KR20120040425A - Removing apparatus for dust cooling tube in cooling chamber - Google Patents

Abstract

PURPOSE: A dust eliminating apparatus for the cooling tube of a cooling chamber is provided to completely eliminate dust from a cooling tube and to drop dust to the lower part of the cooling tube. CONSTITUTION: A dust eliminating apparatus for the cooling tube of a cooling chamber is composed of a cylinder(110), a piston(120), a recovering unit(130), a dust eliminating unit(140). A receiving space is formed in the cylinder. An outlet(110c) is formed at one wall of the columnar of the cylinder in order to discharge fluid which is introduced into the receiving space. A part of the piston is exposed to another part of the cylinder in order to transfer a linear motion and a rotational motion to the outside. The recovering unit is installed between the cylinder and the piston in order to recover the piston to an original position.

Description

Dust removal device of cooling tube for cooling chamber {REMOVING APPARATUS FOR DUST COOLING TUBE IN COOLING CHAMBER}

The present invention relates to a dust removal device of the cooling tube for the cooling chamber, and more particularly, to remove the dust stuck to the inside of the cooling tube during the operation of the electric furnace to remove the dust of the cooling chamber cooling tube to improve the dust collection function. Relates to a device.

In general, a cooling chamber installed on a cooling line in an electric furnace facility sends high-temperature dust generated during operation to a tube room through an inlet damper of a cooling chamber to flow into a cooling tube, thereby lowering the heat by a cooling fan provided in the cooling tube. Then it is sent to the next facility.

1 is a reference diagram showing a through operation of a cooling tube for a conventional cooling chamber.

As shown in FIG. 1, the electric furnace cooling chamber 10 sends high-temperature (400-600 ° C.) dust generated during operation to the tube room 12 through the inlet damper 11 of the cooling chamber 10, 2000. By flowing into two cooling tubes 13, the cooling fan 14 provided in the cooling tube 13 allows the dust to cool to about 250 ° C and is then sent to the next facility.

At this time, the dust containing moisture accumulates in the inside of about 2000 cooling tubes 13 and is fixed, and eventually the cooling tube 13 is blocked by the dust. When the cooling tube 13 is blocked by the dust, the worker conventionally uses a pipe 15 having a length of about 2 m to pierce the blocked portion first and then removes the remaining dust by using an air hose.

However, the removal of dust in the cooling tube in this way is not only a large number of operators, but also completes the work within 10 hours according to the operating time of the electric furnace, so that all the cooling tubes in the tube room cannot be completely removed. There is.

In particular, the length of the pipe to remove dust from the cooling tube is 2m, whereas the length of the cooling tube is about 6m, so even if the operator removes the dust directly, the dust is removed from only the upper part of the cooling tube. It may not be completely removed, causing a problem of low dust collection efficiency.

In addition, in the conventional dust removal work of the cooling tube, the worker manually removes dust by using an air hose in a confined space such as a tube room, so it is difficult to secure the operator's field of view due to the reversed dust. Inhalation of excess gas can lead to occupational diseases such as respiratory and eye diseases.

The present invention is to solve the problems as described above, the object is to remove the dust from the cooling tube by the manual operation of the operator as in the prior art hammer function to automatically tap the dust stuck in the cooling tube in rotation It is to remove dust automatically by giving a combination of cutting function.

In order to solve the above-mentioned problems,

A cylinder in which a fluid inlet is formed at one end thereof, an accommodating space is formed therein, and one side of the circumferential wall has a discharge outlet configured to discharge the fluid into the accommodating space; Mounted inside the cylinder is a linear movement by the fluid in the longitudinal direction of the cylinder is a rotational movement is made together via a movement switching means provided between the cylinder, the cylinder to transmit the linear movement and rotational movement to the outside A piston partially exposed out of the other end of the piston; Restoring means provided between the cylinder and the piston so that the piston can be restored to an initial position after the fluid introduced into the cylinder is discharged; Cooling chamber comprising; dust removal unit having a knife for substantially removing the dust stuck to the cooling tube for cooling chamber is connected to a portion of the piston exposed to the other end of the cylinder to perform a linear movement and rotational movement Provide dust removal device of cooling tube.

Here, the movement switching means, the spin gear is formed to protrude in a spiral for a predetermined period on the outer peripheral surface of the piston, and the spin gear groove is inserted into the spin gear sliding on the cylinder inner wall surface corresponding to the spin gear It is characterized in that the linear motion of the piston is converted into a rotational motion by forming.

In addition, the piston is provided with a hydraulic action portion in close contact with the cylinder inner diameter to receive the pressure by the fluid, one end of the piston toward the inlet side relative to the hydraulic action portion than the hydraulic action portion to receive the hydraulic pressure It is characterized in that the reduced diameter shaft portion is formed.

