KR20090050214A - Ball sensor - Google Patents

Abstract

Ball sensor of the present invention is coupled to the transmission line, the sensor frame for receiving the sensor and the device for detecting the temperature, transmission current, wind direction, wind speed of the transmission line to grasp the situation of the transmission line; It is coupled to the surface of the frame and includes a solar cell for powering the sensor and the device.

Power line, sensor frame, cell,

Description

Ball Sensor

The present invention relates to a ball sensor mounted on a power transmission line, and more particularly, to a ball sensor for mounting the solar cell on the surface of the sensor frame to supply power to the sensor and the device itself.

In general, the ball sensor continuously detects the status of the transmission line, grasps the situation of the transmission line in real time in case a problem occurs in the transmission facility due to a natural disaster of typhoon or earthquake, and includes the electric power including the transmission facility. Carry out monitoring of the interlock equipment. The detected signal is then sent to the control room to cope with an emergency situation.

 Therefore, as shown in Figure 1, the ball sensor 10 is installed on the line of the transmission line 20 to grasp the state of the transmission line 20.

This conventional ball sensor must be supplied with power using a separate power supply, the power supply is powered from a battery built in the ball sensor.

However, since such a conventional ball sensor is powered by a battery, after a certain time, the battery power is consumed, and thus the power supply can no longer be supplied. Therefore, there was a problem in that the replacement of the consumed battery, there was a problem that the maintenance and repair costs incurred during the replacement is charged separately.

The present invention was created to secure the above problems, by combining the solar cell on the ball sensor surface, it can supply power semi-permanently in one installation, the ball sensor can reduce the maintenance and repair costs generated separately To provide.

Ball sensor of the present invention for achieving the above object is coupled to the transmission line, the sensor frame for receiving a sensor and device for sensing the temperature, transmission current, wind direction, wind speed of the transmission line to grasp the situation of the transmission line; And a solar cell coupled to the surface of the frame and supplying power to the sensor and the device.

The solar cell may include a controller configured to maintain a constant voltage of generated electricity; An inverter for converting a direct current of electricity applied from the controller into an alternating current; It is preferable to include a battery for storing the electricity applied from the controller.

In addition, the sensor frame, it is preferable to have a grating skeleton so as to couple the solar cell to the surface.

As described above, the ball sensor of the present invention can use the ball sensor semi-permanently by coupling the solar cell to the surface of the sensor frame, and there is no failure even after using it for a long time due to the durability of the solar cell. This can reduce costs.

Hereinafter, a ball sensor according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing an embodiment of the ball sensor according to the invention, Figure 3 is a perspective view for explaining the solar cell of the embodiment shown in Figure 2, Figure 4 is a perspective view of the solar cell of the embodiment shown in Figure 2 It is a block diagram.

As shown in FIG. 2, the embodiment 100 includes a sensor frame 110 having a sensor and a device 128 for detecting a state of a transmission line, and a sensor frame 110 mounted on a surface of the sensor frame 110. The solar cell 120 for supplying power to the 128, the controller 125 for maintaining a constant voltage of electricity generated by the solar cell 120, and a direct current applied through the controller 125 are alternating current. Inverter 126 to convert to a battery, and includes a battery 127 for storing the electricity applied from the controller (125).

The sensor frame 110 includes a grating skeleton having a grating skeleton in a ball shape, and a predetermined space is formed in the grating skeleton.

The sensor frame 110 is provided with a sensor and the device 128 on the line of the transmission line for identifying the situation of the transmission line therein. The sensor and device 128 sense the temperature, transmission current, wind direction and wind speed of the transmission line.

The solar cell 120 is coupled to the surface of the sensor frame 110, which is coupled to the space of the grating skeleton of the surface of the sensor frame 110.

Therefore, the solar cell 120 is coupled to the surface of the sensor frame 110 to absorb solar energy, thereby converting the solar energy directly into electrical energy.

Herein, the principle of the solar cell 120 will be described in detail. As illustrated in FIG. 3, the solar cell 120 is formed of a P-type semiconductor and an N-type semiconductor assembly. A semiconductor having this unique property generates a weak electric field by combining a P-type semiconductor and an N-type. At this time, it receives solar energy and generates negative charges (electrons) and positive electrons (holes) in the P-type semiconductor near the junction. Here, the major is a hole lacking one electron.

