KR102553579B1 - Double conduction type rainfall measuring instrument and method performing thereof - Google Patents

Abstract

In the dual conduction precipitation meter implementation method executed in the dual conduction rain meter according to an embodiment of the present invention, any one of the standard observation cup and the sub observation cup for measuring precipitation of different capacities in a rainy state is Checking whether or not it moved, comparing the amount of precipitation collected by the moving observation cup and the amount of precipitation collected by the non-moving observation cup, and as a result of the comparison, the amount of precipitation collected by the moving observation cup was collected by the non-moving observation cup. and calculating the measured amount of precipitation using the amount of precipitation collected by the corresponding observation cup according to whether or not the amount of precipitation is greater than or equal to the amount of precipitation.

Description

Double conduction precipitation meter and its implementation method {DOUBLE CONDUCTION TYPE RAINFALL MEASURING INSTRUMENT AND METHOD PERFORMING THEREOF}

The present invention is a dual conduction type precipitation meter and its implementation method, more specifically, by using observation cups having different measuring capacities and integrating them into a precipitation meter to compensate for the disadvantages of each and separate operation that can accurately measure precipitation It relates to a dual conduction rainwater meter that can provide cost and operational budget savings in operational installation and a method of implementing the same.

Conventionally, there is a problem in that two precipitation meters are not installed due to cost and operational problems when installing a precipitation meter subdivided into 0.1 mm and a precipitation meter subdivided into 0.5 mm separately.

More specifically, a precipitation meter subdivided into 0.1 mm has an observation error when a lot of precipitation comes, and a precipitation meter subdivided into 0.5 mm has a limit in which observation is impossible when precipitation of less than 0.5 mm is received.

However, the dual conduction type precipitation meter pre-registered by the present applicant is configured to observe up to within 0.4 mm from the first observation cup and move to the second observation cup, separately measure precipitation within 0.5 mm and more than 0.5 mm, respectively, and obtain data. It is structured to assemble.

In the present invention, by using observation cups having different measuring capacities and integrating them into a precipitation meter, it is possible to compensate for the disadvantages of each and accurately measure precipitation, and to provide cost and operational budget savings during operational installation due to separate operation. An object of the present invention is to provide a dual conduction type precipitation meter and a method for implementing the same.

In addition, the present invention provides a dual conduction type rain meter capable of providing cost and operational budget savings during operation, which allows more accurate calculation by calculating the amount of precipitation collected in the sub-observation cup based on the amount of precipitation collected in the standard observation cup, and Its purpose is to provide an implementation method thereof.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention not mentioned above can be understood by the following description and will be more clearly understood by the examples of the present invention. It will also be readily apparent that the objects and advantages of the present invention may be realized by means of the instrumentalities and combinations indicated in the claims.

In order to achieve this purpose, the dual conduction precipitation meter implementation method implemented in the dual conduction precipitation meter determines which one of the reference observation cup and the sub observation cup that measures precipitation of different capacities in a rainy state is moved. checking whether or not the amount of precipitation collected by the moving observation cup and the amount of precipitation collected by the non-moving observation cup are compared, and as a result of the comparison, the amount of precipitation collected by the moving observation cup is greater than or equal to the amount of precipitation collected by the non-moving observation cup. and calculating the measured amount of precipitation using the amount of precipitation collected by the corresponding observation cup according to whether or not the measurement is performed.

In an embodiment, the step of determining and providing the current amount of precipitation as the measured amount of precipitation may include determining that the sub-observation cup has moved if the amount of precipitation collected by the moving observation cup is less than or equal to the amount of precipitation collected by the non-moving observation cup as a result of the comparison. The method may include calculating the measured amount of precipitation using the amount of precipitation collected by the moving observation cup according to the number of times the observation cup moves.

In one embodiment, in the step of determining and providing the current amount of precipitation as the measured amount of precipitation, if it is determined that the reference observation cup is moved simultaneously with the movement of the sub observation cup, the number of movements of the sub observation cup is initialized and the movement of the reference observation cup is determined. A step of calculating a measured amount of precipitation using the amount of precipitation collected by the observation cup according to the number of times may be included.

