KR100954481B1 - Drying machine - Google Patents

Abstract

An object of the present invention is to detect the humidity contained in the recovered air in the air-circulating drying furnace to automatically adjust the intake amount of the outside air and the exhaust air of the circulating air according to the detected humidity value to improve the drying efficiency to improve the drying efficiency It is to provide a humidity circulation control thermocirculation drying apparatus that can shorten the drying time of the.

The humidity interlocking control thermocirculation drying apparatus of the present invention includes a combustion chamber 20 for generating hot air using a heat source including a burner, a drying chamber 10 into which the hot air of the combustion chamber is introduced, and the drying chamber. A drying apparatus including a heat recovery pipe (60) having a circulation fan (50) for exhausting the residual residual hot air used and circulating the residual heat wind in the drying chamber exhausted by the circulation fan toward the combustion chamber. The inlet port 63 and the exhaust port 64 are provided adjacent to the pipe 60, and the inlet port and the exhaust port are recovered by adjusting the opening angle of the single circulation / exhaust control valve 90 according to the operation of the valve actuator 80. The displacement of the air and the inflow of external air are interlocked and proportionally controlled, and the valve actuator is output by the controller 100 according to the detected humidity value of the humidity sensor 70 installed in the heat recovery pipe 60.It characterized in that the air to be configured.

Humidity Linkage Control, Return Line, Single Circulation / Exhaust Control Valve, Proportional Control, Humidity Sensor

Description

Humidity Interlocking Control Thermocirculation Drying Equipment {Drying machine}

The present invention relates to a drying apparatus that can dry clothes, agricultural and aquatic products using a burner, and more particularly, detects the humidity of the return air circulating air in an air circulation drying furnace and detects the intake air volume and the circulating air according to the detected humidity value. The present invention relates to a thermo-circulation drying apparatus for controlling humidity linkage, which can shorten the drying time of a drying object by improving energy saving and drying efficiency by automatically proportionally controlling the amount of gas discharged.

In general, a hot air drying apparatus using a burner is mainly used to dry clothes or agricultural products quickly, and the structure of the hot air drying apparatus provides a drying tank into which a drying object is charged or placed, and a hot air supplying hot air in the drying tank. A burner that generates heat by burning fuel such as means and gas, and a blower motor for blowing heat generated from the burner to a drying tank.

In particular, the drying apparatus can be designed in a circulating structure that communicates with the intake passage through the recovery pipe of the exhaust air of the drying chamber for drying efficiency and energy saving. In the intake and exhaust circulation passage for the drying apparatus, some suction of external air and internal drying air A separate open intake and exhaust passage is provided for the partial exhaust of.

1 is a configuration diagram of a conventional exhaust heat exchange drying apparatus, which includes a combustion chamber 20 generating hot air using the burner 30 as a heat source, and a drying chamber 10 into which the hot air of the combustion chamber is introduced. ), And a heat exchanger 12 and a heat recovery tube 60 for collecting waste heat from the dry residual hot air used in the drying chamber and circulating and supplying the waste heat to the combustion chamber.

Here, the burner 30 burns fuel supplied through the fuel supply pipe 31 to generate heat, and the heat generated from the burner 30 passes through the air inlet 21 at the upper portion of the combustion chamber 20. The hot air is carried by the blowing air force and is introduced into the drying chamber 10.

The hot air introduced into the drying chamber is dried by removing moisture contained in various drying objects put into the drying chamber, and the residual hot air used for drying is recovered by a heat exchanger 12 such as a heat pipe or a radiator to recover heat. Supplied into the drying chamber 20 through 60;

Waste air in the drying chamber passing through the heat exchanger 12 is discharged to the outside through the discharge port (13).

In addition to the circulating heat recovered through the heat recovery pipe 60, the air is introduced into the drying chamber 20 through the intake port 62, thereby improving the energy utilization efficiency of the drying apparatus.

However, the waste heat recovery circulator of the conventional drying apparatus as described above always maintains a constant fixed ratio of residual hot air exhaust and constant fixed ratio throughout the operation period of the drying apparatus without considering the moisture content or drying conditions of the drying object put into the drying chamber. Unexpectedly, since the mixing is performed, there is a disadvantage in that the drying efficiency of the object to be dried cannot be increased.

In particular, in order to maximize the drying efficiency of the drying object loaded into the drying chamber, it is necessary to change the hot air temperature and the hot air amount according to the drying process of the drying object and to control the intake and exhaust amount on the hot air recovery path. Since there was no means for monitoring the status of each drying situation, there is no choice but to maintain the drying conditions uniformly from the start of drying to the end of drying.

This makes it impossible to guarantee the safety maintenance and optimization related to the drying of the drying object charged into the drying chamber.

