KR100358299B1 - A adjustable swirler for controlling a flame shape of a fluid burner - Google Patents

Abstract

The present invention is installed in the rotary dryer inlet, by adjusting the air direction supplied to the rotary dryer inlet to control the flame shape of the fluid burner according to the size of the aggregate when the fluid burner heats the aggregate stored in the interior of the rotary dryer The variable swirler for controlling the flame shape of the fluid burner to be able to efficiently heat other aggregates, the variable swinger is connected to the driver (8) when it rotates the second link arm (22) The connecting rod 23 is linearly moved and the angle ring 20 connected to the connecting rod 23 rotates to rotate the vanes 12 of the wind direction controller 7. In this manner, when the vane 16 is disposed parallel to the airflow direction, the resistance of the air supplied into the tumble dryer 6 is minimal, and when the vane 16 is crossed at right angles to the airflow direction, the air Is the maximum resistance.

Therefore, according to the size of the aggregate it is possible to selectively adjust the shape of the flame generated from the fluid burner (B) by controlling the flow of air by rotating the blade 12 at any angle using the driver (8).

Description

A variable swirler for controlling a flame shape of a fluid burner

The present invention is installed in the rotary dryer inlet, by adjusting the air direction supplied to the rotary dryer inlet can control the flame shape of the fluid burner according to the size of the aggregate when the fluid burner heats the aggregate stored in the interior of the rotary dryer. And a variable swirler for controlling the flame shape of the fluid burner.

Asphalt mixing plant (asphalt mixing plant) it is necessary to heat the aggregate mixed with asphalt to a certain temperature for ascon production. Accordingly, in order to heat aggregates having various mixing ratios, the aggregates are stored in a rotary dryer corresponding to a furnace and the aggregates are heated by using a fluid burner. The flow path of the air register supplying air, that is, rotary type A swirler is installed at the inlet of the combustion zone of the dryer to guide the air supplied to the inlet of the rotary dryer.

Such a conventional swirler simply performs the role of guiding the air into the swirler because its wings are arranged in parallel with the air flow direction, and thus, it is impossible to adjust the shape of the flame so that aggregates can be adjusted according to the size of the aggregate. There was a drawback of not properly controlling the amount of heat required to heat these aggregates when surface area differences occur. More specifically, the flame shape is controlled by the fuel injection pressure of the burner because the wing of the conventional rotor is fixed. . The control of the burner flame shape through the fuel injection amount is different depending on the amount of heat required by these aggregates depending on the aggregate surface area is large (6 mm or less aggregate) and the surface area is small (25 mm or more aggregate). There was a drawback that you cannot control it in real time. In other words, when the content of the coarse aggregate is large, a large amount of space is generated between each aggregate and the aggregate, so that the total surface area is reduced. Therefore, in order to raise the aggregate to the required temperature in a certain time, a fluid burner is used as a fuel. If the injection amount should be increased, and the content of small aggregates is large, the space between each aggregate and the aggregate becomes smaller and the total surface area becomes larger, so that the heat loss must be reduced so that the fuel injection amount can not be controlled in real time. In order to heat the coarse aggregate, it is necessary to increase the calorific value of the burner, which causes a waste of fuel, and a high temperature exhaust gas is generated to exhaust the exhaust gas from the second dust collector 1 of FIG. There was a problem of shortening the life of the filter bag 2 to be filtered. The cooling damper (3) is opened and closed depending on the temperature of the switch. If the temperature of the exhaust gas in the thermocouple (4) is not reduced even by the control of the cooling damper (3), the fuel injection amount of the burner must be lowered. However, such a reduction in fuel injection results in a decrease in the calorific value of the burner, which causes a problem in that the yield is accompanied.

