KR102298261B1 - Condenser control method of dryer - Google Patents

Abstract

The present invention relates to a method for controlling a condenser of a dryer, and specifically, to a method for controlling the operation of a condenser for condensing gas generated in a drying process of food waste. The present invention implements a new condenser operation method that can properly control the concentration and amount of wastewater discharged from the condenser in a manner of controlling the cooling water circulation amount and cooling water temperature of the condenser for the treatment of condensed gas discharged from the drying process of food waste, thereby providing a method for controlling a condenser of a dryer, which can improve overall water treatment efficiency and secure economic feasibility through process management in conjunction with the wastewater treatment process that is a subsequent process.

Description

Condenser control method of dryer

The present invention relates to a method for controlling a condenser of a dryer, and more particularly, to a method for controlling an operation of a condenser for condensing and treating gas generated during a food waste drying process.

Recently, modern society, which is made up of mass production and mass consumption, is causing serious environmental pollution problems due to mass waste. There is this.

In relation to these soil and water pollution issues, the agricultural sector is not only free from a free position, but as the efficiency of production is prioritized and intensive agriculture has been promoted, the problem of soil and water pollution has been caused by excessive dumping of pesticides and chemical fertilizers and improper management of livestock manure. because it was caused by

In addition, in the case of incineration or drying of waste in relation to waste treatment, in the case of applying direct flame or steam to waste, it is completely Combustion or complete drying is practically impossible, and there is a problem in that a large amount of odor, soot, dust, air polluting exhaust gas, etc. are generated due to incomplete combustion or drying.

Therefore, in recent years, a drying method for drying organic waste such as food waste and using it as a renewable energy resource has been attracting attention. can get

As a facility for drying organic wastes, there are direct and indirect drying dryers using hot air and steam, and electromagnetic wave drying dryers using microwaves.

However, in order to remove the moisture evaporated during the drying process, there must be an air flow, which inevitably generates a high-strength condensed gas containing a large amount of moisture and oil, that is, a high-strength odor gas, during drying. There is a problem that causes contamination.

Considering this, as a method to remove odor components emitted to the outside during the drying process, separate odor removal facilities such as wet scrubbing towers, activated carbon adsorption towers, and biofilter facilities are installed, and the odor gas discharged from the dryer is collected. There is a method of removing odor components and then releasing them into the atmosphere.

As an example, there is a method of installing a condenser on a line through which the condensed gas generated in the drying process of food waste is discharged, and using such a condenser to remove a high concentration of oil contained in the condensed gas.

Usually, the gas discharged from the drying process of food waste is sent to the condenser for condensing treatment, and the gas generated after the condensing treatment is incinerated in a deodorizing furnace, which is a post-process, and wastewater is purified at a wastewater treatment plant, a post-process.

However, due to the high concentration and excessive amount of condensed wastewater discharged from the condenser, there is a problem in water treatment such as an overload factor of the wastewater treatment process, which is a post-treatment process.

Laid-Open Patent Publication No. 10-2006-0064141 Laid-open Patent Publication No. 10-2002-0014975 Laid-Open Patent Publication No. 10-2003-0068273 Registered Patent Publication No. 10-1692830

Accordingly, the present invention has been devised in view of the foregoing, and the concentration of wastewater discharged from the condenser and the amount of wastewater discharged from the condenser are appropriately controlled in a manner that controls the cooling water circulation amount and cooling water temperature of the condenser for the treatment of condensed gas discharged during the drying process of food waste. The purpose of this is to provide a condenser control method of a dryer that can improve overall water treatment efficiency and secure economic feasibility through process management in conjunction with the wastewater treatment process, which is a subsequent process, by implementing a new condenser operation method that can be adjusted.

In order to achieve the above object, the condenser control method of the dryer provided in the present invention has the following characteristics.

The condenser control method of the dryer includes a cooling water tank for supplying cooling water, a cooling water supply line, a pump installed on the cooling water supply line, and a jacket having a cooling water inlet and a cooling water outlet, and condensing the condensed gas supplied from the dryer side. a condenser, a plurality of cooling towers for cooling the cooling water flowing out of the condenser and then sending it to the cooling water tank side through a cooling water replenishment line, and a temperature sensor installed on the cooling water supply line to sense the temperature of cooling water supplied to the condenser; and a controller for controlling the operation of the cooling tower and the operation of the pump.

