KR101198533B1 - Rain and snow gauge - Google Patents

Abstract

PURPOSE: A rain and snow gauge is provided to reduce the error of measurement by reducing the movement of angle of a tipping bucket. CONSTITUTION: A rain and snow gauge includes a base, a cylindrical cover, a collecting cup, a tipping bucket(120), a fixing part, and a sensor part. The tipping bucket is installed at the lower part of the collecting cup and moves according to the amount of introduced rainwater. The sensor part detects the movement of the tipping bucket. The collecting cup includes a funnel part, a fastening part, a nozzle, and a nozzle part. The tipping bucket includes a main body(121), a partition(122), a first receiving part(123), a second receiving part(124), supporting parts(125, 126), and hinge holes(125a). The partition is formed at the center of the main body. The receiving parts are formed at both sides of the main body based on the partition. The lower sides of the receiving parts are curved. The supporting parts are formed at both sides of the center parts of the supporting parts. The rotary shaft of the hinge holes is combined on the supporting parts.

Description

Rain and snow gauge {RAIN AND SNOW GAUGE}

The present invention relates to a rainfall snow gauge for measuring precipitation of rainfall or melted snow, and more particularly, to a rainfall snow meter that enables accurate measurement by improving the structure of the collecting cup and the tipping bucket.

Rainfall snow gauge as is well known as a device for measuring the precipitation of rainfall or melted snow will be described with reference to the accompanying drawings.

Conventional rainfall snow meter is as in Figures 1 to 3,

It includes a base 10 fixed to be installed horizontally on the ground or a predetermined place, and a cylindrical cover 20 fixed to the upper portion of the base.

In addition, the upper end of the cover 20 is formed with a squirt opening 21 through which rainwater flows, and a squid tank 22 for collecting rainwater introduced therein is formed inside the squirt opening 21, and the squirt tank ( At the upper end of 22), the filtering net 23 is installed.

In addition, at the lower end of the sump tank 22, a water collecting cup 30 for collecting water discharged through the sump tank 22 and discharging downwardly stably is installed in the upper bracket 11, and the sump cup ( 30 is fixed to the tipping bucket 40 and the radius of the seesaw operation of the tipping bucket 40 and the seesaw operation to the left and right according to the amount of rain water dropped through the catching cup 30 ) Is installed connected to the lower bracket (12).

In addition, the left and right drain pipes 51 and 52 are formed on the base 10 at both lower ends of the tipping bucket 40 to guide the drained water to the ground when water contained in the tipping bucket 40 is discharged by the seesaw operation. do.

An inner lower end of the drain pipes 51 and 52 is opened so that rainwater introduced from the tipping bucket 40 is discharged to the lower end of the base 10.

In addition, the rainwater falling from the catching cup 30 alternately flows into the first and second accommodating portions 43 and 44 of the tipping bucket 40, so that the tipping bucket 40 performs a right and left seesaw operation. In this case, the sensor 60 connected to the rear surface of the lower bracket 12 detects the seesaw motion of the tipping bucket 40.

The sensor unit 60 detects the seesaw rotation of the rotary shaft 61 by using a magnetic body installed at the rear end of the rotary shaft 61 of the tipping bucket 40 and a reed switch installed close to the magnetic body.

The rainfall measurement method of the rainfall snow gauge constructed as above will be examined.

Rainfall meters have 1.0 mm and 0.5 mm types depending on the unit of rainwater being measured.

First, the 1.0mm type, when rainwater is accumulated at a height of 1mm in an area of 1 square meter (m ² ), the precipitation at this time is called '1', and the weight of the rainwater is about 31.42g.

In addition, in the 0.5mm type, when rainwater is accumulated at a height of 0.5mm in an area of 1 square meter (m ² ), the precipitation at this time is called '0.5', and the weight of the rainwater is about 15.71g.

The tipping bucket 40 maintains an inclined state toward the initial left or right side, wherein the first height adjusting bolt of the fixing part 70 is opposite to the first shock absorbing part 47 or the second shock absorbing part 48. 71 or the second height adjusting bolt 72 is maintained in contact.

