KR102067166B1 - Automatic control system of wave height gauge calibration - Google Patents

Abstract

The present invention relates to a wave-height meter calibration automatic control system. More specifically, the wave-height meter calibration automatic control system enables installation of a plurality of capacitive wave-height meters on a lifting table and enabling simultaneous lifting operation of each capacitive wave-height meter. Therefore, the wave-height meter calibration automatic control system can provide convenience of measurement work and greatly reduce the working time such as convenience of installing the capacitive wave-height meter and enabling collective measurement and so on. In particular, the wave-height meter calibration automatic control system enables the plurality of capacitive wave-height meters to simultaneously perform the same lifting operation, thereby increasing measurement accuracy.

Description

Automatic control system of wave height gauge calibration

The present invention relates to a crest height calibration control system, and more particularly to a crest height calibration automatic control system for improving the accuracy of the up and down lifting operation, while enabling the installation of a plurality of capacitive crest meter.

In general, meteorological observation at sea and offshore is an essential item for ocean and port investigation to identify marine phenomena such as marine structures, marine environment, fishing, navigational safety and meteorological phenomena. The most important and basic part of such marine or port investigation is the measurement of the marine environment such as waves, wind, and tides.

In particular, various vessels and offshore structures are reviewed in the initial design stage, and various performances such as resistance and movement of ships and offshore structures in the target area are examined and reflected in the final design. At this time, in performing the model test, characteristics of the target sea area such as waves, wind, and tidal current should be reproduced in the test tank. At this time, the wave acting as the largest external force in ships and offshore structures is one of the most important environmental factors and precise measurement is required.

On the other hand, the measurement of the crest is largely divided into an indirect measurement method for measuring the change in physical quantity caused by the change of the sea level and obtaining an indirect elevation of the sea level, and a direct measurement method for directly measuring the elevation of the sea level. Here, the indirect measurement method includes a method using a change in air pressure, a method using an accelerometer and using an acceleration change, a method using a buoyant crest meter, and a method using a hydraulic crest meter. On the other hand, direct measurement methods include optical methods using categorical methods, stereography, stereotyped crestometers, and spadiactic crestometers, acoustic methods using underwater-type ultrasonic crestometers, and airborne ultrasonic crestometers, and buzzer crestometers. There is a mechanical method using a parallel type crestometer, a resistance crestometer, a stepped crestometer, an electric method using a capacitive crestometer and the like. Various types of crest measurement methods and crest meters applied to the crest measurement methods have been variously proposed.

Among them, a capacitive crest meter having excellent linearity and responsiveness to an output value is typically used. The capacitive crest meter has an insulated sheath (electric insulator) wire having an axis (conductor that is easily connected to electricity) when the conductor is placed in water. Capacitor is formed between and water. Since water is at 0 level (G: Ground), a potential difference is generated between the metal conductors, and the insulator between them becomes a capacitor movement. The capacitance of the capacitor portion changes as the depth of the electrostatic capacity changes, and the change is proportional, so that the depth increases, the capacitance increases, and when the depth decreases, the capacitance decreases. This capacitance is converted into a voltage proportional to that inside the detection, and amplified again in the crest body, and numerically converted from the reference level to output.

That is, the oscillation unit which detects through the axis of the capacitive wavemeter for detecting the capacitance value that is variable according to the displacement of the crest, and provides the oscillation frequency by the induced voltage that is changed according to the variable capacitance (CV) value, and included in the oscillation frequency By converting the oscillation frequency into a crest amount through a filter section for removing the noise component and an amplifier section amplifying the oscillation frequency filtered by the filter section, the crest measurement can be performed.

However, the above-described capacitive crest meter is that the measured value is different depending on the water level when using a plurality, the measurement accuracy is lowered, such as to measure and correct each measured value, each of which has a constant value after the measurement Work inconveniences and time spent were considerable, such as correction to come out.

Korean Patent Registration No. 10-1995-0072313. Korean Patent Registration Application No. 10-2004-0024297.

The present invention has been devised to solve the above-mentioned problems, while allowing the installation of a plurality of capacitive crestometers on a platform, while allowing the simultaneous lifting and operation of each capacitive crestometer, the convenience in installing a capacitive crestometer Cavity calibration to enable the measurement operation convenience and the working time drastically shortened, and especially the plural capacitive clinometer enables the same lifting operation collectively to improve the measurement accuracy. It is an object of the present invention to provide an automatic control system.

