JP6696668B2 - Contaminant processing equipment - Google Patents

Description

  The present invention relates to a contaminant treatment device that is installed in a water channel of a sewage treatment plant or the like and that treats water to be treated containing contaminants such as residue floating in water. More specifically, the present invention relates to a contaminant treatment device that includes a screen unit for capturing contaminants such as residue floating in water, and a crushing unit for crushing contaminants captured by the screen unit.

  In a waterway of a sewage treatment plant or the like, a foreign matter treatment device equipped with a crusher with a screen for crushing foreign matters floating in water, such as residues, is installed. For example, Patent Document 1 discloses a dust processing device including a screen and a crusher on one side of the screen. This waste treatment device is provided with a screen for capturing foreign substances and a crusher for crushing foreign substances, and the screen is installed so as to be inclined with respect to the water channel. According to the present invention, by tilting the screen, the dust caught on the screen can be guided to the crusher by utilizing the water flow without providing a device such as a scraper. In addition, the conventional example of Patent Document 1 describes a configuration including a scraper for guiding foreign substances captured on a screen to a crusher.

JP, 2000-129654, A

  In the foreign matter treatment device provided with the screen portion and the crushing portion, the screen portion is provided with a plurality of screen bars that are overlapped with each other, and a lateral gap is formed. When the water to be treated containing impurities passes through the screen portion, the water to be treated passes through the gap of the screen bar, and the impurities in the water to be treated are captured by the screen portion. However, since the contaminants floating on the water surface float so that the thickness in the vertical direction becomes small, there is a problem that a thin contaminant such as a film may slip through the gap of the screen portion.

  Therefore, an object of the present invention is to prevent the foreign matter from slipping through in the screen portion near the water surface in the foreign matter treatment device including the screen portion and the crushing portion.

The present inventor, as a result of diligent examination of the above problems, in the upstream of the screen portion, damming the contaminants floating near the water surface and directly guiding the crushing portion to the surface of the water without reducing the area of the screen portion. The present invention has been completed by finding that it is possible to prevent the passing of foreign substances in the vicinity.
Specifically, it is the following foreign matter treatment device.

  The contaminant treatment device of the present invention for solving the above problems is a screen part for capturing contaminants in the water to be treated, a crushing part installed on one side of the screen part for crushing contaminants, and And a guide member which is arranged on the upstream side of the screen portion and which guides foreign substances in the vicinity of the water surface toward the crushing portion.

  According to this foreign matter treatment device, the guide member arranged upstream from the screen portion dams the foreign matter floating near the water surface and directly guides it to the crushing portion. Can be prevented. On the other hand, since the screen area does not decrease, the permeation flow rate can be maintained. Further, since a part of the impurities captured by the screen portion is directly guided to the crushing portion by the guide member, there is an effect that the amount of the impurities captured by the screen portion is reduced and clogging can be suppressed.

Further, according to an embodiment of the foreign matter treatment device of the present invention, the guide member has a feature that the height can be changed.
In general, conditions such as the flow rate of water to be treated and the amount of contaminants may change in the water channel in which the contaminant treatment device is installed. Therefore, if the water level in the water channel decreases and the guide member is exposed above the water surface, the guide member does not work. However, according to the above feature, since the height of the guide member can be changed, it is possible to cope with a change in water level.
In addition, when a large amount of impurities flow in, the screen portion is clogged, and the problem that the permeation flow rate of the screen portion is reduced occurs. However, by changing the height of the guide member, it is possible to directly guide the crushing portion without going through the screen portion, and it is possible to suppress clogging of the screen portion.

Further, according to an embodiment of the foreign matter treatment device of the present invention, the guide member is characterized in that it is arranged from the other side end of the screen portion to the upstream region of the crushing portion.
According to this feature, since the guide member is formed in the entire region from the other side end of the screen portion to the crushing portion, it is possible to reliably guide the impurities floating near the water surface to the crushing portion. ..

