JP7493896B2 - Oil Detection System - Google Patents

Description

The present invention relates to an oil detection system for monitoring and detecting oil in the field of marine and river construction, for example, in dam reservoirs, in order to prevent water pollution caused by oil leakage during construction.

Conventional examples of oil recovery include, for example, oil film detectors used in water storage facilities and oil storage facilities (discharge pipes with shutoff valves), but there are no examples in the field of marine and river construction. In marine and river construction, measures to prevent oil leakage from machinery and equipment used, and measures to remove oil if a leakage occurs, are also necessary. One method of preventing oil leakage is to surround the work area (around the main work vessel) with an oil fence, visually inspect the surrounded area from a small vessel, and drop in the required number of oil absorption mats (e.g., 300mm x 300mm x 10mm) to recover the oil.

Here, examples of oil detectors include devices that irradiate the water surface with laser light and receive the reflected light, detecting oil based on differences in the intensity of the reflected light (e.g., JP 10-090177 A).

However, when carrying out work on a water-utilization dam lake intended to secure drinking water, complete recovery of the oil is essential to prevent it from being drawn into the discharge facilities, and work must be carried out under stricter conditions than usual. For example, if the work area is a relatively wide area on the lake surface, including the area around a barge equipped with a 70-ton lifting crane, it is not certain that all leaked oil can be confirmed by visual inspection, and there is a concern that some will be overlooked. There is also no guarantee that oil will not leak within the work area at night, when no work is being carried out.

Therefore, there is a need for measures to constantly monitor oil leakage and to reliably recover the leaked oil, and it is expected that such social demands will continue to increase in the future. The present invention has been made in consideration of these points, and provides a system that can constantly monitor the generation of oil by reliably and efficiently directing surface water to a fixed point even in a relatively wide work area.

Japanese Patent Application Laid-Open No. 10-090177

Thus, the present invention has been devised to address the above-mentioned conventional demands and problems, and aims to provide an oil detection system that can reliably guide surface water and oil to an oil collection device and collect it, even in a relatively wide work area, thereby allowing the occurrence of oil to be monitored constantly and the system to be constructed taking into account on-site conditions, thereby enabling the occurrence of oil to be monitored and detected reliably and efficiently.

The present invention relates to
The oil collection system comprises an oil collection device which collects water containing floating oil, an oil detection means which detects oil from the water collected by the oil collection device, a diffusion prevention means which is disposed to surround the oil leakage control object and the oil collection device and which prevents the diffusion of the oil floating in the water, and a water flow generating means which generates a water flow so that the oil flows toward the oil collection device,
The oil collecting device has an inlet through which water flows in, and a water discharge means for discharging water in the oil collecting device from within the oil collecting device,
a water flow generating means for generating a water flow within the range surrounded by the diffusion prevention means, so that water containing floating oil flows toward the oil collecting device, and the oil detecting means detects oil from the water that flows into the oil collecting device;
It is characterized by:
or
The oil collecting device has a flow plate through which the water flowing in from the intake flows, and is adjusted and installed so that the lower end of the intake is lower than the water level,
The oil detection means detects oil from the water flowing on the flow plate.
It is characterized by:
or
The flow plate is held in an inclined state so that the side facing the intake port is lower than the intake port side.
It is characterized by the above.

According to the present invention, even in a relatively wide work area, surface water and oil can be reliably guided to and collected by the oil collection device, thereby enabling constant monitoring of oil generation and enabling the system to be constructed taking into account on-site conditions, thereby achieving the effect of reliably and efficiently monitoring oil generation.

FIG. 1 is an explanatory diagram (1) for explaining a schematic configuration of the present invention. FIG. 2 is an explanatory diagram (2) illustrating the schematic configuration of the present invention. FIG. 3 is an explanatory diagram (3) for explaining the schematic configuration of the present invention.

The present invention will now be described with reference to the embodiments shown in the drawings.
1 is a schematic plan view of the oil detection system of the present invention. The oil detection system of the present invention is mainly used in construction work using a construction vessel 5 such as a crane barge on a water-utilizing dam lake for the purpose of securing drinking water in a lake, dam reservoir, or the like.

As shown in Figure 1, the oil detection system is configured with a diffusion prevention means (guiding fence 1), an oil collection device 2, an oil detection means 3, and a water flow generation means 4. Each component is described in detail below.

First, the guide fence 1 is intended to surround within a specified area an object to be protected from oil leakage, such as a construction vessel 5 that requires oil leakage prevention measures, in order to prevent the oil from spreading outside the specified area in the event of an oil leakage. A pollution prevention film (e.g., an oil fence or silt fence) is used. The guide fence 1 is also positioned so that its width gradually narrows as it approaches the oil collection device 2, which allows water and oil floating on the water to be guided reliably and efficiently into the oil collection device 2.

Next, the oil collection device 2 is installed inside the guiding fence 1, near the stern of the construction vessel 5 (see Figure 1). As an example of the installation method, a steel material (φ50mm) is attached to an angle projecting horizontally from the stern of the construction vessel 5 so that it extends vertically, and the steel material is inserted into a sheath pipe (φ60mm) attached to the oil collection device 2, so that the oil collection device 2 can be installed so that it can sway up and down in accordance with the swaying of the water surface.

