KR20100004559A - Measure system of the wind and wind velocity in golf course - Google Patents

Abstract

PURPOSE: A measure system of wind direction and wind velocity in golf course is provided to measure accurate wind direction and wind velocity in the golf course entire region by arranging an anemometer and anemoscope through temperature variation of thermopile. CONSTITUTION: A measure system of wind direction and wind velocity in golf course comprises a plurality of wireless wind direction and wind velocity gauges(1000); a central processing unit(2000) that calculates wind direction and wind velocity in the golf course entire region by wirelessly receiving the output of the anemometer and anemoscope; and a user terminal(3000) for providing the wind direction and wind velocity information to users.

Description

Measurement system of the wind and wind velocity in golf course}

The present invention relates to a golf course wind direction and wind speed measurement system, and to arrange the wind direction anemometer using the thermopile for each area in the golf course, and to measure the wind direction and wind speed of the entire golf course by receiving the output signal of the wind direction anemometer by wireless communication, It relates to a golf course wind direction and wind speed measurement system for transmitting the measured results to the golf course customer.

In general, when playing golf at the golf course, the emergency distance and position of the golf ball hit by the user is changed according to the strength and direction of the wind blowing on the golf course.

In particular, in the case of a golf game, in order to play a driver shot or putty, the wind direction and the wind speed of the spot to be hit, as well as the wind direction of the entire area where the pitched golf ball flies, are very important. In other words, it is important to know the state of the field accurately.

However, in the related art, the wind direction and the wind speed were determined only by plucking the ground grass or shaking the tree branches without using any auxiliary equipment.

Recently, the golf information display device has been developed to more accurately and surely determine the state of the wind. That is, a golf game information display apparatus disclosed in Korean Patent Laid-Open No. 10-2002-007839 has been disclosed. This detects the direction and level of the signal transmitted from the signal transmitter of the golf ball and displays the position of the golf ball according to the detection result. Of course, the Korean Laid-open Patent Publication is provided with a wind direction / wind speed detection means in the information display, but this is the difference between the negative pressure and atmospheric pressure acting on the phytotube of the narrow path by the wind passing through the wind direction / wind speed detection means Since the wind speed is measured using the voltage difference induced by the differential transformer according to the displacement of the knitting member, the displacement of the knitting member is changed according to the humidity or temperature of the surrounding air, so an error occurs in the measured wind speed. There is a problem. In addition, this does not know the information of the entire golf course (that is, the field), there is a disadvantage that can only know the wind direction and wind speed of the local point hitting the golf ball.

Therefore, an object of the present invention is to arrange a wind direction anemometer for measuring the wind direction and wind speed through the temperature variable of the thermopile throughout the golf course, and to collect the sensing signals of these wirelessly to measure the exact wind direction and wind speed throughout the golf course The present invention provides a golf course wind direction and wind speed measurement system.

In order to solve the above problems, a plurality of wireless wind direction anemometers installed throughout the golf course according to the present invention for measuring wind direction and wind speed, and the output of the wireless wind direction anemometer wirelessly to calculate the wind direction and wind speed throughout the golf course It provides a golf course wind direction and wind speed measurement system comprising a central processing unit and a user terminal for providing the wind direction and wind speed information of the central processing unit to the golf course user.

Each of the wireless wind direction anemometer includes a measuring unit for measuring the wind direction and wind speed with a thermopile, a wireless communication unit for transmitting the measured wind direction wind speed, and a power supply unit for supplying power to the measuring unit and the wireless communication unit. It features.

The measuring unit includes a sensor unit for sensing and outputting a temperature change in four directions according to the wind, an analog amplifying unit for amplifying and outputting an output signal of the sensor unit, and a control unit for controlling the operation of the sensor unit and the amplifying unit. It is characterized by.

The sensor unit includes a body substrate, a heating element provided at the center of the body substrate, and a plurality of temperature sensors respectively disposed in four directions of the heating element.

The heating element is manufactured in a quadrangular shape, and four temperature sensors are respectively disposed on the upper, lower, left, and right sides of the heating element, and each of the temperature sensors includes a thermo pile having a plurality of thermo couples.

The central processing unit and the wireless wind direction anemometer is characterized in that the communication through any one of the wireless communication method of CDMA, WiBlo, Bluetooth, radio frequency, WLAN, IrDA, WCDMA, HSDPA and SWAP.

The central processing unit and the user terminal is characterized in that communication through any one of the wireless communication method of CDMA, WiBlo, Bluetooth, radio frequency, WLAN, IrDA, WCDMA, HSDPA and SWAP.

