KR20100125732A - The method for waste heat recovery of dryer and there of apparatus - Google Patents

Abstract

PURPOSE: A method and an apparatus for recovering waste heat of a drier are provided to completely remove sludge from heat transfer plates of a heat exchanger using a rotating brush installed between the heat transfer plates. CONSTITUTION: A method for recovering waste heat of a drier is as follows. Hot wind created by a boiler is provided to a clothes drying chamfer(1) and exhausted through vent after drying clothing. The exhausted waste heat and gas are transferred by a polluted gas blower(2) and supplied to a waste heat recovery apparatus by a pressure control valve in order to recover heat. The heat-exchanged gas is discharged to a dust collector. A sludge removal device is operated when sludge caused by waste heat and contaminated gas is generated in the heat transfer plate of a heat exchanger(3). Water is sprayed by a pump through a nozzle onto the heat transfer plate. The sludge is eliminated with a brush which is transferred along a rail by a motor. The nozzle and the brush are restored.

Description

The method for waste heat recovery of dryer and there of apparatus}

The present invention relates to a waste heat recovery method and apparatus for recovering and recycling waste heat of exhaust gas discharged from a dryer in a drying step of processing a fiber fabric.

In general, a drying process is required when processing a fiber fabric. In the drying process, a processing material, ie, a fabric, which is input by high temperature hot air in a dryer having a plurality of drying chambers, may be used as the plurality of drying chambers. After passing through it, the workpiece is discharged through the following process.

At this time, the high temperature hot air used in the drying process is forced to be discharged to the outside of the dryer by the exhaust fan connected to the drying chamber in a state contaminated with the gas generated while drying the fabric, while continuously supplying fresh air to the dryer It is supposed to be.

In the conventional drying system as described above, the drying of the fabric in the chamber and the heat discharged together with the high-temperature exhaust gas are discharged together, while cold air is introduced again into the dryer to lower the temperature at the inlet of the dryer for a long drying time. The problem is that the waste heat contained in the exhaust gas is not immediately recovered but is immediately discharged and thus unnecessary fuel is wasted, causing the user to increase the cost of the workpiece.

In order to solve the above problems, the applicant has devised a pre-registered "10-0653197 waste heat recovery device".

The drying system equipped with the waste heat recovery device is preheated by supplying cold air into the housing in which the heat exchanger is installed to absorb the heat retained by the exhaust gas and preheat it to a high temperature. This provides high thermal efficiency and condensation due to the temperature difference between the cold air and the exhaust gas so as to prevent the pipe of the heat exchanger from being blocked by solids or oils contained in the exhaust gas without the need for a separate cleaning device. A waste heat recovery system has been developed that can naturally drain solids or fats and oils by water droplets.

However, the waste heat recovery device is difficult and difficult to clean the sludge generated by the waste heat and polluted gas after the heat exchange as the waste heat is discharged.

That is, in the above invention, the condensed water generated by the heat exchange is easy to treat the condensed water because the pipe of the heat exchanger is inclined, but the treatment of the sludge is difficult and difficult.

In addition, the above invention has a problem in that it takes a long time and wastes unnecessary manpower, since a person has to clean the hand manually after stopping the dryer itself in order to process the sludge.

On the other hand, while conventionally removed by spraying water on the contaminated portion of the waste heat recovery apparatus, there is a disadvantage in that the abnormal pressure is generated when washing the contaminated portion is not smooth discharge of contaminated gas inside the dryer.

As such, when an abnormal pressure is generated in the heat exchanger, the exhaust gas is not discharged, causing polluting gas inside the dryer, causing defective products, and inadvertently causing a fire.

The present invention has been made to solve the above problems, and an object thereof is to enable easy and simple removal of sludge generated in the heat transfer plate of the waste heat recovery apparatus.

Another additional object of the present invention is to prevent dust from occurring during sludge removal in heat transfer plates through which waste gas passes.

As a means for solving the above problems, it is possible to solve by providing a brush to each heat transfer plate provided in the heat exchanger to move the brush from side to side.

As a means to solve the above additional object can be eliminated by removing the sludge by the brush and water by spraying the water with the brush when cleaning the heat transfer plate.

As described above, the present invention has a simple structure, which is easy to manufacture, and by installing a rotary brush between each heat exchanger plate and the heat transfer plate installed in the heat exchanger, the sludge can be completely removed by removing the sludge while the brush moves left and right.

In addition, the present invention can remove the sludge at the same time as the rotary brush to remove the sludge on the heat transfer plate to prevent the generation of dust by the brush works with the water to remove the gutter on the heat transfer plate completely.

And the present invention is a useful invention that can work faster and reduce the waste of manpower by operating the nozzle and the nozzle is sprayed with water from side to side.

