KR100791942B1 - Apparatus for cooling mixed air in transfer pipe for dust collector - Google Patents

Abstract

A device for cooling mixed air in a transfer pipe for a dust collector is provided to prevent mixed air comprising dust from flowing into the dust collector in a state that the mixed gas maintains a high temperature. A device(100) for cooling mixed air in a transfer pipe for a dust collector comprises: at least one cooling pipeline(110) which forms a portion of the transfer pipe in a state that the cooling pipeline is installed on a mixed air transfer pipeline for connecting a suction hood for sucking mixed air containing dusts in a heated state and a dust collector for collecting dusts in the mixed air; a plurality of cooling steel sheets(120) continuously disposed within the cooling pipeline with being spaced from one another in a predetermined distance and heat exchanged with the mixed air passing through the cooling pipeline; and a dust accumulation part(130) which is formed in a depressed form on a front lower portion of the cooling pipeline having the mixed air flown thereinto such that dusts contained in the mixed air are collided with the cooling steel sheets and dropped to be collected into the dust accumulation part.

Description

Apparatus for cooling mixed air in transfer pipe for dust collector

1 is a perspective view showing a state in which a mixed air cooling device installed in a transport pipe in the transport pipe for dust collector according to the present invention.

Figure 2 is a perspective view for showing the configuration of the mixed air cooling apparatus in the conveying pipe for the dust collector according to the present invention.

3 is a cross-sectional view taken along line III-III of FIG. 2;

4 is a cross-sectional view taken along line IV-IV of FIG. 2;

5 is a perspective view of a front cooling steel sheet according to another embodiment of the front cooling steel sheet constituting the present invention.

6 is a cross-sectional view of the mixed air in the conveying pipe for the dust collector to which the front cooling steel sheet of FIG.

<Explanation of symbols for the main parts of the drawings>

110.Cooling line 112,131 ... door

113,132 Safety hook 120 Cooling steel plate

121 ... front cooled steel plate 122 ... rear cooled steel plate

124 ... indentation bend 124a ... indentation surface

124b ... indented bending surface 130 ... dust deposit

140 ... Horizontal support rod D ... dust

The present invention relates to a dust collector installed in a steel mill, which is installed in a mixed air transfer pipe connected to the dust collector side and mixed in the transport pipe path for the dust collector to cool the mixed air including the hot dust generated in the steelmaking process before entering the dust collector side. It relates to an air cooler.

In general, dust collecting facilities are to be installed in all industrial sites where a large amount of dust is generated.

Dust collection equipment is usually provided with a dust suction hood provided to suck the mixed air containing dust at the dust generating place, a dust collector for the dust collection treatment, and a transfer pipe connecting the dust suction hood and the dust collector, One side of the dust collector is provided with a fan for providing a suction force to the dust collector side so that the mixed air containing the dust can be sucked to the dust collector side through the transfer pipe.

In addition, the dust collector is generally a dust collector having a bag filter type filter, such a bag filter has a narrow, elongated bag shape and is used in a bag cage in the dust collector. . As the bag filter is used for a long time, when dust is deposited on the surface of the filter, the pressure loss (differential pressure) increases and blows compressed air in the opposite direction to the filtration direction to shake off (after dedusting) to collect dust again. It is designed to be used semi-permanently.

However, such a dust collector has a problem that it is difficult to apply in a facility such as steel mill because the bag filter is made of a non-woven fabric susceptible to heat. Because, in the steel mill, fine iron powder dusts generated during the steelmaking process is generated, because the mixed air containing these dusts is heated to a high temperature during the steelmaking process.

If the hot mixed air is continuously in contact with the nonwoven fabric, which is susceptible to heat, the nonwoven fabric deteriorates and the dust collecting performance of the dust collector is notably reduced, and the life of the dust collector is greatly shortened.

The present invention has been made in consideration of the above-described conventional problems, and an object of the present invention is to provide a mixed air cooling device in a transport pipe path for a dust collector such that mixed air containing dust does not flow into the dust collector at a high temperature.

In order to achieve the above object, the present invention is installed in the mixed air transfer pipe path connecting between the suction hood for suctioning the mixed air containing the dust of the heat generated state and the dust collector for collecting the dust in the mixed air portion of the transport pipe At least one cooling conduit; A plurality of cooling steel sheets continuously disposed at predetermined intervals inside the cooling conduit to exchange heat with the mixed air passing through the cooling conduit; And a dust deposit formed in a concavity formed in the front lower portion of the cooling conduit through which the mixed air flows so that the dust included in the mixed air falls after colliding with the cooling steel sheets.

The features and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments based on the accompanying drawings. Prior to this, the terms or words used in the present specification and claims are defined in the technical spirit of the present invention on the basis of the principle that the inventor can appropriately define the concept of the term in order to explain his invention in the best way. It must be interpreted to mean meanings and concepts.