As a specific means for achieving the above object, the caster mounting portion to which the caster is mounted to be movable in all four sides of the lower end is formed, the lower side is formed with a drain valve capable of discharging water, the upper side of the handle is formed;

A vertical lifting screw which is vertically formed at the center of the left and right sides of the outside of the tank, and is operated up and down;

A lifting and lowering operation unit which vertically penetrates the lifting screw and regulates the lifting and lowering of the lifting screw by a rotation operation;

A lift table coupled to the upper end of the lift screw to lift and operate with the lift screw;

A pair of guide rails formed on both sides of the lifting screw at an outer side of the tank to be symmetrically perpendicular to guide the lifting of the lifting table;

A plate-shaped pagoda mount having a left and right lengths protruding from the upper end of the elevator to the center of the water tank and having a plurality of capacitive pagoda installed therein; And

It is configured to include a control unit connected to each of the capacitive crestometer to perform a calibration by processing the capacitance value measured in the capacitive crestometer,

The platform,

The center plate is coupled to the upper end of the elevating screw while forming the left and right lengths, and the elevating plate is elevated together with the elevating screw;

A pair of vertical connecting rods protruding downward from both ends of the elevating plate; And

It is configured to include a guide plate for connecting the lower side of both vertical connecting rod, sliding guides on both side guide rails to guide the lifting of the lifting plate,

In the crest system mounting stand,

It consists of a plurality of screw holes at left and right regular intervals,

The capacitive digging system further comprises an installation bracket having a long hole forming the length before and after the bolt is penetrated to the digging system body,

The capacitive pagometer can be achieved by configuring the adjustment of the front and rear spacing by bolting and long holes through the mounting bracket.

As described above, according to the present invention, the automatic crest-based calibration control system is configured to simultaneously install a plurality of capacity-type crestometers on the crest-based mount table, and the crest-based mounts can be lifted and operated through a lift table. It is very convenient and the same lifting operation is possible, so the measurement is very convenient and the working time can be shortened.

In addition, it is possible to obtain an effect of further improving accuracy, such as minimizing an error, by collectively lifting and lowering operations of a plurality of capacitive crest systems.

1 is an overall perspective view of the present invention clinometer calibration automatic control system.
Figure 2 is a front view of the present invention clinometer calibration automatic control system.
Figure 3 is a plan view of the present invention clinometer calibration automatic control system.
4 is a cross-sectional view of the present invention clinometer calibration automatic control system.
Figure 5 is an embodiment of the lifting operation unit of the present invention clinometer calibration automatic control system.
Figure 6 is another embodiment of the present invention clinometer calibration automatic control system.
Figure 7 is a water tank horizontal adjustment state of the present invention pagometer calibration automatic control system.
8 is a capacitive crest meter installation state of the present invention crestimeter calibration automatic control system.
9 is a capacitive crest height lifting state diagram of the present invention crest height calibration automatic control system.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concepts of terms in order to best describe their invention. It should be interpreted as meanings and concepts corresponding to the technical idea of the present invention based on the principle that the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention, and do not represent all of the technical idea of the present invention, which can be replaced at the time of the present application It should be understood that there may be various equivalents and variations.

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

1 is an overall perspective view of an automatic wave height calibration automatic control system of the present invention, FIG. 2 is a front view of an automatic wave height calibration automatic control system of the present invention, FIG. 3 is a plan view of an automatic wave height calibration automatic control system, and FIG. A cross section of an automatic control system.

As shown in Figures 1 to 4 of the present invention crest height calibration automatic control system,

The water tank 100, the lifting screw 200, the lifting operating unit 300, the lifting table 400, the guide rail 500, the wave height mounting table 600, and the control unit 700.

First, the water tank 100 is configured to accommodate the water for the measurement in the construction of the present invention pagometer calibration automatic control system.

To this end, the water tank 100 is configured to form a rectangular enclosure that is open to the top.