Waste heat discharging step of supplying hot air heated by a boiler to each clothes drying chamber to dry the clothes and then discharge them through the respective outlets:

Waste heat transfer step of transferring the discharged waste heat and gas by the polluting gas blower:

Heat exchange step in which the conveyed gas is supplied to the waste heat recovery apparatus by the pressure control valve to recover the waste heat:

Discharge stage where the heat exchanged gas is discharged to the dust collector.

 If the sludge is generated in the heat exchanger plate due to waste heat and polluted gas, the operation step of operating the sludge removal device:

A water spray step of spraying water onto the heat transfer plate through a nozzle by a pump,

Washing and sludge removing step of removing sludge as the brush is transported on the rail by the motor as in the water spraying step,

The nozzle and the brush is made up of the original return step to return to the original.

In the above, the heated air that is heat-exchanged by waste heat is injected to the inlet through which the product is put in and the outlet discharged after drying, respectively, by spraying hot air to prevent cold air from entering the inside of the chamber. It is also preferable to install.

 Referring to the heat exchanger of the present invention as described above is as follows.

Chamber (1), which is supplied with hot air heated by a boiler to dry clothes and then discharges through respective outlets:

Polluted gas blower (2) for transferring the waste heat and gas discharged from the chamber (1),

The pressure sensor 7 and the pressure controller 8 and the pressure control valve 9 which transfer the gas transferred by the polluting gas blower 2 to the heat exchanger 3 and transfer the gas to the dust collector as it is when abnormal pressure occurs. ),

A heat exchanger (3) provided with an automatic sludge removing device () for heat-exchanging the gas transferred by the pressure control valve (4) and automatically removing sludge generated in the heating plate (5) with water and a brush;

It characterized in that it comprises a heating air blower (6) for supplying the hot air heat exchanged in the heat exchanger (3) back to the chamber (1).

The heat exchanger (3) can be opened and closed by installing a door (12) formed with a supply hole (11) for supplying waste heat and gas to the upper side of the pedestal body 10, one side of the lower end of the pedestal body (10) Form a discharge hole 13 for discharging waste heat and gas,

A plurality of heat transfer plates 4 are vertically installed and fixedly installed on the upper side of the pedestal body 10 at regular intervals to form a waste heat transfer passage 14 through which waste heat and exhaust gas pass from the top to the bottom between the heat transfer plates 4 and the heat transfer plates. ,

Each heat transfer plate 4 forms a through hole therein, and forms a cold air transfer passage 15 so that cold air flows through the through hole from one side to the other side to exchange heat, and the upper side of the heat transfer plate 4. There is formed a nozzle 16 and a sludge removal apparatus 17 through which water is injected.

The sludge removal apparatus 17 of the heat exchanger 3 is

Install a motor 20 provided with a reducer on the upper front surface of the heat exchanger 3 having the residual heat plate 4 installed thereon, and rotating shafts 22 (both sides of the motor shaft 21 and before and after the rear and lower ends of the heat exchanger 3, respectively) 22 ') and 22 "are fixedly installed but rails 29 are installed on both sides in the longitudinal direction of the heat transfer plate, and sprockets 23 and 23 on both sides of each of the rotary shafts 22, 22' and 22". ') Is installed to be interlocked by the chain 24, but the roller 24 is installed on the chain 24 so that the roller 30 moves on the rail 29, and the motor shaft 21 and the lower end thereof. The rotating shaft 22 of the conveying portion 26 to be interlocked by the belt 25,

The transfer bars 27 and 27 'are fixed to the chains 24 installed on the upper and lower portions of the transfer unit 26, and the nozzle 16 to which water is injected is installed on the upper transfer bar 27, and the heat transfer plate is installed. The brush 28 is inserted into each waste heat transfer path 14 between the heat transfer plate and the heat transfer plate, respectively, and the upper and lower portions are fixed to the transfer bars 27 and 27 ', respectively, to remove sludge while moving back and forth. .

As an embodiment of the transfer unit of the present invention,

A plurality of transfer bars 27 and 27 'of two sets are horizontally fixed to the chain 24 provided at the upper and lower portions of the transfer unit 26, and water is provided to each upper transfer bar 27. The nozzles 16, 16 'and 16 "are sprayed and inserted into the waste heat transfer passages 14 between the heat transfer plate 4 and the heat transfer plate, respectively, and the upper and lower portions are respectively transferred to the transfer bars 27 and 27. It is also possible to provide a plurality of brushes 28, 28 ', 28 " which are fixed to') and remove sludge while moving back and forth.

Referring to the driving of the present invention as described above is as follows.

