KR200429976Y1 - Elliptic motion driving apparatus for step screen - Google Patents

Abstract

The present invention uses a cylinder that can transmit a relatively large force to move the moving frame with respect to the fixed frame of the toothed staircase filter, equipped with a pair of cylinders to operate alternately by moving the moving frame up, down, front And a hydraulic toothed filter which can be moved in the rearward direction.

Serrated Cascade Filter, Cylinder

Description

Hydraulic serrated filter {Elliptic motion driving apparatus for step screen}

1 is a perspective view of a cascade filter with an operating device according to the present invention.

Figure 2 is a perspective view showing the outline of the stair filter according to the present invention.

Figure 3 is a plan view showing an installation state of the operating device according to the present invention.

Figure 4 is an exploded perspective view showing a part of the operating device according to the present invention.

5a to 5d is a side view showing an operating state of the operating device according to the present invention.

Figure 6 is a state showing the operation trajectory of the teeth according to the operation of the operating device according to the present invention.

* Explanation of symbols for main parts of drawings *

10: fixed frame 20: moving frame

30: fixed lattice tooth 40: moving lattice tooth

50: driven link unit 100: operating means

110: upper fixing rod 120: upper connecting rod

130: lower mount 140: up and down drive

141: vertical drive cylinder 142: drive shaft

145: link shaft 146: guide member

150: front and rear drive unit 152: front and rear drive cylinder

154: hinge axis

The present invention relates to a hydraulic toothed filter, and more particularly, a cylinder capable of transmitting a relatively large force to move a moving frame relative to a fixed frame of a toothed staircase filter, and alternately provided with a pair of cylinders The present invention relates to a hydraulic toothed filter which allows the movable frame to move in up, down, forward and backward directions.

In general, a step screen that removes contaminants mixed in wastewater flowing through sewage inlet, such as a sewage terminal treatment plant or industrial wastewater treatment plant, has several lattice teeth having a certain angle so that the contaminants can be lifted and mounted. The lattice processed in the step shape is alternately arranged in the moving structure and the fixed structure so that the moving lattice, which is the moving structure among the lattice boards, can be lifted one by one step continuously in order to transfer the caught impurities. It is designed to be lifted and cleaned to the post-treatment process without disturbance or leakage of the hand as it is.

In particular, an elliptic drive type hydraulic serrated filter has been pre- filed by the applicant.

That is, Korean Patent Registration No. 0265245, registered by the applicant, relates to an elliptical drive type hydraulic toothed filter which can lift and remove contaminants mixed in wastewater flowing through a water channel structurally without restriction on installation conditions. Even if the installation angle of the screen forms a steep slope of 45 ° or more with respect to the channel floor by allowing the movable grid to be elliptical, the inclined surface of each lattice tooth is formed above the installation angle of the screen so that the waste water can be formed on the movable grid formed with a long step depth. To make sure that the contaminants of the car are lifted and transported as it is, and the rotary motion of the drive rotary cam connected to the power transmission side of the drive motor is operated as the horizontal motion of the horizontal eccentric shaft and the vertical motion of the vertical eccentric shaft. An elliptic motion driving unit generating an elliptic motion while being synthesized, and the elliptic motion Was characterized by a steep slope consists of a movable grating coupled to move, copy and the elliptical motion of the eastern column portion of the driven link uniformly elliptical motion with respect to the longitudinal direction.

However, the conventional elliptic drive type hydraulic toothed filter has a structure that allows the lattice teeth to ellipse movement by connecting the eccentric rotation cam with the lattice teeth, but the cam is easily broken because the relatively heavy lattice teeth must be lifted through the cams. There was a problem.

The present invention was devised to solve the above problems, the object of the present invention is to move the moving frame forward and backward to move the moving frame relative to the fixed frame of the staircase filter and the moving frame in the up and down direction The present invention provides a hydraulic sawtooth filter for providing a moving cylinder and alternately moving the moving frame along a trajectory of a substantially parallelogram as the cylinders alternately operate.

