JP2001098537A - Suspended matter recovery device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a suspended matter recovery device simple in structure in an air eliminating device. SOLUTION: This suspended matter recovery device is adapted to collect suspended matter in a recovery chamber 7 by utilizing the relative speed between water and the device, sucking the suspended matter in the recovery chamber 7 by a pump 12 and discharging the same from the recovery chamber 7. The recovery device includes a float valve 20 provided on the top of the recovery chamber 7, and an ejector 40 in which the inlet side of a suction pipe 47 is communicated with the outlet of the float valve 20. The float valve 20 is automatically opened and closed by the up and down motion of water level, so that air in the recovery chamber 7 is sucked and removed by the ejector 40.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a suspended matter recovery apparatus provided on a ship, a river crest, or the like. The suspended matter collection device collects and removes suspended matters such as oil floating on the water surface such as the sea, lakes and rivers.

[0002]

2. Description of the Related Art As one of the floating substance collecting apparatuses, there is a floating substance collecting apparatus which collects floating substances in a collecting chamber by using a water flow, sucks the floating substances in the collecting chamber by a pump, and discharges them from the collecting chamber. For example, JP-A-49-78295 discloses a "device for removing a contaminant layer floating on the water surface".
The removal device utilizes the relative speed of the water and the removal device to introduce water and contaminants floating thereon at the taper into the cyclone chamber through a tangential inlet. The contaminants completely separated from the water are collected in a collection chamber above the cyclone chamber, and are suctioned by a suction pump or the like and discharged to a collection tank. The contaminated water is discharged into the water from the tangential outlet at the bottom of the cyclone chamber.

[0003] There is also known a device which has an introduction portion inclined with respect to the water surface, guides water and suspended matter floating on the water from the introduction portion to a collection chamber, and discharges the water and a suction pump.

[0004] In any of the suspended solids recovery devices, the upper part of the inflow port may be exposed on the water surface due to vertical movement of the ship or waves. When the inlet is exposed, air is entrained with the water and the air enters the collection chamber. This reduces the efficiency of the pump that sucks suspended matter from the collection chamber. The water level in the collection device drops due to the decrease in suction force, and suspended matter flows out of the cyclone chamber, and the collection efficiency also decreases.

Conventionally, a vacuum pump has been used to remove air from the recovery chamber. However, vacuum pumps are expensive due to their complex structure and require regular maintenance.

[0006] Even when a suspended matter recovery device is installed in a river crest or the like, the same problem as described above occurs due to a change in the type of suspended matter or the amount of water in the river.

[0007]

SUMMARY OF THE INVENTION An object of the present invention is to provide an apparatus for collecting suspended matter having a simple structure of an air removing apparatus.

[0008]

SUMMARY OF THE INVENTION According to the present invention, there is provided an apparatus for collecting suspended matter, which collects suspended matter in a collecting chamber by utilizing a relative speed between water and the apparatus, sucks the suspended matter in the collecting chamber with a pump, and collects the collected substance. The apparatus for recovering suspended solids discharged from the apparatus comprises a float valve provided at the top of the recovery chamber, and an ejector whose inlet side of the suction pipe communicates with the outlet of the float valve.

[0009] In the above-mentioned suspended matter recovery apparatus, when the water level falls due to the intrusion of air into the recovery chamber, the float lowers and the float valve opens. When the float valve opens, the air in the collection chamber is sucked into the mixing chamber by the operation of the ejector. The air is mixed with the drive water of the ejector in the mixing chamber,
It is discharged from the ejector together with the driving water. When the water level rises due to the discharge of air, the float rises and the float valve closes. Therefore, the collected suspended matter is not discharged together with the air.

In the present invention, since the air removing device has no moving parts, the structure of the device is small and lightweight. The air removal device is inexpensive and requires little maintenance. As a result, it is possible to reduce the facility cost and the operating cost of the entire suspended matter collection device.

[0011] The float valve may be a ball valve.
If the top of the ball is used as a valve body and an orifice is provided at the valve outlet and the inlet side is used as a valve seat, the structure of the float valve is simplified.

An orifice may be provided between the float valve outlet and the suction pipe inlet of the ejector. Depending on the size of the orifice diameter, the discharge flow rate of the air from the float valve and therefore from the recovery chamber changes. Thus, the opening / closing timing of the float valve can be adjusted, and one float valve or ejector can be used for a suspended solids recovery device having a different throughput. Since the orifice inlet side can be used as the valve seat of the float valve, the size of the air removing device with the orifice can be reduced.

[0013] A flow control valve may be attached to an inlet pipe of the ejector. By adjusting the flow rate of the driving water with the flow rate control valve, an ejector of one size can be used for a suspended solids recovery device having a different throughput.