1 is a block diagram showing the process of the present invention, Figure 2 is a block diagram showing the entire drying line of the present invention, Figure 3 is a schematic front view showing the heat exchanger of the present invention, Figure 4 is a schematic plan view of the heat exchanger of the present invention. 5 is a schematic side view showing a heat exchanger of the present invention, FIG. 6 is an enlarged cross-sectional view of a main portion showing the transfer portion of the present invention, FIG. 7 is an enlarged cross-sectional view of a main portion showing a lower portion of the transfer portion of the present invention, and FIG. 8 is a main portion of the transfer portion of the present invention. 9 is an enlarged cross-sectional view, and FIG. 9 is a side cross-sectional view showing another embodiment of the present invention.

As shown in FIG. 2, when the hot air heated by the boiler is supplied to each chamber, and the product is input at the product inlet of the chamber 1 and discharged to the discharge port, the product is supplied to each chamber 1 while passing through each chamber. By drying.

After drying the fabric put into the chamber 1, the waste heat and the gas generated while drying the fabric are discharged through an outlet, and the waste heat and gas are supplied to the heat exchanger 3 by the polluting gas blower 2.

Waste heat and gas supplied to the heat exchanger (3) is transferred to the lower end through a supply hole (11) installed on the upper side of the 0010 heat exchanger as shown in Figure 7 waste heat transfer passage 14 formed between the heat transfer plate (4) and the heat transfer plate. Pass through the discharge through the discharge hole 13 installed in the heat exchanger to the dust collector.

In the above state, the heat transfer plate 4 is heated by the waste heat while passing through the waste heat transfer passage 14 formed between the heat transfer plate 4 and the heat transfer plate, and at the same time, the cold air transfer passage 15 formed in each heat transfer plate 4. Heated cold air passing through) is heated.

Thus, the waste heat passing through the heat exchanger (3) is supplied to the chamber (1) by the heating air blower (6) again, supplied to the boiler and reheated and then supplied to the chamber, and products installed before and after the chamber. Waste heat is injected into the inlet and the outlet in an air curtain manner to prevent cold air from entering the chamber (1).

In the above state, when the heat exchanger 1 does not operate normally because sludge is generated in the heat transfer plate 4 due to the polluted gas and the pollutant gas and waste heat do not pass, the pressure sensor 7 detects this and the controller ( 8) the pressure control valve (9) is operated to send waste heat and gas to the dust collector as it is.

On the other hand, when sludge occurs in the heat transfer plate 4, the motor 20 for forward / reverse rotation in which the speed reducer is installed rotates and thus the sprockets 23 and 23 'installed in the motor shaft 21 rotate. The chain 24 and the belt 25 are operated.

When the chain is operated as described above, the rotary shaft 22 installed at the lower end of the pedestal body 10 and the rotary shafts 22 'and 22 " do.

When the chain 24 is operated as described above, the roller 30 installed on the chain 24 moves on the rail 29, and at the same time, the transfer bars 27 and 27 ′ installed on the chain 24 move together. The brush 28 fixed between the upper and lower transfer bars 27 and 27 'moves together to wash the sludge generated on the surface of the heat transfer plate 4.

Meanwhile, while the chain 24 rotates by the motor 20, water is sprayed from the nozzle 16 installed on the upper transfer bar 27 to wash the heat transfer plate 4 while the brush cleans the surface of the heat transfer plate 4. Since it is broken, sludge generated on the surface of the heat transfer plate 4 can be completely removed.

As such, the sludge generated on the surface of the heat transfer plate 4 by the water and the brush 28 is removed, and then the motor 16 rotates in reverse to spray the water, and the transfer bar 27 provided with the brush 28. (27 ') will return to its original state.

On the other hand, as shown in Fig. 9, a plurality of sets of two transfer bars are horizontally installed in the chain 24, and nozzles 16, 16 ', 16 "and brushes 28 and 28' are installed on each transfer bar. (28 ") is installed to minimize the distance the brush is moved to reduce the overload of the motor, and the brush movement distance is small, it is possible to prevent the wear of the brush to maximize the life.

1 is a block diagram illustrating a process of the present invention.

Figure 2 is a block diagram showing the entire drying line of the present invention

Figure 3 is a schematic front view showing a heat exchanger of the present invention

4 is a schematic plan view showing the present invention heat exchanger

5 is a schematic side view showing the present invention heat exchanger

Figure 6 is an enlarged cross-sectional view of the main portion showing the present invention the conveying unit

Figure 7 is an enlarged cross-sectional view of the main portion showing the lower end of the present invention transfer portion

8 is an enlarged cross-sectional view of the main portion of the transfer portion of the present invention.

