JP2010106528A - Screen dust collector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To further effectively obtain a cleaning effect by the mechanical cleaning of a screen member. <P>SOLUTION: The screen member 13 is curved to become convex toward an upstream side in a position in which fluid firstly abuts on the screen member 13. A cleaning brush roller 14 is arranged in a position in which chains 9 and 10 are engaged with drive sprockets 3 and 4 for the screen member 13 to change a direction of rotation. A tip of a brush of the cleaning brush roller 14 abuts on the curved convex surface 13b<SB>2</SB>of the rotating screen member 13. Consequently, the sliding friction force of the cleaning brush roller 14 against the convex surface 13b<SB>2</SB>of the screen member 13 can be increased, and the cleaning effect can be more effectively obtained. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a technical field of a screen dust remover that captures and removes dust, such as floating substances present in a fluid and foreign matters, in a fluid by a screen member.

  2. Description of the Related Art Conventionally, various types of screen dust removers have been known, in which dusts such as floating substances on a fluid and foreign matters in the fluid are continuously captured by a plate-like screen member and removed from the fluid. In such a conventional screen dust remover, the screen member is made of punching metal, and the punching metal is attached to the left and right endless chains, and the punching metal is rotated along with the rotation of the chain. It is designed to be captured and transported.

  As such a conventional screen dust remover, a screen dust remover has been proposed in which the punching metal of the screen member is curved so as to protrude downstream of the fluid to increase the strength of the punching metal (for example, see Patent Document 1). ).

JP-A-8-33814.

  Incidentally, in the screen dust remover as described above, a cleaning brush for cleaning the screen member is used in order to remove dust adhering to the screen member. In this case, the screen member is mechanically cleaned by bringing the tip of the cleaning brush into contact with the concave surface of the screen member at a linear portion of the chain, that is, at a position where a plurality of screen members are linearly arranged.

  However, when the cleaning brush is brought into contact with the concave surfaces of the screen members arranged in this way to clean the concave surface of the screen member, the contact pressure of the cleaning brush is small, and the mechanical cleaning effect There is a problem that it may not be possible to sufficiently obtain.

  This invention is made | formed in view of such a situation, The objective is to provide the screen dust remover which can acquire the cleaning effect by the mechanical cleaning of a screen member more effectively.

  In order to solve the above-described problem, a screen dust remover of the present invention includes at least a plurality of screen members arranged endlessly and a cleaning member for cleaning the plurality of screen members, and the plurality of screen members In the screen dust remover that captures dust mixed in the fluid, conveys the captured dust by rotating the plurality of screen members, and removes the conveyed dust from the screen member by the cleaning member, Each of the plurality of screen members is curved around an axis in the width direction of the screen member in a direction orthogonal or substantially orthogonal to the rotation direction, and the curved direction of the screen member is the position of the screen member where the fluid first contacts. Is a direction that is convex toward the upstream side of the fluid, and is in front of the convex surface of the screen member. The cleaning member is characterized in that contact.

In the screen dust remover of the present invention, the curved shape of the screen member is an arc shape of a circle having the same or substantially the same radius as the rotation radius when the plurality of screen members change the rotation direction. It is said.

  Furthermore, the screen dust remover of the present invention is characterized in that the cleaning member abuts on a convex surface of the screen member at a position where the plurality of screen members change the rotation direction.

  Furthermore, the screen dust remover of the present invention is characterized in that the cleaning member is a rotatable cleaning brush roller, and the cleaning brush roller is controlled to rotate in conjunction with the rotation of the plurality of screen members.

  Furthermore, the screen dust remover according to the present invention is characterized in that the cleaning member is a rotatable cleaning brush roller, and the cleaning brush roller is controlled to rotate independently of the rotation of the plurality of screen members.

  Furthermore, the screen dust remover of the present invention is characterized in that a rake for scooping up dust mixed in the fluid is detachably attached to at least a part of the plurality of screen members.