In addition, the lower end of the water tank 100 is configured such that the caster mounting portion 110 protrudes horizontally in all directions corresponding to the corner portion, and the caster 120 is configured to be coupled to the caster mounting portion 110.

At this time, the water tank 100 in the present invention is that it is important to maintain the horizontal when the water is accommodated, it is configured to be horizontally adjustable through the caster (120).

To this end, a screw shaft 121 is formed at the top of the caster 120 to vertically penetrate the caster mounting portion 110, and the nut at the upper and lower portions of the caster mounting portion 110 is passed through the screw shaft 121. (N) is configured to be fastened.

In addition, the water tank 100 is configured with a drain valve 130 to enable the discharge of the water used in the lower portion.

The lifting screw 200 is configured to interpose the up and down lifting of the capacitive pawl system 10 to be described later in the center of the configuration of the present invention, the height-based calibration automatic control system.

To this end, the lifting screw 200 is typically formed in a vertical form formed with a threaded portion around, and is configured to be located in the left, right center spaced apart from the outer surface in the width direction of the water tank (100).

The lifting operation unit 300 is configured to intermittently move up and down the lifting screw 200 in the construction of the present invention crest-based calibration automatic control system.

On the other hand, the lifting operation unit 300 applied to the present invention is not limited, but may be configured as an electric worm driver 310 that converts a normal vertical rotational force into a horizontal rotational force.

At this time, the worm driver 310 is formed with a worm 311 that imparts a vertical rotational force in the horizontal direction with reference to Figure 5, and is engaged with the worm 311 therein to convert the vertical rotational force into a horizontal rotational force The worm wheel 312 is configured, the lifting screw 200 is configured to penetrate and screw through the worm wheel 312.

In addition, a drive motor 313 is configured at the worm wheel 312 to impart rotational force.

The lifting table 400 is configured to operate the up and down lifting operation together with the lifting screw 200 in the construction of the present invention height-based calibration automatic control system.

To this end, the lifting platform 400 is first, the lifting plate 410 is configured, the lifting plate 410 is configured to form a plate body forming a left, right length, the top of the lifting screw 200 in the center of the bottom surface It is configured to be connected.

In addition, the lifting table 400 is configured with a pair of both sides of the connecting table 420 supporting both sides of the lifting plate 410, the connecting table 420 is configured to protrude downward from both ends of the lifting plate 410.

In addition, the lifting platform 400 is configured with a guide plate 430, the guide plate 430 is configured to be coupled to the sliding guide and the guide rail 500 to be described later, while connecting the lower ends of the both side connecting table 420.

That is, the lifting platform 400 forms a rectangular field shape through the lifting plate 410, the connecting table 420, and the guide plate 430 with respect to the lifting screw 200, thereby providing a sense of stability during the lifting operation. .

The guide rail 500 is configured to guide the stable up and down of the platform 400 in the construction of the present invention height automatic calibration control system.

To this end, the guide rail 500 is configured to be installed vertically symmetrically on both sides about the lifting screw 200 in the width direction outer surface of the water tank (100).

In addition, each guide rail 500 is configured to slide both sides of the guide plate 430 of the platform 400.

That is, the lifting platform 400 is to be moved up and down along the guide rails 500 in the up and down lifting operation, it is configured to give a uniform lifting power of both sides.

The crest system 600 is configured to enable the installation of a plurality of capacitive crest system 10 in configuring the present invention automatic calibration system.

To this end, the pagoda mount 600 is configured to form a plate body forming a left, right length, coupled to the elevating plate 410 of the platform 400, while being configured to protrude toward the central side of the water tank (100). do.

On the other hand, the capacitive crest system 10 to be applied to the present invention, as in the conventional capacitive crest system 10, the bottom of the crest system 11 is composed of a support rod 12 protruding downward vertically, and also the crest system 11 ) And the lower end of the support rod 12 is configured to be connected to the wire sensor 13 for measuring the water level, the upper end of the wire sensor 13 is configured to be connected to the crest meter body 11 and the tension control spring 14 do.

In addition, in the present invention, the digging system mounting table 600 is configured with a plurality of screw holes 620 and 620 'to enable a large number of capacitive crest systems 10, and the screw holes 620 and 620' are left, It is composed at regular intervals.

