KR102511254B1 - Eco-friendly vacuum blasting system exclusively for steel structure background treatment - Google Patents

Abstract

The present invention relates to an eco-friendly vacuum blast system dedicated to the background treatment of steel structures. In order to improve the structure to connect an intake port of a vacuum generator to a recycling module to suck in waste abrasives, and connect an exhaust port of the vacuum generator to a blast head to output compressed air to compactly form a blast main body and the recycling module into one piece, and to enable blasting work to be performed efficiently in a narrow space including the lower part of the bridge, the main components of the eco-friendly vacuum blast system of the present invention comprises a blast body part (100), a blast head part (200), a cover part (300), and a recycling module (400).

Description

Eco-friendly vacuum blasting system exclusively for steel structure background treatment}

The present invention relates to an eco-friendly vacuum blast system dedicated to the background treatment of steel structures, and more specifically, connects the intake port of a vacuum generator to a recycling module to suck in waste abrasives, and connects the exhaust port of the vacuum generator to the blast head to output compressed air It relates to an eco-friendly vacuum blasting system dedicated to the ground treatment of steel structures, which can efficiently perform blasting in a narrow space including the lower part of a bridge, by improving the structure so as to compactly form the blast body and the recycling module integrally.

Blast is a processing method of trimming or cutting the surface of a material by spraying an abrasive from a nozzle, and is widely used for various tasks such as rust removal, surface contamination removal, protrusion removal, adhesion or pretreatment of plating.

Accordingly, in Patent Registration No. 10-2132382 disclosed in the prior art, a spray nozzle for removing the painted surface by spraying sand on a painted surface by an operator; and a suction unit positioned at the lower end of the spray nozzle to suck the sprayed sand and paint residues; , Hood portion for restraining them in a shape surrounding the injection nozzle and the suction portion, respectively; and an observation screen perforated in the hood portion and formed as a transparent window; and a hand grip for transporting the injector portion formed outside the hood portion; and a sand hopper in which sand is stored; and a sand hopper connected to a transfer pipe for supplying sand to the spray nozzle of the spray device unit; and the sand hopper A compression pump for supplying sand to the injection nozzle through a transfer pipe; and a supply device provided as a supply device driving unit for moving the sand; and a suction pipe for transporting sand and paint residue sucked through the suction part of the injection device;, a dust collecting material storage unit in which sand and paint residues are collected through the suction pipe; and an air intake pump equipped with a dust collector filter; and a dust collector unit provided as a dust collector driving unit for moving the same; a technique consisting of a previously proposed bar.

However, the prior art is intended to minimize environmental or civil complaints by preventing dust and contaminants generated during the paint removal operation from scattering, but since the supply unit and the dust collector unit are operated independently and separately, the narrow working space at the bottom of the bridge It was impossible to apply to the spray device, and a lot of force was required for operation due to the volume of the hood installed in the spray device, and the paint removal operation could not be performed even in a narrow area such as the corner due to the interference of the hood.

KR 10-2132382 B1 (2020.07.03.)

Accordingly, the present invention has been conceived to solve the above problems, and the suction port of the vacuum generator is connected to the recycling module to suck in the waste abrasive, and the exhaust port of the vacuum generator is connected to the blast head to output compressed air. Structure improvement The purpose is to provide an eco-friendly vacuum blast system dedicated to the ground treatment of steel structures that can efficiently perform blast work in a narrow space including the lower part of the bridge, while compactly forming the blast body and the recycling module as an integral unit. there is.

The features of the present invention to achieve this object, the blast head portion 200 is provided with a nozzle 210 to output the abrasive at high pressure together with the compressed air output through the blast body portion 100; a cover part 300 installed to cover the spray hole 210 and provided to recover waste abrasives scattered after colliding with a workpiece; and a recycling module 400 connected to the cover part 300 to suck in the waste abrasive and supply the waste abrasive to the blast head part 200 again.