  According to the screen dust remover according to the present invention configured as described above, the plurality of screen members are curved to be convex toward the upstream side of the fluid, and the cleaning member is brought into contact with the convex surface of the screen member. Therefore, the rubbing force of the screen member by the cleaning member can be increased, and dust adhering to the convex surface of the screen can be efficiently removed. Thereby, the cleaning effect by mechanical cleaning of a screen member can be acquired more effectively.

  In addition, by changing the shape of the plurality of screen members to the arc shape of a circle having the same or almost the same radius as the rotation radius when these screen members change the rotation direction, the direction of the plurality of screen members is changed. Sometimes, the plurality of screen members can be positioned in an arc of a circle with a turning radius of the plurality of screen members. Therefore, the rubbing force of the convex surface of the screen member by the cleaning member can be made almost constant. Therefore, stable cleaning of the screen member by the cleaning member can be realized.

  Further, the cleaning member is composed of a cleaning brush roller, and the cleaning brush roller is rotated in conjunction with the rotation of the screen member, so that the cleaning brush roller can be rotated whenever the screen member rotates. Therefore, the dust captured by the screen member can be more reliably removed by the cleaning brush roller.

  Further, the cleaning member is constituted by a cleaning brush roller, and the cleaning brush roller is rotated independently of the rotation of the screen member, so that the rotation speed and rotation direction of the screen member, the rotation speed and rotation direction of the cleaning brush roller, and Can be controlled differently. As a result, the cleaning effect by the cleaning brush roller can be obtained according to the use environment of the screen dust remover, the adhesion state of the screen member, and the like.

  Furthermore, detachable attachment of a rake that scoops up the dust mixed in the fluid to at least a part of the plurality of screen members allows the dust flowing by the fluid to be captured by the screen member and scooped up by the rake. It becomes. Therefore, the effect of removing dust in the fluid can be further increased.

Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view showing an example of an embodiment of a screen dust remover according to the present invention.
As shown in FIG. 1, the screen dust remover 1 of this example has a frame body 2. A pair of left and right drive sprockets 3 and 4 and a pair of left and right driven sprockets 5 and 6 are rotatably attached to the frame body 2. In this example, the drive sprockets 3 and 4 and the driven sprockets 5 and 6 are all formed in the same size. The pair of left and right drive sprockets 3 and 4 are integrally rotated by a rotating shaft 7, and the pair of left and right driven sprockets 5 and 6 are integrally rotated by a rotating shaft 8.

The rotary shafts 7 of the drive sprockets 3 and 4 are rotationally driven by a motor 7 that is a drive device. An endless chain 9 is stretched over the left drive sprocket 3 and the driven sprocket 5, and an endless chain 10 is also stretched over the right drive sprocket 4 and the driven sprocket 6. Both the left and right chains 9, 10 have the same configuration. Therefore, the left chain 9 will be described. As shown in FIG. 2A, the chain 9 has a large number of links 11 connected to each other by connecting pins 12 in an endless manner.

  In this case, of the links 11 adjacent to each other, the connecting edge 11a of one link 11 is formed as a circular arc-shaped convex portion centering on the connecting pin 12, and the connecting edge 11b of the other link 11 is connected. It is formed in a circular arc-shaped recess having a circle centered on the pin 12. And the connection edge 11a of a circular-arc-shaped convex part is made to slide relatively. Thereby, the adjacent links 11 smoothly rotate relative to each other. The connecting pin 12 engages with the teeth of the drive sprocket 3 and also engages with the driven sprocket 5. Similarly, the connecting pin 12 of the right chain 10 engages with the teeth of the drive sprocket 4 and engages with the driven sprocket 6.

As shown in FIGS. 3 (a) to 3 (d), a plate-like screen member 13 is constructed for each pair of left and right links 11 corresponding to the left and right chains 9, 10. The screen member 13 consists of a rectangular support frame 13a, a screen 13b consisting of plate-shaped punching metal having a plurality of holes 13b _1. As shown in FIG. 3 (e), the screen member 13 is bent in the direction perpendicular to the rotation direction β of the screen member 13 and around the axis in the width direction of the screen member 13 (upward in FIG. 3 (e)). Has been improved.