The condenser control method of such a dryer turns on the operation of the cooling tower through the control of the controller when the coolant temperature detected by the temperature sensor is out of the preset upper limit value, or the coolant temperature detected by the temperature sensor is the preset lower limit of the temperature. It is characterized in that the concentration and discharge of condensed wastewater discharged from the condenser can be adjusted by turning off the cooling tower through the control of the controller.

As another example, the method for controlling the condenser of the dryer further includes a flow meter installed on the cooling water supply line to detect the flow rate of the cooling water supplied to the condenser, while the cooling water flow rate detected by the flow meter is outside the preset upper limit of the flow rate (condenser When the cooling tower operation is turned off through the control of the controller, or the cooling water flow rate detected by the flowmeter is out of the preset lower limit of the flow rate (cooling water temperature rises due to a decrease in the condenser coolant flow rate), the controller controls By turning on the cooling tower through the ON operation, it is possible to control the concentration and discharge amount of the condensed wastewater discharged from the condenser.

As another example, the method for controlling the condenser of the dryer further includes a flow meter installed on the cooling water supply line to detect a flow rate of cooling water supplied to the condenser, and the pump applies a variable capacity pump, while the cooling water flow rate detected by the flow meter If the flow rate exceeds this preset upper limit value (coolant temperature drop), the discharge capacity of the pump is reduced through the control of the controller, or if the coolant flow rate detected by the flow meter is out of the preset flow rate lower limit value (coolant temperature rise), control the controller. By increasing the discharge capacity of the pump through the

Here, in the method for controlling the condenser of the dryer, it is preferable to control at least one of the plurality of cooling towers to be operated in an always-on state regardless of ON or OFF control of the cooling tower by a controller.

As a preferred embodiment, in the condenser control method of the dryer, when controlling the concentration and discharge amount of condensed wastewater discharged from the condenser, the load factor of the combustion furnace facility for the exhaust gas incineration treatment, which is a subsequent process (the amount of exhaust gas flowing into the combustion furnace facility) increase/decrease) and the load factor of the wastewater treatment facility for condensed wastewater purification treatment (increase/decrease in the amount of condensed wastewater flowing into the wastewater treatment facility), the concentration and discharge of condensed wastewater can be controlled.

The condenser control method of the dryer provided in the present invention has the following effects.

First, by controlling the circulating amount and/or cooling water temperature of the cooling water provided to the condenser for the treatment of condensed gas discharged from the food waste drying process to appropriately adjust the wastewater concentration and the amount of wastewater discharged from the condenser, the wastewater treatment process and the subsequent process It has the effect of improving the overall water treatment efficiency through the linked process management of

Second, considering the correlation between the wastewater treatment facility for the purification treatment of condensed wastewater discharged from the condenser and the combustion furnace facility for incineration treatment of the exhaust gas discharged from the condenser, the degree of load on the wastewater treatment facility side and the combustion furnace facility side By appropriately distributing the amount of condensed wastewater discharged from the condenser and the amount of exhaust gas in consideration of the degree of load of the

1 is a schematic diagram showing a method for controlling a condenser of a dryer according to an embodiment of the present invention;
2 is a schematic diagram showing the flow of cooling water in a method for controlling a condenser of a dryer according to an embodiment of the present invention;

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram showing a method for controlling a condenser of a dryer according to an embodiment of the present invention, and FIG. 2 is a schematic diagram showing a flow of cooling water in a method for controlling a condenser of a dryer according to an embodiment of the present invention.

1 and 2, the condenser control method of the dryer is a control method based on the condenser facility of the dryer, and the condenser facility of the dryer includes a cooling water tank 10, a pump 12, a condenser 16, a cooling tower 18 , a temperature sensor 19 , a flow meter 21 , a controller 20 , and the like.

The cooling water tank 10 is a tank that stores water to supply cooling water circulating inside the jacket 15 of the condenser 16 , and includes not only the cooling water recovered from the cooling tower 18 , but also reused water and municipal water. can also be saved.

This cooling water tank 10 is connected to the cooling water inlet 13 of the jacket 15 in the condenser 16 through the cooling water supply line 11 to supply cooling water, and with this, the cooling tower 18 extending from the It is possible to recover the cooling water through the cooling water replenishment line 17 .

The pump 12 is a means for discharging water from the cooling water tank 10 to the jacket 15 side of the condenser 16 , and the pump 12 is installed on the cooling water supply line 11 .

