CN109143415A - A kind of flood-discharge atomizing rainfall Stereometric device and method - Google Patents
A kind of flood-discharge atomizing rainfall Stereometric device and method Download PDFInfo
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- 238000000034 method Methods 0.000 title abstract description 22
- 238000001556 precipitation Methods 0.000 claims abstract description 19
- 238000012360 testing method Methods 0.000 claims abstract description 11
- 230000008859 change Effects 0.000 claims abstract description 7
- 238000005259 measurement Methods 0.000 claims description 16
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 16
- 238000005192 partition Methods 0.000 claims description 13
- 238000009434 installation Methods 0.000 claims description 12
- 239000011148 porous material Substances 0.000 claims description 10
- 239000003595 mist Substances 0.000 claims description 8
- 238000012545 processing Methods 0.000 claims description 7
- 238000000691 measurement method Methods 0.000 claims description 6
- 238000004458 analytical method Methods 0.000 claims description 5
- 238000012546 transfer Methods 0.000 claims description 5
- 230000002159 abnormal effect Effects 0.000 claims description 3
- 210000001364 upper extremity Anatomy 0.000 claims description 3
- 238000012544 monitoring process Methods 0.000 abstract description 5
- NJPPVKZQTLUDBO-UHFFFAOYSA-N novaluron Chemical compound C1=C(Cl)C(OC(F)(F)C(OC(F)(F)F)F)=CC=C1NC(=O)NC(=O)C1=C(F)C=CC=C1F NJPPVKZQTLUDBO-UHFFFAOYSA-N 0.000 abstract description 4
- 230000008569 process Effects 0.000 abstract description 4
- 241001269238 Data Species 0.000 abstract description 3
- 230000001360 synchronised effect Effects 0.000 abstract description 2
- 230000009466 transformation Effects 0.000 abstract description 2
- 238000000889 atomisation Methods 0.000 description 7
- 238000011160 research Methods 0.000 description 6
- 239000007921 spray Substances 0.000 description 4
- 238000004891 communication Methods 0.000 description 2
- 238000011161 development Methods 0.000 description 2
- 239000000463 material Substances 0.000 description 2
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- 238000004088 simulation Methods 0.000 description 2
- 238000010189 synthetic method Methods 0.000 description 2
- 241000237509 Patinopecten sp. Species 0.000 description 1
- 230000002457 bidirectional effect Effects 0.000 description 1
- 230000015572 biosynthetic process Effects 0.000 description 1
- 238000004364 calculation method Methods 0.000 description 1
- 238000010276 construction Methods 0.000 description 1
- 238000007405 data analysis Methods 0.000 description 1
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- 238000001514 detection method Methods 0.000 description 1
- 238000009792 diffusion process Methods 0.000 description 1
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- 238000005516 engineering process Methods 0.000 description 1
- 238000002474 experimental method Methods 0.000 description 1
- 230000005484 gravity Effects 0.000 description 1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01W—METEOROLOGY
- G01W1/00—Meteorology
- G01W1/14—Rainfall or precipitation gauges
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01W—METEOROLOGY
- G01W2203/00—Real-time site-specific personalized weather information, e.g. nowcasting
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A90/00—Technologies having an indirect contribution to adaptation to climate change
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Abstract
The invention discloses a kind of flood-discharge atomizing rainfall Stereometric device and methods, including rain gage bucket, atmospherium and mounting seat, the rain gage bucket includes rain trap, storage rain chamber, precipitation rain fall sensor, power supply and control module, display screen, rain gage bucket spirit bubble, compass and positioning system;Mounting seat includes support pier, clamp, supporting leg, adjusting knob and pedestal spirit bubble.The present invention collects the rainfall with horizontal plane different angle (0 °~90 °), and a point different direction counts rainfall intensity respectively;When measuring distribution of rainfall intensity, the meteorological datas such as synchro measure wind direction and wind velocity;Using meter formula sensor certainly, available real-time rainfall process;Positioning system is set in instrument, and the location information of observation in real time and positioning rain gage bucket, measuring point transformation overcomes point position to change unpredictable drawback without default observation point.The system real-time monitoring, recording and displaying observed result, test item is synchronous, high degree of automation.