Accordingly, the present invention is to solve the conventional problems as described above, the purpose of which is installed in the rotary dryer inlet, the aggregate of the fluid burner is stored in the interior of the rotary dryer by adjusting the air direction supplied to the rotary dryer inlet In order to control the flame shape of the fluid burner according to the size of the aggregate when heating the, to provide a variable swirler for controlling the flame shape of the fluid burner to efficiently heat the aggregate of different sizes. The variable swirler for controlling the shape is installed at the inlet of the tumble dryer and rotatable in heating the goods contained in the tumble dryer, which has a fluid burner installed at the inlet of the tumble dryer and generates a flame therein. Air chamber supplied into the tumble dryer by installed vanes Wind direction controller to adjust the incense; A driver for rotating the wind direction controller to adjust the angle of the wing of the wind direction controller to adjust the air direction supplied into the rotary dryer; And a power transmission means installed between the driver and the wind direction controller to transmit the rotational force of the driver to the wind direction controller so as to rotate the vanes of the wind direction controller. Here, the wind direction controller has an annular shape. Inner ring having; An outer ring concentric with the inner ring center and disposed outside the inner ring and having an annular shape; And a plate-shaped body, wherein a plurality of radially rotatable axes are formed between the inner ring and the outer ring about the center of the inner and outer rings, and are rotated by the power of the driver to be supplied into the rotary dryer. It includes; a wing for adjusting. The power transmission means further comprises: an angle ring having an annular shape; A first link arm whose one end is fixed to the shaft of the blade penetrating the outer ring and protruding out of the outer ring; A hinge having one end fixed to the angle ring and the other end rotatably connected to the first link arm; A second link arm having a slot formed inside the body and having one end fixed to a rotation shaft of the driver, the second link arm rotating in accordance with the rotation of the driver; And a connecting rod having one end rotatably connected to the angling and the other end variably connected to a slot of the second link arm to transmit the rotational force of the second link arm to the angling.

1 is a view showing that the flame is formed long like a rugby ball by the variable swirler according to the present invention

2 is a view showing that the flame is rounded by the variable swirler according to the present invention.

3 is a partial side view of the variable pivot according to the present invention. FIG. 4 is a cross-sectional view of the variable pivot of FIG. 3.

FIG. 5 is a partial side cross-sectional view showing the inside and outside of the variable turner of FIG.

Figure 6 relates to a variable swinger according to the present invention, the wind vane front view showing a state in which the wing of the swinger is disposed parallel to the burner nozzle.

Figure 7 relates to a variable turner according to the present invention, a front view showing the wind vane is rotated at a predetermined angle of the turner

FIG. 8 is an enlarged view of the inside of the circle of FIG. 4, illustrating an assembly state of a wing of a variable pivoter; FIG.

FIG. 9 is an enlarged view of the inside of the circle of FIG. 6, illustrating an assembled state of a wing of a variable pivoter. FIG.

10 is a front view and a left side view of the blade shaft of the variable pivot according to the present invention.

11 is a view showing a wing plate front view, left side view and a plan view of a variable pivot according to the present invention.

12 is an angled front view and a right side view of a variable pivot according to the present invention.

FIG. 13 is an enlarged view of the inside of the circle of FIG. 3, showing a driver of a variable swinger and power transmission means connected to the driver; FIG.

14 is a front view of a second link arm of the power transmission means according to the present invention. FIG. 15 is a bottom view of the second link arm of FIG.

* Explanation of symbols for the main parts of the drawings

5: variable turning machine 7: wind direction dryer

8 driver 9 power transmission means

10: inner ring 11: outer ring

12 wing 17 first link arm

20: angled 21: hinge

22: second link arm 23: connecting rod

DETAILED DESCRIPTION OF THE EMBODIMENTS Hereinafter, an exemplary configuration of a variable swirler of the present invention will be described in detail with reference to the accompanying drawings.

1 to 2 is a view showing that the flame shape is controlled by a variable turner according to the present invention, Figure 3 is a partial side view of the variable turner according to the present invention, Figure 4 is a variable turn of Figure 3 It is a cross-sectional view of the group. FIG. 5 is a partial side cross-sectional view partially showing the inside and outside of the variable turner of FIG. 3.

