JPS6334924B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention aims at leveling the upper part of a rubble layer formed on the water bottom as a foundation for quay walls, seawalls, and other underwater structures by using a vibrating underwater rubble leveling machine that vibrates vertically. This relates to a vibrating underwater rubble leveling method for leveling the ground.

Underwater structures such as quay walls and seawalls are made up of a layer of rubble formed on the water bottom. L-shaped block. It is generally composed of cells, etc. This rubble layer is usually formed by throwing stones into the water at a certain width, but if the stones are simply thrown into the water, the upper part of the rubble layer formed on the water bottom will undulate; The structure being constructed has poor stability. Therefore,
The top of this rubble layer needs to be leveled almost horizontally.

This leveling method involves vertically vibrating a vibrating underwater rubble leveling machine suspended from a crane on a work boat on the underwater rubble layer, and at the same time moving the vertical scale on the vibrating underwater rubble leveling machine to the quay. While measuring the water depth below the sea surface with the vibrating underwater rubble leveling machine by measuring with a transit installed at A method is being considered to equalize the

However, this method has the problem that the leveling site is far away from the quay, or it is impossible to perform the work in areas where there is fog.

The purpose of the present invention is to provide an underwater rubble leveling method that solves this problem by detecting changes in the water depth on the top surface of the underwater rubble layer, and vibration of the leveling weight of the vibrating underwater rubble leveling machine. By controlling the number of layers, the top surface of the underwater rubble layer is leveled to a constant water depth regardless of the leveling location or mist.

Embodiments of the present invention will be described below with reference to the drawings.

In FIG. 1, 1 is a hook of a crane of a work boat (not shown), and 2 is a vibrating underwater rubble leveler suspended from the hook 1. This vibrating underwater rubble leveling machine 2 has a leveling weight 3, a casing 4 for storing vibrators fixed on the leveling weight 3, and a manhole 5 connected to the casing 4. Note that a vibro (vibration generator) that vertically vibrates (vertically vibrates) the entire vibrating underwater rubble leveler 2 is housed in the casing 4.

An air pipe 6, which is the main body of the water depth measuring device, is attached to the side of the manhole 5. As shown in FIGS. 2 and 3, this air pipe 6 opens downward, and the tip of an air supply pipe 7 is disposed directly below it, and these openings face each other. ing. Inside this air supply pipe 7 is a one-way valve 8 which closes as shown in FIG. 2 under external water pressure and opens as shown in FIG. 3 under internal air pressure.
is installed. In FIG. 1, 9 is a valve interposed in the middle of the air supply pipe.

Furthermore, in FIG. 1, a pressure gauge 10 is connected to the upper end of the air pipe 6. This pressure gauge 10
is designed to indicate the pressure inside the air pipe 6, convert the amount of pressure change into an amount of electrical change, and output it. The electrical output terminal of this pressure gauge 10 is connected to the input terminal of the central processing unit 11. This central processing unit 11 includes a control panel 1 that controls the vibration of the vibro in the casing 4.
2, and the vibration frequency of the vibro is controlled in accordance with changes in the indicated value of the pressure gauge 10. In the figure, 13 is an underwater rubble layer, and 14 is the upper surface of the underwater rubble layer 13.

Next, we will introduce the vibrating underwater rubble leveling machine 2 with this configuration.
A vibration leveling method for leveling the upper surface 14 of the underwater rubble layer 13 using the following will be explained.

First, the valve 9 is opened and air is pumped to the tip end of the air supply pipe 7 using an air pump (not shown). As a result, when the pressure inside the air supply pipe 7 becomes higher than the outside water pressure, the one-way valve 8 opens as shown in FIG. 3, and air flows out from the tip of the air supply pipe 7 in the form of bubbles. Thereafter, the bubbled air flows into the air pipe 6, and when the air pipe 6 is filled with air, the air overflows from the lower end of the air pipe 6 and floats to the water surface. After confirming this floating air on the work boat, the valve 9 is closed to stop the air supply.

Next, with the leveling weight 3 placed on the upper surface 14 of the underwater rubble layer 13 as shown in FIG. , move this horizontally. At this time, the pressure change within the air pipe 6 is converted into an electrical variation via the pressure gauge 10, and this electrical variation is constantly input to the central processing unit 11. And this central processing unit 1
1 calculates the water depth to the bottom surface of the leveling weight 3 from this input electric change signal and controls the control panel 12, and when the water depth of the leveling weight 3 becomes deeper and reaches a certain value, the vibro is activated. Decrease vibration frequency. In this way, the upper surface 1 of the underwater rubble layer 13
4 is leveled at a constant depth.

Fig. 1 shows an example in which the main body of the water depth measuring device is attached to the vibrating underwater rubble leveling machine 2 with a manhole 5 protruding above the sea surface 15, but as shown in Fig. 4, a vibrating type without a manhole 5 The main body of the water depth measuring device may be attached to the underwater rubble leveling machine 2'. In the figure, 16
is the hanging wire.

Further, in the embodiment described above, the pressure gauge 10 is used to measure the water depth of the vibrating underwater rubble leveling machine 2, 2', but the invention is not necessarily limited to this. The water depth of the vibrating underwater rubble leveling machine may be measured using the water depth measuring device shown in FIG. 8 (described later).