Further, according to one embodiment of the foreign matter treatment device of the present invention, the screen portion is extended to an upstream region of the crushing portion, and the guide member is arranged to be closer to one side end of the screen portion. It has characteristics.
By extending the screen portion to the upstream region of the crushing portion, it is possible to guide the foreign substances captured by the screen portion to a position where the blade of the crushing portion meshes.
Further, by disposing the guide member to the front side of the one side end of the screen portion, it is possible to sufficiently prevent the foreign matter from slipping through the screen portion without unnecessary damming of the water channel. ..

The guide member according to the present invention is installed in a foreign matter treatment device that includes a screen portion that captures foreign matter in the water to be treated, and a crushing portion that is installed on one side of the screen portion and that crushes the foreign matter. The device is characterized in that it is arranged on the upstream side of the screen part and guides foreign matters near the water surface toward the crushing part.
According to this guide member, the existing foreign matter treatment device can be easily modified to the foreign matter treatment device of the present invention.

  According to the present invention, it is possible to prevent the foreign matter from slipping through the screen portion near the water surface in the foreign matter treatment device including the screen portion and the crushing portion.

It is a schematic explanatory drawing (plan view) which shows the structure of the foreign material processing apparatus of the 1st embodiment of this invention. It is a schematic explanatory drawing (side view) which shows the structure of the foreign material processing apparatus of the 1st embodiment of this invention. It is a schematic explanatory drawing explaining arrangement | positioning of the guide member of the 1st embodiment of this invention. It is a schematic explanatory drawing which shows various aspects of the guide member of this invention. (A) A schematic explanatory view showing a configuration of a vertically movable guide member. (B) A schematic explanatory view showing a configuration of a guide member that is movable in response to fluctuations in water level. (C) A schematic explanatory view showing the configuration of a guide member capable of varying the height and size of the guide member. It is a schematic explanatory drawing (plan view) which shows the structure of the foreign material processing apparatus of the 2nd embodiment of this invention. It is a schematic explanatory drawing (plan view) which shows the structure of the foreign material processing apparatus of the 3rd embodiment of this invention.

Hereinafter, an embodiment of a foreign matter treatment device according to the present invention will be described in detail with reference to the drawings.
The contaminant treatment device of the present invention is installed in a water channel and used for treating contaminants in the water to be treated flowing in the channel. For example, a water channel is a sand basin such as a sewage treatment plant, and an example of contaminants is a residue contained in wastewater such as sewage. It should be noted that the structure of the foreign matter treatment device described in the embodiment is merely an example for explaining the foreign matter treatment device according to the present invention, and is not limited to this.

[First embodiment]
FIG. 1 is a plan view showing the structure of a foreign matter treatment device 10 according to the first embodiment of the present invention. Further, FIG. 2 is a side view showing the structure of the foreign matter treatment device 10 according to the first embodiment of the present invention.
As shown in FIG. 1, the foreign matter treatment device 10 of the first embodiment is installed so as to cross a water channel R provided in a sand basin such as a sewage treatment plant.

  The foreign matter treatment apparatus 10 of the first embodiment of the present invention includes a screen unit 1 for capturing the foreign matter G contained in the water to be treated flowing through the water channel R, a crushing unit 2 for crushing the foreign matter G, And a guide member 3 for guiding impurities near the water surface toward the crushing section 2. The crushing unit 2 is arranged on one side of the screen unit 1, and is configured to cross the water channel R by the screen unit 1 and the crushing unit 2. The guide member 3 is arranged upstream of the screen unit 1. Further, a rotary rake unit 4 is provided on the downstream side of the screen unit 1 as a scraping unit for scraping the contaminants G captured by the screen unit 1 to the crushing unit 2.

  The screen portion 1 is composed of a plurality of screen members that are stacked in a substantially vertical direction, and the screen members are installed apart from each other. The water to be treated flowing from the upstream side of the screen portion 1 passes through the gap between the screen members, and the contaminant G is captured on the upstream side of the screen portion 1. Any member may be used to form the screen unit 1, and for example, a plate member having a plurality of slits formed substantially horizontally may be used.