In addition, the dual conduction type precipitation meter to achieve this purpose is a standard observation cup for measuring the amount of precipitation of a specific capacity, a sub-observation cup for measuring the amount of precipitation with a smaller capacity than the standard observation cup, and sensing the movement of the reference observation cup. A first motion sensor providing first motion information by sensing the motion of the sub-observation cup and a second motion sensor providing second motion information by sensing the motion of the sub observation cup, and the first motion information and the second motion information in a rainy state When any one information is received, it is checked whether any one of the reference observation cup and the sub observation cup has moved, and the amount of precipitation collected by the moving observation cup and the amount of precipitation collected by the non-moving observation cup are compared, and a final precipitation determination unit that calculates the measured precipitation using the amount of precipitation collected by the observation cup according to whether or not the amount of precipitation collected by the observation cup that has moved is equal to or greater than the amount of precipitation collected by the observation cup that has not moved as a result of the comparison.

In one embodiment, the final precipitation determination unit determines that the sub-observation cup has moved if the amount of precipitation collected by the moving observation cup is less than or equal to the amount of precipitation collected by the observation cup that is not moved as a result of the comparison, and determines that the sub-observation cup has moved according to the number of movements of the observation cup that has been moved. The measured amount of precipitation may be calculated using the amount of precipitation collected by the moving observation cup.

In an embodiment, when the final precipitation determiner determines that the reference observation cup moves simultaneously with the movement of the sub observation cup, the number of movements of the sub observation cup is initialized, and the number of movements of the reference observation cup is collected into the observation cup according to the number of movements of the reference observation cup. Precipitation can be used to calculate the measured precipitation.

According to the present invention as described above, by using observation cups having different measuring capacities and integrating them into a precipitation meter, it is possible to compensate for each of the disadvantages and accurately measure precipitation, and it is possible to measure the amount of precipitation accurately. It has the advantage of being able to provide savings.

In addition, according to the present invention, by calculating the amount of precipitation collected in the sub-observation cup based on the amount of precipitation collected in the standard observation cup, there is an advantage in that cost and operational budget can be reduced during operational installation so that the amount of precipitation collected in the sub-observation cup can be calculated more accurately.

1 is a diagram for explaining a dual conduction type precipitation meter according to an embodiment of the present invention.
2 is a diagram for explaining a process of executing a dual conduction type precipitation meter according to an embodiment of the present invention.
3 is a diagram for explaining a process of executing a dual conduction type precipitation meter according to another embodiment of the present invention.
4 is a view for explaining a dual conduction type precipitation meter according to another embodiment of the present invention.

The above objects, features and advantages will be described later in detail with reference to the accompanying drawings, and accordingly, those skilled in the art to which the present invention belongs will be able to easily implement the technical spirit of the present invention. In describing the present invention, if it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar components.

1 is a diagram for explaining a dual conduction type precipitation meter according to an embodiment of the present invention.

Referring to FIG. 1, the dual conduction type precipitation meter 100 includes a first motion sensor 110, a second motion sensor 120, a first funnel 130, a second funnel 140, and a reference observation cup 150. ), a sub-observation cup 160, and a final precipitation determining unit 170.

The first motion sensor 110 senses the motion of the reference observation cup 150 when water falling through the first funnel 130 falls on the reference observation cup 150 and transmits the motion to the final precipitation determining unit 170. . The standard observation cup 150 is connected to the first motion sensor 110, and water falling from the first funnel 130 at a constant speed is collected.

The second motion sensor 120 senses the motion of the sub observation cup 160 when water falling through the second funnel 140 falls on the sub observation cup 160 and transmits the motion to the final precipitation determination unit 170. . The sub-observation cup 160 is connected to the second motion sensor 120 so that water falling from the second funnel 140 at a constant speed is collected.

The first funnel 130 allows the rainwater that has fallen along the surface of the culvert to fall at a constant speed to the reference observation cup 150, and the second funnel 140 drops the rainwater that has fallen along the surface of the culvert into the sub-observation cup ( 160) so that it falls at a constant speed.

The standard observation cup 150 collects rainwater that has fallen through the first funnel 130 along the surface of the water outlet. The standard observation cup 150 moves when rainwater of a predetermined measurement capacity is collected.

In one embodiment, when the measurement capacity of the reference observation cup 150 is 0.5 mm, rainwater collected by falling through the first funnel 130 along the surface of the water conduit is moved whenever it reaches 0.5 mm.

As described above, when the rainwater collected in the standard observation cup 150 becomes 0.5 mm and moves, the first motion sensor 110 senses the movement of the reference observation cup 150 and provides it to the final precipitation determining unit 170. .