In addition, the rainwater discharged from the catching cup 30 is filled in the first receiving part 43 or the second receiving part 44 of the tipping bucket 40.

For example, in the case of a 1.0 mm precipitation meter, when 31.42 g of rainwater is filled in one side of the first accommodating part 43, the tipping bucket 40 rotates to the left, and the buffer part 47 of the first height adjusting bolt is installed. At the same time as 71 is contacted, the rainwater contained in the first accommodating part 43 is poured into the drain pipe 51.

At the same time, the sensor unit 60 detects the rotation of the rotary shaft 61 of the tipping bucket 40 and detects the rainfall '1'.

Then, when the other side of the second receiving portion 44 is filled with 31.42g of rainwater, the tipping bucket 40 is rotated to the right so that the buffer portion 48 and the second height adjustment bolt 72 is in contact with the second Rainwater contained in the receiving portion 44 is poured into the drain pipe 52, the sensor unit 60 is to detect the precipitation '2'.

In the rainfall snow gauge configured as described above, first, the structure of the catching cup 30 will be described in detail. As shown in FIG. 4, the catching cup 30 is formed in a funnel shape, and has an inclined portion 31 and a nozzle at the center bottom. The part 32 is provided.

The catching cup 30 configured as described above has a structure in which water discharged through the water tank 22 slides downward through the inclined portion 31 and is discharged downward through the nozzle portion 32. When a large amount of water is discharged through the water tank 22, the amount of water discharged through the nozzle unit 32 is also increased, and the amount of water discharged is not constant and has irregular directionality and strength.

This is because water is directly down through the inclined portion 31 and the nozzle portion 32 due to the structure of the collecting cup 30. In this case, the water flowing into the receiving portion of the tipping bucket 40 is not stably supplied and a measurement error (malfunction) occurs due to the pressure (falling speed) of the water applied to the tipping bucket 40.

On the other hand, looking at the structure of the tipping bucket 40, as shown in Figure 5 (a) (b) the tipping bucket 40 is a triangular body 41, a triangular diaphragm 42 formed in the center of the main body and First and second receiving parts 43 and second receiving parts 44 formed on both left and right sides of the triangular diaphragm 42 to receive the incoming water, and fixedly installed on both side surfaces of the main body 41. The first and second guide parts 45 and 46 and the bottom of the main body 41 are fixedly installed between the first and second guide parts 45 and 46, and one end thereof extends to the sensor part 60. It includes a rotating shaft 61 connected to.

In addition, the height adjustment unit 70 is a component that sets the minimum position when the tipping bucket 40 is operated to seesaw left and right, the first height adjustment bolt 71 and the second height adjustment bolt 72 at both ends. ) Is formed.

In the tipping bucket 40 configured as described above, the tipping bucket 40 is moved to the left and right by the center rotating shaft 61 positioned below the bottom surface of the main body 41 as shown in FIG. 5 (b). The conduction angle becomes large.

This is because the rainwater flowing from the water collecting cup 30 is filled in the first accommodating part 43 and then discharged and filled in the second accommodating part 44 at the same time. While the water in the portion 43 is drained, measurement errors occur because rainwater flows from the water collecting cup 14 into the first accommodating portion 43.

In addition, the tipping bucket 40 of the prior art has a bent portion (a) (b) in which the surface is in contact with the inside of the first accommodation portion 43 and the second accommodation portion 44, as shown in Figure 5 (a) After the water filled in each of the receiving portions 43 and 44 of the tipping bucket 40 is drained to the corresponding drain pipes 51 and 52, water remains in the bent portion (a) (b). The phenomenon was

This is a phenomenon that a small amount of water adheres to the space of the bent portion (a) (b), and the water filled in the first or second accommodating portion 43 or 44 is not completely discharged, resulting in a measurement error. .

The present invention was devised to solve the above problems, and an object of the present invention is to provide a rainfall snow meter that allows accurate measurement by improving the structure of the sump cup and tipping bucket.