As shown in Figures 1 to 4, the mixed air cooling device 100 in the transport pipe for the dust collector according to the present invention is a suction hood (not shown) and the mixing to suck the mixed air containing dust in the heat generated state At least one cooling conduit 110 that is installed in the mixed air conveying conduit 1 connecting the dust collector (not shown) for collecting dust in the air and forms part of the conveying conduit 1, and the cooling conduit 110 A plurality of cooling steel plates 120 and heat exchanged with the mixed air passing through the cooling conduit 110 at a predetermined interval therein, and the dust contained in the mixed air falls after colliding with the cooling steel plates 120 It is composed of a dust deposit 130 formed in the concave in the front lower portion of the cooling conduit 110 is introduced into the mixed air.

The cooling conduit 110 is an enclosure having both ends open, and the mixed air flowing along the conveying conduit 1 flows into the open front, and the mixed air passed through the cooling conduit 110 into the open rear. Is discharged.

The cooling conduit 110 is fitted into the conveying conduit 1 so as to be detachable from the conveying conduit 1. To this end, both ends of the cooling conduit 110 are formed in the same shape as the cross section of the conveying conduit 1 is formed fitting portion 111 to be fitted in close contact with the end of the conveying conduit (1).

Inside the cooling conduit 110, a plurality of cooling steel plates 120 are arranged in a multi-layered multilayer. The cooling steel plates 120 are thin plates made of steel having excellent heat exchange performance, and are continuously arranged in a horizontally fixed state at predetermined intervals on horizontal support rods 140 crossing the inside of the cooling conduit 110 in the width direction.

On the other hand, the cooling steel plate 120, the cooling steel plate 120 is the front cooling steel plate 121 is disposed in front of the cooling conduit 110 and the rear cooling steel plate 122 disposed in the rear of the cooling conduit 110 It is preferred to be divided into two.

In this case, the front cooling steel plates 121 and the rear cooling steel plates 122 have different arrangement forms. That is, the front cooling steel plates 121 are disposed such that the front and rear directions of the cooling conduits 110 are in the longitudinal direction, and the vertical direction of the cooling conduits 110 is in the width direction, and the rear cooling steel plates 122 are the cooling conduits ( The front-rear direction of 110 is a width direction, and the up-down direction of the cooling pipe 110 is arrange | positioned so that a longitudinal direction may be provided.

In addition, the front cooling steel plates 121 and the rear cooling steel plates 122 are arranged to cross along the width direction of the cooling conduit 110. In this way, the mixed air passing through the front cooling steel plates 121 may be evenly contacted with the rear cooling steel plates 122.

Therefore, the mixed air generated in the steelmaking process passes through the cooling conduit 110 in the course of passing through the conveying conduit 1, and exchanges heat evenly while contacting the cooling steel plates 120 disposed in the cooling conduit 110. It flows into the dust collector in a state where the temperature is lowered.

On the other hand, as shown in Figure 5 and 6, as another embodiment of the front cooling steel plate, the front cooling steel plate 121 is a plurality of concave bent portion formed at a predetermined interval along the front and rear direction of the cooling conduit 110 ( 124). The concave bent portion 124 is a pair formed inclined to connect the front and rear ends of the concave surface 124a parallel to the surface of the front cooling steel plate 121 and the front cooling steel plate 121 and the concave surface (124a). It consists of a concave bending surface 124b.

 The reason for forming the concave bent portion 124 is to increase the contact area with the mixed air to improve heat exchange performance and at the same time the corner portion (A) formed by the concave bent surface 124b and the concave surface (124a) In order to rapidly reduce the flow rate of the mixed air in the dust to be included in the mixed air to easily fall to the bottom of the cooling conduit (110).

In consideration of this point, it is preferable that the indentation bent portion 124 has an angle θ formed between the indentation surface 124a and the indentation bending surface 124b of 130 ° to 170 °. That is, if the angle θ formed between the concave and concave surface 124a and the concave and concave surface 124b is smaller than 130 °, the flow rate of the mixed air passing through the concave and concave portion 124 is mixed air. This is because dust contained in the dust is not sufficiently degraded to easily fall. If the angle θ formed between the concave indentation surface 124a and the concave bending surface 124b is greater than 170 °, the mixed air passing through the concave bending portion 124 may be This is because the flow rate decreases sharply, which hinders the smooth flow of the mixed air.

In addition, it is preferable that the concave bending surface a base length L1 and the concave concave surface length L2 based on the longitudinal direction of the front cooling steel plate 121 is 1: 2. The depth of the concave bent portion 124 is determined according to the length ratio, but the length L2 of the concave convex surface is relatively short compared to the length L1 of the concave concave surface so that the depth of the concave bent portion 124 is too deep. If formed, the flow of the mixed air passing through the concave bent portion 124 is not smooth, the length of the concave concave surface (L2) is relatively long compared to the length (L1) of the concave concave surface is the depth of the concave bent portion 124 This is because if the formation is too shallow, the area of the flow rate lowering region of the mixed air becomes too small and the dust deposition rate decreases.

According to the present invention, a dust deposit 130 is formed at the front lower portion of the cooling conduit 110 to collect dust falling while contacting the front cooling steel plates 121. The dust depositing unit 130 is recessed downwardly to prevent the mixed air from scattering the dusts D deposited on the floor while passing through the cooling conduit 110 and to collect a large amount of dust. In addition, the dust deposition unit 130 is preferably formed to be narrower toward the lower center to facilitate the collection.