And a plurality of fixed shafts for fixing the plurality of wireless wind direction anemometers to an upper region on the surface of the golf course, wherein at least one wireless wind direction anemometer is disposed at the same position or at different positions.

As described above, in the present invention, a plurality of wireless wind direction anemometers are disposed throughout the golf course, and the measurement result thereof is provided through a wireless communication from the central processing unit to measure the wind direction and wind speed of the entire golf course.

With reference to the accompanying drawings, the description of the present invention for achieving the above object will be described.

1 is a conceptual diagram of a golf course wind direction and wind speed measurement system according to an embodiment of the present invention. 2 is a block diagram of a golf course wind direction and wind speed measurement system according to an embodiment. 3 is a block diagram of a wireless wind vane according to an embodiment. 4 to 7 are photographs of the wireless wind direction anemometer according to the embodiment, FIG. 8 is a plan view of the sensor unit of the wind direction anemometer according to the embodiment, and FIG. 9 is a cross-sectional view of the sensor unit according to the embodiment.

1 to 9, the golf course wind direction and wind speed measuring system according to the embodiment is installed in the entire golf course to measure the wind direction and wind speed and a plurality of wireless wind direction anemometer 1000, the output of the wireless wind direction anemometer 1000 It is provided with a wireless central processing unit 2000 for calculating the wind direction and wind speed throughout the golf course, and a user terminal 3000 provided with the wind direction and wind speed calculation results of the central processing unit 2000.

Here, the wireless wind direction anemometer 1000 is located above the fixed shaft 1001 extending upward from the surface of the golf course. In this case, the height of the fixed shaft 1001 may vary depending on the region where the corresponding wireless wind direction anemometer 1000 is located. In addition, a plurality of wireless wind direction anemometer 1000 may be positioned on a single fixed shaft 1001. Through this, wind direction and wind speed according to altitude can be measured.

In the present embodiment, it is preferable that the wireless wind direction anemometer 1000 is spaced at a predetermined distance. At this time, it is preferable that one wireless wind direction anemometer is disposed every 50 to 1000 meters to optimize the wind direction and wind speed measurement. In addition, the separation distance of the plurality of wireless wind vane 1000 may be the same or different.

The wireless wind direction anemometer 1000 of the present embodiment measures the wind direction and the wind speed by using a thermopile.

That is, each of the plurality of wireless wind direction anemometers 1000 includes a thermopile measuring unit 1100 for measuring wind direction and wind speed, a wireless communication unit 1200 for transmitting the measured wind direction wind speed to a central processing unit, and the measuring unit. 1100 and a power supply unit 1300 for providing power to the wireless communication unit 1200. Of course, it may further include a storage unit for storing the predetermined information.

Here, the measurement unit 1100 includes a sensor unit 100, an analog amplification unit 200, and a control unit 300 as shown in FIGS. 4 to 9.

Here, the sensor 100 is manufactured in the form of a chip to measure both the wind direction and the wind speed. As illustrated in FIGS. 8 and 9, the sensor unit 100 is disposed in four directions of the body substrate 110, the heating element 120 provided at the center of the body substrate 110, and the heating element 120, respectively. A plurality of temperature sensors 130 are provided.

A silicon wafer is used as the body substrate 110. As the body substrate 110, a semiconductor substrate or an insulating substrate (eg, a PCB) may be used. However, a silicon wafer is used to fabricate the heating element 120 and the plurality of temperature sensors 130 thereon. Wind direction and wind speed measuring instrument of the present embodiment is manufactured in the form of a sensor chip it is possible to miniaturize and light weight. And, the size of the wind direction wind speed measuring instrument of this embodiment is about 1.5mm * 1.5mm, the size of the membrane is 600㎛. Of course, depending on the range and place where the meter is used, it can be manufactured in a smaller or larger size within the range of about 10 to 1000%.

A rectangular heating element 120 is formed in the center of the body substrate 110. At this time, the heating element 120 generates heat by electric energy. The resistance of the heating element 120 is 400 to 600 ohm (ohm), it is preferably designed to flow a voltage of about 2 to 10V and a current of 2 to 20mA. At this time, the heating element 120 may be a conductive plate shape or a plurality of heating wiring is laid in a rectangular form. It is effective that the average temperature of the heating element 120 is about 100 to 250 degrees.