The present invention for achieving the above object is fixed to be installed on the ground or a predetermined horizontal to the base, the upper end is formed with a squirt flows into which rainwater is introduced, the inside of the filtration net and the rainwater introduced through the squirt catches A cylindrical cover is formed to be fixed to the upper portion of the base, and the collection cup is installed at the lower end of the sump tank to collect the water discharged through the sump and to be discharged downward stably, and the house Tipping buckets installed at the bottom of the cup to seesaw the left and right according to the amount of rain water dropped, and the first height adjustment bolt and the second height adjustment bolt to set the maximum angle when the tipping bucket is rotated left or right And a fixed part including the upper and lower sides of the tipping bucket, the water contained in the tipping bucket being discharged by the seesaw operation. In the rainfall snow meter comprising a left and right drain pipe for guiding the drain to the ground, and the sensor unit for detecting the left and right motion of the tipping bucket, the catching cup has a funnel-shaped water collecting pipe with a screw portion formed on the outer side down A nozzle portion including a funnel portion, a fastening portion fastened to the screw portion of the funnel portion, a nozzle formed below the air gap, and an air hole formed between the fastening portion and the nozzle; The tipping bucket includes a triangular main body, a diaphragm formed at the center of the main body, and rainwater flowing into the left and right sides of the diaphragm, and the first accommodation part and the second accommodation part having a curved bottom surface. And a support part formed at both sides in the center of the main body, and a hinge hole formed to be coupled to the rotation shaft on the support part, the hinge hole being positioned above the position of the bottom of the main body.

In addition, the interior of the nozzle portion of the collecting cup according to the present invention is characterized in that the space is formed around the collection pipe.

In addition, the collecting pipe end of the collecting cup according to the present invention is characterized in that located below the air hole of the nozzle portion.

In addition, the bottom surface central end of the first receiving portion and the second receiving portion of the tipping bucket according to the present invention is characterized in that it further comprises a curved extension portion extending a predetermined length.

In addition, the upper end of the inside of the diaphragm bucket according to the present invention is characterized in that it is attached to the counterweight having a certain weight.

Thus, in the present invention, even if a large amount of rainwater flows into the catching cup, the dropping speed of the rainwater is buffered by the internal space formed by the funnel and the nozzle part, and the dropping is carried out in the form of continuous droplets through the nozzle. By supplying a constant (small amount) and stable water stream, it provides an advantage of greatly improving the measurement efficiency.

In addition, the tipping bucket of the present invention is configured so that the position of the rotating shaft for rotating and supporting the main body is positioned above the bottom position of the main body, thereby reducing the angle of the tipping bucket left and right seesaw operation to greatly reduce the error during measurement.

In addition, the weight balance weight is installed at the top of the center of the main body to reduce the left and right conduction angles of the tipping bucket from the rotation axis and at the same time, the center of gravity is located at the top. Will not be.

In addition, the bottom surface of the first and second accommodating portions of the tipping bucket is formed in a curved shape so that the remaining amount does not remain when the rainwater is discharged, thereby enabling very accurate measurement.

1 is an external view of a conventional rainfall snow meter,
2 is an exploded perspective view of FIG. 1;
3 is an internal configuration diagram of FIG.
4 is a detailed configuration diagram of the collecting cup of FIG.
Figure 5 (a) (b) is a detailed configuration diagram of the tipping bucket and the fixing portion of FIG.
6 is a block diagram of a rainfall snow meter according to the present invention,
7 is a perspective view of a water collecting cup according to the present invention;
8 is an exploded perspective view of a collecting cup according to the present invention;
9 is a side cross-sectional view of the sump cup according to the present invention;
10 is a perspective view of the tipping bucket according to the present invention,
Figure 11 (a) (b) is a side configuration and cross-sectional view of the present invention,
12 is an operational state diagram of the tipping bucket according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

First, in adding reference numerals to the components of each drawing, the same components have the same reference numerals as much as possible even though they are displayed on different drawings.

6 is a block diagram of a rainfall snow meter according to the present invention.