As shown in this figure, the configuration of the variable swirler 5 for controlling the flame shape of the fluid burner of the present invention for adjusting the flame shape generated by the fluid burner B is installed at the inlet of the rotary dryer 6. And rotatably installed wind direction controller (7) for adjusting the air direction supplied to the rotary dryer (6) by the rotatable blades, by adjusting the angle of the wing of the wind direction controller (7) And a driver 8 to adjust the air direction supplied into the rotary dryer 6, and between the driver 8 and the wind direction controller 7 and adjust the rotational force of the driver 8 to the wind direction controller 7. It includes a power transmission means (9) to transmit to rotate the wings of the wind direction controller (7).

The wind direction controller 7 is to adjust the air direction supplied into the rotary dryer 6, the inner ring 10 having an annular shape, concentric with the center of the inner ring 10 and the inner ring 10 An outer ring 11 disposed on the outside and having an annular shape, and having a plate-shaped body and a plurality of axes about the inner and outer rings 10 and 11 centered between the inner ring 10 and the outer ring 11; The dog is rotatably installed radially and includes a wing 12 that rotates by the power of the driver 8 to adjust the air direction supplied into the rotary dryer 6.

The inner ring 10 and the outer ring 11 is a plurality of assembly holes radially so that the body is configured in a circular shape, that is, a ring shape as shown in Figure 6, 9 and the shaft 15 of the wing 12 to be described later 13 is penetrated. In addition, the inner ring 10 is disposed in the state in which the outer ring 11 is accommodated. The inner and outer rings 10 and 11 have the same center point, and the center point is the burner nozzle 14 of the air resistor. Are arranged to match.

The wing 12 is composed of a shaft 15 and a wing plate 16 fixed to the shaft 15, as shown in Figures 8 to 11, the assembling hole 13 of the inner and outer rings 10, 11 Is rotatably fixed radially).

The shaft 15 has a hinge protrusion 15a formed at one end thereof as shown in FIG. 10 so as to be rotatably fixed to the assembly hole 13 of the inner ring 10, and a fixing protrusion 15b formed at the other end thereof. It protrudes through the assembly hole 13 of the outer ring 11 and is fixed to the first link arm 17. The wing 12 is recessed in the receiving portion 18 for receiving and fixing the wing plate 16 in the central portion of the body.

The wing plate 16 has a plate-shaped body as shown in FIG. 11, which is fixed to the shaft 15 to control the direction of air supplied into the rotary dryer 6. The wing plate 16 has a narrow portion (L1) is formed in the inner end portion close to the inner ring 10, and a wide portion (L2) is formed in the outer end portion close to the outer ring 11, the overall shape is trapezoidal. The ratio of the length of the narrow portion L1 to the length of the large portion L2 (the length of the narrow portion L1 ÷ the large portion L2) is 0.5 or less. In addition, the wing plate 16 is bent at a predetermined angle on one side of the wide end portion (L2) end, the bent surface 19 is a rotary dryer (6) to supply the air supplied to the rotary dryer (6) 6) It will lead to the center.

The driver 8 generates power to adjust the air direction supplied into the tumble dryer 6 by adjusting the angle of the blade 12 of the wind direction controller 7 as shown in FIGS. 3, 5, and 13. As a known technique already widely used in the industrial field, detailed descriptions thereof will be omitted.

The power transmission means 9 for transmitting the power of the driver 8 to the wind direction controller 7 has an annular ring 20 having an annular shape as shown in FIGS. 3 to 5, and one end thereof penetrates the outer ring 11. The first link arm 17 is fixed to the shaft 15 of the wing 12 protruding outside the outer ring 11, one end is fixed to the angle ring 20 and the other end is the first link arm ( Hinge 21 rotatably connected to 17, a second link arm 22 and one end of which a slot is formed in the body and one end is fixed to the rotation shaft of the driver 8 to rotate in accordance with the rotation of the driver 8 An additional portion is rotatably connected to the angle ring 20 and the other end is variably connected to a slot of the second link arm 22 to transmit the rotational force of the second link arm 22 to the angle ring 20. It includes a connecting rod 23 for transmitting.

