KR200481033Y1 - Draft measuring devices - Google Patents

Abstract

The present invention relates to a hull structure comprising a hollow seawater inflow pipe extending along a draft indication point of a shellboard and inflowing seawater to the inside, a magnetic force member magnetically attached to the hull shell, and both ends in the longitudinal direction of the seawater inflow pipe and the magnetic member A connecting member for connecting the seawater inflow pipe to the outer shell of the ship, a movable member installed in the seawater inflow pipe so as to be movable along the longitudinal direction, and moving up and down in the seawater inflow pipe according to the seawater flowing into the seawater inflow pipe And a sensor unit provided inside the float and the seawater inflow pipe for detecting the position of the float and outputting the detected position information to the outside.
In such a draft measuring device, after the seawater inflow pipe having the floating body disposed inside is fixedly arranged on the shipboard shell by the magnetic member and the connecting member, the sensor unit detects the position of the floating body and outputs the detected position information to the outside , It is possible to perform the draft measurement easily and stably.

Description

Draft measuring devices

The present invention relates to a draft measuring apparatus, and more particularly, to a draft measuring apparatus capable of conveniently performing a measurement of a required draft at the time of an abrupt test or a tilt test of a ship.

In general, ship's resilience in shipbuilding is one of the most important factors to be considered on ship because it is a basic matter for cargo loading when loading. For this purpose, the ship makes various data related to the restoration of the hull after drying (calculation of the trim & stability and damage stability calculation). At this time, the light weight and the weight center of the ship itself should be grasped.

First, the light ship weight can be calculated from the displacement and the deadweight, that is, the light weight corresponds to the difference between the displacement and the mass. In this case, the amount of drainage is calculated by Draft reading on the hull at the seawall, and the deadweight is calculated through deadweight measurement.

In addition, the center of gravity has a vertical center of gravity (VCG), a longitudinal center of gravity (LCG) and a transverse center of gravity (TCG), which have the greatest influence on the restoring force of the hull. Gravity, which is calculated from the inclination test, which forces the ship to tilt. In other words, the mid-range test is carried out in order to determine the weight of the ship, and the tilt test is performed in order to obtain the center of the height by forcing the hull to the center of gravity,

In order to accomplish this purpose, when performing the mid / slope test, the ship moored at the quay wall is separated from the ship so that the ship is not affected by the external external force. Particularly, check of the draft before the middle / slope test is performed by moving the work boat to the DRAFT MARK point indicated on the outer shell of the hull, Of equipment.

In this case, since the measuring person directly measures the draft with the hand extended, it may be accompanied by a stenosis phenomenon between the work line and the hull due to external environmental factors such as waves and winds. And remains as a generating element.

This conventional draft measurement is disclosed in Korean Patent Laid-Open Publication No. 2001-0112720.

The object of the present invention is to provide a draft measuring apparatus capable of easily measuring the draft of the hull during the heavy / sloping test after the drying of the ship, thereby preventing the occurrence of safety accidents and reducing the measurement time have.

The present invention relates to a hull structure comprising a hollow shaped seawater inlet pipe extending along a draft indication point of a shellboard and having seawater flow inward, a magnetic force member magnetically attached to the shell shell, A connecting member which is connected to the magnetic force member and fixes the seawater inflow pipe to the outer shell of the hull, a movable member installed in the seawater inflow pipe so as to be movable along the longitudinal direction, And a sensor unit installed inside the seawater inflow pipe for detecting the position of the float and outputting the detected position information to the outside.

In addition, the connection member may include a connection groove formed at a center in a longitudinal direction thereof and having a lengthwise one end hinged to be rotatably hinged to the magnetic force member, one end of the connection groove is inserted into the position adjustment groove, And a fixing screw fastened to the inflow pipe and provided with a lever at the other end to enable gripping of an operator.

The sensor unit may include a laser sensor disposed inside the upper end of the seawater inflow pipe and a reflector installed on the float to reflect the optical signal output from the laser sensor.

The seawater inflow pipe may include an upper pipe into which the laser sensor of the sensor unit is inserted and a lower pipe connected to the lower portion of the upper pipe and into which the floating water is inserted and into which the seawater flows, And a blocking plate may be interposed between the upper tube and the lower tube to block inflow of the seawater introduced from the lower tube into the upper tube.

