JP2012096184A - Dust collection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a dust collection system which can reduce the consumption of nonflammable powder (a nonflammable agent) and has a compact structure.SOLUTION: The dust collection system includes a dust generation source surrounding hood, a dust collection hood with a nonflammable agent spray unit which is communicated/connected with the dust generation source surrounding hood, and a dust collector communicated/connected with the dust collection hood with the nonflammable agent spray unit through a connection duct. The dust collection hood with the nonflammable agent spray unit has a dust collection hood which transports dust in the vertical direction, a dust collection duct which is communicated/connected with the side surface of the dust collection hood and transports the dust in the horizontal direction, and a nonflammable agent spray unit which is communicated/connected with the side surface of the dust collection duct, stores the nonflammable agent, and sprays the nonflammable agent. The nonflammable agent spray unit has a nonflammable agent stirring means which sprays compressed air and has a tube made of a flexible material.

Description

  The present invention sprays a non-combustible agent to prevent the occurrence of a fire in a dust collector or a duct, and supplies the non-combustible agent into the duct. A dust collecting hood with a non-combustible agent spray unit is installed upstream of the dust collector. Related dust collection system.

  Conventionally, when a combustible dust such as magnesium is transported together with a transport gas and collected in a dust collection pipe, in order to reduce the possibility of dust explosion, a non-combustible powder is placed in the dust collection pipe in the first step. A dust collection method and a dust collection device for circulating a contained gas and then circulating a carrier gas containing the combustible dust in the dust collecting pipe in the second step are known (for example, Patent Documents). 1).

Japanese Patent Laid-Open No. 2001-17815

  However, the thing of patent document 1 is combustible dust which the quantity of the nonflammable powder in the gas containing nonflammable powder distribute | circulated per said 1st process is distribute | circulated per said 2nd process by volume ratio. This is 3 to 15 times the amount of combustible dust in the contained carrier gas, and there is a problem that the amount of consumption of the noncombustible powder is large. In addition, there is a problem that the apparatus becomes large including the dust collecting pipe.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a dust collection system having a compact structure while reducing the consumption of non-combustible powder (non-combustible agent).

  In order to achieve the above object, a dust collection system of the present invention includes a dust generation source surrounding hood that surrounds a dust generation source, and a dust collection hood with a non-combustible agent spray unit that is connected to the dust generation source surrounding hood. A dust collector connected to the dust collection hood with the incombustible spray unit via a connection duct, wherein the dust collection hood with the non-combustible spray unit is generated at the dust generation source. A dust collection hood that conveys dust in the vertical direction together with a carrier gas, and a dust collection duct that communicates with the side surface of the dust collection hood and communicates the dust in a horizontal direction with the carrier gas, and communicates with a side surface of the dust collection duct. A flame retardant spraying unit for storing the flame retardant together and spraying the flame retardant, wherein the flame retardant spraying unit jets compressed air and is made of a flexible material. Characterized by comprising a non-combustible agitating means having a drive.

  In the dust collection system of the present invention, the precoat agent supply device in which the precoat agent is stored is communicated with the dust collector, and the precoat agent supply device and the incombustible agent agitation means are connected to the compressed air source via the same on-off valve. The precoat agent is supplied from the precoat agent supply device to the dust collector and sprayed with the incombustible agent at the same time by communicating and opening the on-off valve.

  The present invention relates to a dust generation source surrounding hood surrounding a dust generation source, a dust collection hood with a non-combustible spray unit connected to the dust generation source surround hood, and a duct connected to the dust collection hood with the non-combustible spray unit A dust collection system having a dust collector connected to each other via a dust collection hood, wherein the dust collection hood with the non-combustible agent spray unit conveys dust generated in the dust generation source together with a carrier gas in a vertical direction. A hood, connected to a side surface of the dust collection hood, and a dust collection duct for conveying the dust in a horizontal direction together with a carrier gas; and connected to a side surface of the dust collection duct and storing a non-combustible agent. A flame retardant spraying unit for spraying the flame retardant, wherein the flame retardant spray unit includes a flame retardant stirring means for injecting compressed air and having a tube made of a flexible material. Since the, and the like various effects which can be dust collection system compact structure it is possible to reduce the consumption of non-combustible material.

1 is a schematic configuration diagram showing a first embodiment of the present invention. It is an expansion perspective view of a dust collection hood with a nonflammable agent spray unit. It is a schematic block diagram which shows 2nd Embodiment of this invention.

  First, a first embodiment of the present invention will be described in detail with reference to the drawings. In FIG. 1, a processing machine (automatic welding machine in the present embodiment), that is, a dust generation source 101 is surrounded by a dust generation source surrounding hood 102, and an incombustible spray is applied to the top surface of the dust generation source surrounding hood 102. A dust collection hood A with a unit is installed. A dust collector 104 (in this embodiment, a dry dust collector) is connected to the dust collection hood A with the incombustible spray unit via a connection duct 103.