At this time, the cover part 300 is provided with a brush module 310 at the front end corresponding to the workpiece, and the brush module 310 is a flat processing type in which elastic hairs are circularly arranged on a plane, and at least one inclined protrusion. It is characterized in that the elastic hair is formed in a corner type along.

In addition, the cover part 300,

A cover body 320 in which a cutout 322 is formed to accommodate a plate-shaped workpiece and a pair of blast head parts 200 are installed at an inclined angle on both sides;

A brush module 310 installed in the incision groove 322 of the cover body 320 and in close contact with the plate-shaped workpiece;

Includes a guide roller 330 installed on the cover body 320 corresponding to both ends of the incision groove 322 and transported on a plate-shaped workpiece,

A plate-shaped workpiece is inserted into the incision groove 322 of the cover body 320, and while moving along the plate-shaped workpiece using the guide roller 330, the abrasive is output from both sides through the blast head unit 200, , The waste abrasive is characterized in that it is provided to be suctioned and recovered through the recycle module 400 connected to the cover body 320.

In addition, the blast head part 200 is provided to blast the workpiece disposed on the floor while being moved by the driving module 250,

The driving module 250,

A clamp 252 mounted on the blast head part 200;

A driving wheel 254 supported by a support arm 253 extending from the clamp 252 and rotatably disposed at the distal end of the blast head 200;

Including a handle bar 255 extending upward from the clamp 252,

It is characterized in that when holding the handlebar 255 and pushing or pulling, the blast head 200 is moved along the driving wheel 254 to blast the workpiece disposed on the floor.

In addition, the blast head unit 200 is connected to an air gun 220 equipped with a nozzle stand 222 for spraying compressed air and a nozzle stand 222 of the air gun 220, and the abrasive material is blown by compressed air injection pressure. It is characterized in that it includes an injector module 230 for inhaling and mixing the output through the injection hole 210.

In addition, the injector module 230 has a rod hole 232 into which the nozzle rod 222 is inserted at one end, a clamp 234 is installed at the end of the rod hole 232, and the air gun 220 nozzle rod. 222 is characterized in that it is provided to be fastened by the clamp 234 in a state inserted into the rod hole 232.

In addition, the blast body part 100 has one end connected to the vacuum generator 110 in which the intake port 112 and the exhaust port 114 are formed, and the exhaust port 114 of the vacuum generator 110, and the other end connected to the air gun 220, an air output line 120 for outputting the compressed air discharged from the exhaust port 114 to the air gun 220 side, and a filter installed at the intake port 112 of the vacuum generator 110 to filter the air. It includes a cartridge 130 and a vacuum chamber 140 installed in the intake port 112 area of the vacuum generator 110 including the filter cartridge 130, and the recycling module 400 includes a vacuum chamber 140 A container 410 installed inside, open to communicate with the intake port 112 of the vacuum generator 110, and in which the waste abrasive is stored, one end communicates with the container 410, and the other end communicates with the cover. A suction line 420 connected to the unit 300 to suck waste abrasives, one end communicating with the lower part of the container 410, and the other end connected to the injector module 230 to resupply the waste abrasive supply line ( 430).

In addition, the blast body part 100 is connected to the cover part 300, a suction line 150 for sucking the waste abrasive, and a vessel connected to the suction line 150 to separate and store the waste abrasive ( 161) is provided, a filtration module 170 removes foreign substances from the air discharged through the sorting module 160, and a vacuum generator connected to the filtration module 170 to suck air ( 180), and the recycling module 400 mixes the waste abrasive stored in the vessel 161 with compressed air and supplies it to the nozzle 210 side of the blast head 200. Including a pressure line 440 characterized by

In addition, in the sorting module 160, the inner space is divided by the inner hopper 162, and the sorting space part 163 is formed on the upper part and the vessel 161 is formed on the lower part, and on the sorting space part 163, The sorting chamber 164 provided with the inlet and output ports 164a and 164b at the bottom, and the inside of the sorting chamber 164 are arranged at a downward inclination angle to each other, and contained in the air introduced through the input port 164a. A sorting net 165 that separates the waste abrasives by conveying them downward in a zigzag direction, and is installed at the outlet 162a of the inner hopper 162 and is opened and closed by a valve to sort compressed air output from the vacuum generator 180. It is characterized in that it includes a pop-up nozzle 166 for spraying upward toward the space portion 163.