The present invention for achieving the above object is an upper fixing rod for connecting the inner side of the upper end of the fixed frame as the operation means, and an upper connecting rod for connecting the upper end of the pair of moving frames respectively provided on both sides of the fixed frame And a lower fixing stand which is formed inside the fixing frame at a position higher than the upper connecting stand and is spaced apart from the upper fixing stand, and is constrained by an operation hole which is connected to the upper fixing stand and formed in a rectangle on an opposite side of the fixing frame. An up-and-down driving part for reciprocating the moving frame in the height direction of the fixed frame, and interposed between the upper connecting rod and the lower fixing stand to operate alternately with the upper and lower driving parts, and during operation, the moving frame moves in the longitudinal direction of the fixed frame. Hydraulic Serrated Filtration with Reciprocating Forward and Backward Drive The intended offer.

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

1 is a perspective view of a staircase filter having an operating device according to the present invention, Figure 2 is a perspective view showing the outline of the staircase filter according to the present invention, Figure 3 is a plan view showing an installation state of the operating device according to the present invention to be.

And, Figure 4 is an exploded perspective view of the main portion showing a part of the operating device according to the present invention, Figures 5a to 5d is a side view showing the operating state of the operating device according to the present invention, Figure 6 of the operating device according to the present invention This is a state diagram showing the operation trajectory of the tooth according to the operation.

As shown in Figure 1 to 3, the hydraulic serrated filter of the present invention is fixed frame 10, moving frame 20, fixed lattice tooth 30, moving lattice tooth 40, operating means 100 And a driven link unit 50.

The fixed frame 10 has a rectangular frame shape forming an outer shape, and is obliquely erected into the water surface in the ground and is fixedly installed.

In addition, the fixing frame 10 forms the extension piece 12 along the longitudinal direction, respectively, on the upper and lower edges of the opposite sides facing each other.

In addition, the fixing frame 10 protrudes from the lower portion of the extension piece 12 formed in the lower rim protruding from the fixing flange 14 to be spaced at a predetermined interval in the longitudinal direction.

That is, a plurality of fixed flanges 14 are formed in pairs facing each other, and each of the fixed flanges 14 is connected to the fixed bar 15.

In addition, the extension piece 12 forms a rectangular insertion hole 13 at regular intervals that do not overlap the fixed flange 14.

In addition, the moving frame 20 has a plate shape provided on each side of the fixed frame 10, one each.

That is, the movable frame 20 is provided between the pair of extension pieces 12 so as not to be integrally formed with the fixed frame 10 so as to be movable.

At this time, the movable frame 20 is not separated in the upper and lower directions of the fixed frame 10 by the extension pieces 12 on both sides.

In addition, the fixing frame 10 forms the operation hole 16 on both sides facing each other, and the moving frame 20 is connected to the connection hole 23 at a position coinciding with the operation hole 16 of the fixing frame 10. ).

In addition, the moving frame 20 is formed to protrude the moving flange 22 at a predetermined interval and inserted into the insertion hole 13, respectively.

Here, the insertion hole 13 is formed in a rectangle having a length similar to the moving distance of the moving frame 20.

As the moving frame 20 is provided with a pair, the moving flanges 22 are provided in pairs facing each other, and the pair of moving flanges 22 are connected by the moving bars 24.

In addition, the fixed lattice tooth 30 is arranged side by side at least one inside the fixed frame (10).

At this time, the fixed grid tooth 30 is fixed because the fixed bar 15 is formed integrally with the welding bar 15, or the like.

In addition, the mobile lattice tooth 40 is provided between the fixed lattice tooth 30, and has the same shape as the fixed lattice tooth 30.

In particular, since the moving grid tooth 40 is formed integrally with the moving bar 24, the moving lattice 40 moves in the same trajectory as the moving bar 24.

By means of the operation means 100 of the present invention, the moving grid tooth 40 continuously draws a substantially parallelogram trajectory so that foreign matters in the water surface are gradually pulled out of the water surface.

On the other hand, the operating means 100 transmits a force so that the upper portion of the moving frame 20 can continuously move along the parallelogram trajectory.

At this time, the operation means 100 is largely composed of the upper fixing unit 110, the upper connecting rod 120, the lower fixing unit 130, the upper and lower driving unit 140 and the front and rear driving unit 150.

In particular, the fixing frame 10 reinforces the inside of the rectangular frame shape, and has a blocking plate 17 to block the operation means 100 from the fixed lattice tooth 30 and the moving lattice tooth 40.