  Next, the dust collection hood A with the incombustible agent spray unit will be described in detail with reference to FIG. FIG. 2 is an enlarged perspective view of a dust collection hood A with a non-combustible agent spray unit. In FIG. 2, a dust collection hood 1 that conveys dust generated by the dust generation source 101 in the vertical direction together with a carrier gas is connected to an upper surface of the ceiling of the dust generation source surrounding hood 102. Is communicated with the dust generating source surrounding hood 102 through the lower end opening 1a.

A dust collection duct 2 that conveys the dust in the horizontal direction together with a carrier gas is connected to one side surface of the dust collection hood 1, and the dust collection duct 2 is connected to the dust collection duct 2a through one end opening 2a. The dust hood 1 communicates. The other end opening 2 b of the dust collection duct 2 communicates with the dust collector 104 via the connection duct 103. As can be seen from this, the dust collection hood A with the non-combustible agent spray unit is installed upstream of the dust collector 104.

Further, a nonflammable agent spraying unit 3 for storing the nonflammable agent F (calcium carbonate in this embodiment) and spraying the nonflammable agent F is connected to a side surface orthogonal to the one end opening 2a of the dust collecting duct 2. The one end side surface of the incombustible spray unit 3 is connected to one side surface of the dust collection hood 1. A side opening 3a is provided on a side surface orthogonal to one end side surface of the incombustible spray unit 3, and the incombustible spray unit 3 is communicated with the dust collecting duct 2 through the side opening 3a. ing.

Further, a flame retardant stirring means 4 is suspended from the lower surface of the ceiling in the flame retardant spraying unit 3, and the flame retardant stirring means 4 includes a plurality of tubes 4a made of a flexible material at the tip. The tube 4a has one end fixed, and the other end (the most advanced side) can move freely. The incombustible agent stirring means 4 is communicated with a compressed air source (not shown) via an on-off valve 105 (not shown in FIG. 2; see FIG. 1), and compressed air is supplied to the incombustible agent stirring means 4. If it does, compressed air will be injected from the said tube 4a, and the other end of the said tube 4a will move irregularly (move). Thereby, the incombustible agent F stored in the incombustible material spraying unit 3 is sprayed.

In addition to the above-mentioned calcium carbonate, incombustible agent F in the present invention, for example, zeolite, perlite, glass powder, quartz sand, dry concrete powder, limestone powder, pumice powder, borax, diatomaceous earth, celite, cement, slaked lime , Dry clay, feldspar, dry salt, bentonite, silica.

The operation of the apparatus configured as described above will be described. First, when the dust generation source 101, that is, the processing machine is operated, dust is generated, so that the dust collector 104 is operated. Then, the dust in the dust generating source surrounding hood 102 is sucked into the dust collecting hood 1 through the lower end opening 1 a of the dust collecting hood 1 by the suction force of the dust collector 104, and in the dust collecting hood 1. It is conveyed in the vertical direction together with the carrier gas.

Thereafter, the dust in the dust collection hood 1 is sucked into the dust collection duct 2 through the one end opening 2 a of the dust collection duct 2, and is conveyed in the horizontal direction together with the carrier gas in the dust collection duct 2. In the incombustible stirring means 4, the on-off valve 105 communicated with the incombustible stirring means 4 opens for a few seconds (5 seconds in this embodiment) at regular intervals (every 28 minutes in this embodiment). While the on-off valve 105 is open, compressed air is supplied to the incombustible material agitating means 4, and the compressed air is injected from the tube 4a and the other end of the tube 4a moves irregularly (runs out). Thereby, the incombustible agent F stored in the incombustible agent spraying unit 3 is sprayed.

Then, the sprayed incombustible agent F is sucked into the dust collection duct 2 through the side surface opening 3 a of the incombustible agent spray unit 3 and mixed with the dust in the dust collection duct 2. Thereafter, the mixed dust and incombustible agent F are sucked into the dust collector 104 together with the carrier gas through the other end opening 2 b of the dust collection duct 2 and the connection duct 103.

  Next, a second embodiment of the present invention will be described with reference to FIG. In the second embodiment, a precoat agent supply device 106 in which a precoat agent P (calcium carbonate in this embodiment) is stored is provided. The precoat agent supply device 106 communicates with the connection duct 103 via the supply pipe 107 and communicates with the dust collector 104 via the connection duct 103. The precoat agent supply device 106 is communicated with an on-off valve 105 communicated with the incombustible agent stirring means 4, and is communicated with a compressed air source (not shown) via the on-off valve 105.

