KR102243084B1 - Dust removing machine - Google Patents

Abstract

The present invention relates to a dust removing device (10), capable of improving the removal efficiency of impurities, which comprises: a frame (200); a guide rail (300); a plurality of main screens (400); a plurality of potential screens (500); a rake (100); an endless chain (700); a driving motor (800); a conveyor (900); a socket part (140); a reinforcing plate (150); a moving block (160); and a guide rod (170).

Description

Dust removing machine

The present invention relates to a vibration damper, and more particularly, improved so that all of the moved impurities fall onto the conveyor when the rake that moves the impurities filtered by the main screen and the front screen while rotating during the operation of the vibration damper falls onto the conveyor at the top and rear of the vibration damper. It is about a vibration damper.

In general, a vibration damper is installed in various open channels such as a drainage treatment plant, a water intake plant, a sewage treatment plant, and a related water channel to improve water quality. The vibration damper is widely used as a device for removing impurities such as plastic containers, plastic bags, bottles, cans, trees, construction wastes, etc. that have been pushed along with water.

A general vibration isolator uses a screen installed in the water to filter out impurities, and a rotary that moves the impurities caught on the screen by pulling them up onto the water surface using several scrapers that move up and down the screen, and then moving the scraper back into the water under the screen. It is adopting the method.

Conventional rotary type vibration dampers include a frame installed on the waterway wall and a guide rail installed on the frame, a main screen installed between the frames to filter out impurities floating along with the water current, and the impurities caught on the screen while moving up and moving in front of the main screen. Consists of a roll-up rake or scraper.

According to such a conventional rotary type vibration damper, among impurities that are pushed down along with the water current, impurities smaller than the interval of the screen bar pass through, and only impurities larger than the interval of the screen bar are filtered through the main screen, the front of the screen is removed. It is scraped with the rake that moves upward and is discharged to the outside through a discharge conveyor installed at the rear of the main screen.At this time, foreign substances are gradually accumulated through continuous trajectory movement as foreign substances are caught in the rake shape of the rake and transported. There is a problem that the ability is deteriorated.

1. Korean Patent Application Publication No. 10-2020-0042686 (Name of invention: Vibrator with improved removal function of impurities) 2. Korean Patent Registration No. 10-1575784 (Name of invention: Vibrator with variable main screen structure) 3. Korean Patent Registration No. 10-2152401 (Name of invention: Vibrator with auxiliary lake)

An object of the present invention for solving the above problems is the space of the outer rake bar constituting the rake when the rake that moves impurities filtered by the main screen and the front screen while rotating while the vibration isolator is dropped onto the conveyor at the top and rear of the vibration isolator. By installing a structure to forcibly discharge the impurities caught in the part, all of the moved impurities fall onto the conveyor.

In order to achieve the above object, the present invention provides a frame installed on both side walls of a waterway or river, a guide rail installed inside the frame, and a plurality of filters installed between the frames to filter out impurities floating along with the water flow. Of the main screen, a plurality of dislocation screens installed at the front bottom of the main screen to filter impurities passing between the main screen and the bottom surface of the waterway, a rake that transports impurities filtered by the dislocation screen and the main screen in one direction, impurities An apron for guiding the filtered rake to the rear to collect impurities, an endless chain installed on both guide rails to continuously rotate the rake, and a driving motor that transmits driving force to the rotation shaft of a sprocket that rotates by being engaged with the endless chain. , In a vibration damper configured as a conveyor for collecting and transporting impurities fallen to the rear of the apron in one direction,

The rake has a flat support bar having a horizontal length and a shape protruding to a predetermined vertical length along the horizontal length of the rear end of the support bar, and the support bar has a plurality of inner rake bars formed at equal intervals and the outer teeth of the inner rake bar. It provides a vibration damper having a structure including a plurality of outer rake bars formed at equal intervals while having a shape extending to a predetermined vertical length along the shear transverse length.