In addition, four temperature sensors 130 are disposed on the top, bottom, left, and right sides (ie, the X-axis and Y-axis directions) of the heating element 120. Through this, the direction of the wind blowing in four directions (ie, east, west, north or south, or + X, -X, + Y, -Y) can be detected, and the wind speed can also be detected. This uses the temperature difference between the temperature sensors 130.

As the temperature sensor 130, a thermo pile having a plurality of thermo couples is used as illustrated in FIGS. 8 and 9. The thermopile has 11 thermocouples each, as shown in FIG. 8. Each thermocouple has a cold junction and a hot junction with a large thermal electromotive force and opposite thermal electromotive force. The hot contact is located on the heating element 120. A thermocouple line is located between the cold junction and the hot junction. That is, as shown in the cross-sectional view of FIG. 9, the thermo pile is formed on the wafer 131, the first silicon oxide film 132, the silicon nitride film 133, and the silicon nitride film 133 formed on the wafer 131. A thermocouple line 135 connected to the contact 134, the cold junction and the hot junction, and a second silicon oxide film 136 covering the thermocouple line are included. The temperature detection of the thermopile consisting of a thermocouple is preferably 0.1 to 1.0mV / ℃.

The sensor unit 100 is manufactured in the form of a chip. That is, the silicon wafer 100 is etched to form a membrane of a silicon nitride film having a thickness of about 1 μm, and a heating element and a temperature sensor are formed of impurity doped silicon (for example, p-Si) and Al on the upper side thereof. The second silicon oxide film 136 is formed on the insulating film to produce it. At this time, the minimum line width of the chip-shaped sensor unit 100 is 4 to 6㎛, the minimum spacing is also 4 to 6㎛.

In this embodiment, a plurality of sensor units 100 in a chip form are manufactured on a silicon wafer. This produced four wind direction / wind MEMS sensors on a 4 inch wafer. That is, a 1 µm nitride film was deposited on a 500 µm thick Si substrate to have a low stress, and a thin film membrane was formed by etching silicon bulk by a deep RIE process after p-Si and Al and SiO ₂ thin film processes. After the thin film membrane was formed, chip dicing was performed for each chip. At this time, chip dicing is performed by a sawing machine by raising a polymer protective film about 10 to 100% thicker than semiconductor chip dicing so as not to damage the membrane. Of course, the protective film is then removed and dry and wet cleaning processes are performed.

In the sensor unit 100, that is, the sensor chip of the present embodiment, the temperature sensors 130 are positioned in four directions of the heating element 120, respectively, and the wind direction and the wind speed which are blown in four directions can be measured. For example, when the temperature sensors 130 respectively disposed in the east, west, north and south directions with respect to the center of the heating element 120 are referred to as the first to fourth temperature sensors 130, the first to fourth temperatures when the wind is not blown. The output value of each sensor 130 is the same. This is because the temperature change between the temperature sensors 130 does not appear. However, if the wind blows from the east, the temperature of the first temperature sensor 130 located in the east of the heating element 120 is lower than the temperature of the other second to fourth temperature sensors 130. This is because the temperature of the thermopile of the first temperature sensor 130 is lowered by the wind. Therefore, the output value of the first temperature sensor 130 is different from the output values of the other second to fourth temperature sensors 130. Therefore, by analyzing the difference of the output value it can be seen that the wind blows from the east as well as the strength of the wind can be calculated.

And the sensor part 100 of this embodiment can measure the wind direction and wind speed of 2-D (all four directions).

The sensing output value of the sensor unit 100 as described above is amplified by the analog amplifier 200. That is, the analog amplifier 200 amplifies the signals of each of the four temperature sensors 130 and outputs the amplified signals.

The analog amplifier 200 amplifies the difference between the outputs of the temperature sensors disposed on the left and right through the differential amplifier to obtain the wind speed in the X direction (for example, east and west directions). In addition, the analog amplifier 200 amplifies the difference between the output of the temperature sensor disposed up and down through the differential amplifier to obtain the wind speed in the Y direction (for example, south, north direction). For example, when the wind speed is 0, a reference voltage (for example, 1.5V) is output, and when the wind blows from left to right, the voltage of X increases, and when blown from right to left, the voltage decreases. The amount of change in voltage varies nonlinearly with the strength of the wind. Of course, winds in the vertical direction of the output of Y have the same result.

The analog amplification unit 200 may further include an amplification circuit for measuring a cold spot (that is, a cold junction) temperature and a temperature of the sensor unit 100.

In the present embodiment, the control unit 300 is provided to control the operation of the sensor unit 100 and the amplification unit 200. To this end, the controller 300 includes a sensor controller and a calculator. The controller 300 further includes an AD converter for converting analog to digital.