The blocking plate 17 prevents foreign substances being pulled upward through the fixed lattice tooth 30 and the moving lattice tooth 40 to prevent the foreign substances from being introduced into the operating means 100 and moves the moving lattice tooth 40. By splashing water serves to prevent the flow into the operating means (100).

On the other hand, the upper fixing stand 110 is formed on the upper end portion of the inner surface facing the fixing frame 10, both ends are fixed to the inner surface of the fixing frame 10.

The upper connecting rod 120 connects the upper end of the moving frame 20 to move the pair of moving frames 20 at the same speed and the same trajectory.

In addition, the lower fixing stand 130 is formed at a position spaced apart from the upper fixing stand 110 of the fixing frame 10 by a predetermined interval in the longitudinal direction.

That is, the lower fixing stand 130 is installed to be fixed to the opposite sides of the fixing frame 10 at positions adjacent to the blocking plate 17, respectively.

At this time, the upper and lower driving unit 140 and the front and rear driving unit 150 of the operating means 100 is formed between the upper fixing unit 110 and the lower fixing unit 130.

In addition, the vertical drive unit 140 serves to raise and lower the moving frame 20 in the height direction of the fixed frame 10 with respect to the fixed fixed frame 10.

At this time, the up and down drive unit 140 is composed of a vertical drive cylinder 141, drive shaft 142, link shaft 145 and the guide member 146.

In particular, the connection relationship between the vertical drive unit 140 is shown in FIG.

The up-and-down driving cylinder 141 is a cylinder that is operated by a normal hydraulic pressure, while reducing the generation of noise during operation, and can transmit sufficient forward and backward force to the moving frame 20.

The driving shaft 142 simultaneously inserts both ends into the operating hole 16 of the fixed frame 10 and the connecting hole 23 of the moving frame 20, respectively.

In addition, the vertical drive cylinder 141 and the drive shaft 142 is connected to the link shaft 145 in order to convert the front and rear vibration of the vertical drive cylinder 141 to the rotational force to the drive shaft 142.

That is, the drive shaft 142 is fixedly installed so as to extend in the upper direction so as not to rotate the link shaft 145, the end of the link shaft 145 is rotatably coupled to the vertical drive cylinder 141.

Thus, when the vertical driving cylinder 141 is operated and repeatedly operated, the link shaft 145 rotates in an arc trajectory, and the drive shaft 142 rotates by the same rotation angle as the link shaft 145. .

At this time, since both ends of the drive shaft 142 is rotated in contact with the inner peripheral surface of the insertion hole 13 of the fixed frame 10 and the connecting hole 23 of the moving frame 20 at the same time, the friction force is large. .

Accordingly, the driving shaft 142 inserts bearings 143 at both ends thereof to minimize frictional forces with the inner surfaces of the operating hole 16 and the connecting hole 23.

In addition, the drive shaft 142 is exposed to the outside of the moving frame 20 because it is inserted into the operating hole 16 and the connecting hole 23 at the same time.

Thus, the movable frame 20 is to protect the drive shaft 142 by fastening the protective cap 144 to the outside with a screw (144a) and to prevent injuries of workers.

In addition, since the protective cap 144 is detachable as the protective cap 144 is coupled to the movable frame 20 by the screw 144a, the movable shaft can be easily separated.

In particular, the operating hole 16 and the connection hole 23 is formed in a rectangular shape to change the position of the drive shaft 142 to adjust the distance between the vertical drive cylinder 141 and the drive shaft 142.

On the other hand, the guide member 146 serves to reciprocate the moving frame 20 in the height direction of the fixed frame 10 by the operating force of the up and down drive cylinder 141.

At this time, the guide member 146 is composed of a guide block 147 and a guide rail 149.

The guide block 147 is formed in a rectangular parallelepiped shape and inserts one end portion into the driving shaft 142.

At this time, the guide block 147 and the drive shaft 142 is coupled by the boss 148, so that the guide block 147 is rotated in the same direction at the same rotational speed as the drive shaft 142.

In particular, the guide block 147 is eccentrically rotated because the guide block 147 is coupled to the drive shaft 142 biased.