In addition, the other end of the piston is exposed to the other end of the cylinder is characterized in that the piston rod is connected to the dust removal unit is formed.

In addition, the shaft diameter portion of the piston is characterized in that the buffer means for preventing the collision with the inside of the cylinder when the piston is restored to its original position by the restoring means is installed.

In addition, at least one of the side or bottom surface of the dust removal unit is characterized in that a knife portion for cutting the dust stuck to the cooling tube.

Here, the cylinder is located in the upper portion of the cylinder and the cylinder head formed with the inlet at one end, and coupled to the cylinder head to prevent the piston contained therein is separated from the cylinder block formed with the discharge port on one circumferential side wall It is characterized by.

According to the present invention, by inserting the device according to the present invention into the cooling tube to which the dust is fixed, the dust removal unit is a hammer function to hit the dust and at the same time the dust removal unit is rotated to cut the dust and the dust is fixed inside the cooling tube The automatic removal of the bar, as compared with the conventional manual removal of dust by a small number of people can be removed within a short time has the effect of increasing the work efficiency.

Further, according to the present invention, since dust can be removed over the entire length of the cooling tube, there is an advantage that the dust removal of the cooling tube is completely completed. There is a safety advantage to workers.

1 is a reference diagram showing a through operation of a cooling tube for a conventional cooling chamber,
2 is a reference view showing the operation of removing dust using the dust removal apparatus according to the present invention,
Figure 3 is an exploded view showing the configuration of the dust removal apparatus according to the present invention,
Figure 4 is a cross-sectional view of the combined dust removal device according to the present invention,
5 is a perspective view showing a combined state of the dust removal apparatus according to the present invention;
6a and 6b is an operating state diagram showing the operating state of the dust removal apparatus according to the present invention.

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

As shown in FIG. 2, the present invention is a view showing the removal of the dust 210 fixed in the cooling chamber 200 for the cooling chamber. 2, the dust removal device according to the present invention completely removes the dust 210 by performing a linear reciprocating motion along the longitudinal direction of the cooling tube 200 as well as performing a rotational movement in combination.

As shown in FIGS. 3 and 4, the dust removing device of the cooling chamber cooling tube 200 according to the present invention has a large cylinder 110, a piston 120, a restoring means 130, and a dust removing unit 140. It is made, including.

One end of the cylinder 110 is formed with an inlet 110a through which a fluid enters. The fluid is not only a liquid type such as oil, but also a gas type such as compressed air. Air is used but not necessarily limited thereto.

In addition, the inside of the cylinder 110 has a receiving space (110b) is formed in communication with the inlet (110a) is the fluid enters into the receiving space (110b) through the inlet (110a), the cylinder 110 One wall of the outlet 110c is formed so that the fluid entering the receiving space (110b) can go out of the cylinder (110).

Here, the cylinder 110 is preferably provided detachably so that other components can be built in the receiving space, the cylinder 110 is cut in half along the longitudinal direction to be symmetrical with each other to be detachably coupled to each other. In the embodiment of the present invention, as shown in FIG. 3, the cylinder 110 may be cut in the circumferential direction perpendicular to the longitudinal direction of the cylinder 110, so that the cylinder 110 may be the cylinder head 111 and the cylinder block 112. It is configured to be divided into

The cylinder head 111 is located on the upper portion of the cylinder 110, the inlet (110a) is formed to enter the fluid into one end, the inlet (110a) is formed in a simple hole shape on the cylinder head 111 However, it is preferable to form a nipple (Nipple) to facilitate the coupling with the hose or pipe for supplying the fluid.

In addition, the cylinder block 112 is coupled to the cylinder head 111 to prevent the piston 120 accommodated in the receiving space (110b) formed therein is not separated, the circumferential work of the cylinder block 112 The side wall is formed with a discharge port 110c for discharging the fluid to the outside.

On the other hand, the piston 120 is mounted in the cylinder 110 is configured to move along the longitudinal direction of the cylinder 110, the piston 120 is a linear movement in the longitudinal direction of the cylinder 110 by the fluid The rotational movement is performed together with the movement switching means 150 provided between the cylinder 110.

A portion of the piston 120 is exposed to the piston 120 to the outside of the other end of the cylinder 110 to transmit the linear motion and the rotational motion of the piston 120 to the outside of the cylinder 110, wherein the cylinder 110 A portion of the piston 120 that is exposed to the other end, that is, the other end of the piston 120 is formed with a piston rod 121 connected to the dust removal unit.