Description
Technical field
The invention belongs to hydraulic and hydroelectric engineering hydraulics tests and measurement technology field, and in particular to a kind of power station flood discharge
Caused atomized rain Stereometric device and method.
Technical background
Flood-discharge atomizing refers to during hydroelectric project discharge structure aerial drainage, generated in the regional area of hinge downstream
Rainfall and spray phenomenon.With the continuous development of world's Dam constructions, large quantities of high dams and superelevation dam are built successively, these high dams
Engineering has the characteristics that high water head, big flow and cajon, mostly uses the flood-discharge energy-dissipating mode for choosing stream, flood-discharge atomizing problem is increasingly
It is prominent, become the new issue that hydroelectric project in recent years is paid special attention to.Flood-discharge atomizing influence forecasting procedure research be currently urgently
Technical problem to be solved.In a large amount of Practical Project, by greatly than ruler flood-discharge atomizing physical experiments, field observation,
The research method of back-to-back testing and numerical simulation studies flood-discharge atomizing coverage and rainfall intensity etc., analyzes it to important
Protection object (such as power plant tail water platform, power station headstock gear, high-tension bus-bar, switchyard, two sides highway, neighbouring village and under
Swim bank slope etc.) influence, and provide safeguard procedures;In fundamental research, majority research is to atomization formation mechenism, flood discharge mist
Change the relationship between intensity and coverage and flood discharge hydraulic parameter, spray fluidised form divides, raininess classification and standard, Wu Yuan decline
Subtract rule etc..Wherein, flood-discharge atomizing test method is one of influence actual engineering design, research precision and depth extremely important
Factor, how accurately, conveniently, timely obtain atomized rain intensity and Distribution Significance it is great.
Atomization form is qualitatively often divided into thick fog area, mist area and mao mao rain belt according to spray fluidised form.Currently, common
Quantitative observation method mainly has: drop-size distribution method and rainfall gauge method.Both methods is a measurement method, presets monitoring site
It sets, the raininess of observation point is measured under the conditions of constant flood discharge, the spatial distribution of atomized rain intensity can be obtained in multimetering, predicts
Flood-discharge atomizing coverage.For two methods, when raininess is smaller, generally measured using drop-size distribution method;When raininess is larger,
Pluviograph or special rain gage bucket is preferably used to measure.Existing pluviograph is chiefly used in hydrology rainfall observation, uses
Tipping bucket principle counts, and converses raininess parameter, and this rainfall gauge is generally tubbiness, suitable for reading to receive vertical rainfall, belongs to one-dimensional
Measurement method is suitable for the lesser natural precipitation measurement of calm or wind.Special rainfall bucket includes unidirectional, two-way and three-dimensional receives rain
The mode of mist, one way system are generally similar to pluviograph, the vertical rainfall of primary recipient;Bidirectional mode is arranged two vertically
The receiving port in direction, one vertical, and a level receives the rainfall of orthogonal both direction, then Vector modulation respectively;Three
Three orthogonal receiving ports are set to mode, one vertical, other two is orthogonal in the horizontal plane, receives orthogonal three respectively
The rainfall in direction, then Vector modulation.Also there is researcher that atomized rain collecting direction associates with wind direction, propose one
Two receiving ports are equally arranged in the rain gage bucket that kind horizontally rotates with wind direction, and one vertical, another alignment comes wind direction.This
Kind of component measurement then synthetic method, seems rationally, but theoretically still then limitation, as that can only receive single direction
Raindrop, although using component synthetic method, investigate it finds that, the acquisition of this rainfall simultaneously be unsatisfactory for vector conjunction
At principle.
In practical applications, atomized rain and spray drift process are the complicated steam two-phases with three-dimensional feature
Flow problem, simulation and forecast are very difficult.Atomized rain phenomenon caused by flood discharge and natural precipitation difference are very big, with Lapping quantity
For atomization, mist source mainly has two, i.e., overflow moves in the sky is formed by atomization and overflow enters water and swash to splash generated mist
Change, under the drive of overflow wind, diffusion and drift around forms regional area rainfall.Therefore, it looks up from side, atomization drop
Rain comes rain direction radially, for being atomized the measuring point of the zone of influence, can occur at random it is vertical, laterally, even have from bottom to
" rainfall " of overhead drift;From raininess, flood-discharge atomizing rainfall intensity is usually much larger than the extra torrential rain raininess of natural precipitation.