Figure 9 is a side cross-sectional view showing another embodiment of the present invention transfer unit

          ** Description of symbols for the main parts of the drawing **

1. Chamber 2. Pollution gas blower

3. heat exchanger 4. heating plate

6. Heating air blower 7. Pressure sensor

8. Pressure controller 9. Pressure control valve

10. Base body 11. Supply hole

12. Door 13. Outlet

14. Waste heat transfer passage 15. Cold air transfer passage

16.16'.16 ". Nozzle 17. Sludge Removal Device

20. Motor 21. Motor shaft

22. 22 '. 22 ". Rotary Shaft 23. 23 '. Sprocket

24. Chain 25. Belt

26. Transport 27. 27 '. Transfer bar

28. 28'.28 "Brush 29. Rail

30. Roller

Claims (6)

Waste heat discharging step of supplying hot air heated by a boiler to each clothes drying chamfer, drying the clothes and then discharging them through respective outlets: Waste heat transfer step of transferring the discharged waste heat and gas by the polluting gas blower: Heat exchange step in which the conveyed gas is supplied to the waste heat recovery apparatus by the pressure control valve to recover the waste heat: Discharge stage where the heat exchanged gas is discharged to the dust collector.  If the sludge is generated in the heat exchanger plate due to waste heat and polluted gas, the operation step of operating the sludge removal device: A water spray step of spraying water onto the heat transfer plate through a nozzle by a pump, Washing and sludge removing step of removing sludge as the brush is transported on the rail by the motor as in the water spraying step, Waste heat recovery method of the dryer, characterized in that the nozzle and the brush made of a return to the original phase. The method of claim 1, Hot air is blown out through the nozzle to the inlet through which the product is heat exchanged by the heat exchanger and the outlet discharged after drying, respectively, to install an air curtain to prevent cold air from flowing into the chamber. Waste heat recovery method of the dryer. Chamber (1), which receives hot air heated by a boiler, dries clothes, and discharges them through respective outlets: Polluted gas blower (2) for transferring the waste heat and gas discharged from the chamber (1), The pressure sensor 7 and the pressure controller 8 and the pressure control valve 9 which transfer the gas transferred by the polluting gas blower 2 to the heat exchanger 3 and transfer the gas to the dust collector as it is when abnormal pressure occurs. ), A heat exchanger (3) provided with an automatic sludge removal device (17) for heat-exchanging the gas transferred by the pressure control valve (4) and automatically removing sludge generated in the heating plate (5) with water and a brush; And a heating air blower (6) for supplying the hot air heat exchanged in the heat exchanger (3) back to the chamber (1). The method of claim 3, wherein The heat exchanger (3) can be opened and closed by installing a door (12) formed with a supply hole (11) for supplying waste heat and gas to the upper side of the pedestal body 10, one side of the lower end of the pedestal body (10) Form a discharge hole 13 for discharging waste heat and gas, The heat transfer plate 14 is installed on the upper side of the pedestal main body 10 at regular intervals and is vertically installed to form a waste heat transfer passage 14 through which waste heat and exhaust gas pass from the upper side to the lower side between the heat transfer plate 4 and the heat transfer plate. , Each heat transfer plate 4 forms a through hole therein to form a cold air transfer passage 15 for heat exchange as cold air passes through the through hole from one side to the other side, and the upper side of the heat transfer plate 4. The waste heat recovery device of the dryer, characterized in that the nozzle 16 and the sludge removal device 17 is sprayed water is formed. The method of claim 4, wherein The sludge removal apparatus 17 of the heat exchanger 3 is A motor 20 having a speed reducer is installed on the upper front surface of the heat exchanger 3 having the heat transfer plate 4 installed thereon, and the rotary shafts 22 and 22 are respectively located at both sides of the motor shaft 21 and before and after the rear and lower ends of the heat exchanger 3. ') (22 ") is fixedly installed, but rails 29 are installed on both sides in the longitudinal direction of the heat transfer plate, and sprockets 23, 23' are provided on both sides of each of the rotary shafts 22, 22 ', and 22". ) To be interlocked by the chain 24, the roller 24 is installed on the chain 24 so that the roller 30 is moved on the rail 29, the motor shaft 21 and its lower end The rotating shaft 22 is a conveying part 26 which is interlocked by the belt 25, The transfer bars 27 and 27 'are fixed to the chains 24 installed on the upper and lower portions of the transfer unit 26, and the nozzle 16 to which water is injected is installed on the upper transfer bar 27, and the heat transfer plate is installed. It is inserted into each waste heat transfer passage 14 between the heat transfer plate (4) and the upper and lower portions are respectively fixed to the transfer bar (27, 27 ') includes a brush 28 for removing sludge while moving back and forth Waste heat recovery apparatus of the dryer. The method of claim 5, A plurality of transfer bars 27 and 27 'of two sets are horizontally fixed to the chain 24 provided at the upper and lower portions of the transfer unit 26, and water is provided to each upper transfer bar 27. The nozzles 16, 16 'and 16 "are sprayed and inserted into the waste heat transfer passages 14 between the heat transfer plate 4 and the heat transfer plate, respectively, and the upper and lower portions are respectively transferred to the transfer bars 27 and 27. And a plurality of brushes (28) (28 ') (28 ") which are fixed to') and remove sludge while moving back and forth.

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