One end of the piston 120 is applied to the pressure of the fluid introduced into the cylinder 110 through the inlet (110a), this fluid is to provide a force in the linear direction to the piston 120 but the movement switching means The piston 120 moves in the rotational direction as well as the linear direction.

The movement switching means 150 is composed of a spin gear 151 formed in the piston 120, and a spin gear groove 152 formed in the cylinder 110, the spin gear 151 of the piston 120 It is formed to protrude in a spiral shape on the outer circumferential surface by a predetermined section.

In addition, the spin gear groove 152 is formed on the inner wall surface of the cylinder 110 corresponding to the spin gear 151 of the piston 120 so that the spin gear 151 is inserted into the spin gear groove 152 so that the piston When the fluid pressure is applied to one end of the 120, the piston 120 linearly moves and at the same time, the spin gear 151 slides along the spiral direction of the spin gear groove 152 to rotate the piston 120. Allow the exercise to be performed.

That is, in the state in which the piston 120 is inserted into the receiving space of the cylinder 110, there is an area in contact with each other on the outer peripheral surface of the piston 120 and the inner wall surface of the cylinder 110, among which the piston ( When the spin gear 151 is formed in a portion of the 120, the cylinder 110 corresponding to the spin gear groove 152 is formed so that the piston 120 linearly moves along the longitudinal direction of the cylinder 110. Always make a rotational movement together.

In addition, the piston 120 is formed with a hydraulic action unit 122 in close contact with the inner diameter of the cylinder 110 to receive the pressure by the fluid, the inlet port 110a based on the hydraulic action unit 122 One end portion of the piston 120 toward the side is formed with an axis diameter portion 123 is reduced in diameter than the hydraulic action portion 122 to properly receive the hydraulic pressure from the fluid.

That is, when the fluid is introduced into the cylinder 110 through the inlet 110a of the cylinder 110, the fluid is introduced into the shaft diameter portion 123 having a diameter smaller than the inner diameter of the cylinder 110, Hydraulic pressure by the fluid by the hydraulic action portion 122 of the piston 120 is in close contact with the piston 120 as it is.

Accordingly, the piston 120 moves along the direction in which the hydraulic pressure acts, that is, the longitudinal direction of the cylinder 110, and then the hydraulic action portion 122 passes through the outlet 110c and the shaft diameter portion 123 and the outlet 110c. ) Comes to the place communicating with each other, the fluid is discharged through the outlet (110c) all the movement of the piston 120 is stopped.

On the other hand, the restoring means 130 is restored to the initial position where the piston 120 can receive the hydraulic pressure after the fluid introduced into the cylinder 110 is discharged out of the cylinder 110 through the outlet 110c. It is installed between the cylinder 110 and the piston 120 so that, in the present invention, the restoration means 130 was implemented as a coil spring that can be installed in the cylinder 110, but is not necessarily limited thereto.

If the pressure of the fluid acts on the piston 120 and the piston 120 moves in a straight direction until the fluid exits the cylinder 110 through the outlet 110c, the restoring means 130 is elastically compressed but the fluid After the gas is discharged to the outside through the outlet 110c, the piston 120 is returned to the initial position by the restoring force of the restoring means 130. At this time, the piston 120 is restored by the restoring force of the restoring means 130. A problem that may collide with the inside of the cylinder 110 occurs. Therefore, in order to prevent such a problem, in the shaft diameter portion 123 of the piston 120, a separate shock absorbing means (not provided) so that the piston 120 restored to its original position by the restoring means 130 does not collide with the inside of the cylinder 110. 131 is preferably installed.

The shock absorbing means 131 is an additional configuration for preventing the collision between the piston 120 and the cylinder 110, but is not necessarily a configuration, but is preferably provided for the protection of the component, the shaft diameter portion of the piston 120 When the shock absorbing means 131 is provided at the 123, the piston 120 not only buffers the shock by the piston 120 restored to the initial position but also applies the repulsive force by the shock absorbing means 131 to the piston 120 again. In addition to the hydraulic energy there is an advantage that can be provided with repulsive energy. Here, the buffer means 131 may be implemented as a coil spring as shown.

On the other hand, the dust removal unit 140 is connected to a portion of the piston 120 exposed outside the other end of the cylinder 110 to perform the same linear and rotary motion as the piston 120, the dust removal unit 140 ) Is a configuration for substantially removing the dust 210 fixed to the cooling tube 200 for the cooling chamber.

Here, the dust removal unit 140 is connected to a portion of the piston 120 exposed to the other end of the cylinder 110, that is, the piston rod 121, the piston rod (121) to be detachably coupled with the piston rod (121) It is preferable that the male screw 141a is processed at the end of 121 and the female screw 140a is processed at the upper surface of the dust removing unit 140.