In addition, a cap for sealing the upper portion of the upper tube is coupled to the upper end of the upper tube, and a pressing protrusion bar connected to the laser sensor is formed at a lower portion of the cap. When the operator presses the cap, A bar may enable the laser sensor to operate.

The draft measuring apparatus according to the present invention is characterized in that a seawater inflow pipe in which a floating body is installed inside is fixedly arranged on a shipboard shell by a magnetic member and a connecting member and then the position of the sensor unit float is detected and the detected position information is output to the outside Bar and draft measurements can be performed easily and stably.

1 is a perspective view of a draft measuring apparatus according to an embodiment of the present invention.
2 is a perspective view of a draft measuring apparatus according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a draft measuring apparatus according to an embodiment of the present invention. Referring to FIG. 1, the draft measuring apparatus includes a seawater inlet pipe 100, a magnetic force member 200, a connecting member 300, a float 400, and a sensor unit 500.

The seawater inlet pipe 100 is a hollow pipe structure extending along the draft indication point of the outer shell of the ship. In this way, seawater flows into the inside of the seawater inflow pipe 100. Here, the seawater inlet pipe 100 includes an upper pipe 110 and a lower pipe 120.

The upper tube 110 is a tube portion into which the laser sensor 510 of the sensor unit 500 to be described later is inserted. That is, the upper tube 110 is connected to the upper end of the lower tube 120 with the lower end inserted with the laser sensor 510 inserted therein. At this time, a first blocking plate 111 is coupled to a lower end of the upper pipe 110 to be separated from the lower pipe 120. Here, the first blocking plate 111 is made of a transparent material so as to transmit the optical signal output from the laser sensor 510. The upper end of the upper tube 110 may be provided with a cap 112 for sealing the upper end of the upper tube 110. At this time, a descending ball bar 113 connected to the laser sensor 510 may be extended downwardly below the cap 112. When the pushing force of the cap 112 is generated by the operator, the push rod mechanism 113 transmits the generated pushing force to the laser sensor 510 so that the laser sensor 510 operates, .

The lower tube 120 is a tube portion in which the float 400 to be described later and the reflection plate 520 of the sensor unit 500 are inserted. That is, the lower portion of the lower tube 120 is opened to allow the seawater to flow into the lower tube 120, and the float 400 and the reflector 120 are disposed inside the lower tube 120 according to the amount of the seawater flowing into the lower tube 120, The guide member 520 is guided to move up and down. The upper end of the lower tube 120 is coupled to the lower end of the upper tube 110. At this time, a second blocking plate 121 is coupled to the upper end of the lower tube 120 to be separated from the upper tube 110. Here, the second blocking plate 121 is made of a transparent material so as to transmit the optical signal output from the laser sensor 510, like the first blocking plate 111 described above. The lower pipe 120 and the upper pipe 110 are connected to each other by the pin member 101 in a horizontal state between the second blocking plate 121 and the first blocking plate 111. At this time, the second blocking plate 121 and the first blocking plate 111 are separated from each other to be connected to each other, and air is introduced between the second blocking plate 121 and the first blocking plate 111 Allowing them to pass through, thereby reducing wind resistance.

An extension hose 130 may be connected to the lower end of the lower tube 120 to extend the lower tube 120. The extension hose 130 may extend the distance of the seawater introduced into the lower pipe 120 and increase the water level of the seawater outside the lower pipe 120 even if the water level is suddenly changed due to wind or impact. Thereby minimizing changes in the water level of the seawater flowing into the lower tube 120.

The magnetic force member 200 allows the seawater inlet pipe 100 to be fixedly attached to the outer shell of the hull. The magnetic force member 200 is attached and fixed to the outer shell of the ship by a magnetic force and is attached to the outer shell of the ship by a magnetic force in a state where the seawater inlet pipe 100 is connected to a connecting member 300 to be described later . It should be noted that the magnetic force member 200 may be a permanent magnet or an electromagnet.

The connection member 300 is a member that connects the seawater inlet pipe 100 to the magnetic force member 200. That is, the connecting member 300 connects the seawater inlet pipe 100 to the magnetic force member 200 attached to the outer shell of the hull, so that the seawater inlet pipe 100 is fixed to the outer shell of the hull, . One end in the longitudinal direction of the connecting member 300 is connected to one side of the magnetic force member 200 and the other end in the longitudinal direction of the connecting member 300 is rotatably connected to one side of the sea water inflow pipe 100 Lt; / RTI > At this time, one longitudinal end and the other end of the connecting member 300 are rotatably connected to the magnetic force member 200 and the seawater inlet pipe 100, respectively, so that the operator can rotate the seawater inlet pipe 100, It is possible to adjust the position so that the air conditioner 100 is vertically disposed on the sea surface and then fix it. Here, the connection member 300 includes a connection bar 310 and a fixing screw 320.