The sub observation cup 160 collects rainwater that has fallen through the second funnel 140 along the surface of the water outlet. This sub-observation cup 160 can measure a capacity smaller than the measurement capacity of the standard observation cup 150 .

In one embodiment, when the measurement capacity of the sub-observation cup 160 is 0.1 mm, rainwater collected by falling through the second funnel 140 along the surface of the water conduit moves whenever it reaches 0.1 mm.

When the final precipitation determination unit 170 receives motion information for each of the standard observation cup 150 and the sub observation cup 160 from the first motion sensor 110 and the second motion sensor 120, the motion information Accordingly, the measured precipitation is calculated using the measurement information of each of the standard observation cup 150 and the sub observation cup 160.

First, when receiving first motion information from the first motion sensor 110, the final precipitation determining unit 170 determines that the reference observation cup 150 has moved, and receives second motion information from the second motion sensor 120. Upon reception, it is determined that the sub observation cup 160 has moved.

When the first motion information is not received from the first motion sensor 110 but the second motion information is received from the second motion sensor 120, the final precipitation determination unit 170 determines that the sub observation cup 160 has moved. do.

At this time, the final precipitation determining unit 170 determines that the sub observation cup 160 has moved as many times as the number of times the second motion information is received, and measures the sub observation cup 160 according to the number of times the sub observation cup 160 moves. Calculate the measured precipitation using the capacity.

For example, when the precipitation is 0.3 mm, the final precipitation determining unit 170 calculates the measured precipitation using the measurement capacity of the sub observation cup 160 0.1 mm * 3 as the sub observation cup 160 moves three times. can do.

However, the final precipitation determination unit 170 calculates the maximum measurement capacity of the sub observation cup 160 as the measured precipitation when the accumulated precipitation exceeds the measurement capacity of the sub observation cup 160 . For example, when the amount of precipitation is 0.6 mm, the final precipitation determination unit 170 exceeds the measurement capacity of the sub observation cup 160 by 0.4 mm, so that the maximum measurement capacity of the sub observation cup 160 is 0.4 mm or 0.5 mm. It can be calculated from measured precipitation.

In the above process, when the first motion information is received, the final precipitation determination unit 170 initializes the number of motions of the sub observation cup 160 and the maximum measurement capacity of the observation cup according to the number of motions of the reference observation cup. Calculate the measured precipitation using

Hereinafter, a process of calculating the measured precipitation by the final precipitation determination unit 170 will be described in more detail.

First, when receiving second motion information from the second motion sensor 120, the final precipitation determining unit 170 determines that the sub observation cup 160 has moved.

After that, if the value of the count variable of the sub-observation cup 160 is smaller than the measurement capacity of the standard observation cup 150, the final precipitation determining unit 170 determines the value of the count variable of the sub-observation cup 160 as a sub-observation It is increased by the measurement capacity of the cup 160, and the accumulated precipitation is increased by the measurement capacity of the sub-observation cup 160.

Meanwhile, when motion information is received from the first motion sensor 110, the final precipitation determiner 170 determines that the standard observation cup 150 has moved, and subtracts the count variable value of the sub observation cup 160 from the accumulated precipitation. After that, the value of the count variable of the sub observation cup 160 is initialized, and then the accumulated precipitation is increased by the measurement capacity of the reference observation cup 150.

2 is a diagram for explaining a process of executing a dual conduction type precipitation meter according to an embodiment of the present invention. An embodiment disclosed in FIG. 2 relates to an embodiment capable of measuring precipitation through a dual conduction type rain meter when the amount of precipitation collected by the standard observation cup is 0.5 mm and the amount of precipitation collected by the sub observation cup is 0.1 mm. .

Referring to FIG. 2 , a first motion sensor 110, a second motion sensor 120, a first funnel 130, a second funnel 140, a 0.5mm reference observation cup 150, and a 0.1mm sub observation cup. 160 and a final precipitation determining unit 170 .

The first motion sensor 110 senses the movement of the 0.5mm reference observation cup 150 when water falling through the first funnel 130 falls on the 0.5mm reference observation cup 150, and the final precipitation determining unit 170 ) is sent to The 0.5mm standard observation cup 150 is connected to the first motion sensor 110 and the water falling from the first funnel 130 at a constant speed is collected.