In particular, the pump 12 can be applied to a variable capacity pump that discharges only the flow rate required by the place of use, for example, the condenser 16 by changing the discharge capacity, and this pump 12 is connected to the controller 20 . It can be operated under the output control by the

The condenser 16 removes a high concentration of oil contained in the condensed gas generated during the drying process of food waste, thereby reducing the release of odor components into the atmosphere, and condensed water from which the odor components have been removed. It is a means to create

This condenser 16 cools the condensed gas with the jacket 15 through which the cooling water flows and removes the oil contained in the high-concentration condensed gas, thereby converting the condensed gas into the low-condensed gas from which the oil is completely removed. do.

To this end, the condenser 16 includes a jacket 15 having a cooling water inlet 13 and a cooling water outlet 14 and enclosing the outer wall of the condenser body, as well as an inner space of the condensed gas formed at the upper end and lower end. It is composed of an exhaust space and a condensed gas inlet space.

At this time, the cooling water inlet 13 is connected to a cooling water supply line 11 extending from the cooling water tank 10 , and a cooling water discharge line 22 extending to the cooling tower 18 is connected to the cooling water outlet 14 .

Accordingly, in the state in which the condensed gas discharged from the dryer side enters the condenser 16, the cooling water entering the cooling water inlet 13 below the jacket 15 passes through the inside of the jacket and then the cooling water outlet 14 at the upper side. As the cooling water flowing while staying inside the jacket 15 has a heat exchange action with the condensed gas flowing inside the condenser 16, the oil in the condensed gas undergoes a phase transition. It can be removed by development or separation by boiling or the like.

The cooling tower 18 serves to cool the cooling water that has exited the condenser 16 and then sends it to the cooling water tank 10 side. is connected with

Here, a plurality of cooling towers 18 may be operated, and at least one cooling tower 18 among the plurality of cooling towers 18 is always operated regardless of ON or OFF control of the cooling tower 18 by the controller 20 . By being controlled to operate in the ON state, the temperature of the cooling water can always be maintained at a certain level.

For example, even in a state in which one cooling tower 18 among the two cooling towers 18 is controlled to be turned OFF by the controller 20, the remaining one cooling tower 18 continues to operate ON, It is possible to maintain the temperature of the cooling water supplied to the condenser 16 at a predetermined constant level.

The temperature sensor 19 is installed on the cooling water supply line 11 to sense the temperature of the cooling water supplied to the condenser 16 . The cooling water temperature value detected by the temperature sensor 19 is the controller 20 side. provided in the controller 20 to be used to control the temperature of the cooling water supplied to the condenser (16).

The flow meter 21 is installed on the cooling water supply line 11 to sense the flow rate of cooling water supplied to the condenser 16 , and the coolant flow rate value detected by the flow meter 21 is provided to the controller 20 side. Thus, the controller 20 can be used to control the flow rate of the cooling water supplied to the condenser 16 .

The controller 20 is a means for controlling the temperature and/or the flow rate of the coolant circulating in the jacket 15 of the condenser 16 , and a signal provided from the temperature sensor 18 and/or the flow meter 21 . By inputting (cooling water temperature/cooling water flow rate) as an input to output control the cooling tower 18 and/or the pump 12, it is possible to appropriately control the cooling water temperature and flow rate supplied to the condenser 16 side, and eventually this control Through this, it is possible to adjust the concentration and discharge amount (relatively the amount of exhaust gas) of the condensed wastewater generated in the condenser 16 to an appropriate level.

Accordingly, a method of controlling the operation of the condenser based on the condenser facility of the dryer configured as described above will be described as follows.

First, looking at the method of controlling the condenser based on the cooling water temperature, when the cooling water temperature detected by the temperature sensor 19 is out of the preset upper limit value, the operation of the cooling tower 18 is turned on through the control of the controller 20 or, when the cooling water temperature sensed by the temperature sensor 19 is out of the preset lower limit value, the cooling tower 18 is turned OFF under the control of the controller 20 .

That is, when the coolant temperature sensed by the temperature sensor 19 rises above a preset upper limit value, for example, 70 to 80° C., preferably 75 to 77° C., the cooling tower 18 is controlled by the controller 20 ) is turned on, the cooling water temperature is lowered below the preset upper limit value, and consequently, the concentration of the condensed wastewater discharged from the condenser 16 can be increased, and in addition, the discharge of the condensed wastewater can be increased. .

Here, when the temperature of the cooling water rises above the preset upper temperature limit of 70 to 80° C., the concentration (pollution degree) of the condensed waste water at this time is about 5,500 to 13,000 mg/ℓ, and the discharge of the condensed waste water is about 2.0 to 2.5 ㎥/m , and these condensed wastewater concentration and discharge values are at a relatively low level compared to the median value, for example, the preset daily (or monthly, annual, etc.) average treatment concentration and throughput. It is necessary to increase and increase the discharge of condensed wastewater.