  The screen portion 1 has the other side (opposite to the crushing section 2) end fixed to the side wall R1 of the water channel R, and the one side (the crushing section 2 side) extends to substantially the center of the water channel R. An arc portion curved in an arc shape from the approximate center of R toward the downstream side is formed. Then, one side of the screen portion 1 is fixed to the casing side surface of the crushing portion 2 on the central side of the water channel.

  As described above, the screen portion 1 forms a circular arc portion on one side (the crushing portion 2 side), and the circular arc portion extends to the upstream region of the crushing portion 2. As a result, the contaminants G captured on the screen 1 can be properly guided to a position where the blades of the crushing unit 2 mesh with each other.

  The crushing section 2 is installed between the screen section 1 and the side wall R2 of the water channel R. The crushing unit of the present invention may be any crusher, for example, a vertical biaxial crusher or a horizontal crusher. It is preferable to use a vertical crusher because the crushing unit can be installed evenly in the height direction of the screen unit 1.

  The rotary rake unit 4 is composed of a rotary shaft 42 and a plurality of rakes 41 radially fixed from the rotary shaft 42. The rake 41 is a blade having a thickness that allows it to pass through the gap between the stacked screen members, and the rake 41 having the same number as the gap formed in the screen portion 1 is arranged in the height direction in the rotary rake portion 4. Has been done.

  The rotary shaft 42 of the rotary rake unit 4 is installed eccentrically with respect to the center of the arc portion of the screen unit 1. When the rake 41 orbits around the rotary shaft 42, the rake 41 projects from between the screen members. Then, while the rake 41 projects from the outer peripheral surface of the screen portion 1, the contaminant G captured by the screen portion 1 is scraped and flows into the crushing portion 2.

The scraping section may have any configuration as long as it can scrape the contaminants G captured by the screen section 1 into the crushing section 2, and can be appropriately designed according to the shape of the screen section 1. For example, like the rotary rake unit 4 of the first embodiment, in addition to the configuration including the rotary shaft 42 and the rake 41, a loop rake unit including a chain to which a rake is attached and a plurality of sprockets for circulating the chain Etc. The rotary rake portion of the first embodiment does not have a structure that meshes with a chain and a sprocket, and is a simple structure. Therefore, there is an advantage that troubles such as foreign matter entangled in the scraping portion are unlikely to occur. ..
The scraping unit is not an essential component of the present invention, but may be, for example, a structure in which the screen unit is inclined and a contaminant is trapped in the screen unit by the water flow and guided to the crushing unit 2. When the scraping part is not provided, power is not required, and therefore, an excellent effect is obtained from the viewpoint of energy saving.

(Guiding member)
The guide member 3 is a member for blocking the foreign matter G floating near the water surface and directly guiding it to the crushing unit 2, and is arranged on the upstream side of the screen unit 1. More specifically, the guide member 3 is supported by the support portion 31 attached to the side wall R1 of the water channel R, and is installed so as to substantially cross the water channel R to the upstream region of the crushing section 2. Further, the guide member 3 is installed so that the upper end is located above the water surface and the lower end is located below the water surface in order to block the foreign matter G near the water surface. By providing the guide member 3 on the upstream side of the screen portion 1, the foreign matter G floating near the water surface is directly guided to the crushing portion 2, and thus the foreign matter G near the water surface is not reduced without reducing the area of the screen portion 1. It is possible to prevent slipping through. In addition, since a part of the impurities G captured by the screen unit 1 is directly guided to the crushing unit 3 by the guide member 3, the amount of the impurities G captured by the screen unit 1 is reduced, and clogging can be suppressed. There is also the effect.

It is preferable that the guide member 3 has a height that can be changed. Since the height of the guide member 3 can be changed, it is possible to cope with the fluctuation of the water level of the water channel R. Further, when a large amount of the foreign matter G flows in, the height of the guide member 3 may be changed so that the amount of the foreign matter G directly guided to the crushing unit 2 may be adjusted so that the screen portion 1 is not clogged. it can.
The height of the guide member 3 may be fixed, and for example, the height of the guide member 3 may be set according to the expected fluctuation range of the water level of the water channel R. When the height of the guide member 3 is fixed, the guide member can be provided by a simple structure. In addition, since it is not necessary to change the height due to the fluctuation of the water level, there is an effect that the management is easy.