On the other hand, it is coupled to the lower portion of the support bar of the rake and has a length corresponding to the horizontal length of the support bar and is connected to and bent at one end to the horizontal portion attached and fixed to the lower surface of the support bar. A “a”-shaped socket part formed by an extended vertical part,

One side of the vertical part of the socket part and one side of the outer rake are connected together to the bottom of the outer rake bar of the rake to correspond to the number of outer rake bars and formed at equal intervals. It provides a vibration damper further comprising a reinforcing plate formed in a right-angled triangular shape in which the other side coupled to the lower surface of the bar is orthogonal to each other.

On the other hand, a guide hole is formed inside the other side of the reinforcing plate in a direction corresponding to the longitudinal direction of the outer rake bar with a predetermined length,

It is located between the reinforcing plate and the reinforcing plate, and a plurality of them are installed on the rake, and are connected to one side of the outer circumference so as to protrude into the second space between the outer rake bar and the outer rake bar while the insertion hole penetrated to the left and right is formed. A cylindrical moving block in which a protruding moving tab is formed,

It provides a vibration damper including a guide rod that passes through the guide hole of the reinforcing plate and is inserted into the insertion hole of the moving blocks disposed between the outer rake bars.

When the vibration isolator of the present invention is rotated while moving the impurities filtered on the main screen and the front screen, the rake is forcibly discharged from the space of the outer rake bar constituting the rake when the rake is dropped onto the conveyor at the top and rear of the vibration damper. It also has the effect of improving the efficiency of removing the impurities by installing a structure that moves all of the impurities that have been moved down to the conveyor.

1 is a side view of a vibration damper according to the present invention.
Figure 2 is a view showing the front of the vibration damper according to the present invention.
3 is an enlarged view of a portion in which a sprocket in which an interlocking pulley is disposed is located in a vibration damper according to the present invention.
4 is a view showing a rake structure in a state in which a socket part and a reinforcing plate are installed in the vibration damper according to the present invention.
5 is a separate coupling diagram in which a socket portion and a reinforcing plate are coupled to a rake in a vibration damper according to the present invention.
6 is a view showing a structure in a state in which a moving block and a guide rod are installed in a rake in which a socket part and a reinforcing plate are installed in the vibration damper according to the present invention.
7 is a separate coupling diagram in which a movable block and a guide rod are coupled to a rake to which a socket portion and a reinforcing plate are coupled in the vibration damper according to the present invention.
8 is a view showing the structure of a moving block in the vibration damper according to the present invention (a), a separate drawing in which a rotation supporter is coupled between the moving blocks (b), and a front view in which a connection pipe is coupled between the moving blocks (c). ).

Hereinafter, a preferred embodiment of a vibration damper according to the present invention will be described in detail with reference to the accompanying drawings.

The vibration damper 10 according to a preferred embodiment of the present invention includes a frame 200 installed on both side walls of a waterway or a river, as shown in FIGS. 1 and 2, and a guide rail installed inside the frame 200 ( 300), a plurality of main screens 400 installed between the frames 200 and for filtering out impurities floating along with the water current, and installed at the front and lower ends of the main screen 400 and between the main screen 400 and the waterway. A plurality of dislocation screens 500 for filtering impurities passing between the bottom surface, a rake 100 for transferring impurities filtered by the dislocation screen 500 and the main screen 400 in one direction, and the rake 100 in which impurities are filtered ) Guided to the rear to collect impurities, an apron 600 for collecting impurities, an endless chain 700 for continuously rotating the rake 100 by being installed on the both guide rails 300, and meshing with the endless chain 700 A drive motor 800 that transmits a driving force to the rotation shaft 830 of the rotating sprocket 820, and a conveyor 900 for collecting and transporting impurities that have fallen to the rear of the apron 600 in one direction.

As shown in Figs. 1 and 2, the vibration damper 10 of the present invention is installed in a waterway or river to filter impurities, and is vertically inclined at the edge of a waterway or river, and is spaced apart from each other by a certain distance, and is vertically inclined. A pair of frames 200 to be installed and a guide rail 300 are installed inside each of the frames 200, and the pair of frames 200 are spaced apart from each other at a certain distance at the edge of a waterway or river, and are vertical The rake 100 installed in the space between the frame 200 is installed to have a high slope from the bottom to the top, and moves upward along the main screen 400 and the front screen 500 While doing so, lift the impurities and drop the impurities while moving downwards.