The second motion sensor 120 senses the movement of the 0.1mm sub-observation cup 160 when the water that has fallen through the second funnel 140 falls on the 0.1mm sub-observation cup 160, and the final precipitation determination unit 170 ) is sent to The 0.1mm sub-observation cup 160 is connected to the second motion sensor 120 and the water falling from the second funnel 140 at a constant speed is collected.

The first funnel 130 allows rainwater that has fallen along the surface of the culvert to fall at a constant speed to the 0.5mm standard observation cup 150, and the second funnel 140 measures the rainwater that has fallen along the surface of the culvert 0.1mm. It is allowed to fall at a constant speed to the sub observation cup 160.

The 0.5mm standard observation cup 150 gathers rainwater that has fallen through the first funnel 130 along the surface of the water outlet. The 0.5mm standard observation cup 150 moves when rainwater of a predetermined measurement capacity is collected.

As described above, when the rainwater collected in the 0.5mm standard observation cup 150 becomes 0.5mm and moves, the first motion sensor 110 senses the movement of the 0.5mm standard observation cup 150 to determine the final amount of precipitation 170 will be provided to

The 0.1mm sub-observation cup 160 gathers rainwater that has fallen through the second funnel 140 along the surface of the water outlet. The 0.1mm sub-observation cup 160 can measure a capacity smaller than the measurement capacity of the 0.5mm standard observation cup 150 .

When the final precipitation determination unit 170 receives motion information for each of the 0.5mm reference observation cup 150 and the 0.1mm sub observation cup 160 from the first motion sensor 110 and the second motion sensor 120, respectively. , After updating the count variable and cumulative precipitation for each observation cup of the 0.5 mm standard observation cup 150 and the 0.1 mm sub observation cup 160 according to the motion information, the final amount of precipitation is determined. Hereinafter, it will be described in more detail with reference to [Table 1].

First, when motion information is received from the second motion sensor 120, the final precipitation determining unit 170 determines that the 0.1 mm sub-observation cup 160 has moved.

Then, if the value of the count variable of the 0.1mm sub-observation cup 160 is smaller than the measurement capacity of the 0.5mm reference observation cup 150, the final precipitation determination unit 170 determines the count of the 0.1mm sub-observation cup 160. The value of the variable is increased by the measurement capacity of the 0.1mm sub-observation cup 160, and the accumulated precipitation is increased by the measurement capacity of the 0.1mm sub-observation cup 160.

Meanwhile, the final precipitation determining unit 170 determines that the 0.5mm standard observation cup 150 has moved when receiving motion information from the first motion sensor 110, and counts the 0.1mm sub observation cup 160 from the accumulated precipitation. After subtracting the variable value, the value of the count variable of the 0.1mm sub-observation cup 160 is initialized, and then the accumulated precipitation is increased by the measurement capacity of the 0.5mm reference observation cup 150.

[Table 1]

For example, if the value of the count variable of the 0.1 mm sub observation cup 160 is 0 and the precipitation is 0.4 mm, and the 0.1 mm sub observation cup 160 moves once, the count variable of the sub observation cup 160 If the value is updated to 0.1mm, the cumulative precipitation is updated to 0.1mm, and the 0.1mm sub-observation cup 160 moves twice, the value of the count variable of the sub-observation cup 160 is updated to 0.2mm and the accumulated precipitation is 0.2mm. , and when the 0.1mm sub-observation cup 160 moves three times, the value of the count variable of the sub-observation cup 160 is updated to 0.3mm, the accumulated precipitation is updated to 0.3mm, and the 0.1mm sub-observation cup 160 When this movement is performed 4 times, the value of the count variable of the sub observation cup 160 is updated to 0.4 mm and the accumulated precipitation is updated to 0.4 mm.

As described above, the 0.1mm sub-observation cup 160 moves when the precipitation amount is 0.4mm, but since the maximum measurement capacity of the sub-observation cup 160 is 0.4mm, the precipitation amount will continue to be 0.4mm.

In the above state, if the 0.5mm standard observation cup 150 moves once, the value of the count variable of the sub observation cup 160 is subtracted by 0.4mm from the accumulated precipitation 0.4, and then the 0.5mm standard observation cup (150 ) is increased by 0.5 mm to determine the cumulative precipitation as 0.5 mm.