The main body of the suspended solids recovery device can be a cyclone type. In this case, the collection chamber is provided at the top of the cyclone chamber, so that the attachment / detachment and maintenance of the air removing device are simplified.

[0015]

FIG. 1 shows one embodiment of the present invention, and is a schematic view of a cyclone type suspended solids recovery apparatus mounted on a ship. Hereinafter, the suspended matter will be described as oil floating on the sea surface.

The oil recovery apparatus main body 1 has a cyclone chamber 2 composed of a cylindrical upper chamber 3 and a conical lower chamber. The upper chamber 3 is provided with an inflow port 5 on a peripheral wall. A headrace that guides the seawater in which the oil floats from the inlet 5 into the cyclone chamber 2 is connected to the upper chamber 3. Since the seawater is introduced from the inflow port in the tangential direction of the inner peripheral surface of the upper chamber 3, it turns in the cyclone chamber 2. A drain port 6 opens into the lower chamber 4.
A collection chamber 7 is provided at the top of the cyclone chamber 2. The collection chamber 7 is provided with an oil discharge pipe 11 that communicates with a collection tank (not shown) via a suction pump 12.

FIG. 2 shows a main part of the air removing device 15 attached to the oil recovery device main body 1. An air removal device 15 is attached to the top of the collection chamber 7. The air removing device 15 mainly includes a float valve 30 and an ejector 40.

FIG. 3 shows the float valve 20. The valve chamber 21 of the float valve 20 has a cylindrical shape, and has an inlet flange 23 and an outlet flange 24 at both ends. Three guides 26 extending along the cylinder axis direction are provided on the inner peripheral surface of the valve chamber 21 at intervals of 120 degrees in the circumferential direction. The lid 26 is sandwiched between the outlet flange 24 of the valve chamber 21 and the inlet flange 48 of the ejector suction pipe 47 and is fixed with bolts 37. Outlet flange 24,
Gaskets 38 are inserted between the lid 26 and the inlet flange 24 of the suction pipe 47, respectively. Lid 2
6 is provided with a valve seat 28 at the center. Valve outlet 28
Is determined by the air discharge flow rate, the performance of the ejector 40, and the like. A cylindrical float 31 is inserted into the valve chamber 21. A valve body 33 is provided above the float 31. The float 31 is made of resin and has a specific gravity of about 0.7.
5 The float 31 moves up and down guided by the guide 26. A wire mesh 35 is provided on the inlet flange 23 of the float valve 20. The wire mesh 35 is connected to the float valve 20.
It prevents dust from flowing into the interior and supports the float 31 when the float descends. The float valve 20 includes a pipe flange 8 provided at the top of the recovery chamber 7 and an inlet flange 23.
Are connected to each other by bolts 37 and attached to the collection chamber 7. A gasket 38 is inserted between the pipe flange 8 and the inlet flange 23.

The ejector 40 has a throat portion 42 and a mixing chamber 43 formed in an ejector body 41 as shown in FIG. An inlet pipe 45 is connected to an inlet of the throat part 42. A suction pipe 47 is connected to the suction side of the mixing chamber 42, and a diffuser 49 is connected to the outlet side. As the ejector 40, a commercially available standard product is used, and is selected according to the pressure in the collection chamber 7, the air discharge flow rate, and the like. As shown in FIG. 1, a water supply pump 50 and a flow control valve 5
2 are installed. The water supply pump 50 supplies driving water to the ejector 40. The outlet of the float valve 20 is connected to the suction pipe 47. The outlet of the diffuser 40 is open to the atmosphere, and the drainage from the diffuser 49 flows out to the sea. Since the amount of driving water supplied is small, water may be supplied to the ejector 40 from a miscellaneous water pump (not shown) provided on the ship.

The operation of the oil recovery device configured as described above will be described. In FIG. 1, the ship is traveling in the direction of arrow S. The seawater containing oil is guided from the headrace 9 into the cyclone chamber 2. The seawater turns inside the cyclone chamber 2 along the inner wall, and flows out from the drain port 6. The oil moves to the center of the cyclone chamber by turning the seawater, rises by buoyancy, and collects in the recovery chamber 7. The collected oil is sucked by the suction pump 12 and discharged from the oil discharge pipe 11 to a collection tank (not shown). When the discharge of air proceeds and the oil level in the recovery chamber 7 rises, the float 31 rises and the float valve 20 closes. If the sea level SL becomes too low with respect to the inflow port 5 of the cyclone chamber 2 due to the vertical movement of the ship or waves, the air flows into the cyclone chamber 2 and rises up in the chamber to accumulate in the recovery chamber 7. When the amount of air in the collection chamber 7 increases, the oil level drops, the float 31 also drops, and the float valve 20 opens. Float valve 2
When 0 is opened, the air in the recovery chamber 7 flows into the mixing chamber 42 via the float valve 20 and the suction pipe 47, where it mixes with seawater. Seawater containing a large amount of air flows out into the sea through the diffuser 49. When the oil level rises due to the discharge of air from the recovery chamber 7, the float 31 rises and the float valve 20 rises.
Closes. As a result, the collected suspended matter is not discharged together with the air.

