KR20100122538A - Device for observing sea - Google Patents

Abstract

PURPOSE: An oceanographic observation device is provided to accurately measure the temperature and pressure of the seawater per depth of water at the same time and measure the seawater characteristic of wide area in a short time, thereby providing an oceanographic observation device which improved the structure. CONSTITUTION: Sensors(20~40) are installed in a housing and measure at least one among the temperature and the salinity of the marine at the depth of specified water. A coil(50) generate power according to the change of the magnetic flex passing through inside. A storage battery(60) stores the power source created by coil and supplies the saved power source to sensor. A transmitter wirelessly transmits a signal corresponding to a measured value from a sensor.

Description

Device for observing sea

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oceanographic observation apparatus, and more particularly, to an oceanographic observation apparatus for measuring characteristic characteristics of the ocean, for example, salinity and temperature, which is used for weather forecasting or research of ecological conditions of marine life.

The most important thing in weather forecasts or the study of marine conditions is to actually measure the state of the ocean. In order to measure the marine conditions, salinity and temperature are generally measured according to the depth of water. An example of an apparatus for measuring salinity and temperature of the ocean is shown in FIG. 1.

These measuring devices form a large external body and are buoyant (1) floating floating on the sea surface, a sensor (not shown) for detecting and collecting the temperature of the seawater, and connected to the sensor to receive data and wirelessly It includes a repeater (not shown) for transmitting the collected data to a remote location using a communication network, and a battery (not shown) for supplying power to the sensor and the wireless repeater. Here, the sensor, repeater and battery are installed inside the floating body.

By the way, the above-described measuring device is configured to measure the temperature of the sea water in a state floating on the sea surface, there is a limit that can not measure the temperature of the sea water for each depth. As a result, weather forecasting and marine research are difficult to achieve effectively. This is because the temperature distribution of sea water temperature is a very important factor in predicting weather and analyzing marine ecological conditions.

In addition, since a large number of measuring devices are required to measure the seawater temperature in a large area, it is difficult to economically measure the seawater temperature.

In addition, it is difficult to measure the temperature of seawater in areas where weather is not good, such as typhoons or hurricanes, and there is a problem in that the path of typhoons or hurricanes cannot be accurately predicted.

The present invention has been made to solve the above problems, and an object of the present invention is not only to measure the temperature and pressure of sea water at the same time and accurately, but also to observe the seawater characteristics of a large area in a light and fast time. It is to provide an offshore observation device with an improved structure.

In order to achieve the above object, the marine observation device according to the present invention is a marine observation device for measuring at least one of the temperature and salinity of the ocean at a certain depth spaced from a sea level, is formed long in one direction, the end Is formed in a streamlined housing; A sensor installed in the housing and measuring at least one of a temperature and salinity of the ocean at the specific depth; A coil installed in the housing and generating power according to a change in magnetic flux passing through the inside; A storage battery installed in the housing and configured to store power generated by the coil and to supply power stored in the sensor to operate the sensor; And a transmitter installed in the housing and wirelessly transmitting a signal corresponding to the value measured from the sensor.

According to the present invention, the temperature and pressure of seawater can be measured simultaneously and accurately by depth.

In addition, it is light in weight and easy to use. Furthermore, it is easy to observe the seawater characteristics of a large area in a short time.

2 is a schematic front view of the marine observation apparatus according to an embodiment of the present invention, Figure 3 is a schematic block diagram for explaining the operation of the marine observation apparatus shown in Figure 2, Figures 4 and 5 An example of the observation data format measured using the marine observation apparatus shown in FIG. 2 is shown.

2 to 5, the marine observation apparatus 100 of the present embodiment measures both the temperature and salinity of the ocean at a certain depth spaced from a sea level. The marine observation device 100 includes a housing 10, a temperature sensor 20, a salinity sensor 30, a pressure sensor 40, a coil 50, a storage battery 60, and a controller 70. And a transmitter 80.

The housing 10 is formed to be elongated in one direction, and a space in which the temperature sensor 20 and the pressure sensor 40 are installed is formed in the housing 10. In addition, the end of the housing 10 is formed in a streamlined shape. Thus, the frictional force of the seawater against the housing 10 is reduced when the housing 10 is launched into the ocean from a vehicle or a vessel. In addition, the housing 10 is formed with a ring portion 101 to which the connecting line 11 is connected. The connecting line 11 is composed of a wire or a rope, and is connected to a launch device installed in an airplane or a mechanism or a ship. And, the connecting line 11 is wound by an appropriate length, and is released when the marine observation device is launched toward the sea water.

Temperature sensor 20 is for measuring the temperature of the ocean, a pair is installed inside the housing (10). The pair of temperature sensors 20 are spaced apart from each other along the longitudinal direction of the housing 10.