In addition, the pressure line 440 is connected to the vacuum generator 180 and the compressor through a distribution pipe 442, and compressed air supplied from at least one of the vacuum generator 180 and the compressor is supplied by a valve operation to the pressure line. It is characterized in that it is provided to be supplied to (440).

In addition, the brush module 310 is provided so that the rotation angle is variable on the cover part 300 by the turning module 500, and the turning module 500 is formed at an inclination angle on the outer circumferential surface of the cover part 300 The cam rail 510, the cam pin 520 formed on the inner circumferential surface of the brush module 310 so as to be engaged with the cam rail 510 for inclined movement, and installed on the outer circumferential surface of the cover part 300 to move the brush module 310 in all directions. It includes an elastic body 530 provided to pressurize, and when the blast head part 200 is pressed toward the workpiece while the blast head part 200 is moved and the blast work is performed, the cam pin 520 moves the cam rail 510 ), the brush module 310 rotates while tilting, and the waste abrasive remaining in the area of the brush module 310 on the opposite side to the moving direction of the blast head 200 is located by the turning operation of the brush module 310 It is characterized in that it is provided to be moved and recovered to the recycling module 400 side.

According to the above configuration and operation, the present invention connects the inlet of the vacuum generator to the recycling module to suck in the waste abrasive, and connects the outlet of the vacuum generator to the blast head to output compressed air, thereby improving the structure so that the blast body and In addition to forming the recycling module compactly in one piece, there is an effect of efficiently performing the blasting operation in a narrow space including the lower part of the bridge.

1 and 2 are configuration diagrams showing an eco-friendly vacuum blast system dedicated to the ground treatment of steel structures according to an embodiment of the present invention as a whole.
3 to 4 are configuration diagrams showing an eco-friendly vacuum blasting system dedicated to the ground treatment of steel structures according to another embodiment of the present invention as a whole.
5 is a configuration diagram showing a brush module of an eco-friendly vacuum blast system dedicated to the background treatment of steel structures according to an embodiment of the present invention.
Figure 6 is a block diagram showing a modified example of the cover portion of the eco-friendly vacuum blast system dedicated to the background treatment of steel structures according to an embodiment of the present invention.
7 is a block diagram showing a driving module of an eco-friendly vacuum blast system dedicated to the background treatment of steel structures according to an embodiment of the present invention.
8 is a block diagram showing a turning module of an eco-friendly vacuum blast system dedicated to ground treatment of steel structures according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in the description of the present invention, if it is determined that the related known function may unnecessarily obscure the subject matter of the present invention as an obvious matter to those skilled in the art, the detailed description thereof will be omitted.

1 and 2 are schematic diagrams showing an eco-friendly vacuum blast system exclusively for ground treatment of steel structures according to an embodiment of the present invention, and FIGS. 3 and 4 are eco-friendly vacuum blast systems exclusively for ground treatment of steel structures according to another embodiment of the present invention. Figure 5 is a configuration diagram showing the system as a whole, Figure 5 is a configuration diagram showing the brush module of the eco-friendly vacuum blast system dedicated to the background treatment of steel structures according to an embodiment of the present invention, Figure 6 is the background treatment of steel structures according to an embodiment of the present invention It is a configuration diagram showing a modified example of a cover part of a dedicated eco-friendly vacuum blast system, and FIG. 7 is a configuration diagram showing a driving module of an eco-friendly vacuum blast system dedicated to background treatment of steel structures according to an embodiment of the present invention. FIG. It is a configuration diagram showing the turning module of the eco-friendly vacuum blast system dedicated to the steel structure background treatment according to an embodiment.