In addition, when the temperature of the cooling water sensed by the temperature sensor 19 falls below a preset lower limit value, for example, 40 to 50° C., preferably 42 to 45° C., the cooling tower 18 is controlled by the controller 20 . ), the temperature of the cooling water is raised above the preset lower limit of the temperature, and consequently, the concentration of the condensed wastewater discharged from the condenser 16 can be lowered, and in addition, the discharge of the condensed wastewater can be reduced.

Here, when the temperature of the cooling water falls below the preset temperature lower limit of 40 to 50° C., the concentration (pollution degree) of the condensed waste water at this time is about 23,000 to 33,000 mg/ℓ, and the discharge of the condensed waste water is 2.5 to 2.8 ㎥/m Since these condensed wastewater concentration and discharge figures are relatively high compared to the preset daily (or monthly, yearly, etc.) average treatment concentration and throughput, in this case, increase the temperature of the cooling water to lower the concentration of condensed wastewater and reduce the amount of condensed wastewater. need to reduce

In this case, the preset upper limit of the coolant temperature and the lower limit of the coolant temperature mean a temperature value obtained through repeated calibration calculated by linking the concentration and discharge amount of condensed wastewater according to various coolant temperatures in relation to the operation of the condenser.

On the other hand, looking at the method of controlling the condenser based on the cooling water flow rate, when the cooling water flow rate detected by the flow meter 21 is out of the preset upper limit of the flow rate, the operation of the cooling tower 18 is turned off through the control of the controller 20. Alternatively, when the coolant flow rate detected by the flow meter 21 is out of the preset lower limit of the flow rate, the cooling tower 18 is turned ON through the control of the controller 20 .

That is, when the coolant flow rate (circulation water amount) sensed by the flow meter 21 exceeds a preset upper limit of flow rate, for example, 140 to 160 m3/m, preferably 145 to 150 m3/m, the controller 20 By turning off the operation of the cooling tower 18 through the control, the cooling water temperature is raised above the preset upper temperature limit, and eventually the concentration of the condensed wastewater discharged from the condenser 16 can be lowered, and with this, the discharge of the condensed wastewater can be reduced. be able to reduce

Here, when the flow rate of the cooling water exceeds the preset upper limit of the flow rate of 140 to 160 m3/m, the concentration (pollution degree) of the condensed wastewater at this time is about 23,000 to 33,000 mg/ℓ, and the discharge of the condensed wastewater is 2.5 to 2.8m3/m m, and these condensed wastewater concentration and discharge figures are relatively high compared to the preset daily (or monthly, annual, etc.) average treatment concentration and throughput. need to reduce

In addition, when the cooling water flow rate (circulating water amount) sensed by the flow meter 21 falls below a preset flow rate lower limit, for example, 50 to 80 m 3 /m, preferably 60 to 70 m 3 /m, the controller 20 By turning on the operation of the cooling tower 18 through the control of emissions can be increased.

Here, when the flow rate of cooling water falls below the preset flow rate lower limit of 50 to 80 m3/m, the concentration (pollution degree) of the condensed wastewater at this time is about 5,500 to 13,000 mg/ℓ, and the discharge of the condensed wastewater is 2.0 to 2.5m3 /m, and these condensed wastewater concentrations and discharge figures are relatively low compared to the preset daily (or monthly, yearly, etc.) average treatment concentration and throughput. emissions need to be increased.

In this case, the preset upper limit value of the coolant flow rate and the lower limit value of the coolant flow rate refer to the flow rate values obtained through repeated calibration calculated by linking the condensed waste water concentration and discharge amount according to various coolant temperatures in relation to the operation of the condenser.

In addition, looking at another example of a method of controlling the condenser based on the coolant flow rate, when the coolant flow rate sensed by the flow meter 21 is out of the preset upper limit of the flow rate, the pump 12 is discharged through the control of the controller 20 . When the capacity is reduced or the coolant flow rate sensed by the flow meter 21 is out of the preset lower limit of the flow rate, the discharge capacity of the pump 12 is increased through the control of the controller 20 .

That is, when the coolant flow rate (circulation water amount) sensed by the flow meter 21 exceeds a preset upper limit of flow rate, for example, 140 to 160 m3/m, preferably 145 to 150 m3/m, the controller 20 Through the control, the discharge capacity of the pump 12 is relatively reduced, and consequently, the concentration of the condensed wastewater discharged from the condenser 16 can be lowered, and in addition, the discharge of the condensed wastewater can be reduced.