The angle ring 20 is preferably formed in the letter-shaped cross-section for the strength reinforcement, as shown in Figs. 4, 5, 12, the front surface to fix the shaft 15 of the wing 12 A plurality of fastening holes 24 are radially through, and a rod 25 for connecting the connecting rod 23 protrudes from the side thereof.

The first link arm 17 is for connecting the wing 12 and the angle ring 20, one end of which penetrates the outer ring 11 to protrude out of the outer ring 11 ( It is fixed to the shaft 15 of 12, the other end is rotatably connected to the fixed hinge 21 of the angle ring 20, the angle ring 20 is rotated by the power of the driver 8 When the blade 12 is rotated by a predetermined angle to control the air direction supplied into the rotary dryer (6).

The hinge 21 connects the wing 12 to the angle ring 20 in cooperation with the first link arm 17, one end of which is rotatably fixed to the first link arm 17. The other end is fixed to the angle ring 20, and when the angle ring 20 rotates, the first link arm 17 rotates to rotate the wing 12.

The second link arm 22 is fixed to the shaft 8a of the driver 8 as shown in FIGS. 14 to 15 and rotates with the shaft 8a to transmit power to the angle ring 20. A slot 22a is formed in the longitudinal body, and at one end, an assembling hole 22b for accommodating the shaft 8a of the driver 8 is formed, and this assembling hole 22b has a length for convenience of assembly. It is configured to be bisected and expanded and contracted by the incision 22c cut in the direction. The slot 22a provides room for the connecting rod 23 connected to the angle ring 20 to be variable.

The connecting rod 23 is rotatably connected to the rod 25, one end of which is fixed to the angle ring 20, and the other end of the connecting rod 23 is variably fixed to the slot 22a. It serves to deliver to the angling (20).

Next, the variable swirler 5 for controlling the flame shape of the fluid burner of the present invention configured as described above controls the air volume of the air supplied to the rotary dryer 6 to generate the flame generated from the fluid burner B. It will be described in detail the process of adjusting the shape of.

If the surface area of the aggregate contained in the tumble dryer 6 is large, that is, if the size (volume) of each aggregate contained in the combustion chamber 8 of the dryer 6 is small, these aggregates will be in close contact with each other, so that the voids generated therebetween. The rate is small, and consequently, the total surface area is large. In this case, these small aggregates open the wings 12 a lot due to the rapid heat absorption, thereby increasing the air velocity, so that the flame shape is concentrated in the center of the dryer in the longitudinal direction of the rugby ball. It is preferable not to make the internal temperature of the dryer too high so as to be formed long.

On the contrary, bulky aggregates are not only large in porosity but also large in their volume, so the heat absorption is slow and requires a large amount of heat, thus closing the wings 12 and reducing the air flow rate, thereby rounding the flame shape. It is preferable to raise the dryer temperature by bringing the flame close to the inner wall and aggregate of the rotary dryer 6.

The operation of the blade 12 is that when the driver 8 rotates the second link arm 22 in the direction of the arrow as shown in FIG. 5, the connecting rod 23 connected thereto is linearly moved, and the connecting rod 23 is connected to the connecting rod 23. The connected angling 20 rotates in the direction of the arrow to rotate the vanes 12 of the wind direction controller 7. In this manner, when the vane 16 is disposed parallel to the air flow direction (zero angle), the resistance of the air supplied into the tumble dryer 6 is minimal, and the vane 16 is perpendicular to the air flow direction. The resistance of the air is maximized. Therefore, according to the size of the aggregate, by using the actuator 8 to rotate the blade 12 at an arbitrary angle to control the flow of air generated in the fluid burner (B) It is possible to selectively control the shape of the flame. The manner in which the compound aggregate is heated is such that the two flame forms mentioned above can be continuously transformed in the heating system to which the present invention is applied. As the surface area is changed by a certain range or more, the exhaust gas temperature in the dust collector 1 of the asphalt mixing plant is changed as shown in FIGS. 1 and 2, and is installed between the dust collector 1 and the cooling damper 3. The thermocouple 4 measures the exhaust gas temperature, and the driver 8 connected to the thermocouple 4 recognizes and drives the measured temperature, thereby automatically operating the blade 12 by a set angle to control the flame shape in real time. You can control it.