The present invention is to solve the problems of the prior art as described above is an operation of the drying apparatus to significantly improve the drying efficiency of the drying apparatus using a variety of heat sources including a burner and to ensure the safety of the drying object The present invention provides a humidity interlocking control thermocirculation drying apparatus capable of optimally controlling the intake and exhaust volume of a recovery path by monitoring the drying state of a drying object.

Humidity interlocking control thermocyclic drying apparatus of the present invention for achieving the above object is a combustion chamber for generating hot air using a heat source including a burner, a drying chamber into which the hot air of the combustion chamber is introduced, and in the drying chamber A drying apparatus having a circulating fan for exhausting the residual residual hot air used and comprising a recovery pipe circulating the residual hot air in the drying chamber exhausted by the circulation fan to the combustion chamber side, wherein an intake port and an exhaust port are provided on the recovery pipe. Are installed adjacent to each other, but the inlet and the exhaust ports are installed so that the exhaust amount of the recovered air and the inflow rate of the external air are proportionally controlled by mutually interlocking by adjusting the opening angle of a single circulation / exhaust control valve according to the operation of the valve actuator. Is configured to be controlled by the output of the control unit according to the detected humidity value of the humidity sensor installed in the recovery pipe. It is characterized by.

In the humidity interlocking control thermocirculating drying apparatus of the present invention, the drying condition of a drying object is monitored during operation of a drying apparatus using various heat sources including a burner, and the monitoring information is prepared on a circulating air recovery pipe of the drying apparatus by comparing the monitoring information with a reference set value. By optimizing the intake and exhaust volume, the energy saving and drying time of the drying object can be shortened and the damage of the drying object can be avoided.

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

2 is a block diagram of a humidity interlocking control thermocirculation drying apparatus of the present invention.

Here, the combustion chamber 20 is a device for generating hot air using the burner 30 having the fuel supply pipe 31 as a heat source, and is generated in the burner 30 by a blowing force supplied through the upper air inlet 21. The heat is discharged to the drying chamber.

The heat source of the combustion chamber 20 may be replaced with one of several types of heat exchangers in addition to the burner 30 driven by the combustion motor 40.

The drying chamber 10 is configured to input hot air generated in the combustion chamber 20 to dry the drying object loaded in the drying chamber 10. The drying chamber 10 is equipped with a temperature sensor 11 therein, the temperature value detected by the temperature sensor is processed in the control unit, the combustion motor 40 and the fuel supply pipe in accordance with the difference between the set temperature value It is configured to adjust the hot air temperature and the intensity of the combustion chamber 20 by adjusting the valve opening angle on 31.

In particular, the drying chamber 10 may be a rotary drum method for rapid and efficient drying of the drying object.

The exhaust residual hot air used in the drying chamber is installed to be circulated and supplied to the combustion chamber 20 through the heat recovery pipe 60 and the circulation fan 50, and an inlet for inflow of external air on the heat recovery pipe 60. 63) and an exhaust port 64 for exhausting the residual residual wind.

The inlet port 63 and the exhaust port 64 are adjusted in accordance with the operation of one valve actuator 80 so that the exhaust (discharge) amount of the recovered (circulated) air and the inflow of the external air interlock with each other in proportion to each other. It is installed in the form of a single circulation / exhaust control valve (90).

The valve actuator 80 is configured to be controlled by the output of the controller 100 according to the detected humidity value of the humidity sensor 70 installed in the heat recovery tube 60, as referred to in FIG. 6.

3 is an explanatory view of the inflow state of the exhaust air and the outside air according to the opening conditions of the circulation / exhaust control valve of the humidity interlocking control thermocirculating drying apparatus according to the present invention.

As referred to herein, when the circulation / exhaust control valve 90 is in the horizontal condition (a) (full closed condition) as shown in the drawing, the inlet port 63 and the exhaust port 64 are completely closed (closed). Since the heat recovery pipe 60 is fully open, the remaining hot air discharged from the drying chamber 10 is circulated and supplied to the air inlet 21 of the upper portion of the combustion chamber 20 through the circulation fan 50. The closing (closing) of the circulation / exhaust control valve 90 is to extract moisture from the drying object in a short time by rapidly heating a drying object having a large amount of water in the initial state input to the drying chamber 10.

If the moisture in the drying chamber is saturated by heating and drying in a state where the circulation system is closed in the early stage of drying, further drying progress efficiency decreases. In this case, the saturation discharged from the drying chamber is opened by opening the circulation / exhaust control valve 90. The humidity air is discharged to the outside through the exhaust port 64 and at the same time, the fresh air from the outside is introduced into the combustion chamber through the inlet port 63.