The main screen 400 is installed between the frames 200 on both sides and is for filtering out impurities floating along with the water current, and the interval between neighboring main screens 400 is easily adjusted to Regardless of the size of the contaminants for the contaminants of the micro or large contaminants that are sequentially floated, the collection efficiency can be remarkably increased throughout the contaminants.

In addition, the plurality of potential screens 500 are installed at the front bottom of the main screen 400 to filter impurities passing between the main screen 400 and the bottom surface of the waterway.

In addition, the rake 100 is to transport the impurities filtered by the front screen 500 and the main screen 400 in one direction, and the apron 600 guides the rake 100 through which the impurities are filtered to the rear. It is a structure to collect impurities.

In addition, the endless chain 700 is installed on both guide rails 300 provided inside the both frames 200 to continuously rotate the rake 100, and the drive motor 800 is the endless chain ( The driving force is transmitted to the rotation shaft 830 of the sprocket 820 that is engaged with and rotates 700, and the conveyor 900 collects and transports impurities that have fallen to the rear of the apron 600 in one direction.

Although the main screen 400 may have a fixed structure, the vibration isolator 10 according to the present invention may have a variable structure to correspond to the size of the above-described impurities.

As shown in FIG. 3, looking at the transmission structure of the driving force for rotational driving to repeatedly circulate the rake 100, the drive shaft 810 of the drive motor 800 is a rotation shaft 830 that rotates the sprocket 820. ) To rotate the rotation shaft 830 interlockingly, but an interlocking pulley 821 provided on one side of the rotation shaft 830 of the sprocket 820 and a driving pulley 811 provided on one side of the drive shaft 810 Is connected to the connection belt 840 and rotated interlockingly.

And, as shown in Figs. 4 and 5, the rake 100 has a flat support bar 110 having a horizontal length and a shape protruding to a predetermined vertical length along the horizontal length of the rear end of the support bar 110. In order to correspond to the external teeth of the inner rake bar 120 and the inner rake bar 120 formed in a plurality of equal intervals, while having a shape extending to a predetermined vertical length along the front end horizontal length of the support bar 110, at equal intervals. It has a structure consisting of a plurality of outer rake bars 130 formed.

The inner lake bar 120 passes between the main screen 400, and in this case, a plurality of screen bars having a predetermined vertical length are formed in a horizontal arrangement at equal intervals between the screen bar and the screen bar. The inner rake bar 120 passes, and a first space portion 121 is formed between the inner rake bar 120 and the inner rake bar 120 to move the screen bar along the main screen 400. It is located in the space, and impurities filtered by the electric potential screen 500 installed in the front and lower part of the vibration isolator 10 are caught by the outer rake bar 130 of the rake 100, and at this time, the electric potential screen 500 The outer lake bar 130 passes between the vertical screen bar and the screen bar constituting it.

In addition, the outer rake bar 130 may have a shape having an end inclined at a predetermined inclination while being disposed to face the position of the inner rake bar 120, and the length of the outer rake bar 130 is an inner rake It may have a longer length than the length of the bar 120.

And, as shown in Figures 4 and 5, coupled to the lower portion of the support bar 110 of the rake 100, while having a length corresponding to the horizontal length of the support bar 110, the lower surface of the support bar 110 A "b"-shaped socket part 140 formed of a horizontal part 141 that is attached and fixed to the horizontal part 141 and a vertical part 142 that is bent connected at one end to the horizontal part 141 and extended to a predetermined vertical length,

It is connected to one surface of the vertical part 142 of the socket part 140 and the lower surface of the outer rake bar 130 of the rake 100 together to correspond to the number of the outer rake bar 130, forming a plurality at equal intervals And, a reinforcing plate 150 formed in a right-angled triangular shape in which one side coupled to one side of the vertical portion 142 of the socket unit 140 and the other side coupled to the lower surface of the outer rake bar 130 are mutually orthogonal is further provided. It provides the included vibration damper (10).

As the socket portion 140 and the reinforcing plate 150 are coupled to the rake 100, the rigid support of the rake 100 for moving impurities having a heavy load is increased, while maintaining a structural stability.