In that case, the bending direction of the screen member 13 is curved in an arc shape so as to protrude upstream with respect to the fluid flowing direction α (shown in FIG. 1). Further, as shown in FIGS. 2A and 2B, the radius of curvature of the screen member 13 is substantially the same as the turning radius when the chains 9 and 10 rotate in the driving sprockets 3 and 4 and the driven sprockets 5 and 6. Is set. Therefore, the chains 9, 10 are connected to the drive sprockets 3, 4 and the driven sprockets 5,
When rotating by 6, the screen members 13 connected to each other draw a circular arc centered on the rotation shafts 7 and 8.

Furthermore, the screen dust remover 1 has a rake 20 that scoops up dust flowing by the fluid, as shown in FIGS. 1 and 3A to 3C and 3E. The rake 20 is formed in a comb-like shape and is detachably provided on the punching metal of the screen 13b.

As shown in FIGS. 1 and 2B, a cleaning brush roller 14 is disposed at a position where the chains 9 and 10 engage with the drive sprockets 3 and 4 and the screen member 13 changes the rotation direction. The brush tip of the cleaning brush roller 14 is in contact with the curved convex surface 13b ₂ of the rotating screen member 13.

Further, a brush roller drive sprocket 15 is provided on the rotating shaft 7 of the drive sprockets 3 and 4. On the other hand, the rotating shaft 14 a of the cleaning brush roller 14 is provided with a brush roller driven sprocket 16 having a smaller diameter than the brush roller driving sprocket 15. An endless chain 17 is stretched between the brush roller drive sprocket 15 and the brush roller driven sprocket 16. Therefore, when the rotary shaft 7 rotates clockwise in FIG. 1 and the drive sprockets 3 and 4 rotate clockwise, the brush roller drive sprocket 15 also rotates at the same speed. That is, the cleaning brush roller 14 is controlled to rotate in conjunction with the rotation of the screen member 13.

The rotation of the brush roller drive sprocket 15 is accelerated and transmitted to the brush roller driven sprocket 16 via the endless chain 17. As a result, the brush roller driven sprocket 16 rotates clockwise as indicated by the arrow γ, so that the cleaning brush roller 14 rotates. As a result, the brush tip of the cleaning brush roller 14 rubs against the curved convex surface 13b ₂ of the screen member 13. Thereby, the cleaning brush roller 14 efficiently removes dust adhering to the convex surface 13b _{2 of the} screen 13b.

In that case, the rotation direction of the cleaning brush roller 14 is the same clockwise as the rotation direction of the screen member 13. In other words, at the contact portion between the screen member 13 and the cleaning brush roller 14, the tangential movement direction of the screen member 13 and the tangential movement direction of the cleaning brush roller 14 are opposite to each other. Therefore, the brush tip of the cleaning brush roller 14 rubs the curved convex surface 13b ₂ of the screen member 13 more strongly and effectively.

Thereby, the cleaning brush roller 14 more effectively removes dust adhering to the convex surface 13b _{2 of the} screen 13b. Moreover, since the radius of the convex surface 13b ₂ of the rotating screen 13b is substantially the same as the rotational radius of the screen member 13, the rubbing force of the convex surface 13b ₂ of the screen 13b by the brush tip of the cleaning brush roller 14 becomes substantially constant. Therefore, stable cleaning of the screen member 13 by the cleaning brush roller 14 is performed.

  Further, the frame body 2 is provided with a chute 18 positioned below the cleaning brush roller 14. The dust removed by the cleaning brush roller 14 falls on the chute 18 and is collected.

The screen dust remover 1 of this example configured as described above is installed such that a part of the driven sprockets 5 and 6 side is buried below the water surface W.L as shown in FIG. In that case, the screen dust remover 1 is installed so as to be inclined so that the convex surface 13b _{2 of the} screen 13b faces the upstream side of the running water and obliquely upward.