Here, when the flow rate of the cooling water exceeds the preset upper limit of the flow rate of 140 to 160 m3/m, the concentration (pollution degree) of the condensed wastewater at this time is about 23,000 to 33,000 mg/ℓ, and the discharge of the condensed wastewater is 2.5 to 2.8m3/m m, and these condensed wastewater concentration and discharge figures are relatively high compared to the preset daily (or monthly, annual, etc.) average treatment concentration and throughput. need to reduce

In addition, when the coolant flow rate (circulation water amount) sensed by the flow meter 21 falls below a preset flow rate lower limit, for example, 50 to 80 m 3 /m, preferably 60 to 70 m 3 /m, the controller 20 The discharge capacity of the pump 12 is relatively increased by controlling the

Here, when the flow rate of cooling water falls below the preset flow rate lower limit of 50 to 80 m3/m, the concentration (pollution degree) of the condensed wastewater at this time is about 5,500 to 13,000 mg/ℓ, and the discharge of the condensed wastewater is 2.0 to 2.5m3 /m, and these condensed wastewater concentration and discharge figures are relatively low compared to the preset daily (or monthly, yearly, etc.) average treatment concentration and throughput. Emissions need to be increased.

In particular, in the present invention, when controlling the concentration of condensed wastewater discharged from the condenser 16 and the discharge of condensed wastewater, the load factor of the combustion furnace facility for the exhaust gas incineration treatment, which is a subsequent process, and the load factor of the wastewater treatment facility for the condensed wastewater purification treatment It provides a method of controlling the concentration of condensed wastewater and the discharge of condensed wastewater in conjunction with the .

To this end, the discharge amount of the condensed wastewater discharged from the condenser 16 according to the load factor of the wastewater treatment facility that purifies the condensed wastewater discharged from the condenser 16 (eg, increase/decrease in the amount of condensed wastewater flowing into the wastewater treatment facility). can be adjusted, and in connection with this, the exhaust gas discharged from the condenser 16 is discharged from the condenser 16 according to the load factor (eg, increase or decrease of the inflow amount of the exhaust gas flowing into the combustion furnace facility) of the combustion furnace facility for incineration treatment. It is possible to control the amount of exhaust gas produced.

For example, when the load factor of the wastewater treatment facility is high (eg, the amount of condensed wastewater flowing into the wastewater treatment facility is large) and the load factor of the combustion furnace facility is low, in this case, the temperature of the cooling water circulating in the condenser 16 and cooling water flow rate control to reduce the concentration of condensed wastewater discharged from the condenser 16 and control to reduce the amount of condensed wastewater, thereby reducing the amount of condensed wastewater sent to the wastewater treatment facility and reducing the amount of exhaust gas sent to the combustion furnace. It is desirable to increase the amount.

Conversely, when the load factor of the wastewater treatment facility is low (eg, the amount of condensed wastewater flowing into the wastewater treatment facility is small) and the load factor of the combustion furnace facility is high, in this case, the temperature of the cooling water circulating in the condenser 16 and the cooling water By controlling the concentration of condensed wastewater discharged from the condenser 16 and increasing the amount of condensed wastewater through the flow control of It is desirable to reduce

In this way, by linking the condensed wastewater concentration and condensed wastewater discharge control on the condenser side and the load ratio of the combustion furnace facility and the load ratio of the wastewater treatment facility, which are the subsequent processes, efficient operation of the entire treatment system related to incineration and purification as well as condenser operation is possible. There are possible advantages.

As described above, in the present invention, when treating the condensed gas discharged from the drying process of food waste, a new condenser control method capable of appropriately adjusting the concentration and amount of wastewater discharged from the condenser in a manner that controls the cooling water circulation amount and the cooling water temperature of the condenser. By providing this, it is possible to reduce the discharge concentration and amount of condensed wastewater in consideration of the load level of the wastewater treatment plant, and the condensed wastewater discharge concentration and It is possible to improve the overall water treatment efficiency and secure economic feasibility, such as being able to properly control the amount of generation and the amount of exhaust gas.