For another example, if the 0.1mm sub observation cup 160 moves 11 times and the 0.5mm reference observation cup 150 moves twice, if the 0.1mm sub observation cup 160 moves once, the sub observation cup 160 ) is updated to 0.1mm, the cumulative precipitation is updated to 0.1mm, and when the 0.1mm sub observation cup 160 moves twice, the count variable value of the sub observation cup 160 is updated to 0.2mm When the cumulative precipitation is updated to 0.2mm, and the 0.1mm sub-observation cup 160 moves three times, the value of the count variable of the sub-observation cup 160 is updated to 0.3mm, the cumulative precipitation is updated to 0.3mm, and the 0.1mm sub When the observation cup 160 moves four times, the value of the count variable of the sub observation cup 160 is updated to 0.4 mm and the accumulated precipitation is updated to 0.4 mm.

In the above state, if the 0.5mm standard observation cup 150 moves once, the value of the count variable of the sub observation cup 160 is subtracted by 0.4mm from the accumulated precipitation 0.4, and then the 0.5mm standard observation cup (150 ) can be increased by 0.5 mm to obtain a cumulative precipitation of 0.5 mm.

Then, when the 0.1mm sub-observation cup 160 moves 6 times, the value of the count variable of the sub-observation cup 160 is updated to 0.1mm and the cumulative precipitation is updated to 0.6mm, and the 0.1mm sub-observation cup 160 is When the sub observation cup 160 moves 7 times, the value of the count variable of the sub observation cup 160 is updated to 0.2 mm and the accumulated precipitation is updated to 0.7 mm, and when the 0.1 mm sub observation cup 160 moves 8 times, the count variable of the sub observation cup 160 If the value of is updated to 0.3mm, the accumulated precipitation is updated to 0.8mm, and the 0.1mm sub-observation cup 160 moves 9 times, the value of the count variable of the sub-observation cup 160 is updated to 0.4mm and the accumulated precipitation is accumulated. Update precipitation to 0.9 mm.

In the above state, when the 0.5mm standard observation cup 150 moves twice, the cumulative precipitation 0.9 is subtracted by 0.4mm from the count variable of the sub observation cup 160 and updated to 0.5mm, and then 0.5mm is added to the accumulated precipitation. The accumulated precipitation may be 1.0 mm by increasing the measurement capacity of the standard observation cup 150 by 0.5 mm.

Then, when the 0.1mm sub-observation cup 160 moves 10 times, the value of the count variable of the sub-observation cup 160 is updated to 0.1mm and the accumulated precipitation is updated to 1.1mm, and the 0.1mm sub-observation cup 160 When this movement is performed 11 times, the value of the count variable of the sub observation cup 160 can be updated to 1.2 mm.

As described above, the present invention calculates the measured precipitation by revolutionizing the amount of precipitation collected in the sub-observation cup based on the amount of precipitation collected in the standard observation cup, thereby providing cost and operational budget savings at the time of operational installation so that the amount of precipitation can be calculated more accurately. There is an advantage to being

3 is a diagram for explaining a process of executing a dual conduction type precipitation meter according to another embodiment of the present invention.

Referring to FIG. 3, the dual conduction type precipitation meter 100 checks whether any one of the standard observation cup and the sub observation cup for measuring precipitation of different capacities has moved in a rainy state (step S310). ).

The dual conduction type precipitation meter 100 compares the amount of precipitation collected by the moving observation cup and the amount of precipitation collected by the non-moving observation cup (step S320).

In one embodiment of step S320, the dual conduction type precipitation meter 100 determines that the sub-observation cup has moved if the amount of precipitation collected by the already moved observation cup is less than the amount of precipitation collected by the non-moving observation cup, and the moved observation cup. The measured precipitation may be calculated using the amount of precipitation collected by the moving observation cup according to the number of times of movement of the.

In another embodiment of step S320, the double conduction type precipitation meter 100 initializes the number of movements of the sub-observation cup when it is determined that the reference observation cup moves simultaneously with the movement of the sub-observation cup, and the movement of the reference observation cup The measured precipitation may be calculated using the maximum measurement capacity of the observation cup according to the number of times.

The double conduction type precipitation meter 100 calculates the measured amount of precipitation using the amount of precipitation collected by the corresponding observation cup according to whether or not the amount of precipitation collected by the moving observation cup is greater than or equal to the amount of precipitation collected by the non-moving observation cup as a result of comparison (step S330). ).

4 is a view for explaining a dual conduction type precipitation meter according to another embodiment of the present invention.