  The above points are the differences in configuration from the first embodiment. Other than this, the configuration is the same as that of the first embodiment. In addition, about the same component as 1st Embodiment, it shall show with the same code | symbol and shall abbreviate | omit the description.

The operation of the second embodiment configured as described above is basically the same as that of the first embodiment. However, when the on-off valve 105 is opened, compressed air is supplied to the incombustible material stirring means 4 and the incombustible material F stored in the incombustible material spraying unit 3 is sprayed, and at the same time, the precoat material supply device 106 is compressed. Air is supplied and the precoat agent P is supplied from the precoat agent supply device 106 to the dust collector 104. This point is different from the first embodiment.

As the precoat agent P in the present invention, in addition to the above-described calcium carbonate, for example, zeolite, perlite, glass powder, quartz sand, dry concrete powder, limestone powder, pumice powder, borax, diatomaceous earth, celite, cement, slaked lime , Dry clay, feldspar, dry salt, bentonite, silica.

In the present invention, the incombustible spray unit 3 includes the incombustible stirring means 4 for injecting compressed air and having a tube 4a made of a flexible material. For this reason, when compressed air is supplied to the incombustible agent stirring means 4, the compressed air is injected from the tube 4 a and the other end of the tube 4 a moves irregularly and is stored in the incombustible agent spray unit 3. The fuel F is stirred and sprayed. As a result, the agitated and sprayed incombustible agent F uniformly forms a layer of the incombustible agent F in the dust collection duct 2 and the connection duct 103 along the flow of the airflow. There is an effect that the consumption of F can be reduced.

In the present invention, the dust collection duct 2 is connected in communication with the side surface of the dust collection hood 1, and the nonflammable agent spray unit 3 is connected in communication with the side surface of the dust collection duct 2. It is a dust system.

  Further, in the present invention, the precoat agent supply device 106 in which the precoat agent P is stored is communicated with the dust collector 104, and the precoat agent supply device 106 and the incombustible agent stirring means 4 are connected to the compressed air via the same on-off valve 105. Since the precoat agent P is supplied from the precoat agent supply device 106 to the dust collector 104 and the incombustible agent F is sprayed at the same time by opening the on-off valve 105, the open / close valve used is connected. There is an effect that the number of valves can be reduced and the air piping can be simplified.

In the first and second embodiments of the present invention, as shown in FIG. 2, the side surface of the dust collection hood 1 to which the dust collection duct 2 is connected in communication and the bottom surface of the dust collection duct 2 form a right angle. With this configuration, it is possible to prevent fire types (for example, spatter) generated at the dust generation source from directly entering the dust collecting duct 2, and to further increase the probability of fire occurrence in the dust collector and the duct. Since it can reduce, it is preferable.

  Moreover, in 1st and 2nd embodiment of this invention, supply of the nonflammable agent F in the nonflammable agent spraying unit 3 opens the inspection door 3b (refer FIG. 2) provided in this nonflammable agent spraying unit 3, I try to supply from there. However, the present invention is not limited to this, and the incombustible agent spraying unit 3 is connected to an incombustible agent feeding means (not shown) via a supply pipe (not shown), and the incombustible agent F is supplied by the incombustible agent feeding means. You may make it supply in the flame retardant spraying unit 3 by pumping.

DESCRIPTION OF SYMBOLS 1 Dust collection hood 2 Dust collection duct 3 Flame retardant spraying unit 4 Flame retardant stirring means 4a Tube 101 Dust generation source 102 Dust generation source surrounding hood 103 Connection duct 104 Dust collector 105 On-off valve 106 Precoat agent supply unit A Collection with flame retardant spray unit Dust hood F Flame retardant P Precoat agent

Claims (2)

A dust generation source surrounding hood surrounding the dust generation source, a dust collection hood with a non-combustible spray unit connected to the dust generation source surrounding hood, and a communication duct connected to the dust collection hood with the non-combustible spray unit A dust collection system comprising: a connected dust collector;
The dust collection hood with an incombustible spray unit is connected in communication with a dust collection hood that conveys dust generated in the dust generation source along with a carrier gas in a vertical direction, and is connected to a side surface of the dust collection hood, and the dust together with the carrier gas. A dust collection duct that is transported in a horizontal direction, and a non-combustible spray unit that sprays the non-combustible agent together with a non-combustible agent that is connected to a side surface of the dust collection duct.
The dust collection system, wherein the flame retardant spraying unit includes a flame retardant stirring means for injecting compressed air and having a tube made of a flexible material. A precoat agent supply device in which a precoat agent is stored is communicated with the dust collector, and the precoat agent supply device and the incombustible agent agitation means are communicated with a compressed air source through the same on-off valve to open the on-off valve. The dust collection system according to claim 1, wherein the precoat agent is supplied from the precoat agent supply device to the dust collector and the incombustible agent is sprayed simultaneously.