The connection bar 310 is a bar member connecting the magnetic force member 200 and the seawater inlet pipe 100. One end in the longitudinal direction of the connecting bar 310 is rotatably hinged to one side of the magnetic force member 200 and the other end in the longitudinal direction is rotatably supported on the seawater inlet pipe 100 through the fixing screw 320. [ Possibly connected. At this time, a position adjusting groove 311 through which the fixing screw 320 is inserted is formed at the longitudinal center of the connecting bar 310. The position adjusting groove 311 allows the position of the fixing screw 320 coupled to the seawater inlet pipe 100 to be adjusted with respect to the longitudinal direction of the connecting bar 310, 100 and the magnetic force member 200 to adjust the position of the seawater inlet pipe 100 in a direction perpendicular to the sea surface so that the operation can be easily performed. One end of the connecting bar 310 in the longitudinal direction is rotatably installed in a hooked state by a bolt member fastened to the magnetic force member 200. After the position of the seawater inlet pipe 100 is adjusted So that one end of the connecting bar 310 in the longitudinal direction can be fixedly coupled to the magnetic force member 200 by tightening the bolt member.

The fixing screw 320 is a member which is fastened to one side of the seawater inlet pipe 100 in a state where the fixing screw 320 is inserted into the position adjusting groove 311 of the connecting bar 310. That is, the fixing screw 320 connects the other end of the connecting bar 310 to the seawater inlet pipe 100. After the position of the seawater inlet pipe 100 is adjusted by the fixing screw 320 while the other end of the connecting bar 310 is connected to the seawater inlet pipe 100, So that the other end of the connecting bar 310 can be fixedly coupled to the seawater inlet pipe 100. A lever 321 may be formed at the other end of the fixing screw 320 to facilitate gripping or unclamping operation of the fixing screw 320 by an operator.

2 is a perspective view illustrating another example of the connecting member 301. The bar member 301a and 301c are interconnected by a universal joint 301b so that the magnetic force member 200 and the seawater inlet pipe 100 May be made easier than the configuration of the connection bar 310 and the fixing screw 320 described above.

The float 400 is a member that is installed in the seawater inflow pipe 100 so as to be movable along the longitudinal direction of the seawater inflow pipe 100. The float 400 is inserted into the lower pipe 120 of the seawater inlet pipe 100 and inserted into the lower pipe 120 according to the level of the seawater flowing into the lower pipe 120, And moves in the vertical direction from the inside. Here, the float 400 may be made of Styrofoam, but it is not limited thereto. A buoyant material such as wood may be selectively applied.

The sensor unit 500 detects the position of the float 400 in the height direction inside the lower pipe 120 of the seawater inflow pipe 100 while being installed inside the seawater inflow pipe 100, And outputs information to the outside. The sensor unit 500 includes a laser sensor 510 and a reflection plate 520.

The laser sensor 510 is installed inside the upper tube 110 of the seawater inlet pipe 100 and emits an optical signal in the direction of the reflection plate 520. That is, after the laser sensor 510 irradiates an optical signal toward the reflection plate 520, the laser sensor 510 converts the return time of the light reflected through the reflection plate 520 into a distance, And outputs the measured draft value to the outside.

The reflector 520 is coupled to the float 400 so as to be opposed to the laser sensor 510 to reflect the optical signal output from the laser sensor 510 back to the laser sensor 510 . The reflection plate 520 is made of a material such as a mirror for reflecting light.

The seawater inlet pipe 400 is connected to the bottom pipe 120 of the water inflow pipe 400 so that the seawater is introduced into the bottom pipe 120 of the water inflow pipe 400, The upper pipe 110 and the lower pipe 120 of the hull are fixedly attached to the outer shell of the hull so as to be perpendicular to the sea surface. That is, after the magnetic force member 200 is attached and fixed to the outer shell of the hull, the both ends of the connecting member 300 and the magnetic force member 200, And adjusts the fastening position of the sea water inflow pipe (400). First, after adjusting the degree of rotation of one end in the longitudinal direction of the connection member 300 connected to the magnetic force member 200, the other end in the longitudinal direction of the connection member 300 by the fixing screw 320, The connection portions of the magnetic force member 200 and the seawater inlet pipe 400 connected to both longitudinal ends of the connection member 300 are fixedly coupled after the connection position of the inlet pipe 400 is adjusted.