The present invention relates to an eco-friendly vacuum blast system dedicated to the background treatment of steel structures, which connects the intake port of a vacuum generator to a recycling module to suck in waste abrasives, and connects the exhaust port of the vacuum generator to the blast head to output compressed air. Structural improvement Thus, the blast main body part 100, the blast head part 200, and the cover to compactly form the blast body part and the recycling module integrally and efficiently perform blast work in a narrow space including the lower part of the bridge. It is a main component including the part 300 and the recycling module 400.

The blast head unit 200 according to the present invention is provided with an injection port 210 to output the abrasive at high pressure together with the compressed air output through the blast body unit 100. Here, the abrasive includes aluminum oxide, glass beads, normal silica sand, and steel grit.

The blast body part 100 is a type that supplies compressed air and abrasive to the blast head part 200 through each line, and a type that supplies compressed air and abrasive to the blast head part 200 in a mixed state. It is distinguished, and a detailed description thereof refers to the description of FIGS. 1 to 4 to be described later.

In addition, the cover part 300 according to the present invention is installed to cover the injection hole 210 and is provided to recover waste abrasives scattered after colliding with a workpiece.

The cover part 300 is formed with a diameter larger than that of the spray hole 210, and is provided with a front end to collect waste abrasives scattered in a state of being in contact with a workpiece.

At this time, the cover part 300 is provided with a brush module 310 at the front end corresponding to the workpiece.

The brush module 310 is formed of a combination of elastic hair, and during the blasting operation, the elastic hair of the brush module 310 is elastically deformed and closely adhered to the surface of an irregular workpiece to prevent the waste abrasive from scattering to the outside.

In addition, the brush module 310 is formed in a flat processing type in which elastic hairs are circularly disposed on a plane as shown in FIG. 5 (a), or has at least one inclined protrusion as shown in FIGS. 5 (b) to 5 (c). Accordingly, the elastic hair is formed in a corner type, FIG. 5 (b) shows an outside corner type, and FIG. 5 (c) is a configuration diagram showing a three-sided corner type.

In FIG. 6, the cover part 300 includes a cover body 320 in which a cutout groove 322 is formed to accommodate a plate-shaped workpiece and a pair of blast head parts 200 are installed at an inclined angle on both sides; The brush module 310 installed in the incision groove 322 of the cover body 320 and in close contact with the plate-shaped workpiece, and the brush module 310 installed on the cover body 320 corresponding to both ends of the incision groove 322 and riding the plate-shaped workpiece It includes a guide roller 330 that is transported.

A plate-shaped workpiece is inserted into the incision groove 322 of the cover body 320, and while moving along the plate-shaped workpiece using the guide roller 330, the abrasive is output from both sides through the blast head unit 200, , The waste abrasive is provided to be suctioned and recovered through the recycle module 400 connected to the cover body 320.

In this way, both sides of the plate-shaped workpiece accommodated in the incision groove 322 of the cover body 320 are simultaneously blasted by the abrasive output from the pair of blast head units 200, thereby reducing working time and reducing the operator's space It has the advantage of being able to work without entering into.

In FIG. 7 , the blast head unit 200 is provided to blast a workpiece disposed on the floor while being moved by the driving module 250 .

The driving module 250 is supported by a clamp 252 mounted on the blast head 200 and a support arm 253 extending from the clamp 252, at the front end of the blast head 200 It includes a driving wheel 254 rotatably disposed and a handle bar 255 extending upward from the clamp 252.

Accordingly, when the nozzle 210 of the blast head 200 is disposed facing the floor, holding the grip bar 255 and pushing or pulling the blast head 200 is moved along the driving wheel 254, The workpiece placed on the floor is simply blasted.

In addition, the recycling module 400 according to the present invention is connected to the cover part 300 to suck in the waste abrasive and then supply it to the blast head part 200 again.