The socket part 140 is coupled to the lower part of the support bar 110 of the rake 100, and at this time, the support bar 110 facing if the end of the outer rake bar 130 is inclined above the support bar 110 ), the socket portion 140 is mounted, and the socket portion 140 has a shape of a single body formed of a “b” shape formed of a horizontal portion 141 and a vertical portion 142, and the horizontal portion ( 141 is fastened and fixed to the lower portion of the support bar 110.

The reinforcing plate 150 has a number corresponding to the number of the outer rake bars 130 and the vertical portion 142 of the socket unit 140 and the lower surface of the outer rake bar 130 A reinforcing plate 150 that has a structure that is attached and fixed at the same time and is coupled to one side of the reinforcing plate 150 coupled to one surface of the vertical portion 142 of the socket unit 140 and the lower surface of the outer rake bar 130 The other side of the reinforcing plate 150 has a right-angled triangular shape because they are orthogonal to each other.

And, as shown in Figs. 6 to 8, a guide hole 151 penetrating a predetermined length in a direction corresponding to the longitudinal direction of the outer rake bar 130 is formed inside the other side of the reinforcing plate 150, ,

Located between the reinforcing plate 150 and the reinforcing plate 150, a plurality of pieces are installed on the rake 100, and the left and right insertion holes 161 penetrated into the inside are formed, while the outer rake bar 130 and the outer rake bar (130) A cylindrical moving block 160 formed with a moving tab 162 protruding to a predetermined length by being connected to one surface of the outer circumference so as to protrude into the second space 131 between,

A vibration damper including a guide rod 170 that passes through the guide hole 151 of the reinforcing plate 150 and is inserted into the insertion hole 161 of the moving blocks 160 disposed between the outer rake bars 130 ( 10).

The apron when the impurities fall onto the conveyor 900 of the vibration damper 10 by installing a guide rod 170 on the rake 100 that simultaneously inserts the moving blocks 160 and binds the moving blocks 160 in a horizontal arrangement. (600) While moving the impurities by the rake 100 to the rear, impurities are caught in the second space part 131 formed between the outer rake bar 130 and the outer rake bar 130 of the rake 100 and do not fall. The problem of moving along the guide rail 300 as it is, and to solve the problem, an integrated unit consisting of the moving block 160 and the guide rod 170 is included.

The movable block 160 is located between the reinforcing plate 150 and the reinforcing plate 150, but both sides of the movable block 160 are not in close contact with the reinforcing plate 150 and are disposed to be spaced apart. When the guide rod 170 moves along the guide hole 151 of ), the moving block 160 is also freely moved at the same time.

7 and 8 (a), the movable block 160 is cylindrical and has an insertion hole 161 penetrating left and right inside, and a movable tab 162 protruding upward in the center of the outer circumferential surface At this time, the moving tab 162 is introduced into the second space portion 131 formed between one outer rake bar 130 and the other outer rake bar 130 adjacent to the one outer rake bar 130 The second space part 131 is formed to protrude upward.

When the moving tab 162 of the moving block 160 is located in the second space part 131 of the rake 100 and the guide rod 170 moves along the guide hole 151 of the reinforcing plate 150, the guide hole It moves along the second space part 131 having a longitudinal direction corresponding to the length direction of 151, and at this time, the moving tab 162 moves while maintaining a state protruding upward from the second space part 131. .

The guide rod 170 is a round bar type having a horizontal length that binds a plurality of moving blocks 160 located under the rake 100 while passing through the guide hole 151 of the reinforcing plate 150, and at this time, the guide Forming the outer diameter of the guide rod 170 corresponding to the cross-sectional shape of the insertion hole 161 while the inner diameter of the insertion hole 161 of the moving tab 162 has a circular, triangular or square cross-sectional shape on the rod 170 do.

In addition, as shown in (b) of FIG. 8, the outer circumferential surface of the guide rod 170 on which the moving tab 162 is located has a shape corresponding to the cross-sectional shape of the insertion hole 161, while the guide of the reinforcing plate 150 The outer circumferential surface of the guide rod 170 located in the ball 151 has a circular cross-sectional shape so that when it moves along the guide hole 151 of the reinforcing plate 150, it can move freely without interference. A rotation supporter 163 that freely rotates around the outer periphery of the guide rod 170 when moving along the guide hole 151 while being bound to the outer periphery of the guide rod 170 located in the guide hole 151 is further supported. Can be included.