Referring to FIG. 4 , a first motion sensor 110, a second motion sensor 120, a first funnel 130, a second funnel 140, a standard observation cup 150, a sub observation cup 160, It includes a final precipitation determination unit 170 and a monitoring unit 180.

The first motion sensor 110 senses the motion of the reference observation cup 150 when water falling through the first funnel 130 is sensed and provides the sensed motion to the monitoring unit 180 .

The second motion sensor 120 senses the motion of the sub observation cup 160 when water that has fallen through the second funnel 140 falls on the sub observation cup 160 and provides it to the monitoring unit 180 .

The standard observation cup 150 collects rainwater that has fallen through the first funnel 130 along the surface of the water outlet. The standard observation cup 150 moves when rainwater of a predetermined measurement capacity is collected.

In one embodiment, when the measurement capacity of the reference observation cup 150 is 0.5 mm, rainwater collected by falling through the first funnel 130 along the surface of the water conduit is moved whenever it reaches 0.5 mm.

As described above, when the rainwater collected in the standard observation cup 150 becomes 0.5 mm and moves, the first motion sensor 110 senses the movement of the reference observation cup 150 and provides it to the final precipitation determining unit 170. .

The sub observation cup 160 collects rainwater that has fallen through the second funnel 140 along the surface of the water outlet. This sub-observation cup 160 can measure a capacity smaller than the measurement capacity of the standard observation cup 150 .

In one embodiment, when the measurement capacity of the sub-observation cup 160 is 0.1 mm, rainwater collected by falling through the second funnel 140 along the surface of the water conduit moves whenever it reaches 0.1 mm.

The monitoring unit 180 uses the first motion information and the second motion information from the first motion sensor 110 and the second motion sensor 120, respectively, to determine the state of the standard observation cup 150 and the sub observation cup 160. to monitor

First, the monitoring unit 180 calculates the number of movements of the standard observation cup 150 using the first motion information received from the first motion sensor 110, and the sub-observation received from the second motion sensor 120. The number of movements of the cup 160 is calculated.

Then, the monitoring unit 180 uses the number of movements of the standard observation cup 150 and the number of movements of the sub observation cup 160 to check whether each of the standard observation cup 150 and the sub observation cup 160 is abnormal. do.

In one embodiment, the monitoring unit 180 may determine if the standard observation cup 150 has an abnormality when there is no movement number of the standard observation cup 150 until the amount of precipitation collected according to the number of movements of the sub observation cup 160 reaches a critical amount of precipitation. It can be judged that there is For example, the monitoring unit 180 determines that there is something wrong with the standard observation cup 150 when the amount of precipitation collected according to the number of movements of the sub observation cup 160 is 0.8 mm and the standard observation cup 150 does not move. can do.

The critical precipitation amount may be determined as a value corresponding to a multiple of the measurement capacity of the reference observation cup 150 . For example, when the measurement capacity of the reference observation cup 150 is 0.5 mm, the critical amount of precipitation may be determined to be 1.0 mm corresponding to twice the measurement capacity of the reference observation cup 150 of 0.5 mm.

In another embodiment, the monitoring unit 180 monitors the sub-observation cup 160 when the number of movements of the sub-observation cup 160 is less than or equal to a specific number when the amount of precipitation collected according to the number of movements of the standard observation cup 150 is a critical amount of precipitation. It can be judged that there is something wrong with The specific number of times may be determined as a value corresponding to half of the measurement capacity of the standard observation cup 150 .

For example, if the number of movements of the sub observation cup 160 is 5 times or less when the amount of precipitation collected by moving the reference observation cup 150 twice is 1.0 mm, it can be determined that the sub observation cup 160 has an abnormality.

Although described by the limited embodiments and drawings, the present invention is not limited to the above embodiments, and those skilled in the art can make various modifications and variations from these descriptions. Therefore, the spirit of the present invention should be grasped only by the claims described below, and all equivalent or equivalent modifications thereof will be said to belong to the scope of the spirit of the present invention.