The recycling module 400 is formed integrally with the blast main body 100 and is provided to continuously perform blasting through a circulation cycle of recovering and resupplying waste abrasives.

1 and 2 show an eco-friendly vacuum blasting system dedicated to the background treatment of steel structures according to an embodiment of the present invention as a whole.

1 and 2, the blast head unit 200 is connected to an air gun 220 provided with a nozzle holder 222 for spraying compressed air and a nozzle holder 222 of the air gun 220, compressed air It includes an injector module 230 that sucks in the abrasive by the spray pressure and mixes and outputs the abrasive through the spray hole 210 .

Further, the injector module 230 has a rod hole 232 into which the nozzle rod 222 is inserted is formed at one end, a clamp 234 is installed at the end of the rod hole 232, and the nozzle rod of the air gun 220 222 is provided to be fastened by the clamp 234 in a state inserted into the rod hole 232.

Accordingly, as the blast head part 200 is configured by fitting and coupling the injector module 230 to the nozzle holder 222 of a known air gun 220 distributed on the market, it is coupled to the air gun 220 in use Since it can be used, the cost of facility construction is reduced, and there is an advantage in that it is easy to supply and demand parts in case of failure.

In addition, the blast body part 100 has one end connected to the vacuum generator 110 in which the intake port 112 and the exhaust port 114 are formed, and the exhaust port 114 of the vacuum generator 110, and the other end connected to the air gun 220, an air output line 120 for outputting the compressed air discharged from the exhaust port 114 to the air gun 220 side, and a filter installed at the intake port 112 of the vacuum generator 110 to filter the air. It includes a cartridge 130 and a vacuum chamber 140 installed in the intake port 112 area of the vacuum generator 110 including the filter cartridge 130 .

In addition, the recycling module 400 is installed in the vacuum chamber 140, the upper part is opened to communicate with the intake port 112 of the vacuum generator 110, and the container 410 in which the waste abrasive is stored, One end communicates with the upper part of the container 410 and the other end communicates with the suction line 420 for sucking waste abrasives connected to the cover part 300 and one end communicates with the lower part of the container 410 and the other end communicates with the injector module. It includes a supply line 430 connected to 230 to resupply the waste abrasive.

As such, the intake port 112 of the vacuum generator 110 is connected to the recycling module 400 to suck in the waste abrasive, and the exhaust port 114 of the vacuum generator 110 is connected to the air gun 220 to output compressed air. Because of this configuration, the blast body 100 and the recycling module 400 can be compactly formed integrally.

3 to 4 show an eco-friendly vacuum blast system dedicated to the background treatment of steel structures according to another embodiment of the present invention as a whole.

3 and 4, the blast body part 100 is connected to the cover part 300, is connected to the suction line 150 for sucking the waste abrasive, and the suction line 150, and separates the waste abrasive A sorting module 160 having a vessel 161 for storing and storing, a filtration module 170 for removing foreign substances from the air discharged through the sorting module 160, and connected to the filtration module 170 to clean the air It includes a vacuum generator 180 for suction.

In the sorting module 160, the inner space is divided by the inner hopper 162, and the sorting space part 163 is formed on the upper part and the vessel 161 is formed on the lower part, and the sorting space part 163 is upper and lower. A sorting chamber 164 provided with inlet and output ports 164a and 164b, and waste abrasives contained in the air introduced through the input port 164a and disposed alternately at a downward inclination angle inside the sorting chamber 164 is installed in the discharge port 162a of the inner hopper 162 and the sorting net 165 for separating by downwardly inclined conveying in the zigzag direction, and the compressed air output from the vacuum generator 180 by being opened and closed by the valve is transferred to the sorting space part It includes a pop-up nozzle 166 that sprays upward toward (163).

As such, while the waste abrasive introduced through the inlet port 164a of the sorting space 163 passes through the plurality of sorting nets 165, foreign substances including painting dust pass through the sorting nets 165 and output ports 164b ), and the waste abrasive from which foreign substances are removed is transported downward and stored in the vessel 161 via the inner hopper 162.