In addition, as shown in (c) of FIG. 8, a connection pipe 164 is provided that is disposed between the movable block 160 and the movable block 160 to connect to each other, and the inside of the connection pipe 164 is movable. As a through hole (not shown) communicating with the insertion hole 161 of the block 160 is formed, it has the same inner diameter as the inner diameter of the insertion hole 161, and the outer diameter cross section of the connector 164 has a circular or rectangular shape. I can.

In addition, when the rake 100 moves along the guide rail 300 and is located at the top where the conveyor 900 is located, the rake 100 has an outer rake bar 130 and an upper portion at the lower portion based on the support bar 110. The inner rake bar 120 is positioned vertically, and at this time, the guide hole 151 of the reinforcing plate 150 is positioned vertically and guided by the load of the moving blocks 160 bound to the guide rod 170. It is moved downwards along the ball 151, and at this time, the impurities inserted or introduced into the second space part 131 of the rake 100 are guided to fall through the open space 131-1 of the second space part 131. do.

And, as shown in Figure 7 is bound to the outer periphery of the guide rod 170 located on the outside of the reinforcing plate 150 located at both ends of the rake 100 to prevent the separation of the guide rod 170 and prevent A cylindrical fixing block 180 is provided, and has the same inner diameter as the inner diameter of the insertion hole 161 of the movable block 160 and penetrates left and right into the inside of the fixing block 180 to insert the guide rod 170 Have.

In addition, when the rake 100 moves along the guide rail 300 and is positioned above the conveyor 900, the guide rod 170 of the rake 100 is rotated by the rotation of the rotation shaft 830 of the sprocket 820. The following structure is further included so as to forcibly move along the guide hole 151 of the reinforcing plate 150.

As shown in Figs. 1, 3, and 6, a disk-shaped rotating plate 850 is coupled and fixed to both ends of the rotating shaft 830 located inside the sprocket 820, and to one surface of the outer circumferential end of the rotating plate 850. Protruding pressing tabs 851 are formed, and at this time, when the rake 100 is vertically positioned on the top of the conveyor 900, the pressing tabs 851 of the rotating plate 850 press both ends of the guide rod 170, respectively. Let's do it.

That is, the rotating plate 850 is fixed to the rotating shaft 830 located inside the sprocket 820 and disposed close to the inner side of the sprocket 820 to rotate simultaneously with the rotation of the rotating shaft 830 without interference with the sprocket 820 that is rotated. At this time, a pressing tab 851 protruding from one surface of the outer circumferential end of the rotating plate 850 is formed, and the pressing tab 851 of the rotating plate 850 is vertically positioned at the top of the conveyor 900. When the state is formed, the pressing tabs 851 of the rotating plate 850 press both ends of the guide rod 170 to forcefully move along the guide hole 151.

In addition, a pressing tab (not shown) protrudes from the inner surface of the sprocket 820 without installing the rotating plate 850, and at this time, the sprocket 820 rotates when the rake 100 is positioned above the conveyor 900. Pressing tabs (not shown) formed on the inner surface press the both ends of the guide rod 170 of the rake 100 to forcibly move along the guide hole 151 and the moving block 160 along the second space 131 The moving tab 162 of is forcibly moved.

The above description is merely illustrative of the technical idea of the present embodiment, and those of ordinary skill in the art to which the present embodiment pertains will be able to make various modifications and variations without departing from the essential characteristics of the present embodiment. Accordingly, the present embodiments are not intended to limit the technical idea of the present embodiment, but to explain the technical idea, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of this embodiment should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present embodiment.