As shown, the present invention rainfall snow meter,

The base 10 fixed to be horizontally installed on the ground or a predetermined place, and the squirt opening 21 through which rainwater flows is formed at the upper end thereof, and the filtration net 23 and the rainwater introduced through the squirt opening 21 are formed therein. A water tank 22 for collecting water is formed, and the cylindrical cover 20 fixed to the base 10 is installed at an upper end of the water tank 22 and discharged through the water tank 22. A water collecting cup 110 for collecting water and stably discharging downward, a tipping bucket 120 installed at a lower end of the water collecting cup 110 and acting on a seesaw according to the amount of rain water dropped, and the tipping. Fixing part 70 including the first height adjustment bolt 71 and the second height adjustment bolt 72 to set the maximum angle when the bucket 120 is rotated left or right, and the tipping bucket 120 Formed on both bottom bases 10 of the side) and the water contained in the tipping bucket 120 It includes a left and right drain pipe 51, 52 for guiding it to be drained to the ground when discharged to the ground, and a sensor unit 60 for detecting the left and right motion of the tipping bucket 120.

Here, a detailed configuration of the water collecting cup 110 will be described with reference to FIGS. 7 to 9.

The catching cup 110 includes a funnel 111 and a nozzle 114 coupled thereto.

The funnel 111 has a funnel shape and a water collecting pipe 113 having a threaded portion 112 formed on an outer surface thereof.

The nozzle portion 114 is a fastening portion 115 to be fastened to the screw portion 112 of the funnel portion 111, a nozzle 116 formed below, between the fastening portion 115 and the nozzle 116 Air holes 117 formed in the.

When the funnel portion 111 and the nozzle portion 114 configured as described above are fastened, a space c is formed around the collection pipe 113 inside the nozzle portion 114 as shown in FIG. 9.

  In addition, the end portion of the collecting pipe 113 is positioned below the air hole 117 of the nozzle unit 114.

Look at the action of the catching cup 110 configured as described above.

Rain water fallen from the water tank 22 is discharged to the water collecting pipe 113 through the funnel 111, the water discharged from the water collecting pipe 113 to the internal space (c) of the nozzle unit 114 Inflow.

At this time, the air existing in the space (c) of the nozzle unit 114 is discharged through the air hole 117, and at the same time rainwater introduced into the space (c) is first buffered and then the small diameter nozzle 116 Falls downward in the form of water droplets through.

According to the structure of the present invention collection cup 110, even if a large amount of rain water flows through the water tank 22, the inner space (c) formed by the funnel portion 111 and the nozzle portion 114 By the fall rate of the rain water is buffered to fall through the nozzle 116 in the form of a continuous drop, by supplying a constant (small amount) and stable water flow to the tipping bucket 120 installed on the lower surface to greatly improve the measurement efficiency Will be provided.

In addition, the structure of the tipping bucket 120 will be described in detail with reference to FIGS. 10 and 11.

The tipping bucket 120 has a triangular main body 121, a diaphragm 122 formed at the center of the main body 121, and rainwater formed on both left and right sides of the diaphragm 122 to be introduced therein, The first accommodating part 123 and the second accommodating part 124 formed in the curved shape, the support parts 125 and 126 formed on both sides at the center of the main body 121, and the support part 125 ( The hinge shafts 125a and 125b are formed to be coupled to the rotation shaft 61 on the 126, but the positions thereof are positioned above the bottom of the bottom surface of the main body 121.

In addition, the bottom surface of the first receiving portion 123 and the second receiving portion 124 is further configured to be discharged without a residual amount when the rain water discharged by further configuring a curved extension portion (123a) (124a) extending a predetermined length. .

In addition, the upper end of the inside of the diaphragm 122 of the main body 121 is configured to further attach a balance weight 129 having a certain weight.

In addition, buffers 127 and 128 are further formed on both sides of the bottom of the main body 121.

In addition, the main body 121 is configured to coat the entire surface so that rain water does not remain on the surfaces of the first accommodating part 123 and the second accommodating part 124 during drainage.

It looks at the operation of the tipping bucket 120 configured as described above.

First, the tipping bucket 120 is configured to position (d2) above the bottom position of the main body 121, the position of the rotary shaft 61 for rotating and supporting the main body 121, as shown in Figure 11 (a), As shown in FIG. 12, the tipping bucket 120 reduces the angle d3 of the left and right seesaw operation, thereby greatly reducing the error in the measurement.