In addition, in order to install the capacitive crest system 10 in the screw holes 620 and 620 ', the long hole 15a protrudes horizontally and forms a length before and after the crest system body 11 of the capacitive crest system 10. Mounting bracket 15 is configured with.

That is, each of the capacitive pagoda 10 is to be selectively bolted (B) to the screw holes (620, 620 ') through the mounting bracket 15, the various position adjustment of the installed pagoda mount 600 This becomes possible.

The control unit 700 is connected to the capacitive crest meter 10 in the construction of the present invention crest meter calibration automatic control system to perform a calibration process by calculating the capacitance value measured in the capacitive crest meter 10 It is configured to be connected to the cable of the crest system 11 of the capacitive crest system 10.

On the other hand, the control unit 700 applied in the present invention is not newly implemented, it is possible to perform a normal calibration, it will be possible if the computer is built software.

In addition, in the present invention, when constructing an automatic crest-based calibration control system, referring to Figure 6, the screw 200, the lifting operating unit 300, the lifting table 400, the guide rail 500 and the pagoda mounting table 600, the water tank It can be configured to be symmetrical to both the front and rear sides in the width direction of the (100).

Hereinafter, with reference to the accompanying drawings will be described in detail the operation of the present invention crest-based calibration automatic control system having the above configuration.

1 to 5, in order to perform the calibration using the present invention pagometer calibration automatic control system, first, the water tank 100 is filled with water.

On the other hand, the water tank 100 is filled with water as described above may cause a measurement error according to the horizontal degree, in the present invention, the horizontal by adjusting the caster 120 formed in all directions at the bottom of the water tank 100 Adjustment is possible.

That is, referring to FIG. 7, the caster 120 is capable of adjusting the degree of protrusion of the screw shaft 121 by adjusting the tightening of the nut N. For example, the caster 120 is lowered in a state in which the nut N located at the upper side is released. When tightening the nut in the screw shaft 121 protrudes to the bottom and at the same time the height of the water tank 100, on the contrary loosening the nut (N) of the lower screw shaft 121 protrudes to the top and at the same time By adjusting the height of each caster 120 such that the height of the water tank 100 is lowered, the water tank 100 can be horizontally adjusted.

Thereafter, the conventional pagoda type pagoda 10 is installed in the pagoda mounting table 600 and the water tank 100 may be filled with water.

At this time, the capacitive crest system 10 installed in the present invention with reference to FIG. 8 is installed on the crest system 600 using the mounting bracket 15 protruding horizontally to the crest system body 11, a plurality of capacitive type Simultaneous installation of the crest system 10 becomes possible.

At this time, the capacitive crest system 10 can be installed in the screw holes 620, 620 'of the corresponding crest system mounting table 600, the long hole (15a) of the mounting bracket 15 formed in the crest system body (11) The bolt B is fastened to the screw holes 620 and 620 '.

At this time, the threaded holes 620 and 620 'in the present invention are configured at regular intervals to the left and right bars, which prevents mutual interference between the plurality of capacitive crest gauges 10 which are spaced apart from each other. It can be prevented.

In particular, in installing the capacitive crest system 10, the mounting bracket 15 is configured to the long hole (15a), the front and rear of the capacitive crest system 10 by adjusting the interval before and after through the long hole (15a) And, it can be installed in a variety of positions, such as left, right to be able to prevent the mutual interference of the neighboring capacitive crest meter 10 more effectively, and various and accurate measurement is possible.

Thereafter, the measurement is performed, which is enabled by the up and down lifting operation of the platform 400.

That is, the lifting operation of the lifting platform 400 can be performed by the lifting operating unit 300 as shown in FIG. 9 with reference to FIG. 5. When the driving motor 313 of the lifting operating unit 300 is driven forward and backward, The rotational force acts on the worm 311 and is to be transmitted back to the worm wheel 312, so that the lifting screw 200 moves up and down along the center of the worm wheel 312, and at the same time the lifting screw ( The lifting platform 400 coupled to the 200 is operated up and down together, and thus the capacitance value can be measured through the wire sensor 13 for each capacitive crest meter 10.