10: coolant tank
11: coolant supply line
12 : pump
13: coolant inlet
14: coolant outlet
15 : jacket
16: condenser
17: coolant replenishment line
18: cooling tower
19: temperature sensor
20: controller
21: flow meter
22: coolant discharge line

Claims (5)

A high concentration of oil contained in the cooling water tank 10 for supplying cooling water, the cooling water supply line 11, and the pump 12 installed on the cooling water supply line 11, and the condensed gas generated during the drying process of food waste. As a means to reduce the emission of odor components into the atmosphere by removing A jacket (15) having a cooling water inlet (13) and a cooling water outlet (14) and having a structure surrounding the outer wall of the condenser body (15) serves to convert the condensed gas of low concentration from which the oil is completely removed by removing the oil, etc. ), of course, the inner space is composed of a condensed gas discharge space and a condensed gas inlet space formed at the upper end and lower end, and the cooling water inlet 13 is connected to the cooling water supply line 11 extending from the cooling water tank 10 at the same time As the cooling water discharge line 22 extending to the cooling tower 18 is connected to the cooling water outlet 14, the cooling water entering the cooling water inlet 13 below the jacket 15 in a state where the condensed gas discharged from the dryer is in the jacket After passing through the inside, it can exit through the upper cooling water outlet 14, and the cooling water flowing while staying inside the jacket 15 performs heat exchange with the condensed gas flowing inside the condenser 16, so that The condenser 16 so that oil can be removed by phase transition or separation by boiling point, and the cooling water that has exited the condenser 16 are cooled, and then the cooling water replenishment line 17 is passed through the cooling water tank ( 10) a plurality of cooling towers 18 for sending to the side, a temperature sensor 19 installed on the cooling water supply line 11 to detect the temperature of the cooling water supplied to the condenser 16, and the operation of the cooling tower 18 and a controller 20 for controlling the operation of the pump 12;
When the coolant temperature detected by the temperature sensor 19 is out of the preset upper limit of the temperature, the cooling tower 18 is turned on through the control of the controller 20, or the coolant temperature detected by the temperature sensor 19 When out of the set temperature lower limit value, by turning off the operation of the cooling tower 18 through the control of the controller 20, so that the concentration and discharge amount of condensed wastewater discharged from the condenser 16 can be adjusted,
When the temperature of the cooling water detected by the temperature sensor 19 rises above the preset upper temperature limit of 70 to 80° C., the controller 20 turns on the operation of the cooling tower 18 to set the cooling water temperature to the preset upper limit value. As it is dropped downward, it is possible to increase the concentration of the condensed wastewater discharged from the condenser 16 and at the same time increase the discharge of the condensed wastewater, and the cooling water temperature detected by the temperature sensor 19 is the preset lower limit of the temperature. When phosphorus falls below 40 to 50°C, the operation of the cooling tower 18 is turned off through the control of the controller 20 to raise the cooling water temperature above the preset lower temperature limit, so that the concentration of condensed wastewater discharged from the condenser 16 of the dryer, characterized in that it can reduce the discharge of condensed wastewater while at the same time improving overall water treatment efficiency and securing economic feasibility through process management in connection with the wastewater treatment process, which is a subsequent process. Condenser control method.
The method according to claim 1,
Further comprising a flow meter 21 installed on the cooling water supply line 11 to detect a flow rate of cooling water supplied to the condenser 16, wherein the flow rate of cooling water detected by the flow meter 21 is out of a preset upper limit of flow rate Turning off the operation of the cooling tower 18 through the control of the controller 20, or when the cooling water flow rate detected by the flow meter 21 is out of the preset flow rate lower limit value, the cooling tower 18 through the control of the controller 20 Condenser control method of a dryer, characterized in that it is possible to control the concentration and discharge amount of the condensed wastewater discharged from the condenser (16) by turning on the operation.
The method according to claim 1,
The pump 12 further includes a flow meter 21 installed on the cooling water supply line 11 to sense the flow rate of the cooling water supplied to the condenser 16 , and the pump 12 applies a variable capacity pump, and the flow meter 21 . When the coolant flow rate sensed by the . In this case, by increasing the discharge capacity of the pump (12) through the control of the controller (20), the condenser control method of the dryer, characterized in that it is possible to adjust the concentration and discharge amount of the condensed wastewater discharged from the condenser (16).
delete 4. The method according to any one of claims 1 to 3,
The control for controlling the concentration and discharge amount of the condensed wastewater discharged from the condenser 16 is performed in conjunction with the load rate of the combustion furnace facility for the exhaust gas incineration treatment and the load rate of the wastewater treatment facility for the condensed wastewater purification treatment, which is a subsequent process. A method for controlling a condenser of a dryer, characterized in that.

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