Therefore, the dust included in the mixed air is dropped in the process of passing through the front cooling steel plate 121 is deposited and collected in the dust deposition unit 130, the dust (D) dropped while passing through the rear cooling steel plate 122 Is deposited on the bottom behind the cooling conduit 110 and collected.

Meanwhile, doors 112 and 131 are installed at the bottom of the dust deposition unit 130 and the rear bottom of the cooling conduit 110 to collect the accumulated dusts D. The doors 112 and 131 are normally locked and open only when collecting the dusts D formed while forming the bottom of the dust deposition unit 130 or the cooling conduit 110.

In addition, the doors 112 and 131 are preferably provided with safety rings 113 and 132. The safety rings 113 and 132 are connected to one side of the dust deposition unit 130 or one side of the cooling conduit 110 so that the doors 112 and 131 are not opened at a predetermined angle or more. Accordingly, even if the doors 112 and 131 are opened in an unintended state, the safety rings 113 and 132 restrict the doors 112 and 131 from being opened for a predetermined angle, thereby preventing safety accidents.

According to the mixed air cooling device in the transfer pipe for the dust collector according to the present invention configured as described above has the following effects.

First, the present invention reduces the temperature of the mixed air by cooling the steel plates installed inside the cooling pipe passage heat exchanged with the mixed air before the heated mixed air is introduced into the dust collector, thereby preventing the deterioration of the dust collector, greatly improving the performance and life of the dust collector. There is an effect that can be improved.

Second, the present invention has the effect of maximizing the dust collection performance of the pre-collected dust before the mixed air is introduced to the dust collector by inducing the falling of the dust contained in the mixed air as the cold steel sheet is in contact with the mixed air. . In addition, the present invention may greatly improve the drop rate of the dust contained in the mixed air by forming a concave bent portion in the cold steel sheet.

Third, there is an effect that it is possible to efficiently deposit and collect the dust contained in the mixed air by forming a dust deposit in the front lower portion of the cooling pipe inflowing the mixed air.

While the invention has been shown and described with respect to specific embodiments thereof, it will be understood that the invention can be variously modified and modified without departing from the spirit or scope of the invention as provided by the following claims. It should be included in the scope of the invention.

Claims (10)

At least one cooling conduit provided in a mixed air conveying conduit for connecting a suction hood for sucking the mixed air including dust in a heated state and a dust collector for collecting dust in the mixed air and forming a part of the conduit; A plurality of cooling steel sheets continuously disposed at predetermined intervals inside the cooling conduit to exchange heat with the mixed air passing through the cooling conduit; Mixing air cooling apparatus in a transport pipe for dust collector comprising a dust deposit formed in the lower portion of the front of the cooling conduit in which the mixed air flows so that the dust contained in the mixed air falls after colliding with the cooling steel sheet. . The method of claim 1, Inside the cooling conduit, horizontal support rods are installed which cross the cooling conduit in the width direction. The cooling steel sheets are fixed through the horizontal support rods in order to be mixed air cooling apparatus in the transfer pipe path for the dust collector, characterized in that arranged in a multi-layered multi-layer inside the cooling pipe. The method of claim 2, The cooling steel plates are divided into front cooling steel plates disposed in front of the cooling conduit and rear cooling steel plates disposed in the rear of the cooling conduit, The front cooling steel plates and the rear cooling steel plates are mixed air cooling apparatus in the transfer pipe path for the dust collector, characterized in that the different arrangement form. The method of claim 3, wherein The front cooling steel sheets are arranged such that the front and rear directions of the cooling conduits are in the longitudinal direction and the vertical direction of the cooling conduits is in the width direction, The rear cooling steel sheet is a mixed air cooling device in the transport pipe line for the dust collector, characterized in that the front and rear direction of the cooling conduit is arranged in the width direction and the vertical direction of the cooling conduit. The method of claim 4, wherein The front cooling steel plates and the rear cooling steel plates are mixed air cooling apparatus in the transport pipe line for the dust collector, characterized in that arranged in the cross direction along the width direction of the cooling conduit. The method of claim 4, wherein The front cooling steel sheet is a mixed air cooling device in the transport pipe line for the dust collector characterized in that it has a plurality of concave bent portion formed at a predetermined interval along the front and rear direction of the cooling pipe. The method of claim 6, The concave bent portion is a mixed air cooling device in the conveying path for the dust collector, characterized in that the angle between the concave surface and the concave bent surface is 130 ° to 170 °. The method of claim 7, wherein And a length ratio between the concave bent surface and the concave concave surface based on the longitudinal direction of the front cooling steel sheet is 1: 2. The method of claim 1, Cooling device in the transport pipe passage for the dust collector, characterized in that the bottom of the dust deposition portion and the rear bottom of the cooling conduit is provided with a door that is open to collect the accumulated dust. The method of claim 9, In order to prevent the door from being opened for a predetermined angle, the door is equipped with a safety ring connected to one side of the dust accumulation portion or one side of the cooling pipe passage.

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