The variable turning machine for controlling the flame shape of the fluid burner of the present invention configured as described above increases the aggregate surface area when heating small aggregates, thereby opening the wings a lot and speeding up the flow of air, thereby making the flames look like rugby balls. When rotating, keep the room temperature away from the dryer's inner wall and aggregates. On the contrary, when heating large aggregates, the aggregate surface area decreases, so the wings are closed and the air flow is slowed down. The aggregate can be heated in such a way that it can increase the room temperature by bringing it closer to the side walls and the aggregate.

This method has the advantage of preventing the waste of fuel by adjusting the wind speed of the air supplied at a constant speed by means of the blades. In particular, the change of the flame shape of the continuous burner is input to the dust collector. Controlled in real time and continuously according to the fluctuation of the exhaust gas temperature, it reduces energy waste and maintains the exhaust gas temperature at a constant level inside the dust collector, thereby allowing the filter bag and It is effective to protect other facilities.

Claims (5)

A fluid burner is installed at the inlet of the tumble dryer to heat an article contained in the tumble dryer which generates a flame in the tumble dryer. A wind direction controller installed at the inlet of the tumble dryer and adjusting the air direction supplied into the tumble dryer by a wing rotatably installed; A driver for rotating the wind direction controller to adjust the angle of the wing of the wind direction controller to adjust the air direction supplied into the rotary dryer; And It is installed between the driver and the wind direction controller, the power transmission means for transmitting the rotational force of the driver to the wind direction controller to rotate the wing of the wind direction controller; for controlling the flame shape of the fluid burner comprising a Variable turner. According to claim 1, wherein the wind direction regulator, An inner ring having an annular shape; An outer ring concentric with the inner ring center and disposed outside the inner ring and having an annular shape; And It has a plate-shaped body, a plurality of radially rotatable around the center of the inner and outer rings between the inner ring and the outer ring is installed, and rotates by the power of the driver to supply the air direction supplied into the rotary dryer Variable swinger for controlling the flame shape of the fluid burner comprising a wing to adjust. The method of claim 1, wherein the power transmission means, Angling having an annular shape; A first link arm whose one end is fixed to the shaft of the blade penetrating the outer ring and protruding out of the outer ring; A hinge having one end fixed to the angle ring and the other end rotatably connected to the first link arm; A second link arm having a slot formed inside the body and having one end fixed to a rotation shaft of the driver, the second link arm rotating in accordance with the rotation of the driver; And A connecting rod having one end rotatably connected to the angle ring and the other end variably connected to a slot of the second link arm to transfer a rotational force of the second link arm to the angle ring. Variable swirler for controlling the flame shape of the fluid burner. The method of claim 2, wherein the wing, A shaft having one end rotatably fixed to the inner ring and the other end protruding through the outer ring to be connected to the first link arm; A wing plate having a plate-shaped body, the body being fixed to the shaft to control the direction of air supplied into the rotary dryer; And And a bent surface which is bent at one side of the outer end of the wing plate and moves air supplied into the rotary dryer to a central portion of the rotary dryer. The wing plate of claim 4, wherein The inner end portion is composed of a narrow portion, the outer end portion is composed of a large portion, the overall shape has a trapezoidal shape, the ratio of the length of the narrow portion to the length of the large portion (small portion length ÷ large portion length) is a fluid, characterized in that less than 0.5 Variable swirler to control the flame shape of the burner.