Salinity sensor 30 is for measuring the salinity of the ocean, a pair is installed inside the housing (10). The pair of temperature sensors 30 are spaced apart from each other along the longitudinal direction of the housing 10. In addition, the pair of temperature sensors 20 and the pair of salinity sensors 30 are respectively disposed at the same height from the end of the housing 10 as shown in FIG. 2. Therefore, when the marine observation device 100 is launched such that the longitudinal direction of the housing 10 is parallel to the vertical direction, the salinity sensor 30 and the temperature sensor 20 arranged at the same height are respectively salinity and temperature at the height. Will be measured.

Pressure sensor 40 is for measuring the pressure of the ocean, a pair is installed inside the housing (10). The pair of pressure sensors 40 are spaced apart from each other along the longitudinal direction of the housing 10. In addition, the pair of pressure sensors 40 are disposed in the vicinity of each of the pair of temperature sensors 20, in particular in the present embodiment is disposed at the same height as the pair of temperature sensors 20. Accordingly, one pressure sensor 40 is disposed at the same height as one temperature sensor 20 and the salinity sensor 30, and the other pressure sensor 40 is the other temperature sensor 20 and the salinity sensor. It is disposed at the same height as 30. The pressure measured by the pressure sensor 40 corresponds to the pressure at the position where the temperature and salinity measured from the temperature sensor 20 and the salinity sensor 30 disposed at the same height as the pressure sensor 40 were measured. do.

The coil 50 is installed inside the housing 10. When the magnetic flux passing through the coil 50 changes, power is generated. The generated power is used to operate the temperature sensor 20, the salinity sensor 30, the pressure sensor 40, and the controller 70 or the transmitter 80 described later. On the other hand, the change of the magnetic flux is made when the marine observation device 100 is launched from an airplane or a ship. That is, if a plane or ship is provided with a magnetic flux changing device (not shown) in which the magnetic flux is changed therein, and the marine observation device 100 is fired through the magnetic flux changing device, the coil 50 is released during the launching of the marine observation device. Changes occur in the magnetic flux that passes through them, enabling development.

The storage battery 60 is installed inside the housing. The battery 60 is electrically connected to the coil, so that the power generated from the coil is stored in the battery 60. The battery 60 is electrically connected to the temperature sensor 20, the salinity sensor 30, the pressure sensor 400, the controller 70 to be described later, and the transmitter 80.

The controller 70 is electrically connected to the storage battery 60. The controller 70 calculates the water depth, the temperature and the salinity based on the temperature, salinity and pressure input from the pair of temperature sensor 20, the salinity sensor 30 and the pressure sensor 40, respectively. Here, the temperature and salinity may be measured as a continuous value over time as shown in FIG. 4, or measured at discrete intervals over time as shown in FIG. 5. It may be. The controller may also calculate and output temperature, salinity and pressure in real time.

The controller 70 processes the data measured from each sensor to calculate the temperature, salinity and pressure. For example, if the pressure measured from the pair of pressure sensors 40 is arithmetic average, the pressure at a point among the pair of pressure sensors 40 can be obtained for each depth. Similarly, temperature and salinity can also be obtained by arithmetic average. When the arithmetic average of the temperature, salinity and pressure is obtained as described above, the temperature, salinity and pressure at the point of the pair of pressure sensors 50 can be obtained. In addition, when arithmetic averaged pressure is converted into a depth through a well-known calculation process, a specific depth can be obtained. Therefore, the converted depth is a specific depth and salinity and pressure at the specific depth are obtained by the arithmetic mean described above.

When the temperature, salinity and pressure are obtained by arithmetical average as described above, the measurement of each sensor is compared with the case where one temperature sensor 20, salinity sensor 30 and pressure sensor 40 are installed to obtain temperature, salinity and pressure. Minimizing errors ensures accurate temperature, salinity and pressure.

The transmitter 80 is installed inside the housing 10. The transmitter 80 is electrically connected to the controller 70 and wirelessly transmits a signal corresponding to the temperature, salinity, and water depth output from the controller 70. The transmitted temperature, salinity and depth are stored in the reservoir 95 after being received at the receiver 90, where the receiver 90 can be installed in an airplane or ship or at a remote meteorological or marine laboratory and stored. The machine 95 may also be a memory of a computer installed in an airplane or a ship, or a computer memory of a distant meteorological office or an ocean research institute. The data stored in the reservoir 95 is finally analyzed by the Korea Meteorological Administration, Marine Research Institute, and the like.

In the marine observation apparatus 1000 configured as described above, if the marine observation apparatus is freely dropped toward the sea level and then repeatedly lifted up again, the ocean temperature and salinity can be simultaneously measured for each depth within a short time. In particular, since the marine observation apparatus 100 can be used while moving quickly using an airplane or a ship, the temperature and salinity of seawater can be measured quickly over a wide range. By using the sensor 20, salinity sensor 30 and the pressure sensor 40 it is also possible to minimize the measurement error of the sensor, it is possible to make more accurate ocean observation.