On the other hand, in the present invention, the lifting screw 200 is configured to be connected to the center of the lifting plate 410 and the guide plate 430 is to be guided up and down along the guide rails 500 on both sides, bar of the lifting table 400 The accurate lifting operation is enabled, thereby enabling accurate measurement of capacitance values according to the uniform lifting of the plurality of capacitive crest gauges 10 installed in the crest system mounting table 600.

Subsequently, the capacitance value measured as described above may be transmitted to the control unit 700 through the crest meter body 11 of each capacitive crestometer 10, and the control unit 700 may perform calibration to correct the capacitance value.

In addition, in the present invention, when constructing an automatic crest-based calibration control system, referring to Figure 6, the screw 200, the lifting operating unit 300, the lifting table 400, the guide rail 500 and the pagoda mounting table 600, the water tank When configured symmetrically on both the front and rear sides in the width direction of the 100, it is possible to operate more efficiently the automatic crestimeter calibration automatic control system of the present invention through the selective operation or simultaneous operation as necessary.

As described above, the automatic crestimeter calibrating control system of the present invention enables the measurement of capacitance values of a plurality of capacitive crestometers at the same time, and in particular, enables simple and stable installation and measurement of a plurality of capacitive crestometers.

100: tank 110: caster mounting portion
120: caster 121: screw shaft
130: drain valve
200: lifting screw 300: lifting operating portion
400: platform 410: platform
420: vertical connecting rod 430: guide plate
500: guide rail
600: Pagoda Mounting Table 620,620 ': Screw hole
700: control unit

Claims (5)

The lower four sides are formed caster mounting portion 110 is mounted to the caster 120 to be movable, the lower side is formed with a drain valve 130 for discharging water, the upper side of the upper opening tank formed with a handle 140 100;
A vertical lifting screw 200 which is vertically formed at the center of the left and right sides of the water tank 100 and operates up and down;
Lifting unit 200 is vertically penetrated, the lifting operation unit 300 for intermittent lifting of the lifting screw 200 by the rotation operation;
A lift table 400 coupled to the upper end of the lift screw 200 to move up and down with the lift screw 200;
A pair of guide rails 500 formed on both sides of the elevating screw 200 at an outer side of the water tank 100 to be symmetrically perpendicular to guide the elevating of the elevating table 400;
A plate-shaped pagoda mount 600 having left and right lengths protruding from the upper end of the lifting table 400 toward the center of the water tank 100 and having a plurality of capacitive pagoda 10 installed therein; And
An automatic pagometer calibration control system comprising: a control unit 700 connected to each of the capacitive pagometers 10 and performing calibration by calculating and processing capacitance values measured by the capacitive pagometers 10.
The method of claim 1,
Caster 120,
The screw shaft 121 is formed at the upper end so that the caster mounting unit 110 is vertically penetrated and the nut N is fastened at the upper and lower portions of the caster mounting unit 110.
Height adjustment of the caster (120) by adjusting the nut (N) and the height adjustment calibrated automatic control system, characterized in that configured to enable the horizontal adjustment of the tank (100).
The method of claim 1,
Platform 400,
The lifting plate 410 to which the center is coupled to the upper end of the elevating screw 200 while lifting the left and right lengths, is elevated together with the elevating screw 200, and the crest mount 600 is coupled;
A pair of vertical connecting rods 420 protruding downward from both ends of the elevating plate 410; And
Connecting the lower sides of the vertical connection table 420, the sliding control is automatically coupled to the two guide rails 500 includes a guide plate 430 for guiding the lifting of the elevating plate 410, characterized in that the automatic control of calibration system.
The method of claim 1,
On the crest system mount 600,
It comprises a plurality of screw holes (620, 620 ') at left and right regular intervals,
The capacitive crest system 10 further includes an installation bracket 15 having a long hole 15a that forms a length before and after the bolt B penetrates the crest body 11,
The capacitive crest meter 10 is configured to be able to adjust the front and rear intervals by coupling the bolt (B) to the screw holes 620 and 620 'and mounting holes 15a through the mounting bracket 15. Crestimeter calibration automatic control system
The method of claim 1,
The screw 200, the lifting operation unit 300, the lifting table 400, the guide rail 500 and the pagoda mounting table 600,
Calmimeter calibration automatic control system, characterized in that configured to be formed symmetrically in the front and rear width direction of the water tank (100).

Images