Here, FIG. 2 shows a schematic diagram of the oil collection device 2, where (a) is a perspective view and (b) is a plan view. As can be seen from FIGS. 2(a) and (b), the oil collection device 2 is installed in a state where it floats on the water surface, with a roughly square box-shaped collection body 6 supported by floats 7 attached to both sides. Therefore, as mentioned above, the oil collection device 2 can sway up and down in accordance with the swaying of the water surface, preventing damage caused by the swaying of the water surface.

Then, a weight 8 is attached to the collection body 6. In Fig. 2(a) and (b), the weight 8 is attached to both ends of the front surface where the intake port 9 is provided and approximately in the center of the rear surface. Note that there is no limitation on the positions where the float 7 and weight 8 are attached to the collection body 6, and this is determined according to the site conditions where the present invention is used.

The collector 6 is provided with a water collection section 10 that stores the captured water. A collection path 11 is provided to efficiently capture surface water into the water collection section 10, and the collection path 11 has opposing side walls that gradually narrow from the intake port 9.

A flow plate 14 is installed as a bottom plate extending from the lower end 13 of the intake 9 to the inside of the collection body 6. By providing this flow plate 14, when water with oil suspended therein flows in from the intake 9, the water with oil at the top can pass through the collection path 11 without being stirred, for example, by forming a vortex.

In other words, the flow plate 14 allows the oil to pass through the collection path 11 while still suspended in the water. As a result, the oil flows in a fixed direction on the flow plate 14 without being stirred, while still suspended in the water, improving the accuracy of the oil detection means 3 described below in detecting the oil. Note that the flow plate 14 is not limited to a configuration that extends inward from the lower end 13 of the intake port, so long as the water flowing in from the intake port 9 can flow toward the water collection section 10. For example, the flow plate 14 may be connected from a position slightly below the lower end 13 of the intake port, and the flow plate 14 may extend inward, creating a step.

Here, FIG. 3 is a schematic diagram showing the gradient of the collector 6. The arrows in FIG. 3 indicate the direction of flow of the inflowing water. As shown in FIG. 3, in order to facilitate the flow of water into the water collection section 10, the height of the water surface stored in the water collection section 10 is adjusted to be lower than the water level around the oil collection device 2 (e.g., the surface water level of a water utilization dam lake). Therefore, in order to adjust the height of the water surface in the water collection section 10, a moisture discharge means 12 for discharging moisture is provided in the water collection section 10. The moisture discharge means 12 is, for example, a pump type, and is installed below the side of the water collection section 10 opposite the intake port 9 of the oil collection device 2.

The intake port 9 of the collector 6 is adjusted to be submerged below the surface water level of the water-utilization dam lake, for example (see Figure 3). Therefore, the draft and attitude of the oil collector 2 are adjusted according to the relationship between the weight of the weight 8, the buoyancy of the float 7, the water stored in the water collection section 10, and the weight of the water discharge means 12.

Specifically, as can be seen from FIG. 3, the draft and attitude of the oil collector 2 are adjusted so that the water depth from the lower end 13 of the intake 9 is 5 mm or less, the rear surface (rear side) of the collector 6 facing the intake 9 is lower (deeper) than the intake 9, and the flow plate 14 extending from the lower end 13 of the intake 9 is inclined downward from the intake 9 side to the rear side. At this time, the amount of inflow and the force of the water flowing into the oil collector 2 change depending on the depth to which the lower end 13 of the intake is submerged from the water surface and the inclination angle of the flow plate 14, so adjusting the draft and attitude of the oil collector 2 is an important component of the present invention.

Furthermore, the amount of water discharged by the water discharge means 12 is adjusted in relation to the amount of water inflow so that this state is maintained during operation. A sensor-type on/off switching means (not shown) may be provided to automatically stop the water discharge means 12 when the amount of water stored in the water collection section 10 falls below a predetermined standard.

Next, the oil detection means 3 shown in Figures 2 and 3 is installed on the collection path 11 of the oil collection device 2. As an example of a method for installing the oil detection means 3, it is installed on a construction vessel 5 via a mounting stand, and is adjusted so that a laser can be irradiated perpendicularly to the water surface on the collection path 11 on average in response to the swaying (tilt) of the construction vessel 5 due to waves, etc. Therefore, the presence or absence of oil can be detected by irradiating the surface water passing through the collection path 11 of the oil detection means 3 with a laser or the like and receiving the reflected light.

Even in this case, the flow plate 14 extends from the lower end 13 of the inlet 9 to the inside of the collector 6, so that the oil flows in a fixed direction above the flow plate 14 while suspended in water, allowing the oil detection means 3 to detect the presence or absence of oil from the water flowing above the flow plate 14, thereby improving the accuracy of oil detection.

If the oil detection means 3 detects oil, a specified alarm system will issue an alarm to information terminals such as smartphones and personal computers of construction workers, as well as to water purification plants, etc. Construction workers can then visually check for the presence of oil inside the guiding fence 1, and if oil is found, they can take immediate action, such as responding to an oil leak.