That is, in FIG. 5, a wire 18 wound around the upper end of the torque winch 17 is attached to the upper end of the vibrating underwater rubble leveler 2, and the amount of wire 18 fed out is measured by a rotating drum-type movement amount detector 19. You may also do so. Note that this movement amount detector 19 uses a drum 2 around which the wire 18 is wound several times.
0 and a sliding variable resistor (not shown) interlocked with this drum 20. The electrical signal from this variable resistor is input to the central processing unit 11.

Note that the output side terminal of the control panel 12 into which the electrical signal from the central processing unit 11 is input is connected to a vibro-starting panel 29 via a generator 28. Further, the other output side terminal of the control panel 12 is connected to a vibro activation panel 29. Furthermore, Vibro activation board 2
The output terminal of 9 is connected to the input terminal of the vibro 30 indicated by a chain line. In this case, the control panel 12
The generator 28 is started by the signal from the control panel 12, which activates the vibro starting board 29. This control is done by giving the signal from the control board 12 to the hydraulic motor in the hydraulic circuit, which is operated by the vibro starting board. The vibro 30 is set to operate in accordance with the signal.

Further, arms 21, 21 extending horizontally are attached to the upper part of the casing 4 as shown in FIG. 6, pulleys 22, 23 are attached to the base and tip of each arm 21, and the amount of movement is detected as shown in FIG. Sounding same as vessel
The wire 18 connected to the DMA 24 is connected to the pulley 22,
23, and a buoy 25 with a built-in ultrasonic sounder may be attached to the tip of the wire 18. In this case, the configuration is such that one or both of the depth h ₁ from the sea surface 15 to the buoy 25 and the depth h ₂ from the buoy 25 to the top surface 14 of the rubble layer 13 are measured. Good too. Also, sounding
By continuously measuring the water depth from the amount of wire 18 to the buoy 25 using the DMA 24, and comparing this measured value with the measured value by the ultrasonic sounder inside the buoy 25, this ultrasonic sounding can be performed. In addition to checking the equipment, the water depth of the vibrating underwater rubble leveler 2 may also be measured. In this case, buoys 25, 2 on the left and right in the diagram
The amount of inclination of the vibrating underwater rubble leveler 2 can be detected from the difference in the water depth _h1 between the two, and the subsequent control can be performed.

Furthermore, as shown in FIG. 7, buoy 25 in FIG.
Reflector plate 26 instead of accommodating an ultrasonic depth sounder inside
is installed horizontally, and the ultrasonic depth sounder 28 is installed on the work boat 27 by positioning it directly above the buoy 25, so that the ultrasonic sounder 28 emits ultrasonic waves toward the reflecting plate 26, and The depth to the buoy 25 may be measured by detecting the ultrasonic waves reflected by the reflection plate 26 with the ultrasonic depth sounder 28. In this case, the depth from buoy 25 to arm 21 can be detected by the depth sounding DMA described above,
Since the depth from 1 to the bottom of the leveling weight 3 is constant, by adding these water depths and the water depth of the buoy 25 by the central processing unit, the depth of the rubble layer 1
3. Water depth up to the upper surface 14 can be obtained.

Furthermore, as shown in FIG. 8, the leveling state of the upper surface 14 of the rubble layer 13 may be detected by measuring the water depth before and after the leveling direction of the vibrating underwater rubble leveler 2. In this embodiment, as water depth measuring instruments, a torque winch 17', a movement amount detector 19', and a torque winch 1, which are the same as those shown in FIG.
A test plate 29 is attached to the lower end of a wire 18' that is fed out from the wire 7'.

As explained above, the present invention continuously detects changes in water depth on the top surface of underwater rubble using a water depth measuring device that uses air pressure to control the vibration frequency of the leveling weight. Regardless of fog etc.
The top surface of underwater rubble can be leveled to a constant water depth. In particular, the water depth measuring device of the present invention does not malfunction or break due to the vibrations of the vibrating underwater rubble leveler, thereby making it possible to stably maintain measurement accuracy. The reliability of the construction method as a whole will be significantly improved.

[Brief explanation of the drawing]

FIG. 1 is a partial sectional view showing the relationship between the vibrating underwater rubble leveler used in the construction method of the present invention and the rubble layer. 2 and 3 are sectional views around the lower end of the air pipe in FIG. 1. 4 to 8 are partial cross-sectional views showing other embodiments of the present invention. 2, 2'... Vibrating underwater rubble leveler, 3... Leveling weight, 6... Air pipe, 10... Pressure gauge, 11... Central processing unit, 12... Control panel, 13... Underwater Rubble layer, 14...Top surface, 18,
18'...Wire, 19,19'...Movement amount detector, 20,20'...Drum, 25...Buoy, 2
6...Reflector, 28...Ultrasonic depth sounder, 29...
Inspection board.

Claims (1)

[Claims] 1. An underwater rubble leveling method in which the weight of a vibrating underwater rubble leveling machine placed on the underwater rubble layer is moved in the horizontal direction while vibrating with a vibro to level the upper surface of the underwater rubble layer. In the above-mentioned vibrating underwater rubble leveling machine, an air pipe extending in the vertical direction and having a lower end opened in the water, an air supply pipe having an air supply port facing the opening of the air pipe, and an air supply pipe extending from the air supply pipe. A water depth measuring device equipped with a pressure gauge that detects the pressure of the air supplied to the air pipe is attached, and the water depth measuring device detects the top surface of the rubble layer, and the water depth measuring device is linked to changes in the output signal from the water depth measuring device. An underwater rubble vibration leveling method characterized in that the upper surface of the rubble layer is leveled to a constant water depth using a leveling weight by controlling the vibration frequency of the vibro.