Vibrator 10 Rake 100 Support Bar 110
Inner lake bar 120 Outer lake bar 130 Space part 131
Socket part 140 Horizontal part 141 Vertical part 142
Reinforcement plate 150 Guide hole 151 Moving block 160
Insertion hole 161 Moving tap 162 Rotary supporter 163
Connector 164 Guide bar 170 Frame 200
Guide rail 200 Main screen 400 Front screen 500
Apron 600 Endless chain 700 Drive motor 800
Drive shaft 810 Drive pulley 811 Sprocket 820
Driving pulley 821 Rotating shaft 830 Connecting belt 840
Rotary plate 850 Pressurized tap 851

Claims (5)

A frame 200 installed on both side walls of a waterway or river, a guide rail 300 installed inside the frame 200, and a plurality of installed between the frames 200 to filter out impurities floating along with the water flow. Of the main screen 400, a plurality of potential screens 500 installed at the front bottom of the main screen 400 to filter impurities passing between the main screen 400 and the bottom surface of the waterway, and the potential screen 500 And while having a flat support bar 110 of horizontal length and a shape protruding to a predetermined vertical length along the horizontal length of the rear end of the support bar 110 to transport the impurities filtered in the main screen 400 in one direction, etc. A plurality of inner rake bars 120 formed at intervals and a plurality of equal intervals having a shape extending to a predetermined vertical length along the front end horizontal length of the support bar 110 so as to correspond to the external teeth of the inner rake bar 120 A rake 100 composed of an outer rake bar 130 formed of dogs, an apron 600 for collecting impurities by guiding the rake 100 from which impurities are filtered to the rear, and installed on the guide rails 300 on both sides of the rake ( The endless chain 700 for continuous rotation of 100), a driving motor 800 that transmits a driving force to the rotation shaft 830 of the sprocket 820 that rotates while being engaged with the endless chain 700, and the apron 600 In the vibration damper 10 consisting of a conveyor 900 for collecting and transporting impurities that have fallen to the rear in one direction,
A horizontal portion 141 attached to and fixed to the lower surface of the support bar 110 while being coupled to the lower portion of the support bar 110 of the rake 100 and having a length corresponding to the horizontal length of the support bar 110 and the A "b"-type socket part 140 formed of a vertical part 142 that is connected to the horizontal part 141 and bent at one end and extended to a predetermined vertical length; and,
It is connected to one surface of the vertical part 142 of the socket part 140 and the lower surface of the outer rake bar 130 of the rake 100 together to correspond to the number of the outer rake bars 130, and a plurality of them are formed at equal intervals. And, one side coupled to one side of the vertical portion 142 of the socket unit 140 and the other side coupled to the lower surface of the outer rake bar 130 are formed in a right-angled triangle shape that is orthogonal to each other, while the outer rake inside the other side A reinforcing plate 150 having a guide hole 151 penetrating a predetermined length in a direction corresponding to the longitudinal direction of the bar 130 is formed; And,
Located between the reinforcing plate 150 and the reinforcing plate 150, a plurality of pieces are installed on the rake 100, and an insertion hole 161 penetrating the left and right inside is formed while the outer rake bar 130 and the outer rake bar A cylindrical moving block 160 having a moving tab 162 protruding to a predetermined length by being connected to one surface of the outer circumference so as to protrude into the second space 131 between the 130; And,
A guide rod 170 that passes through the guide hole 151 of the reinforcing plate 150 and is inserted into the insertion hole 161 of the moving blocks 160 disposed between the outer rake bars 130; A vibration damper, characterized in that it has. delete delete The method of claim 1,
When the rake 100 moves along the guide rail 300 and is located at the top where the conveyor 900 is located, the rake 100 has an outer rake bar 130 at the bottom and an inner side at the top based on the support bar 110. The rake bar 120 is positioned vertically, and at this time, the guide hole 151 of the reinforcing plate 150 is positioned vertically, and the guide hole ( A vibration damper, characterized in that it moves downward along the 151). The method of claim 1,
When the rake 100 moves along the guide rail 300 and is positioned above the conveyor 900, the guide rod 170 of the rake 100 is forced by the rotation of the rotation shaft 830 of the sprocket 820. Each disc-shaped rotating plate 850 is coupled and fixed to both ends of the rotating shaft 830 located inside the sprocket 820 so as to move along the guide hole 151 of the furnace reinforcing plate 150, A pressing tab 851 protruding on one side of the outer circumferential end is formed,
At this time, when the rake 100 is vertically positioned on the top of the conveyor 900, the pressing tab 851 of the rotating plate 850 presses the both ends of the guide rod 170, respectively.

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