And in natural precipitation, under lesser wind friction velocity, predominantly vertical rainfall, under windy conditions, raindrop landing just can be in
Now it is tilted a certain angle.Therefore, the measuring instrument that natural precipitation is observed in conventional hydrometeorology is difficult in atomized rain measurement
It directly uses, even the existing multidirectional measurement method for the measurement special development of flood-discharge atomizing also embodies certain limitation
Property.Answer practical engineering application and scientific research needs, it would be highly desirable to solve the technical problem of existing flood-discharge atomizing rainfall measurement method.
In addition, when measuring flood-discharge atomizing, be generally concerned with local meteorological condition, as wind direction, wind speed, humidity, temperature and
Air pressure etc., the rainfall intensity and distribution of these meteorological conditions and flood-discharge atomizing have close contact.Therefore, in flood discharge mist
While changing measurement, how the meteorological condition of synchro measure locality is to be atomized another problem of researcher's concern.
Summary of the invention
The purpose of the present invention is to propose to it is a kind of can take into account different droplet directions, wide range, length last, automatically record and store
With the atomized rain measuring device of display rainfall and meteorologic parameter change procedure, it is comprehensive to solve flood-discharge atomizing rainfall Multi-directional three-dimensional
The problem of measurement discloses a kind of flood-discharge atomizing rainfall Stereometric device and method.
Technical solution:
A kind of flood-discharge atomizing rainfall Stereometric device, the rain gage bucket including measuring raininess, the rain gage bucket include collection rain
Device, storage rain chamber, precipitation rain fall sensor, power supply and control module;
The rain trap is mounted on the storage rain chamber top, including rain trap bottom plate and several equal radiuses sallop screens, institute
It states partition to be vertically installed on the rain trap bottom plate, the rain trap is divided into several collection rain chambers;The rain trap bottom plate
Corresponding fan-shaped region is separated by the partition, an intercommunicating pore is opened in the center point in each fan-shaped region;
The storage rain chamber be cylinder, the storage rain it is intracavitary equipped with it is corresponding with the partition of the rain trap vertically every
The storage rain chamber is separated into corresponding several storage rain chambers by plate, and the storage rain chamber distinguishes the corresponding collection rain chamber
Room is connected to by the intercommunicating pore;
The rainfall for recording each storage rain chamber depth of water in real time is equipped in the middle part of each storage rain cham-ber floor
Sensor is equipped with power supply and control module in the bottom of chamber Chu Yu portion, and the power supply and control module are the precipitation rain fall sensor
Power supply.
The section of the rain trap bottom plate of the rain trap is that horizontal symmetrical places " V " type structure, outer diameter D1;The sector
Hole is located at " V " the type tip of the rain trap bottom plate;The diameter of the scallop hole is D3, D3/D1=0.1~0.3;The collection rain
Device bottom plate upper and lower surface by outer rim to center the gradient | i |=0.2~1.0.
The storage intracavitary diameter of rain is identical as the diameter of the rain trap bottom plate;The storage rain cavity outer wall is higher by the rain trap
60 ° of outer chamfer processing, effective collective area of the edge the raised area not as rain trap are made in bottom plate 1~2cm of outer edge, top.
The diameter of the bottom of chamber the Chu Yu plate of the storage rain chamber is greater than the storage rain chamber diameter, on the outside of storage rain cavity wall face
Centrosymmetric two rain gage bucket spirit bubbles and two compasses are set on the plate of the bottom of chamber Chu Yu, and the rain gage bucket spirit bubble exists
It levels and uses when installation, the compass determines that installation direction uses during installation.
On the outside of the storage rain chamber be equipped with atmospherium, the atmospherium automatic measurement meteorologic parameter, including wind speed, wind direction,
Temperature, air pressure and humidity, the atmospherium are mounted in upright bar, and the upright bar is fixed on the storage rain chamber bucket wall by collateral support
On.