In addition, it is preferable that the knife unit 141 is formed on at least one of the side or the bottom surface of the dust removal unit so that the dust removal unit 140 can more completely remove the dust 210.

The knife unit 141 performs a hammer function that strikes the dust 210 when the dust removing unit 140 reciprocates in a linear direction, and the dust 210 when the dust removing unit 140 rotates. By cutting the cutting (Cutting) function to easily and completely remove the dust 210 is fixed to the inner surface of the cooling tube (200).

Such a dust removal apparatus of the present invention is shown in more detail in Figures 6a and 6b.

First, as shown in FIG. 6A, when hydraulic pressure is applied to the piston 120 positioned above the cylinder 110 in the drawing, the piston 120 may be discharged out of the cylinder 110 through the outlet 110c. The linear motion in the downward direction as well as the rotary motion at the same time.

Therefore, the dust removal unit 140 performing the downward linear motion and the rotational motion in the same manner as the piston 120 hits the dust 210 while simultaneously cutting and removing the dust.

At this time, when the fluid acting on the piston 120 exits through the outlet 110c, the piston 120 returns to the initial position as shown in FIG. 6A again by the restoring force of the restoring means 130, thereby completing one cycle. Bar, while performing the operation continuously such as to completely remove the dust (210).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the invention is not limited to the disclosed exemplary embodiments. It is to be understood that the invention is not limited thereto.

110: cylinder 110a: inlet
110c: outlet 111: cylinder head
112: cylinder block 120: piston
121: piston rod 122: hydraulic action
123: shaft diameter 130: restoring means
131: buffer means 140: dust removal unit
141: knife portion

Claims (7)

A cylinder (110) formed at one end thereof with an inlet (110a) through which fluid enters, an accommodating space therein, and an outlet (110c) through which a fluid entering the accommodating space is formed at one circumferential wall;
Mounted inside the cylinder 110, while the linear movement by the fluid in the longitudinal direction of the cylinder 110, the rotational movement is made together via the movement switching means 150 provided between the cylinder 110, the linear movement A piston 120 partially exposed out of the other end of the cylinder 110 to transmit an external rotation motion;
Restoring means (130) installed between the cylinder (110) and the piston (120) so that the piston (120) is restored to its initial position after the fluid introduced into the cylinder (110) is discharged;
Connected to a portion of the piston 120 exposed to the other end of the cylinder 110 to perform a linear motion and rotational movement, having a knife for removing dust 210 stuck to the cooling tube 200 for the cooling chamber Dust removal unit 140; Dust removal device of the cooling tube for the cooling chamber comprising a. The method according to claim 1, wherein the movement switching means 150,
The spin gear 151 is formed to protrude in a helical shape for a predetermined period on the outer peripheral surface of the piston 120, and inserted into the spin gear 151 on the inner wall surface of the cylinder 110 corresponding to the spin gear 151. The dust removal device of the cooling chamber cooling tube, characterized in that the linear movement of the piston 120 is converted to a rotational movement by forming a spin gear groove 152 is sliding. The method according to claim 2, wherein the piston 120 is formed with a hydraulic actuating portion 122 in close contact with the inner diameter of the cylinder 110 to receive the pressure by the fluid, the hydraulic actuating portion 122 based on the Dust removal of the cooling chamber cooling tube, characterized in that the shaft diameter portion 123 is reduced in diameter than the hydraulic action portion 122 is formed at one end of the piston 120 toward the inlet (110a) side to receive the hydraulic pressure. Device. 4. The cooling tube of claim 3, wherein the other end of the piston 120 is exposed outside the other end of the cylinder 110 to form a piston rod 121 connected to the dust removing unit 140. Dust removal device. 5. The shock absorbing means of claim 4, wherein the shaft portion 123 of the piston 120 prevents the piston 120 from colliding with the inside of the cylinder 110 when the piston 120 is restored to its original position by the restoring means 130. Dust removal device of the cooling tube for the cooling chamber, characterized in that 131 is installed. The method according to claim 1, Cooling, characterized in that the knife portion 141 for cutting the dust 210 fixed to the cooling tube 200 is formed on at least one of the side or bottom surface of the dust 210 removal means. Dust removal device for cooling tube for chamber. The method according to claim 1, wherein the cylinder 110,
Located in the upper portion of the cylinder 110 and one end of the cylinder head 111 is formed with the inlet (110a), and coupled to the cylinder head 111 to prevent the piston 120 accommodated therein is separated from the circumferential work Dust removal apparatus of the cooling tube for the cooling chamber, characterized in that the outlet block (110c) formed on the side wall formed of a cylinder block (112).

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