In addition, the pop-up nozzle 166 installed at the outlet 162a of the inner hopper 162 periodically sprays compressed air upward to remove waste abrasives and foreign substances caught in the sorting net 165.

In addition, the recycling module 400 includes a pressure line 440 for supplying a mixture of waste abrasives stored in the vessel 161 and compressed air to the nozzle 210 of the blast head 200.

At this time, the pressure line 440 is connected to the vacuum generator 180 and the compressor through the distribution pipe 442, and the compressed air supplied from at least one of the vacuum generator 180 and the compressor by valve operation is supplied to the pressure line. It is provided to be supplied to (440).

As such, since the waste abrasive is sucked by the suction force of the vacuum generator 180 and the pressure line 440 is connected to the exhaust port of the vacuum generator 180 to output compressed air, the blast body 100 and the recycling module ( 400) can be integrally and compactly formed.

In FIG. 8 , the brush module 310 is provided to have a variable rotation angle on the cover part 300 by the swing module 500 .

The turning module 500 includes a cam rail 510 formed at an inclination angle on the outer circumferential surface of the cover part 300, and a cam pin 520 formed on the inner circumferential surface of the brush module 310 so as to be engaged with the cam rail 510 for inclined motion. , It includes an elastic body 530 installed on the outer circumferential surface of the cover part 300 and provided to press the brush module 310 in all directions.

When the blast head part 200 is pressed toward the workpiece while moving the blast head part 200 while performing the blasting operation, as shown in FIG. The brush module 310 rotates.

Accordingly, by the swinging operation of the brush module 310, the waste abrasive remaining in the area of the brush module 310 on the opposite side to the moving direction of the blast head 200 is moved and effectively recovered toward the recycling module 400.

That is, when the blast head 200 is moved in one direction during blasting, the waste abrasive is gathered in the area opposite to the moving direction of the blast head 200 and leaks to the outside through the brush module 310. , When the blast head part 200 is intermittently pressed by the turning module 500, the waste abrasives driven to one side area are moved to a different angle while the brush module 310 rotates There is an advantage in that it is effectively collected and processed. .

As described above, the most preferred embodiment of the present invention has been described in the detailed description of the present invention, but various modifications may be made within a range that does not depart from the technical scope of the present invention. Therefore, the scope of protection of the present invention should not be limited to the above embodiments, but the scope of protection should be recognized from the techniques of the claims to be described later and from these techniques to equivalent technical means.

100: blast body part 200: blast head part
300: cover part 400: recycling module

Claims (12)