It is equipped with display screen on the barrel of the storage rain chamber, the display screen is connect with the power supply and control module, institute
Power supply and control module are stated as display screen power supply, and output information to the display screen is shown;The display screen point
It is measured for several sub-regions, rainfall and the atmospherium for showing several storage rain chambers of time, the storage rain chamber
Meteorologic parameter.
Corresponding with eight orientation of the wind direction, eight chambers are arranged in the rain trap, and the atmospherium is initially square
Position is consistent with rain gage bucket placement orientation;The atmospherium measurement wind direction is divided into " east, the southeast, south, southwest, west, northwest, north, east
Eight, north " orientation.
Positioning system is additionally provided in the power supply and control module, the positioning system is being established in coordinate control net,
The spatial coordinated information of the atomized rain Stereometric device is recorded in real time, connects display terminal and is saved and transferred data to
In database.
The rain gage bucket is mounted on observation point position by dedicated mounting seat, and the mounting seat shape is cylinder
Body, top surface recessing, the rain gage bucket nesting is in the groove;The groove upper limb raised support pier, on the support pier
Clamp is set, and the clamp is buckled on the plate of the bottom of chamber Chu Yu;Pedestal spirit bubble is arranged in the mounting seat top levels,
Bottom is hinged with hinged leg, the knob oscilaltion and fixation that the hinged leg passes through adjusting hinged place.
The precipitation rain fall sensor is from note pressure sensor or capacitance water level sensor.
A kind of flood-discharge atomizing rainfall stereoscopic measurement method, comprising steps of
(1) maximum magnitude is influenced according to flood-discharge atomizing and establishes observing and controlling using existing coordinate system or newly-built coordinate system
Coordinate information net in region, and using the accuracy of the built coordinate system of known point verifying;
(2) possible observation point is preselected in flood-discharge atomizing rainfall coverage, to observation point pretreatment, has institute
State the mounting condition of flood-discharge atomizing rainfall Stereometric device;
(3) the flood-discharge atomizing rainfall Stereometric device is installed to observation point, and tests the flood-discharge atomizing
Data acquiring frequency is arranged in the various functions of rainfall Stereometric device, and test data is shown and operating status, is guaranteeing instrument just
Often operation;
(4) recording practical flood discharge time started, end time, orientation label and coordinate position data, centre has flood discharge item
Part variation records the corresponding operating time in time;And flood-discharge atomizing rainfall Stereometric device described in remote reviewing, judge its operation
State, if any abnormal record correlation time in time;
(5) if the flood-discharge atomizing rainfall Stereometric device needs to measure multiple positions, after previous measuring point measurement
Carry out station transfer;After recording timing node, it is inverted in the storage rain chamber for emptying the flood-discharge atomizing rainfall Stereometric device and collects
Rainwater, and be installed to next website, installation steps are the same as (2), (3), (4);
(6) it after flood discharge, takes out the flood-discharge atomizing rainfall Stereometric device and exports acquisition data, in conjunction with measurement
When relative recording carry out data processing and analysis, defined herein comprehensive average rainfall intensity are as follows:
I=∑ R/Sh;
Wherein, ShFor the surface area for the outer profile that the partition is formed, R is each storage rain chamber rainfall, R=Sb×
H, SbFor each storage rain chamber bottom surface net area, h is the depth of water h of each storage rain chamber.
The utility model has the advantages that
A kind of flood-discharge atomizing rainfall Stereometric device proposed by the present invention and method have the advantages that
(1) present invention collects the rainfall with horizontal plane different angle, including from vertically to the rainfall of horizontal direction, i.e. rainfall
The angle of direction and horizontal plane is from 0 degree to 90 degree, available comprehensive rainfall intensity, rather than individually some directions (it is horizontal or
Component vertically).
(2) the multiple and different orientation of the present invention point count rainfall intensity respectively, and available rainfall intensity is in different direction
Partition density.
(3) present invention when measure distribution of rainfall intensity, the meteorological datas such as synchro measure wind direction and wind velocity, synchronous rainfall data and
The meteorological datas such as wind direction and wind velocity are in close relations, to meteorological conditions and atomized rain intensity such as analysis flood discharge hydraulics, overflow wind
And its response relation between distribution is of great significance.