The guide rail 149 is formed at an upper edge of the connection hole 23 of the moving frame 20.

In this case, the guide block 147 rotates eccentrically between the guide rails 149 and repeatedly contacts the upper side, and the moving frame 20 is repeatedly raised as the guide rail 149 is lifted.

Thus, the moving frame 20 is moved up and down by the guide block 147.

In particular, the guide block 147 is fixed to the boss 148 after inserting the pin 148a on the opposite side of the drive shaft 142 and the coupling portion, the bearing 143 is inserted into the pin 148a.

The bearing 143 fitted to the pin 148a is positioned inside the connection hole 23 of the moving frame 20 to reduce frictional force when contacted.

In addition, the drive shaft 142 is provided with a support plate (144b) to prevent swinging when rotating by the vertical drive cylinder 141.

The support plate 144b is fitted to the drive shaft 142 and is integrally connected to the inside of the fixed frame 10.

On the other hand, the front and rear drive unit 150 serves to reciprocate the moving frame 20 in the longitudinal direction of the fixed frame (10).

At this time, the front and rear drive unit 150 is composed of a front and rear drive cylinder 152 and the hinge shaft 154.

The front and rear drive cylinder 152 is connected to the upper connecting rod 120 and the lower fixing rod 130 located at different heights.

That is, when the front and rear drive cylinder 152 is supported by the lower fixing rod 130 to push or pull the upper connecting rod 120, the moving frame 20 continuously in the extension piece 12 of the fixed frame 10 You will move forward and backward.

At this time, since the position of the moving frame 20 is changed by the operation of the up and down driving cylinder 141, the front and rear driving cylinder 152 moves the moving frame 20 in the front and rear directions when the moving frame 20 It may cause distortion of the connection with the.

Thus, the hinge shaft 154 is formed at the connecting portion of the front and rear drive cylinder 152 and the upper connecting rod 120 and the front and rear driving cylinder 152 and the lower fixing rod 130, the upper connecting rod 120 and the lower fixing rod. 130 is a height difference.

The hinge shaft 154 hinges the front and rear drive cylinder 152 to the upper connecting rod 120 and the lower fixing rod 130.

On the other hand, the up and down driving cylinder 141 and the front and rear driving cylinder 152 is operated alternately once, accordingly, the moving frame 20 is moved along a substantially parallelogram trajectory.

5A to 5D illustrate the trajectory of the moving frame 20 that is moved due to the operation of the up and down drive cylinders 141 and the front and back drive cylinders 152.

That is, in the initial state (Fig. 5a) in which the up and down drive cylinder 141 and the front and rear drive cylinder 152 does not operate, the guide block 147 moves the guide rail 149. As it is pushed up, the moving frame 20 rises upward (Fig. 5b).

Then, when the front and rear drive cylinder 152 moves forward after completion of the forward and downward drive cylinder 141, the moving frame 20 moves backward in the raised state (FIG. 5C).

In addition, when the front and rear drive cylinder 152 completes the operation forward, when the vertical drive cylinder 141 completes the reverse operation, the moving frame 20 is in contact with the guide rail 149 guide block 147 It is lowered by the arc trajectory motion of (Fig. 5D).

Finally, as the front and rear drive cylinder 152 moves backward, the moving frame 20 moves forward and becomes an initial state (FIG. 5A).

At this time, the actuating means 100 is provided inside the upper end of the fixed frame 10 to operate to directly transfer the operating force to the upper end of the moving frame 20.

Thus, each of the movable frames 20 has a driven link unit 50 connecting the upper end and the lower end.

The driven link unit 50 is, as is known, the first link support 52 is formed on each of the upper end and the lower end of the movable frame 20, it is connected to each of the first link support 52 Forming a second link support 53 at a position maintaining a predetermined angle with each of the first link support 52, and extending the link arm 54 in a linked state. Linking Combine.

In addition, the connecting arms 56 are connected to the driven arm 58 by link coupling.

Thus, since the upper end and the lower end of the movable frame 20 are mutually restrained by the driven link unit 50, the actuation force of the actuating means 100 can be reliably transmitted to the lower end of the movable frame 20.