  In order to guide the foreign matter G to the crushing section 2, the guide member 3 is installed with the free end of the guide member 3 inclined toward the downstream in the flow direction of the water channel R, as shown in FIG. 1. Any structure may be used as a structure for guiding the contaminant G to the crushing unit 2.

  Further, as a configuration for assisting the action of the guide member 3, a configuration for forming a water flow toward the crushing section 2 may be provided on the upstream side of the guide member 3. As such a structure, for example, a blower for applying a wind to the water surface to form waves in the direction of the crushing section 2, a water jet nozzle provided near the water surface, and a member for diverting the water flow toward the crushing section 2 Etc.

  Next, a preferred mode of arrangement of the guide member 3 will be described. The arrangement of the guide member 3 is not particularly limited as long as it is arranged on the upstream side of the screen portion 1, but it is preferable to arrange the guide member 3 from the other side end of the screen portion 1 to the upstream region of the crushing portion 2. Furthermore, it is particularly preferable that the screen portion 1 is extended to the upstream region of the crushing portion 2 and the guide member 3 is arranged to the front side of one side end of the screen portion 1.

Here, the arrangement of the screen portion 1, the crushing portion 2, and the guide member 3 will be described with reference to FIG.
The "end on the other side of the screen 1" is the end on the opposite side of the crushing portion 2 of the screen portion 1, specifically, the position indicated by the alternate long and short dash line (X) in FIG.
The "upstream region of the crushing unit 2" means a region on the upstream side in the flow direction of the crushing unit 2, and is specifically a region on the side wall R2 side of the alternate long and short dash line (Y) in FIG.
The "one side edge of the screen portion 1" means the position of the end portion of the screen portion 1 on the side wall R2 side (the one-dot chain line (Z) in FIG. 3), and the front side thereof means "the screen portion 1". The region on the side of the sidewall R1 from the “one side end” (Z).

By disposing the guide member 3 from (X) on the other side of the screen portion 1 to the upstream region of the crushing portion 2 (region on the R2 side of Y), from the end (X) on the other side of the screen portion 1 Since the guide member 3 is formed over the crushing unit 2, the contaminant G floating near the water surface can be reliably guided to the crushing unit 2.
Further, according to the configuration in which the screen portion 1 is extended to the upstream region of the crushing portion 2, the impurities G captured by the screen portion 1 can be guided to a position where the blade of the crushing portion 2 meshes. Has the effect. Further, according to the configuration in which the guide member 3 is arranged up to the front side (the region on the R1 side of Z) from the one side end of the screen portion 1, the guide member 3 blocks the water channel R unnecessarily. The effect of being able to sufficiently prevent the foreign matter G from passing through the screen portion 1 can be achieved without any trouble.

The shape of the guide member 3 may be any shape, and examples thereof include a plate shape, a columnar shape, and a polygonal columnar shape. From the viewpoint of a simple structure, it is preferably plate-shaped.
Further, the material may be any material, and examples thereof include metal materials such as stainless steel, and organic materials such as wood and styrofoam.

FIG. 4 shows various modes of the guide member 3.
FIG. 4A is an example of a guide member in which the guide member 3 a is supported by the support portion 31 via the vertical drive mechanism 32 and is vertically movable. According to this, when the water level of the water channel R changes, the height of the guide member 3a can be appropriately changed.

  FIG. 4B is an example of a guide member 3b made of a material such as styrofoam having a specific gravity smaller than that of water and floating near the water surface. A weight 33 is attached to the lower end of the guide member 3b, stands upright in the vicinity of the water surface, and is supported by the support portion 31 via a mechanism that can freely slide in the vertical direction. According to this, the height can be automatically changed corresponding to the change in the water level of the water channel R.