(4) present invention remembers in real time using from meter formula sensor, available real-time rainfall process and changing rule
Record, display and storage different direction rainfall data, high degree of automation, data information is more abundant, rather than just average rain
Strong result.
(5) positioning system is set in instrument, the location information of observation in real time and positioning apparatus of the present invention, measuring point transformation is not necessarily to
Observation point coordinate is obtained in advance, overcomes the drawbacks of can not accurately estimating misty rain range (i.e. arrangement measuring point range and position);It is another
Aspect can judge whether apparatus occurs using high-accuracy position system with the operating status of Real-time Feedback apparatus of the present invention
Topple over or is displaced.
Detailed description of the invention
Fig. 1 is the front view of flood-discharge atomizing rainfall Stereometric device proposed by the present invention.
Fig. 2 is the top view of flood-discharge atomizing rainfall Stereometric device proposed by the present invention.
Fig. 3 is the dedicated mounting seat front view of flood-discharge atomizing rainfall Stereometric device proposed by the present invention.
Fig. 4 is the dedicated mounting seat top view of flood-discharge atomizing rainfall Stereometric device proposed by the present invention.
In figure, 1- rain trap, 2- partition, 3- rain trap bottom plate, 4- intercommunicating pore, 5- store up rain chamber, 6- barrels of walls, the bottom of chamber 7- Chu Yu
Plate, 8- precipitation rain fall sensor, 9- power supply and control module, 10- bottom cover, 11- display screen, 12- rain gage bucket spirit bubble, 13- compass,
14- atmospherium, 15- upright bar, the collateral support of 16-, 17- positioning system;18- rain gage bucket;19- mounting seat;20- support pier;21- card
Head;22- supporting leg;23- adjusting knob;24- pedestal spirit bubble.
Specific embodiment
The present invention will be further explained with reference to the accompanying drawing.
The rain gage bucket and atmospherium that Fig. 1 and Fig. 2 is respectively flood-discharge atomizing rainfall Stereometric device proposed by the present invention are just
View and top view, Fig. 3 and Fig. 4 are respectively mounting seat front view and top view.As shown, flood discharge mist proposed by the present invention
Changing rainfall Stereometric device includes rain gage bucket 18, atmospherium 14 and mounting seat 19.The rain gage bucket 18 include rain trap 1,
Rain trap bottom plate 3, storage rain chamber 5, precipitation rain fall sensor 8, power supply and control module 9, display screen 11, rain gage bucket spirit bubble 12, guide
Needle 13 and positioning system 17;The mounting seat 19 includes support pier 20, clamp 21, supporting leg 22, adjusting knob 23 and pedestal water
Flat bubble 24.
The rain trap 1 is mounted on 5 top of storage rain chamber, and the rain trap 1 is the entrance for collecting rain, including rain trap bottom
Plate 3 and several equal radiuses sallop screens 2, the partition 2 are vertically installed on the rain trap bottom plate 3, the rain trap 1 are divided
At several collection rain chambers, the partition 2 forms a hemispherical outer profile, and the surface area of the outer profile is Sh;The collection
Rain device 1 can receive the rainfall of eight different directions different angles, including vertical rainfall (90 °) and horizontal (0 °) rainfall and Jie
In rainfall at any angle between the two;Eight collection rain chambers respectively correspond eight orientation, including " east-southeast-south-southwest-
West-northwest-north-northeast " (as shown in Figure 2);The diameter D of the rain trap 11For 20cm, with a thickness of 2mm;The rain trap 1
Rain trap bottom plate 3 is divided into eight pieces of fan-shaped panels by rain trap partition, and fan-shaped connection is opened by the center point in the fan-shaped panel
Hole 4, the 4 diameter D of intercommunicating pore3=4cm;In order to which the rainwater of the collection of rain trap 1 when on the one hand making positive place can flow into certainly
Enter the storage rain chamber 5 of lower section, the rainwater of storage rain chamber 5 can be from flowing out when being on the other hand inverted, and the rain trap bottom plate 3 is set as horizontal
" V " the type structure placed, the top and bottom gradient are symmetrical arranged.In the present invention, D3/D1=0.1~0.3, the rain trap bottom plate 3
The gradient | i | take 0.2~0.5;Further, 3 gradient absolute value of rain trap bottom plate takes in the present embodiment | i |=0.3.