That is, when the circulation / exhaust control valve 90 is in the vertical condition (b) (full open condition) as shown in the figure, the inlet port 63 and the exhaust port 64 are completely open, respectively, and the heat recovery pipe 60 is Since the circulation loop is completely blocked around the intake and exhaust ports, the remaining hot air discharged from the drying chamber 10 is exhausted to the outside through the exhaust port 64, and is external to the air inlet 21 above the combustion chamber 20. The new air of is supplied through the inlet (63).

Therefore, the opening / closing condition of the circulation / exhaust control valve 90 is determined by the moisture extraction amount of the dry object detected through the humidity sensor 70 which may be installed in a heat recovery tube or a drying chamber.

When the circulation / exhaust control valve 90 is inclined angle opening condition (c) as shown in the drawing, the inlet port 63 and the exhaust port 64 are partially open, respectively, and the heat recovery pipe 60 also centers on the intake and exhaust port. As part of the open condition, the residual hot wind discharged from the drying chamber 10 is partially exhausted to the outside through the circulation fan 50, and a part of external new air is provided at the air inlet 21 at the upper portion of the combustion chamber 20. Will be supplied.

That is, in the case of the opening angle of the inclination angle of the circulation / exhaust control valve 90, a part of the residual residual wind of the drying chamber 10 is exhausted to the outside through the exhaust port 64, and the other part is supplied to the outside through the suction port 63. It is mixed with the fresh air of the is injected into the air inlet 21 provided in the upper portion of the combustion chamber (20). This condition is mainly applied at the end of drying of the object to be dried.

In this case, the inclination angle opening conditions (a) and (b) of the circulation / exhaust control valve 90 correspond to a 2-way control condition using a solenoid, and the inclination angle opening conditions (a) to (c). The case includes all of them corresponds to a multi-stage control condition using a geared motor.

Figure 4 is a first embodiment of the actuator for the circulation / exhaust control valve of the humidity interlocking control thermocirculation drying apparatus according to the present invention and its operation explanatory drawing.

In the first embodiment of the actuator for the circulation / exhaust control valve 90 according to the present invention, the heat recovery pipe 60 and the intake and exhaust ports 63 and 64 are expressed in the form of a square tube for convenience. It is pointed out that the concept of technical thought can be applied as it is.

Here, the solenoid 80-1 is shown as a valve actuator for operating the circulation / exhaust control valve 90. That is, the solenoid 80 in a state in which the distal end portion of the piston rod 81 of the solenoid 80-1 is rotatably linked with the distal end of the lever 82 fixed to the central axis of the circulation / exhaust control valve 90. When the -1) is operated through the control unit 100, the opening angle of the circulation / exhaust control valve 90 is changed according to the operating position thereof, so that the heat recovery pipe 60 and the intake and exhaust ports 63 and 64 are It has been shown that the residual hot wind circulation control in the drying apparatus can be achieved by adjusting the opening angle.

Figure 5 is a second embodiment of the actuator for the circulation / exhaust control valve of the humidity interlocking control thermocirculating drying apparatus according to the present invention and its operation explanatory drawing

Here, the heat recovery pipe 60 is operated by the operation of the geared motor 80-2 according to the control unit 100 by coupling the central shaft of the circulation / exhaust control valve 90 and the rotation shaft 83 of the geared motor 80-2. It has been shown that the residual hot wind circulation control in the drying apparatus can be achieved by adjusting the opening angles of the intake and exhaust ports 63 and 64.

6 is a control circuit block diagram of the humidity interlocking control thermocirculating drying apparatus of the present invention, wherein the control unit 100 includes a detection temperature value of the drying chamber 10 by the temperature sensor 11 and a recovery path by the humidity sensor 70. The humidity detection value on the 60 is connected to be input, and the control unit 100 is connected to the input value of the control value setting input unit 101 for setting and registering the reference temperature value and the reference humidity value.

The output of the control unit 100 is configured to control not only the control of the circulation / exhaust control valve 90 through the valve actuator 80 but also the circulation fan 50 and the combustion motor 40 to be controlled.

The operation of the apparatus of the present invention configured as described above will be described with reference to the flowchart of FIG. 7.

First, a drying object is introduced into the drying chamber 10 and the burner 30 in the combustion chamber 20 is operated to inject hot air generated in the combustion chamber 20 into the drying chamber 10 and the drying chamber 10. The dry residual hot air discharged through the circulating / exhaust control valve 90 of the closed condition (see FIG. 3 (a)) installed on the heat recovery pipe 60 is configured to dry the drying object under the closed circuit circulation condition. do.

At this time, since the drying object introduced into the drying chamber 10 contains a large amount of water in the initial stage, the humidity in the drying chamber is easily saturated with an increase in the ambient temperature of the drying chamber 10 due to the hot air discharged from the combustion chamber 20. This leads to.