When the motor 7 is driven and the drive sprockets 3 and 4 are rotated in the clockwise direction in FIG. 1, each screen member 13 is also rotated in the clockwise direction indicated by the arrow β in conjunction with this. Further, the brush roller 14 rotates in the direction γ. In this state, when the flowing water flows in the direction α from the left in FIG. 1, the flowing water contacts the screen member 13. Then, dust mixed in running water is captured by the screen 13b of the screen member 13 and adheres to the screen 13b. The dust adhering to the screen 13b is conveyed toward the drive sprockets 3 and 4 by the rotation of the screen member 13 in the direction β.

The dust adhering to the screen 13b is removed from the screen member 13 and the cleaning brush roller 1.
4, the dust is removed from the screen member 13 by the cleaning brush roller 14 and collected by the chute 18. On the other hand, the water from which the dust has been removed flows downstream through a number of holes 13b ₁ of the punching metal constituting the screen 13b. Since the other capture operation of the dust in the running water by the screen dust remover 1 of this example is substantially the same as the conventional general screen dust remover, the description thereof is omitted.

According to the screen dust remover 1 of this example, the screen member 13 is curved so as to protrude toward the upstream side of the fluid, and at the position where the screen member 13 is rotated in an arc shape by the drive sprockets 3 and 4, The convex surface 13b ₂ is curved in the same direction as the arcuate rotation of the screen member 13, and the convex surface 13b _{2 of the} screen 13b.
The cleaning brush roller 14 is in contact with the brush tip.

Therefore, the rubbing force of the screen member 13 by the cleaning brush roller 14 can be increased, and dust adhering to the convex surface 13b _{2 of the} screen 13b can be efficiently removed. Thereby, the cleaning effect by mechanical cleaning of the screen member 13 can be obtained more effectively. In this case, since the cleaning brush roller 14 rotates in conjunction with the rotation of the screen member 13, the cleaning brush roller 14 can always be rotated when the screen member 13 rotates. Accordingly, the dust captured by the screen member 13 can be more reliably removed by the cleaning brush roller 14.

In particular, since the tangential movement direction of the screen member 13 and the tangential movement direction of the cleaning brush roller 14 are opposite to each other at the contact position between the screen member 13 and the cleaning brush roller 14, the cleaning brush roller 14 The sliding force of the convex surface 13b ₂ of the screen 13b by the brush tip can be increased. Therefore, the dust adhering to the convex surface 13b ₂ of the screen 13b can be more effectively removed by the cleaning brush roller 14.

Furthermore, since the radius of the convex surface 13b ₂ of the rotating screen 13b is substantially the same as the rotational radius of the screen member 13, the rubbing force of the convex surface 13b ₂ of the screen 13b by the brush tip of the cleaning brush roller 14 is made substantially constant. Can do. Therefore, stable cleaning of the screen member 13 by the cleaning brush roller 14 can be realized.

  Furthermore, since the dust flowing by the fluid is captured by the screen 13b and scooped up by the rake 20, the effect of removing dust in the flowing water can be increased.

FIG. 4 is a perspective view showing another example of the embodiment of the screen dust remover according to the present invention.
In the screen dust remover 1 of the example shown in FIG. 1, the drive sprockets 3 and 4 and the cleaning brush roller 14 are rotated by one motor 7 in conjunction with each other. As shown in FIG. In the screen dust remover 1, a motor 19 that rotates the cleaning brush roller 14 is provided separately from the motor 7 that rotates the drive sprockets 3 and 4. In the screen dust remover 1 of this example, the brush roller driven sprocket 15, the brush roller driven sprocket 16, and the endless chain 17 in the screen dust remover 1 of the example shown in FIG. 1 are not provided.

Therefore, in the screen dust remover 1 of this example, the rotation of the drive sprockets 3 and 4, that is, the rotation of the chains 9 and 10 for rotating the screen member 13 and the rotation of the cleaning brush roller 14 can be controlled independently. . Thereby, the rotational speed and rotational direction of the screen member 13 and the rotational speed and rotational direction of the cleaning brush roller 14 can be controlled separately. As a result, it is possible to obtain a cleaning effect by the cleaning brush roller 14 in accordance with the usage environment of the screen dust remover 1, the adhesion state of the screen member 13, and the like.
Other configurations and other functions and effects of the screen dust remover 1 of this example are the same as those of the example shown in FIG.