In the present invention, 1 material therefor of rain trap is hydrophobic material, and the rain trap is hit or condensed in misty rain down
It slides on 1 chamber face plate and under the effect of gravity to the bottom plate of the rain trap 1, the bottom plate then through the rain trap 1 passes through
The storage rain chamber 5 of the sector intercommunicating pore 4 from inflow 1 lower section of rain trap.
For the storage rain chamber 5 using cylindrical ladle body, ladle body diameter is identical as 1 diameter of rain trap, is D1, the present embodiment
Take D1=20cm, 5 top of storage rain chamber are connected with the rain trap bottom plate 3;Accordingly, eight are equipped in the storage rain chamber 5
The storage rain chamber 5 is also divided into eight pieces of fans corresponding with the collection rain chamber by block vertical baffle, perforation to the bottom of chamber Chu Yu plate 7
Shape region, referred to as storage rain chamber.5 internal diameter of storage rain chamber also takes D1, the block board thickness is 2mm;Eight storage rain chambers
Room is connected to eight collection rain chambers of the rain trap 1 by the intercommunicating pore 4 respectively, each storage rain chamber bottom surface
Net area is denoted as Sb, each storage rain chamber rainfall calculation formula is R=Sb× h, h are the depth of water h of each storage rain chamber;
The ladle body height of the storage rain chamber 5 is set as 60cm in the present embodiment, if raininess is excessive, customized can increase the storage rain chamber
5 ladle body height can also be fabricated to the storage rain chamber 5 of variable height to meet the requirements.
Further, in order to further ensure the rain trap 1 rainfall that respectively collection rain chamber is collected is not outflowed, the storage rain
Cavity outer wall is higher by the rain trap bottom plate 1~2cm of outer edge, and 60 ° of outer chamfer processing are made at top, and edge the raised area is not as collection
Effective collective area of rain device.
The precipitation rain fall sensor 8 is from note pressure sensor in the present embodiment, and range is set as 0~1m water column, pacifies respectively
In the middle part of the bottom plate of eight storage rain chambers loaded on the storage rain chamber 5, the real-time depth of water h of each chamber can recorde.The power supply
And control module 9 is precipitation rain fall sensor power supply, and controls, shows and store acquired data.In the power supply and control
Wireless communication module is additionally provided in module 9, the wireless communication module is connect with detection service device, and atomization of the invention is dropped
Rainfall data in all directions, weather information measured by rain Stereometric device, location information are sent to the monitoring service on backstage
On device, to realize each orientation rainfall data of real-time remote monitoring observation point, and is recorded, shown and stored in real time.
The bottom of chamber the Chu Yu plate 7 of the storage rain chamber 5 protrudes 5 outside of storage rain chamber, and plate 7 diameter in the bottom of chamber Chu Yu is D2,
Centrosymmetric four orientation are respectively set there are two rain gage bucket spirit bubble 12 and two compasses on the bottom of chamber Chu Yu plate 7
13, respectively to install when instrument leveling and direction determine use.
For meteorologic parameters conditions such as synchro measure meteorology wind speed, wind direction, humidity, temperature and air pressures, on the outside of rain gage bucket
It is provided with atmospherium 14, the atmospherium 14 is mounted in upright bar 15, and the upright bar 15 is fixed on the storage by collateral support 16
It on rain chamber 5, and is connect with the power supply and control module 9, the power supply and control module 9 are the atmospherium 14 power supply, can
To measure the indexs such as wind direction, wind speed, humidity, temperature and air pressure while measuring rainfall intensity, records, stores in real time and pass through
Display screen 11 shows meteorologic parameter index, and (the present embodiment display screen subregion: I- wind speed and direction, display screen subregion J- are wet
Degree, temperature and air pressure).The mounting height of the atmospherium 14 is H2。
The display screen 11 is connected on the barrel 6 of the storage rain chamber 5 by circuit and the power supply and control module 9
Logical, the display screen 11 divides for ten sub-regions, the respectively region A, B, C, D, E, F, G, H, I, J, wherein eight A-B-C-D-
The region E-F-G-H independently shows rainfall (the corresponding orientation: the northeast A-, the east B, C- of eight storage rain chambers of the storage rain chamber
The southeast, the south D-, the southwest E-, the west F-, the northwest G-, the north H-), in addition the region I, J shows meteorologic parameter.