100: dual conduction type precipitation meter running device,
110: first motion sensor,
120: second motion sensor,
130: first funnel,
140: second funnel,
150: reference observation cup,
160: sub observation cup,
170: final precipitation determination unit,
180: monitoring unit

Claims (6)

In the dual conduction rain meter implementation method implemented in the dual conduction rain meter,
checking whether any one of the reference observation cup and the sub observation cup for measuring precipitation of different capacities has moved in a rainy state;
comparing the amount of precipitation collected by the moving observation cup and the amount of precipitation collected by the non-moving observation cup; and
Calculating the measured precipitation using the amount of precipitation collected with the observation cup that moved or the amount of precipitation collected with the observation cup that did not move according to whether or not the amount of precipitation collected with the observation cup that moved was equal to or greater than the amount of precipitation collected with the observation cup that did not move as a result of the comparison. including,
The number of movements of the standard observation cup is calculated using the first motion information received from the first motion sensor for sensing the motion of the reference observation cup, and the second motion is received from the second motion sensor for sensing the motion of the sub observation cup. Calculating the number of movements of the sub observation cup using the information;
determining that the reference observation cup has an abnormality if the reference observation cup does not move until the amount of precipitation collected according to the number of movements of the sub observation cup reaches a critical amount of precipitation; and
Further comprising the step of determining that there is an abnormality in the sub observation cup if the number of movements of the sub observation cup is less than a specific number when the precipitation collected according to the number of movements of the reference observation cup is a critical precipitation amount
How to implement a dual conduction rain meter.
According to claim 1,
The step of calculating the measured precipitation using the amount of precipitation collected by the moving observation cup or the amount of precipitation collected by the non-moving observation cup
As a result of the comparison, if the amount of precipitation collected by the moving observation cup is less than or equal to the amount of precipitation collected by the non-moving observation cup, it is determined that the sub observation cup has moved and the amount of precipitation collected by the moving observation cup according to the number of movements of the moving observation cup is used. characterized in that it comprises the step of calculating the measured precipitation by
How to implement a dual conduction rain meter.
According to claim 2,
The step of calculating the measured precipitation using the amount of precipitation collected by the moving observation cup or the amount of precipitation collected by the non-moving observation cup
When it is determined that the reference observation cup moves simultaneously with the movement of the sub observation cup, the number of movements of the sub observation cup is initialized and the measurement precipitation is calculated using the maximum measurement capacity of the observation cup according to the number of movements of the reference observation cup characterized by comprising the steps
How to implement a dual conduction rain meter.
In the double conduction type precipitation meter,
a standard observation cup for measuring the amount of precipitation in a specific volume;
a sub-observation cup for measuring precipitation with a capacity smaller than that of the standard observation cup;
a first motion sensor sensing a motion of the reference observation cup and providing first motion information;
a second motion sensor sensing a motion of the sub-observation cup and providing second motion information; and
When any one of the first motion information and the second motion information is received in a rainy state, it is checked whether any one of the standard observation cup and the sub observation cup has moved, and the moved observation cup is used. The amount of precipitation collected by the observation cup and the amount of precipitation collected by the non-moving observation cup are compared, and as a result of the comparison, the amount of precipitation collected by the observation cup that moves or the amount of precipitation collected by the observation cup that moves depends on whether or not the amount of precipitation collected by the observation cup that moves is equal to or greater than the amount of precipitation collected by the observation cup that does not move. a final precipitation determination unit that calculates the measured precipitation using the amount of precipitation collected by the non-observation cup; and
The number of movements of the reference observation cup is calculated using the first motion information received from the first motion sensor, and the number of movements of the sub observation cup is calculated using the second motion information received from the second motion sensor. If there is no movement number of the reference observation cup until the precipitation collected according to the number of movements of the sub observation cup reaches the critical precipitation, it is determined that the reference observation cup has an abnormality, and when the precipitation collected according to the number of movements of the reference observation cup is the critical precipitation Characterized in that it includes a monitoring unit that determines that there is an abnormality in the sub observation cup if the number of movements of the observation cup is less than a certain number
Dual conduction rain meter.
According to claim 4,
The final precipitation determination unit
As a result of the comparison, if the amount of precipitation collected by the moving observation cup is less than or equal to the amount of precipitation collected by the non-moving observation cup, it is determined that the sub observation cup has moved, and the maximum measurement capacity of the moving observation cup according to the number of movements of the moving observation cup is determined. Characterized in that the measured precipitation is calculated using
Dual conduction rain meter.
According to claim 5,
The final precipitation determination unit
When it is determined that the reference observation cup moves simultaneously with the movement of the sub observation cup, the number of movements of the sub observation cup is initialized and the measurement precipitation is calculated using the maximum measurement capacity of the observation cup according to the number of movements of the reference observation cup characterized by
Dual conduction rain meter.

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