The electric field around the junction of charges and electrons moves toward the N-type semiconductor and the P-type semiconductor, and when the electrodes on the surface of the semiconductor are connected, they move toward the N-type semiconductor and the P-type semiconductor.

At this time, if the + electrode 121 and the-electrode 124 on the two semiconductor surfaces are connected, the current flows when the N electrode and the P electrode move toward the semiconductor.

The electric current flows through the + electrode 121 and the − electrode 124 across the N-type and P-type semiconductors as described above is called a photovoltaic effect.

The characteristics of the solar cell 120 are mainly determined by the material of the semiconductor used, and mainly silicon, gallium-arsenic, and hafnium sulfide are used as semiconductor materials, and light and electric conversion efficiencies vary depending on materials of the semiconductor.

Therefore, the solar cell 120 may be semi-permanently obtained by coupling to the surface of the frame, there is an advantage that can reduce the separate maintenance and repair costs.

As shown in FIG. 4, the controller 125 maintains a constant voltage of electricity generated by the solar cell 120, controls to prevent overcharging of the battery 127, and controls the battery 127 according to the caution temperature. And charges the battery 127 according to the state of the battery 127. Herein, the description of "keeping the voltage of electricity constant" described above will be described in detail. Since the direct current voltage and direct current of electricity generated in the solar cell 120 are proportional to the intensity of solar energy, At a weak time a difference in voltage and current occurs, and the difference in voltage and current is kept constant.

The inverter 126 converts electricity of direct current applied from the controller 125 into electricity of alternating current.

The inverter 126 converts electricity of direct current applied from the controller 125 into electricity of alternating current and supplies it to the sensor and the device 128.

The battery 127 stores electricity applied by the controller 125. Such a battery 127 supplies electricity to sensors and devices 128 when it is difficult to produce electricity in the solar cell 120.

Therefore, since the solar cell 120 is coupled to the surface of the sensor frame 110 and converts solar thermal energy into electrical energy to serve as a power source for driving the sensor and the device 128, the solar thermal energy can be continuously used. There is an advantage that can be used semi-permanently.

In addition, since the solar cell 120 is durable, there is an advantage that it can be used for a long time.

With reference to the accompanying drawings will be described the operational relationship of the ball sensor according to the present invention.

As shown in FIG. 2 or FIG. 4, the embodiment 100 installed on the line of the transmission line detects the state of the transmission line by driving the sensor and the device 128 installed inside the sensor frame 110 and again. Transfer to the control room.

In this case, solar energy is supplied from the solar cell 120 coupled to the surface of the sensor frame 110 to supply electricity to the sensor and the device 128 and converted into electrical energy.

In addition, the electricity generated by the solar cell 120 is applied to the controller 125, and the controller 125 receiving the electricity is applied to the inverter 126 and the battery 127 by maintaining the strength of voltage and current constant. .

At this time, the inverter 126 converts the electricity of direct current applied from the controller 125 into electricity of alternating current and supplies it to the sensor and the device 128.

By converting the direct current electricity into the alternating current electricity in this way, it is possible to prevent the overcurrent flowing through the sensor and the device 128 and to be damaged.

In addition, the battery 127 stores electricity applied from the controller 125 to generate solar power in the solar cell 120 and thus fails to produce electricity. 128).

Therefore, the solar cell 120 can produce electricity within the limits of the generation of solar energy, and by using the electricity thus produced, this embodiment 100 can be used semi-permanently.

1 is a schematic diagram illustrating a conventional ball sensor.

2 is a perspective view showing an embodiment of a ball sensor according to the present invention.

3 is a perspective view illustrating a solar cell of the embodiment shown in FIG. 2.

4 is a block diagram of the solar cell of the embodiment shown in FIG. 2.

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

110: sensor frame 120: solar cell

125: controller 126: inverter

127: battery

Claims (3)

A sensor frame coupled to a transmission line and accommodating a sensor and a device for detecting a temperature, a transmission current, a wind direction, and a wind speed of the transmission line to grasp the situation of the transmission line; And A ball sensor coupled to the surface of the frame, comprising a solar cell for supplying power to the sensor and the device. The method of claim 1, The solar cell, A controller for maintaining a constant voltage of generated electricity; An inverter converting a direct current of electricity applied from the controller into an alternating current; Ball sensor, characterized in that it comprises a battery for storing the electricity applied from the controller. The method of claim 1, The sensor frame, Ball sensor having a grating skeleton so as to couple the solar cell to the surface.

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