In addition, by installing the weight balance weight 129 in the upper center of the body 121, the left and right conduction angle of the tipping bucket 120 is greatly reduced from the rotating shaft 61 and at the same time the center of gravity is located at the top, the collecting cup 110 Measurement errors do not occur even when the amount of rainwater flowing from the plant is large or small.

In addition, since the bottom surfaces of the first accommodating part 123 and the second accommodating part 124 are both formed in a curved shape, the remaining amount does not remain when rainwater is discharged, thereby enabling highly accurate measurement.

In addition, the amount of the main body 121 when the rain water is discharged from the tipping bucket 120 due to the structure of the curved extension parts 123a and 124a formed at the central ends of the first accommodation part 123 and the second accommodation part 124. All rain water remaining at the end has the effect of completely falling.

10: base 20: cover
21: Sewer hole 22: Sewer tank
23: filter network 51, 52: drain pipe
60: sensor 61: rotating shaft
70: fixing part 71: first height adjustment bolt
72: second height adjustment bolt 110: collecting cup
111: funnel 112: screw portion
113: collecting pipe 114: nozzle unit
115: fastening portion 116: nozzle
117: air hole 120: tipping bucket
121: body 122: diaphragm
123: first accommodating part 124: second accommodating part
123a, 124a: curved extension part 125, 126: support part
125a, 126a: hinge hole 127, 128: buffer part
129: counterweight

Claims (5)

The base 10 fixed to be horizontally installed on the ground or a predetermined place, and the squirt opening 21 through which rainwater flows is formed at the upper end thereof, and the filtration net 23 and the rainwater introduced through the squirt opening 21 are formed therein. A water tank 22 for collecting water is formed, and the cylindrical cover 20 fixed to the base 10 is installed at an upper end of the water tank 22 and discharged through the water tank 22. A water collecting cup 110 for collecting water and stably discharging downward, a tipping bucket 120 installed at a lower end of the water collecting cup 110 and acting on a seesaw according to the amount of rain water dropped, and the tipping. Fixing part 70 including the first height adjustment bolt 71 and the second height adjustment bolt 72 to set the maximum angle when the bucket 120 is rotated left or right, and the tipping bucket 120 Formed on both bottom bases 10 of the side) and the water contained in the tipping bucket 120 In the rainfall snow meter comprising a left and right drain pipe 51, 52 for guiding it to be discharged to the ground when discharged to the ground and a sensor unit 60 for detecting the left and right motion of the tipping bucket 120,
The catching cup 110 has a funnel shape and a funnel portion 111 having a collecting pipe 113 having a screw portion 112 formed on an outer surface thereof, and a fastening portion fastened to the screw portion 112 of the funnel portion 111. A nozzle portion (114) comprising a portion (115), a nozzle (116) formed below it, and an air hole (117) formed between the fastening portion (115) and the nozzle (116);
The tipping bucket 120 has a triangular main body 121, a diaphragm 122 formed at the center of the main body 121, and rainwater formed on both left and right sides of the diaphragm 122 to be introduced therein, The first accommodating part 123 and the second accommodating part 124 formed in the curved shape, the support parts 125 and 126 formed on both sides at the center of the main body 121, and the support part 125 ( Rainfall snow gauge, characterized in that it comprises a hinge hole (125a) (125b) formed to be coupled to the rotating shaft (61) on the position 126 above the position of the bottom surface of the main body (121).
The method of claim 1,
Rainfall meter, characterized in that configured to form a space (c) around the water collecting pipe 113 inside the nozzle portion 114 of the collecting cup (110).
The method of claim 1,
Rainfall snow meter, characterized in that the end of the collecting pipe 113 of the collecting cup 110 is located below the air hole 117 of the nozzle unit 114.
The method of claim 1,
Rainfall, characterized in that the bottom surface of the first receiving portion 123 and the second receiving portion 124 of the tipping bucket 120 further comprises a curved extension portion 123a, 124a extending a predetermined length Snow meter.
The method of claim 1,
Rainfall meter, characterized in that the top of the diaphragm 122 of the tipping bucket 120 is further attached to the balance weight 129 having a predetermined weight.

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