  FIG. 4C is an example of a guide member in which the guide member 3c includes the shutter 34 and the size of the guide member 3c in the height direction can be changed. According to this, the height and size of the guide member 3c can be changed according to the change of the water level of the water channel R and the amount of the impurities G in the water to be treated.

  The guide member can also be attached to an existing foreign matter treatment device for use. According to this guide member, it is possible to implement the foreign matter treatment device of the present invention by utilizing the existing foreign matter treatment device without introducing new equipment.

[Second embodiment]
FIG. 5 is a schematic explanatory diagram of the foreign matter treatment apparatus 11 according to the second embodiment of the present invention. In the foreign matter treatment device 11 of the second embodiment, the curved screen portion 1 of the foreign matter treatment device 10 of the first embodiment is replaced with a linear screen 11, and accordingly, the rotary rake portion 4 is circulated. It is changed to part 5. The orbital rake unit 5 has a structure in which a chain 52 wound around two sprockets 51a and 51b and a plurality of rakes 53 attached to the chain 52 are provided, and the contaminants G captured by the screen unit 11 are removed. This configuration is suitable for linear transfer.

[Third Embodiment]
FIG. 6 is a schematic explanatory diagram of the foreign matter treatment apparatus 12 according to the third embodiment of the present invention. The foreign matter treatment device 12 of the third embodiment has a configuration in which the screen portion 1, the crushing portion 2, the guide portion 3, and the rotary rake portion 4 are installed inside one housing 6. The housing 6 is provided with a concave fitting piece as a fitting mechanism 61 that can be simply installed in the water channel R. By fitting this concave fitting piece with the convex fitting piece provided on the side wall of the water channel R, the foreign matter treatment device 12 of the present invention can be simply installed in the water channel R.

  INDUSTRIAL APPLICABILITY The contaminant treatment device of the present invention can be used to treat contaminants in the water to be treated flowing through the water channel. Specifically, it can be used for capturing and crushing contaminants such as residue in a sand basin of a sewage treatment plant.

  In addition, by providing the guide member of the present invention in an existing foreign matter treatment device, it is possible to provide the foreign matter treatment device of the present invention by a simple mounting operation without updating the entire device.

  10, 11, 12 Contaminant processing device, 1 screen part, 2 crushing part, 3, 3a, 3b, 3c Guide member, 31 support part, 32 Vertical drive mechanism, 33 weight, 34 shutter, 4 rotation rake part, 41 rake , 42 rotary shafts, 5 orbiting rake parts, 51a and 51b sprockets, 52 chains, 53 rakes, 6 housings, 61 fitting mechanism, R water channel, R1 and R2 side walls, G contaminants

Claims (5)

A screen part that captures contaminants in the water to be treated,
A crushing unit that is installed on one side of the screen unit and crushes impurities,
A guide member that is arranged on the upstream side of the screen portion and that guides contaminants near the water surface toward the crushing portion,
Equipped with
The foreign material treatment device is characterized in that the height of the guide member is changeable . The foreign matter treatment device according to claim 1 , wherein the guide member is arranged from the other side end of the screen portion to an upstream region of the crushing portion. A screen part that captures contaminants in the water to be treated,
A crushing unit that is installed on one side of the screen unit and crushes impurities,
A guide member that is arranged on the upstream side of the screen portion and that guides contaminants near the water surface toward the crushing portion,
Equipped with
The guide member is arranged from the other side end of the screen portion to the upstream region of the crushing portion,
The foreign matter treatment device is characterized in that the screen portion is extended to an upstream region of the crushing portion, and the guide member is arranged to be closer to one side end of the screen portion. The foreign material treatment device according to claim 3, wherein the guide member is changeable in height. A screen part for capturing impurities in the water to be treated,
A guide member that is installed on one side of the screen unit and that is installed in a foreign matter treatment device that includes a crushing unit that crushes foreign matter,
It is arranged on the upstream side of the screen portion, and guides foreign substances in the vicinity of the water surface toward the crushing portion ,
A guide member having a height that can be changed .

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