In addition, since the heavy battery is not provided in the marine observation device 100, a large power is not required to drop the marine observation device and pull it up again. Therefore, it is possible to measure the temperature and salinity of the ocean by quickly operating the marine observation apparatus while using a small device.

On the other hand, in the present embodiment is configured to be provided with a controller in the marine observation device, as shown in Figure 6 may be configured so that the controller is not provided.

That is, in this embodiment, the temperature, salinity and pressure measured from the pair of temperature sensor 20, salinity sensor 30 and pressure sensor 40 are respectively input to the transmitter 80, the transmitter 80 is Each pair of input temperature, salinity and pressure are transmitted wirelessly. The transmitted temperature, salinity and pressure are all stored in the reservoir 95 after being received at the receiver 90. Then, the pair of temperature, salinity and pressure stored in the reservoir 95 are read out by the controller 70a and then processed in the controller 70a as in the controller 70 described with reference to FIGS. 2 to 5. . Here, the controller 70a may be a computer installed in an airplane or a ship, or a computer installed in a meteorological office or an ocean research institute.

As mentioned above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above embodiments, and various modifications may be made by those skilled in the art within the technical spirit of the present invention. It is obvious.

1 is a schematic perspective view of a marine observation apparatus according to a conventional example.

2 is a schematic front view of the marine observation apparatus according to an embodiment of the present invention.

FIG. 3 is a schematic block diagram illustrating an operation process of the marine observation apparatus shown in FIG. 2.

4 and 5 show an example of the observation data format measured using the marine observation apparatus shown in FIG.

Figure 6 is a schematic block diagram illustrating the operation of the marine observation apparatus according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10.Housing 20 ... Temperature sensor

30 ... Salinity sensor 40 ... Pressure sensor

50 ... coil 60 ... battery

70, 70a ... Controller 80 ... Transmitter

90 Receiver 95 Storage

100,100a ... Marine Observation System

Claims (5)

In the marine observation device for measuring at least one of the temperature and salinity of the ocean at a certain depth spaced from sea level, A housing elongated in one direction; A sensor installed in the housing and measuring at least one of a temperature and salinity of the ocean at the specific depth; A coil installed in the housing and generating power according to a change in magnetic flux passing through the inside; A storage battery installed in the housing and configured to store power generated by the coil and to supply power stored in the sensor to operate the sensor; And And a transmitter installed in the housing and wirelessly transmitting a signal corresponding to the value measured from the sensor. The method of claim 1, The sensor is provided in pairs to be spaced apart from each other along the one direction, The pair of sensors each measures the temperature or salinity of the ocean, And a controller coupled to the housing, electrically connected to the storage battery, and calculating a temperature or salinity at the specific depth based on the temperature or salinity measured from the pair of sensors. The transmitter is a marine observation device, characterized in that for wirelessly transmitting a signal corresponding to the temperature or salinity calculated by the controller. 3. The method of claim 2, Installed in the housing so as to be disposed in the vicinity of each of the pair of sensors, and measuring the pressure of the ocean at the depth where the pair of sensors are disposed, respectively, and electrically connected to the storage battery so that the stored power is supplied. It is further provided with a pair of pressure sensors connected, The controller calculates the specific depth based on the pressure measured from each of the pair of pressure sensors, And the transmitter wirelessly transmits a signal corresponding to the specific depth. The method of claim 1, The sensor is spaced apart from each other along the one direction and comprises a pair of temperature sensors for measuring the temperature of the ocean and a pair of salinity sensors disposed apart from each other along the one direction to measure the salinity of the ocean, A controller coupled to the housing and electrically connected to the storage battery to calculate the temperature and salinity at the specific depth based on the temperature measured from the pair of temperature sensors and the salinity measured from the pair of salinity sensors Further comprising; The transmitter wirelessly transmitting a signal corresponding to the temperature and salinity calculated by the controller Installed in the housing so as to be disposed in the vicinity of each of the pair of temperature sensors and the pair of pressure sensors, and measure the pressure of the ocean at the depth where the temperature sensors and each pressure sensor are disposed; And a pressure sensor electrically connected to the storage battery so as to be supplied. The controller calculates the specific depth based on the pressures measured from the pressure sensors, respectively. The transmitter is a marine observation device, characterized in that for transmitting a signal corresponding to the specific depth wirelessly. The method of claim 1, The sensor is spaced apart from each other along the one direction and comprises a pair of temperature sensors for measuring the temperature of the ocean and a pair of salinity sensors disposed apart from each other along the one direction to measure the salinity of the ocean, Installed in the housing so as to be disposed in the vicinity of each of the pair of temperature sensors and the pair of pressure sensors, and measure the pressure of the ocean at the depth where the temperature sensors and each pressure sensor are disposed; And a pressure sensor electrically connected to the storage battery so as to be supplied. The transmitter is a marine observation device, characterized in that for transmitting a signal corresponding to the temperature, salinity and pressure respectively measured from the sensors.

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