A blast head unit 200 provided with an injection hole 210 to output the abrasive at high pressure together with the compressed air output through the blast body unit 100; a cover part 300 installed to cover the spray hole 210 and provided to recover waste abrasives scattered after colliding with a workpiece; And a recycling module 400 connected to the cover part 300 to suck in the waste abrasive and then supply it back to the blast head part 200.
The cover part 300 is provided with a brush module 310 at the front end corresponding to the workpiece,
The cover part 300 includes a cover body 320 in which a cutout groove 322 is formed to accommodate a plate-shaped workpiece and a pair of blast head parts 200 are installed at an inclined angle on both sides, and the cover body 320 The brush module 310 installed in the incision groove 322 of ) and in close contact with the plate-shaped workpiece, and the guide roller installed on the cover body 320 corresponding to both ends of the incision groove 322 and transported along the plate-shaped workpiece including (330);
A plate-shaped workpiece is inserted into the incision groove 322 of the cover body 320, and while moving along the plate-shaped workpiece using the guide roller 330, the abrasive is output from both sides through the blast head unit 200, , The waste abrasive is provided to be sucked and collected through the recycle module 400 connected to the cover body 320.
delete delete delete According to claim 1,
The blast head unit 200 is provided to blast a workpiece disposed on the floor while being moved by the driving module 250,
The driving module 250,
A clamp 252 mounted on the blast head part 200;
A driving wheel 254 supported by a support arm 253 extending from the clamp 252 and rotatably disposed at the distal end of the blast head 200;
Including a handle bar 255 extending upward from the clamp 252,
When holding the handle bar 255 and pushing or pulling, the blast head 200 is moved along the driving wheel 254 and is provided to blast the workpiece disposed on the floor Eco-friendly vacuum for exclusive use of steel structure background treatment blast system.
According to claim 1,
The blast head part 200,
An air gun 220 provided with a nozzle stand 222 for spraying compressed air;
It is connected to the nozzle stand 222 of the air gun 220 and includes an injector module 230 that sucks the abrasive by the compressed air spray pressure and mixes and outputs the mixture through the spray hole 210. blast system.
According to claim 6,
The injector module 230 has a rod hole 232 into which a nozzle rod 222 is inserted at one end, a clamp 234 is installed at an end of the rod hole 232, and the air gun 220 nozzle rod 222 ) is an eco-friendly vacuum blast system dedicated to the steel structure background treatment, characterized in that provided to be fastened by the clamp 234 in a state inserted into the rod hole 232.
According to claim 7,
The blast body part 100,
A vacuum generator 110 in which an intake port 112 and an exhaust port 114 are formed;
An air output line 120 having one end connected to the exhaust port 114 of the vacuum generator 110 and the other end connected to the air gun 220 to output compressed air discharged from the exhaust port 114 to the air gun 220 side. class,
A filter cartridge 130 installed in the intake port 112 of the vacuum generator 110 to filter air;
It includes a vacuum chamber 140 installed in the area of the intake port 112 of the vacuum generator 110 including the filter cartridge 130,
The recycling module 400,
A container 410 installed in the vacuum chamber 140, an upper part open to communicate with the intake port 112 of the vacuum generator 110, and storing waste abrasives therein;
A suction line 420 having one end communicated with the upper part of the container 410 and the other end connected to the cover part 300 to suck waste abrasive;
An eco-friendly vacuum blast system dedicated to ground treatment of steel structures, characterized in that it includes a supply line 430 having one end communicated with the lower portion of the container 410 and the other end connected to the injector module 230 to resupply the waste abrasive.
According to claim 1,
The blast body part 100,
A suction line 150 connected to the cover part 300 and sucking the waste abrasive;
A sorting module 160 connected to the suction line 150 and equipped with a vessel 161 for separating and storing waste abrasives;
A filtration module 170 for removing foreign substances from the air discharged via the sorting module 160;
It includes a vacuum generator 180 connected to the filtration module 170 to suck air,
The recycling module 400 includes a pressure line 440 for mixing waste abrasives stored in the vessel 161 and compressed air and supplying them to the injection port 210 side of the blast head 200 Steel structure base, characterized in that Eco-friendly vacuum blast system dedicated to processing.
According to claim 9,
The selection module 160,
The inner space is divided by the inner hopper 162, the sorting space part 163 is formed at the top and the vessel 161 is formed at the bottom, and the input and output ports 164a ( 164b) is provided with a selection chamber 164;
Separating nets 165 that are staggered with each other at a downward inclination angle inside the sorting chamber 164 and transfer and separate waste abrasives contained in the air introduced through the input port 164a downward in a zigzag direction;
It is installed at the outlet 162a of the inner hopper 162, and includes a pop-up nozzle 166 that is opened and closed by a valve to spray compressed air output from the vacuum generator 180 upward toward the sorting space part 163. Eco-friendly vacuum blast system dedicated to the background treatment of steel structures.
According to claim 10,
The pressure line 440 is connected to the vacuum generator 180 and the compressor through a distribution pipe 442, and compressed air supplied from at least one of the vacuum generator 180 and the compressor is supplied by a valve operation to the pressure line 440. ) Environment-friendly vacuum blast system dedicated to the background treatment of steel structures, characterized in that provided to be supplied.
delete

Images