As a result, as the moving frame 20 moves along the parallelogram trajectory by the operating means 100 having the above components, the moving lattice 40 connected to the moving frame 20 moves along the same trajectory. The foreign material in the water is gradually pulled up.

FIG. 6 shows the trajectory of the mobile lattice tooth 40 provided between the fixed lattice teeth 30.

On the other hand, the number of the up and down drive cylinder 141 and the front and rear drive cylinder 152 depends on the force required to move the moving grid tooth (40).

As described above, the hydraulic serrated filter according to the present invention generates noise during operation through a cylinder reciprocating up and down and a cylinder reciprocating forward and backward to move the moving frame along a parallelogram trajectory with respect to the fixed frame. It is effective in reducing power and delivering a certain power.

Claims (7)

The fixed bars connected to the fixed flanges formed to correspond to each other to the bottom of the fixed frame with a fixed bar, and connected to the movable flanges formed to correspond to each other to the bottom of the movable frame formed on each side of the fixed frame, respectively, the fixed bars arranged side by side It is provided with a fixed lattice teeth on the moving bar provided on the moving bar, the hydraulic means for transmitting the operating force evenly to the entire moving bar through the driven link portion while moving the moving frame along the parallelogram trajectory by the operation means. In the sawtooth filter, The actuating means includes an upper fixing rod connecting the inner side of the upper end of the fixing frame; An upper connecting rod connecting upper ends of the pair of moving frames respectively provided at both sides of the fixed frame; A lower fixing stand formed on an inner side of the fixing frame so as to be spaced apart from the upper fixing stand in the longitudinal direction of the fixing frame; An upper and lower driving part connected to the upper fixing stand and restrained by an operation hole formed in a rectangular shape on an opposite side of the fixing frame to reciprocate the moving frame in the height direction of the fixing frame during operation; Hydraulic serrated filtration is interposed between the upper connecting rod and the lower fixing rod and alternately operates with the upper and lower driving units, and includes a front and rear driving unit for reciprocating the movable frame in the longitudinal direction of the fixed frame during operation. group. The method of claim 1, The up and down drive unit and the up and down drive cylinder is rotatably coupled to the upper fixing stand; A drive shaft rotatably inserted into an operation hole of the fixed frame and a connection hole of the movable frame connected thereto; A link shaft coupled to an end of the up and down drive cylinder and fixedly coupled to the drive shaft to reciprocate along an arc path with respect to the drive shaft when the up and down drive cylinder is operated; Hydraulic serrated filter is formed on both sides of the fixed frame is composed of a guide member for reciprocating up and down the moving frame during operation of the vertical drive cylinder. The method of claim 2, The guide member includes a guide block fixedly inserted at both ends of the drive shaft and eccentrically symmetric with the link shaft when the drive shaft is rotated by the operation of the up and down drive cylinders;   Hydraulic serrated filter is provided on the upper edge of the connecting hole of the movable frame to repeatedly lift the movable frame in the height direction of the fixed frame consists of a guide rail repeatedly contacted during the eccentric movement of the guide block. . The method of claim 2, The drive shaft is a hydraulic toothed filter, characterized in that to prevent the friction between the operating hole and the inner circumferential surface of the connecting hole when the bearing is inserted. The method of claim 2 or 3, The movable frame is detachably installed on the outer surface to prevent the outer exposure of the drive shaft; The drive shaft is a hydraulic toothed filter characterized in that it is inserted into a support plate extending from the fixed frame to prevent the swing during rotation and to distribute the lateral pressure applied to the fixed frame. The method of claim 1, The front and rear drive unit and the front and rear drive cylinder for moving the moving frame in the front and rear direction relative to the fixed frame during operation by connecting the upper connecting rod and the lower fixing rod located at different heights; A hydraulic toothed filter is formed on the connecting portion of the upper connecting rod and the front and rear drive cylinders and the lower fixing rod and the front and rear drive cylinders and configured to have a hinge shaft for preventing mutual twisting during operation of the front and rear drive cylinders. The method of claim 1, The fixed frame is a hydraulic sawtooth filter, characterized in that it comprises a blocking plate to block the transmission of the foreign matter by partitioning the up and down drive unit and the front and rear drive unit with the fixed grid tooth and the mobile grid tooth.

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