The humidity saturation information in the drying chamber 10 is detected through the heat recovery tube 60 or the humidity sensor 70 which can be mounted in the drying chamber 10 and is applied to the controller 100.

The control unit 100 changes the state of the circulation / exhaust control valve 90 by sending a control signal to the valve actuator 80 when the saturation humidity information in the heat recovery tube or the drying chamber is input by the humidity sensor 70 and then opened (FIG. 3 (b)). The opening and closing control of the valve actuator 80 may be achieved through the solenoid control shown in FIG. 4 or the geared motor control shown in FIG. 5.

Opening (opening) of the circulation / exhaust control valve 90 by the valve actuator 80 is performed at the same time as the inflow of the outside air and the discharge of the residual residual air in the state in which the circulation path of the drying device is blocked, so that the humidity in the drying chamber is increased quickly. Will be lowered. In this case, only new external air is supplied into the drying chamber 10 through the combustion chamber.

The humidity in the drying chamber 10 is drastically lowered due to the open condition of the circulation / exhaust control valve 90 as described above, and the changed humidity information in the drying chamber is detected by the humidity sensor 70 to the controller 100. Is provided.

The control unit 100 closes (closes) the circulation / exhaust control valve 90 when the humidity drops below a predetermined predetermined rate in the initial humidity saturation state according to the programmed control reference setting value, so that the drying apparatus is in a closed loop state. The condition is circular drying.

At this time, the circulation loop of the drying apparatus is determined in consideration of whether the humidity upper limit value (strictly, the humidity upper limit set value) is reached and the arrival time.

Then, when the humidity detection value in the heat recovery tube 60 or the drying chamber 10 by the humidity sensor 70 is lowered, it is determined whether the control unit reaches the reference humidity value registered by the control value setting input unit 101 and then the control unit. 100 is to open or close the circulation / exhaust control valve 90 to control the inflow of the outside air through the intake, exhaust ports (63, 64) and the circulation of the internal drying air to dry the object to be dried in the drying chamber. .

Meanwhile, when the geared motor 80-2 shown in FIG. 5 is used as the circulation / exhaust control valve 90 of the control unit 100 based on the dry atmosphere humidity detection value by the humidity sensor 70, the intake and exhaust ports ( 63, 64) can finely control the amount of external air mixing and the dry residual hot air emissions to achieve fast and safe drying for the object to be dried.

The present invention as described above is not limited only to the above embodiments, and various modifications and changes may be made by those skilled in the art from the technical spirit described in the claims. Will be self explanatory.

1 is a block diagram of a conventional circulation drying apparatus.

2 is a block diagram of a humidity interlocking control thermocirculation drying apparatus of the present invention.

3 is an explanatory view of the inflow state of the exhaust air and the outside air according to the opening conditions of the circulation / exhaust control valve of the humidity interlocking control thermocirculation drying apparatus according to the present invention.

Figure 4 is a first embodiment of the actuator for the circulation / exhaust control valve of the humidity interlocking control thermocirculation drying apparatus according to the present invention and its operation explanatory drawing.

Figure 5 is a second embodiment of the actuator for the circulation / exhaust control valve of the humidity interlocking control thermocirculating drying apparatus according to the present invention and its operation explanatory drawing

6 is a control circuit block diagram of the humidity interlocking control thermocirculating drying apparatus of the present invention.

7 is a control flowchart of the humidity interlocking control thermocirculating drying apparatus of the present invention.

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

10: drying chamber 20: combustion chamber

21: air inlet 30: burner

31: fuel supply pipe 40: combustion motor

50: circulation fan 60: recovery pipe

63: intake port 64: exhaust port

70: humidity sensor 80: valve actuator

80-1: Solenoid 80-2: Geared Motor

81: piston rod 82: lever

83: rotating shaft 90: circulation / exhaust control valve

100: control unit 101: control value setting input unit

Claims (2)

delete A combustion chamber 20 that generates hot air using a heat source including a burner, a drying chamber 10 into which the hot air of the combustion chamber is input, and a circulation fan for exhausting the residual residual wind used in the drying chamber. And a heat recovery pipe (60) for circulating the residual hot air in the drying chamber exhausted by the circulation fan to the combustion chamber side, wherein the inlet port (63) is provided on the heat recovery pipe (60). And the exhaust port 64 are installed adjacent to each other, and these intake and exhaust ports are mutually controlled by the opening angle of the single circulation / exhaust control valve 90 according to the operation of the valve actuator 80. It is installed in proportional control in conjunction with, the valve actuator is any one of a solenoid or geared motor and the output of the control unit 100 according to the detected humidity value of the humidity sensor 70 is installed in the heat recovery pipe (60) To humidity-linked control thermal cycling drying device characterized in that configured to be controlled.

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