In addition, the control unit 300 includes a temperature control circuit of the heating element 120 of the sensor unit 100. That is, the temperature of the heating element 120 of the sensor unit 100 is constant through voltage control and current sensing. This is the temperature of the heating element 120 is determined by the power consumption, the resistance of the heating element is a few%, there is an error for each sensor and the power adjustable by the MCU to prevent the power consumption changes as the power supply voltage changes, which can make a constant voltage A drive cycle was applied.

And the MCU part for control and association of the sensor part 100 is provided. The MCU digitizes each analog output and controls the sensor's power and heating elements. In order to reduce the total power consumption, the sensor operation is performed at regular intervals, so the power supply of the sensor unit and the amplification circuit unit is controlled ON / OFF by the microcomputer. In this case, after performing nonlinear correction and temperature correction, the microcomputer calculates the wind speed and the wind direction and outputs data in a serial manner.

The measurement unit 1100 including the sensor unit 100, the analog amplifier 200, and the control unit 300 described above is preferably wrapped by a package. That is, it is easy to attach to a ball sensor, etc., and to position a wing | blade to both sides of a center part in order to solidify | fix, and attach a screw to a wing | blade part. In addition, it is preferable that the sensor unit 100 is mounted on the central part (ie, the head) in the horizontal direction, and a cap for protecting the sensor unit 100 is covered. The sensor unit 100 is attached to the PCB and fixed to the sensor holder. The cap is preferably designed with a convex flow path in the middle because the wind speed sensor is located below it, and the thickness of the column is 1/10 to 1/100 of the entire circumference to minimize wind interference. In addition, the number of pillars shall be four or less. Then, the main PCB is vertically assembled under the PCB body to which the sensor unit 100 is attached, and a mode-to-wird connector is used to connect them.

The wireless wind direction anemometer 1000 according to the present embodiment amplifies the wind direction and wind speed signal measured by the sensor unit 100 in the measuring unit 1100 in the above-described analog amplification unit 200 and wirelessly through the control unit 300. The communication unit 1200 is provided. In this case, the wireless communication unit 1200 provides the wind direction and wind speed signals to the central processing unit 2000 through wireless communication. In this case, it is preferable to use any one of CDMA, WiBlo, Bluetooth, radio frequency, WLAN, IrDA, WCDMA, HSDPA, and SWAP as a communication technology of the wireless communication unit 1200. In this case, the wireless communication unit 1200 includes various transmission means according to the communication technology (or method).

At this time, the power supply unit 1300 receives power from the outside and processes it to provide power (that is, voltage or current) corresponding to the measurement unit 1100 and the wireless communication unit 1200 so that they can operate smoothly. do.

The central processing unit 2000 of the present exemplary embodiment collects the wind direction and wind speed signals provided from each of the plurality of wireless wind direction anemometers 1000 described above, and generates wind direction and wind speed information of the entire golf course area using the collected data. The generated information is provided to the user terminal 3000. In this case, the central processing unit 2000 wirelessly receives data provided from the wireless wind direction anemometer 1000 through a wireless communication module, and wirelessly provides data in the central processing unit 2000 to the user terminal 3000.

In addition, the central processing unit 2000 may receive location information from the user terminal 3000, and provide wind direction and wind speed information of the corresponding location to the user terminal 3000. At this time, a wireless communication module is used. In addition, the wireless communication module preferably uses any one of the above-described communication methods of CDMA, WiBlo, Bluetooth, radio frequency, WLAN, IrDA, WCDMA, HSDPA, and SWAP.

Hereinafter, with reference to the drawings, the operation of the golf course wind direction and wind speed measurement system according to the present embodiment.

10 is a flowchart illustrating an operation of a golf course wind direction and wind speed measurement system according to an embodiment.

In this case, operations of the user terminal 3000 and the wireless wind direction anemometer 1000 will be described based on the central processing unit 2000.

First, the user uses the user terminal 3000 to know the wind direction in the golf course. In this case, as illustrated in FIG. 10, the user terminal 3000 requests wind direction and wind speed information to the central processing unit 2000 through a user input (S100). At this time, the command signal and the location signal of the current user terminal 3000 are provided through the wireless communication module.

Subsequently, in response to the request signal of the user terminal 3000, the central processing unit 2000 requests the wind direction and wind speed measurement results from the entire plurality of wireless wind direction anemometers 1000 (S200). Subsequently, each of the wireless wind direction anemometers 1000 measures the wind direction and the wind speed of the corresponding position through the measuring unit 1100 (S300). Subsequently, the wireless wind direction anemometer 1000 amplifies the measured wind direction and wind speed signals through the analog amplifier 200 (S400). The amplified signal is provided to the central processing unit 2000 through the wireless communication unit 1200, that is, the wireless module (S500).