  FIG. 5 shows still another example of the embodiment of the screen dust remover according to the present invention. (A) is a plan view showing the relationship between the chain link and the screen member in this example, and (b) is the front view thereof. (C) is a partial left side view thereof, (d) is a partial right side view thereof (e) is a front view of the screen member of this example.

The screen dust remover 1 of each example described above has the rake 20, but the screen dust remover 1 of this example does not have the rake 20 as shown in FIGS. 5 (a) to 5 (e). According to the screen dust remover 1 of this example, the effect by the rake 20 described above cannot be obtained, but the dust flowing by the fluid can be captured by the screen 13b.
Other configurations and other functions and effects of the screen dust remover 1 of this example are the same as those of the above-described examples.

  The screen dust remover of the present invention is not limited to the above-described examples, and various design changes can be made within the scope of the matters described in the claims.

  The screen dust remover according to the present invention is preferably used for a screen dust remover that captures and removes dust particles such as floating substances present in the fluid and foreign matters present in the fluid by the screen member and removes them from the fluid. Can do.

It is a perspective view which shows an example of embodiment of the screen dust remover which concerns on this invention. (A) is a figure which shows the relationship between a chain, a screen member, and a drive sprocket, (b) is a figure which shows the relationship between a screen member and a brush roller. (A) is a plan view showing the relationship between a chain link and a screen member, (b) is a front view thereof, (c) is a partial left side view thereof, (d) is a partial right side view thereof (e) is a screen. It is a front view of a member. It is a perspective view which shows the other example of embodiment of the screen dust remover which concerns on this invention. The further another example of embodiment of the screen dust remover concerning this invention is shown, (a) is a top view which shows the relationship between the link of the chain in this example, and a screen member, (b) is the front view, (c) ) Is a partial left side view thereof, (d) is a partial right side view thereof (e) is a front view of the screen member of this example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Screen dust remover, 2 ... Frame main body, 3, 4 ... Drive sprocket, 5, 6 ... Driven sprocket, 7, 8 ... Rotating shaft, 9, 10 ... Chain, 11 ... Link, 12 ... Connecting pin, 13 ... Screen member, 13a ... supporting frame, 13b ... screen, 13b ₁ ... hole, 13b ₂ ... convex, 14 ... cleaning brush roller, 15 ... brush roller drive sprocket, 16 ... brush roller driven sprocket, 17 ... endless chain, 18 ... chute, 19 ... motor, 20 ... rake

Claims (6)

A plurality of screen members arranged endlessly, and at least a cleaning member for cleaning the plurality of screen members,
The plurality of screen members capture dust mixed in the fluid, and the captured dust is transported by the rotation of the plurality of screen members, and the transported dust is removed from the screen member by the cleaning member. In screen dust remover,
Each of the plurality of screen members is curved around an axis in the width direction of the screen member in a direction orthogonal or substantially orthogonal to the rotation direction,
The bending direction of the screen member is a direction that protrudes upstream of the fluid at the position of the screen member with which the fluid first contacts,
The screen dust remover, wherein the cleaning member abuts on a convex surface of the screen member.   2. The screen dust removal according to claim 1, wherein the curved shape of the screen member is a circular arc shape of a circle having the same radius or substantially the same radius as the rotation radius when the plurality of screen members change the rotation direction. Machine.   3. The screen dust remover according to claim 1, wherein the cleaning member abuts on a convex surface of the screen member at a position where the plurality of screen members change a rotation direction. 4.   The cleaning member according to claim 1, wherein the cleaning member is a rotatable cleaning brush roller, and the rotation of the cleaning brush roller is controlled in conjunction with rotation of the plurality of screen members. Screen dust remover.   The cleaning member according to claim 1, wherein the cleaning member is a rotatable cleaning brush roller, and the rotation of the cleaning brush roller is controlled independently of the rotation of the plurality of screen members. Screen dust remover.   The screen dust remover according to any one of claims 1 to 5, wherein a rake for scooping up dust mixed in the fluid is detachably attached to at least a part of the plurality of screen members.

Images