is, as shown in the drawing, the drying time is relatively longer than in the normal state depending on the degree of clogging of the exhaust pipe 19. This causes a waste of energy.

The rotation RPM of the blower 17 that is variably controlled in this way can detect the blockage of the lint filter 36 and the blockage of the exhaust pipe 19.

As such, when the lint filter 36 or the exhaust pipe 19 is clogged by foreign matter, the temperature inside the drum 44 is raised above the control temperature range. That is, as shown in FIG. 8, when the temperature inside the drum 44 is compared with the state in which the drying operation is normally performed and the drying operation is performed due to the abnormal operation by clogging of the lint filter, the abnormal operation is performed. The internal drum temperature is relatively higher than during normal operation.

If the drying operation is performed in this state with the normal heater control temperature range and the rotation RPM of the blower, it is damaged by the high temperature of the laundry being dried. In addition, the drying time is increased without the normal discharge of moisture.

Therefore, in the present invention, when the clogging of the lint filter 36 or the clogging of the exhaust pipe 19 is detected by the rotation RPM of the blower 31, the control condition of the drying operation is variably adjusted.                     

Step 140 is a process of controlling the rotation RPM of the blower 31 relatively higher than in the normal drying operation. That is, the control part 52a raises the rotation RPM of the blower 31 higher than a reference value through the blower drive part 52d. In this way, the blower 31 rotates faster than the reference speed, and as a result, the amount of air flow increases so that the moisture discharge in the drum 44 proceeds faster. Therefore, the drying time can be prevented from increasing.

In addition, the controller 52a in the main board 52 adjusts the control temperature by turning on / off the heater 42 (step 150).

The heater 42 is a source of heat energy for supplying hot air into the drum 44. Therefore, the controller 52a recognizes the temperature of the air supplied into the drum 44 by the detected value of the temperature sensor 48, and measures the temperature of the air exhausted through the drum 44. Recognized by the detected value of 32, the on / off operation of the heater 42 is controlled so that the temperature required by the drum 44 can be maintained.

For example, in the case of normal dry operation, in the case of cotton products, the temperature sensor 48 for detecting the temperature of the intake air reaches 120 ± 20 ° C or the temperature sensor for sensing the temperature of the exhaust air ( When the detection temperature of 32) reaches 70 ± 3 ° C., it is recognized as an off condition of the heater 42.

However, when the on / off of the heater 42 is controlled under the condition of the normal drying operation in the state where the lint filter or the exhaust pipe is blocked, the temperature inside the drum 44 is as shown in FIG. 8. Likewise, it is higher than normal. At this time, since the damage to the laundry during the drying operation may be caused by the elevated temperature, step 150 is to control the on / off temperature of the heater 42 to be low. The control of the 150th step is performed through the heater driver 52c under the control of the controller 52a.

In this case, the controller 52a in the main board 52 may control the amount of heat generated by the heater 42 through the heater driver 52c. That is, when the heating temperature of the heater 42 reaches the control temperature for turning off the heater, the heater repeats the on / off operation and increases the drying time. Therefore, in order to prevent this, when the heating operation condition of the heater 42 is approached, it is possible to reduce the amount of heat generated by the heater and ultimately not to reach the off temperature of the heater.

As shown in Fig. 9, the heat generation amount of the heater can be controlled by turning off any one of the heaters when the heaters H1 and H2 in the dryer are configured in parallel. In addition, as shown in FIG. 10, when one heater H3 controls the amount of heat generated by the control of the triac T1, the control signal of the triac T1 through the photocoupler PC1 is controlled. It is also possible to control the amount of heat generated by the heater H3 by adjusting.

As described above, the present invention monitors the rotation speed of the blower which is variably controlled during the drying operation, and detects clogging of the lint filter and the exhaust pipe. When the blockage of the lint filter and the exhaust pipe is detected, the rotation RPM of the blower is increased to a higher value than the reference value to control the air flow in the drum to increase. In addition, it is a basic technical idea to variably control the amount of heat generated by the heater so as not to reach the off temperature of the heater, thereby preventing an increase in drying time.

And within the scope of the technical idea of the present invention, various modifications will be possible to those skilled in the art.

As described above, the present invention detects the blockage of the lint filter or the blockage of the exhaust pipe according to the increase of the blower rotation speed during the drying process. And even in a blocked state to increase the air flow rate or to control the heating value of the heater to perform the optimal drying to proceed.

Therefore, the present invention can prevent an increase in the drying time due to poor air discharge due to clogging of the lint filter and the exhaust pipe as in the prior art. And it is possible to prevent the waste of energy due to the increase in the drying time, it is possible to prevent the damage of the dry matter caused by the increased drum temperature.

Claims (4)

In a dryer having a variable controlled blower for generating a flow of air circulating in a drum and a lint filter for collecting foreign substances generated during the drying operation: Driving the variable controlled blower; Monitoring whether the rotation speed of the blower rises above a predetermined value from a reference set value; Detecting that a lint filter is clogged when the blower's rotational speed is increased; When the blockage of the lint filter is detected, adjusting the rotational speed of the blower relatively higher than a set value; And controlling the driving of the blower at the regulated rotational speed of the blower. The method of claim 1, When the blockage of the lint filter is detected, adjusting the on / off control temperature of the heater for supplying hot air to the drum to be lower than a target value; And controlling the driving of the heater at the control temperature of the regulated heater. The method of claim 1, The driving step of the heater, the control method of the dryer, characterized in that for reducing the heat generation of the heater so that the drying operation proceeds at the controlled control temperature. The method according to any one of claims 1 to 3, Further comprising a control step for the drying operation, Wherein each step of the paragraph is made during the drying operation.

Images