Next, the water flow generating means 4 will be described.
In the present invention, the water current generating means 4 is installed, for example, at two locations within the guide fence 1 (see FIG. 1 ) and generates a water current toward the oil collecting device 2. The arrows in FIG. 1 indicate the direction in which the water flows.

The water flow generating means 4 can be, for example, a generator (25KVA big tank specification) installed on land and a relatively high-output 3.7Kw submersible pump installed, which can generate a jet water flow by discharging the water from this submersible pump. The generated jet water flow then guides the water flow toward the oil collection device 2 within the guide fence 1. This makes it possible to guide surface water toward the oil collection device 2 even in strong winds.

Note that the pump is not limited to an underwater pump, as long as it can generate a water flow toward the oil collecting device 2. It is also possible to branch the drainage outlet of the water flow generating means 4 into two locations, so that jet water flows can be generated from two locations to efficiently guide the water flow.

Next, an example of the operation of the oil detection system of the present invention will be described.
Water currents (jet water currents) are generated by water current generating means 4 installed at two points within the guide fence 1, and the surface water within the guide fence 1 is guided toward the oil collection device 2. The guide fence 1 is arranged so that its width gradually narrows toward the oil collection device 2, so that the water currents generated by the water current generating means 4 reliably and efficiently guide the surface water toward the oil collection device 2.

Here, the lower end 13 of the intake 9 of the oil collecting device 2 is adjusted to be submerged about 5 mm below the surface water level of the water supply dam lake, and the oil collecting device 2 is held in an inclined state so that the flow plate 14 has a downward slope as it moves rearward from the intake 9. Furthermore, the height of the water surface stored in the water collecting section 10 of the oil collecting device 2 is adjusted by the moisture discharge means 12 so that a water level difference occurs, lowering the height of the water surface stored in the water collecting section 10 of the oil collecting device 2 below the surface water level of the water supply dam lake. The moisture discharge means 12 is configured to stop when the amount of water stored in the water collecting section 10 falls below a predetermined standard.

In other words, the lower end 13 of the intake port is positioned lower than the water level of the water supply dam lake, the flow plate 14 is provided with a downward slope, and the height of the water surface that is always stored is adjusted to be lower than the surface water level of the water supply dam lake to create a water level difference, so that the surface water can be drawn from the intake port 9 into the collection body 6 reliably and efficiently, and the surface water of the water supply dam lake can be collected so that it flows into the water collection section 10.

The surface water of the water supply dam lake that passes through the collection path 11 of the oil collection device 2 is irradiated with a laser from the oil detection means 3, and oil is detected by changes in the reflected light. Even in this case, since the collection path 11 is provided and the flow plate 14 is installed, the inflowing water is less likely to be stirred and tends to flow stably in a certain direction, so oil can be reliably detected.

If oil is detected in the surface water of a water supply dam lake, a designated notification system will notify construction workers (an alarm will be issued to each worker's information terminal, the water purification plant, the on-site office, etc.), and construction workers will immediately travel across the lake in a mobile boat, for example, to check for the leaked oil, drop in an absorbent mat (for example Magic Fiber (registered trademark)) to absorb and recover it, and also drop in powdered activated carbon, for example, to deodorize it. Note that if activated carbon is used, it will settle and there is no need to collect it. Water pollution can then be prevented by identifying the cause of the oil leak and taking measures to prevent it from leaking.

This oil detection system is basically operated during construction work, and is intended to detect oils such as gasoline, diesel, hydraulic oil, and grease used on work boats and work machinery, but it can also be applied to oils other than those listed above in environments where measures to prevent water pollution by oil are required.

REFERENCE SIGNS LIST 1 Guidance fence 2 Oil collecting device 3 Oil detecting means 4 Water flow generating means 5 Construction vessel 6 Collector 7 Float 8 Weight 9 Intake 10 Water collecting section 11 Collection channel 12 Moisture discharge means 13 Intake lower end 14 Flow plate

Claims (3)

The oil collection system comprises an oil collection device which collects water containing floating oil, an oil detection means which detects oil from the water collected by the oil collection device, a diffusion prevention means which is disposed to surround the oil leakage control object and the oil collection device and which prevents the diffusion of the oil floating in the water, and a water flow generating means which generates a water flow so that the oil flows toward the oil collection device,
The oil collecting device has an inlet through which water flows in, and a water discharge means for discharging water in the oil collecting device from within the oil collecting device,
a water flow generating means for generating a water flow within the range surrounded by the diffusion prevention means, so that water containing floating oil flows toward the oil collecting device, and the oil detecting means detects oil from the water that flows into the oil collecting device;
An oil detection system comprising:
The oil collecting device has a flow plate through which the water flowing in from the intake flows, and is adjusted and installed so that the lower end of the intake is lower than the water level;
The oil detection means detects oil from the water flowing on the flow plate.
2. The oil detection system according to claim 1.
The flow plate is held in an inclined state so that the side facing the intake port is lower than the intake port side.
3. The oil detection system according to claim 2.

Images