Subsequently, the central processing unit 2000 determines wind direction and wind speed of the entire golf course by using wind direction and wind speed signals provided from the plurality of wireless wind direction anemometers 1000 (S600). That is, the wind direction and the wind speed of the area in which the one wind direction anemometer 1000 is located are determined. Subsequently, the central processing unit 2000 transmits wind direction and wind speed information according to the user location to the user terminal 3000.

Subsequently, the user terminal 3000 displays the wind direction and wind speed information transmitted from the central processing unit 2000 so that the user can know. As such, the user can know the wind direction and wind speed information of each golf course by using the wind direction and wind speed information displayed on the user terminal 3000.

Of course, the present invention is not limited thereto, and the central processing unit 2000 of the golf course wind direction and wind speed measurement system according to the present embodiment may provide the user with wind direction and wind speed information of a region desired by the user. In addition, it is preferable that the central processing unit 2000 and the wireless wind direction anemometer 1000 exchange information in real time. That is, the output result of the wireless wind vane 1000 may be continuously provided without a separate command. In addition, the central processing unit 2000 may receive an output signal of the wireless wind direction anemometer 1000 at predetermined time intervals.

1 is a conceptual diagram of a golf course wind direction and wind speed measurement system according to an embodiment of the present invention.

2 is a block diagram of a golf course wind direction and wind speed measurement system according to an embodiment.

3 is a block diagram of a wireless wind vane according to an embodiment.

4 to 7 are photographs of a wireless wind vane according to an embodiment.

8 is a plan view of a sensor unit of the wind direction anemometer according to the embodiment;

9 is a sectional view of a sensor unit according to an embodiment.

10 is a flowchart illustrating the operation of the golf course wind direction and wind speed measurement system according to the embodiment.

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

1000: wind direction anemometer 2000: central processing unit

3000: User terminal 1100: Measuring unit

1200: wireless communication unit 1300: power unit

100 sensor 110 110 body substrate

120: heat generating unit 130: temperature sensor

200: amplifier 300: control unit

Claims (8)

A plurality of wireless wind direction anemometers installed throughout the golf course for measuring wind direction and wind speed; A central processing unit receiving the output of the wireless wind direction anemometer wirelessly and calculating wind direction and wind speed throughout the golf course; And Golf course wind direction and wind speed measurement system, characterized in that it comprises a user terminal for providing a golf course user with the wind direction and wind speed information of the central processing unit. According to claim 1, wherein each of the wireless wind direction anemometer, Measurement unit for measuring the wind direction and wind speed with a thermopile, A wireless communication unit which transmits the measured wind direction wind speed, And a power supply unit for supplying power to the measurement unit and the wireless communication unit. The method of claim 2, wherein the measuring unit, And a sensor unit for sensing and outputting a temperature change in four directions according to the wind, an analog amplifier for amplifying and outputting an output signal of the sensor unit, and a controller for controlling the operation of the sensor unit and the amplification unit. Golf course wind direction measurement system. The method of claim 3, wherein the sensor unit, A golf course wind direction wind speed measurement system comprising a body substrate, a heating element provided in the center of the body substrate, and a plurality of temperature sensors respectively disposed in four directions of the heating element. The method of claim 4, wherein The heating element is manufactured in the form of a square, Four temperature sensors are respectively arranged on the upper, lower, left, and right sides of the heating element, Wherein each of the temperature sensors includes a thermo pile having a plurality of thermo couples. The method of claim 1, Golf course wind direction wind speed measurement system for communication between the central processing unit and the wireless wind direction anemometer through any one of the wireless communication method of CDMA, WiBlo, Bluetooth, radio frequency, WLAN, IrDA, WCDMA, HSDPA and SWAP. The method of claim 1, The golf course wind direction wind speed measurement system for communication between the central processing unit and the user terminal through any one of the wireless communication method of CDMA, WiBlo, Bluetooth, radio frequency, WLAN, IrDA, WCDMA, HSDPA and SWAP. The method of claim 1, A plurality of fixed shafts for fixing the plurality of wireless wind direction anemometers to an upper region on the surface of the golf course, Golf wind direction wind speed measurement system, characterized in that at least one wireless wind direction anemometer is disposed at the same position or different positions on the fixed shaft.

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