FIG. 5 shows another embodiment of the float valve. In FIG. 5, the same members as those shown in FIG. 3 are denoted by the same reference numerals, and description thereof will be omitted. The float valve 60 has a ball-shaped float 62 inserted into the cylindrical valve chamber 21.
The float 62 is made of resin and has a specific gravity of about 0.75. The float 62 is guided up and down by the guide 26 in the valve chamber 21. The inlet periphery of the orifice 65 described below serves as a valve seat 66 of the float valve 60, and the top 63 of the float 62 functions as a valve element. In FIG. 5, a float indicated by a chain line indicates a state in which the float valve 60 is closed.
The float valve 60 is attached to the top of the collection chamber 7 via the pipe flange 8.

The orifice 65 is connected to the outlet flange 24 of the float valve 60 and the inlet flange 4 of the ejector suction pipe 47.
8 and is attached. The orifice diameter is determined by the air discharge flow rate, the performance of the ejector 40, and the like. Thus, the opening / closing timing of the float valve can be adjusted, and one float valve or ejector can be used for an oil recovery device having a different throughput. Since the orifice inlet side can be used as the valve seat of the float valve, the size of the air removing device with the orifice can be reduced. The operation of this oil recovery device is the same as the operation of the device shown in FIG.

The suspended solids recovery apparatus of the present invention is not limited to the cyclone type apparatus, but may be, for example, the above-mentioned inclined type suspended solids recovery apparatus. In addition, the suspended matter is oil, but may be a layer having a layer on the water surface such as red tide, and may be fluid.

[0024]

According to the present invention, since the air removing device has no moving parts, the structure of the device is small and light. The air removal device is inexpensive and requires little maintenance.
As a result, it is possible to reduce equipment costs and operation costs of the entire suspended matter collection device. No explosion-proof measures are required because it operates only with water supply.

Further, the float valve automatically opens and closes according to the rise and fall of the water level to discharge the air, so that the collected suspended matter is not discharged together with the air.

[Brief description of the drawings]

FIG. 1 shows an embodiment of the present invention, and is a schematic diagram of an entire suspended matter collection device.

FIG. 2 is a side view of an air removing device of the above device.

FIG. 3 is a sectional view of a float valve.

FIG. 4 is a cross-sectional view of the ejector.

FIG. 5 is a sectional view showing another example of the float valve.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 oil recovery device main body 2 cyclone chamber 7 recovery chamber 9 water conduit 12 suction pump 15 air removal device 20 float valve 21 valve chamber 26 lid 28 valve seat 31 float 33 valve element 40 ejector 47 suction pipe 50 water supply pump 52 flow control valve 60 Float valve 62 Float 65 Orifice

Continued on front page F term (reference) 2D025 BA25 3H079 AA14 AA23 BB10 CC19 CC23 DD12 DD23 DD28 4D051 AA01 AA06 AB07 CA15 CA18 DD01 DD23 DD30 4D053 AA01 AA03 AB04 BA01 BB02 BC01 BD01 CA03 CB11 CD12

Claims (5)

[Claims] 1. Collecting suspended matter in a collecting chamber using a relative speed between water and a device, sucking the suspended matter in the collecting chamber with a pump,
A floating material recovery device discharged from a recovery chamber, comprising: a float valve provided at the top of the recovery chamber; and an ejector having an inlet side of a suction pipe communicating with an outlet of the float valve. . 2. The apparatus according to claim 1, wherein said float valve is a ball valve. 3. An apparatus according to claim 1, wherein an orifice is provided between the float valve outlet and the suction pipe inlet of the ejector. 4. The apparatus according to claim 1, wherein a flow control valve is attached to an inlet pipe of the ejector. 5. A cyclone chamber having a cylindrical upper chamber having an inflow opening and a conical lower chamber having a drainage opening, and a top provided with the recovery chamber,
2. A water conduit connected to the cylindrical upper chamber so as to guide water into the cyclone chamber through the inlet.
The suspended solids recovery apparatus according to any one of claims 4 to 4.