The operator then presses the stopper 112 to operate the laser sensor 510 so that the laser sensor 510 irradiates an optical signal toward the reflection plate 520 and transmits the optical signal through the reflection plate 520 The return time of the reflected light is converted into a distance to grasp the position information of the float 400 and to output the measured draft value to the outside.

In this way, the draft measuring apparatus according to an embodiment is configured such that the seawater inlet pipe 100 in which the float 400 is installed is fixed to the hull girder plate by the magnetic force member 200 and the connecting member 300 The sensor unit 500 detects the position of the float 400 and outputs the detected position information to the outside so that the draft measurement can be performed easily and stably.

Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that various modifications and equivalents may be made thereto by those skilled in the art. Accordingly, the true scope of technical protection of the present invention should be determined by the technical idea of the appended utility model registration claim scope.

100: Seawater inflow pipe 110: Upper pipe
120: lower tube 130: extension hose
200: magnetic force member 300: connecting member
310: connecting bar 320: fastening screw
400: float 500: sensor part
510: laser sensor 520: reflector

Claims (5)

A hollow-shaped seawater inlet pipe extending along a draft indication point of the outer shell of the ship,
A magnetic force member magnetically attached to the outer shell of the hull;
A connecting member connected at both ends in the longitudinal direction to the seawater inlet pipe and the magnetic force member to fix the seawater inlet pipe to the outer shell of the hull;
A float which is installed in the seawater inflow pipe so as to be movable along the longitudinal direction and moves up and down in the seawater inflow pipe according to the seawater flowing into the seawater inflow pipe; And
And a sensor unit installed inside the seawater inflow pipe for detecting the position of the float and outputting the detected position information to the outside,
The longitudinal directional end of the connecting member is rotatably connected to the magnetic force member and the other longitudinal directional end of the connecting member is rotatably connected to the seawater inlet pipe so that the operator can rotate the seawater inlet pipe To be positioned so as to be perpendicular to the sea surface and then to be fixedly installed,
The connecting member is provided with a positioning groove at the center in the longitudinal direction, a connecting bar having one end in the longitudinal direction hinged to the magnetic force member so as to be rotatable, one end of the connecting bar being inserted into the positioning groove, And the other end of which is provided with a lever that enables gripping of the worker. A hollow-shaped seawater inlet pipe extending along a draft indication point of the outer shell of the ship,
A magnetic force member magnetically attached to the outer shell of the hull;
A connecting member connected at both ends in the longitudinal direction to the seawater inlet pipe and the magnetic force member to fix the seawater inlet pipe to the outer shell of the hull;
A float which is installed in the seawater inflow pipe so as to be movable along the longitudinal direction and moves up and down in the seawater inflow pipe according to the seawater flowing into the seawater inflow pipe; And
And a sensor unit installed inside the seawater inflow pipe for detecting the position of the float and outputting the detected position information to the outside,
The longitudinal directional end of the connecting member is rotatably connected to the magnetic force member and the other longitudinal directional end of the connecting member is rotatably connected to the seawater inlet pipe so that the operator can rotate the seawater inlet pipe To be positioned so as to be perpendicular to the sea surface and then to be fixedly installed,
Wherein the connecting member is connected to a plurality of bar-shaped bars by a universal joint. The method according to claim 1 or 2,
The sensor unit includes:
A laser sensor installed inside the upper end of the seawater inflow pipe,
And a reflector installed in the float to reflect the optical signal output from the laser sensor. The method of claim 3,
The seawater inflow pipe includes:
An upper tube into which a laser sensor of the sensor unit is inserted,
And a lower pipe connected to the lower portion of the upper pipe and into which the floating water is inserted and into which the seawater flows,
And a shield plate interposed between the upper tube and the lower tube for blocking inflow of the seawater introduced from the lower tube into the upper tube. The method of claim 4,
A cap for sealing an upper portion of the upper tube is coupled to an upper end of the upper tube,
And a pushing protrusion bar connected to the laser sensor is formed at a lower portion of the stopper so that the pushing protrusion bar actuates the laser sensor when an operator presses the stopper.

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