The power supply and control module 9 are located at 5 bottommost of storage rain chamber, respectively with the precipitation rain fall sensor 8 and described
Display screen 11 is connected to, and is powered for the precipitation rain fall sensor 8 and the display screen 11;The power supply and control module 9 also have
The function of control, acquisition, storage and real-time display measurement result, circuit are set in the barrel 6 of the storage rain chamber 5, this region
To seal anti-pool, bottom cover 10 is installed in 5 bottom of storage rain chamber, bottom cover 10 can be opened, this instrument testing and peace are used for
It is used when dress.
The positioning system 17 is set in power supply described in rain gage bucket bottom and control module 9, is establishing coordinate control net
It is interior, can be with its spatial coordinated information of Real-time Feedback, while atomized rain Stereometric device of the present invention is recorded and fed back in real time
Operating status, judges whether it topples over or be displaced;The positioning system 17 connects display terminal and saves and transmit data
To database.
In the present invention, the precipitation rain fall sensor 8 can also use capacitance water level sensor, principle and wave-height gauge class
Seemingly, resistance wire is set in each chamber of the storage rain chamber, and both ends are individually fixed in the bottom plate and top plate of storage rain chamber, vertical to draw
Tight to place, circuit loop is set to a barrel wall, is powered and is controlled by the power supply and control module.And wireless receiving mould can be used
Formula, remote collection rainfall data.
The rain gage bucket 18 is mounted on observation point position by mounting seat 19, and 19 shape of mounting seat is cylinder
Body, top surface recessing, the rain gage bucket 18 are nested in the groove;In the groove upper limb raised support pier 20, the branch
It supports and clamp 21 is set on pier 20, the clamp 21 can be buckled on the bottom of chamber Chu Yu plate 7, can be automatically locked described in fixing
The bottom of chamber Chu Yu plate 7, to fixed rain gage bucket 18;19 top levels of mounting seat are provided with pedestal spirit bubble 24, bottom
It is hinged with hinged leg 22, the hinged leg 22 can pass through the knob oscilaltion and fixation of adjusting hinged place.
Specifically used method or step are as follows:
(1) establish observing and controlling area coordinate Information Network: estimation flood-discharge atomizing influences maximum magnitude, utilizes existing coordinate system
Or newly-built coordinate system, the coordinate information net in observing and controlling region is established, and the accurate of built coordinate system is verified using known point
Property, in the case where meeting required precision, positioning system is set, can show and record the sky of atomized rain Stereometric device of the present invention
Between location coordinate information.
(2) setting observation base platform: pre-selection observation point preselects possible sight in flood-discharge atomizing rainfall coverage
Measuring point position pre-processes and installs base used specially to observation point, levels and fix dedicated mounting seat, has present invention atomization drop
The mounting condition of rain Stereometric device.
(3) installation test: pacify before the rain gage bucket of atomized rain Stereometric device of the invention is installed to base used specially
Power supply is filled, and tests the functions such as display, record and control, is installed to base used specially after function is normal;Specific installation method are as follows: first
First rain gage bucket is placed on base used specially, rain gage bucket horizontal bubble is checked, is leveled if unhorizontal;Secondly referred to according to compass
To true bearing is determined, due north position is found out, the leeward placement of rain gage bucket display screen is found out in the orientation A-H most at this time convenient for observation
Close to the label of direct north, and the storage rain chamber face direct north that rain gage bucket direction makes this label is finely tuned, writes down this volume
Number be direct north;Rain gage bucket is fixed again, initializes the orientation of atmospherium, so that atmospherium initial wind azimuth at this time
It is consistent with true bearing, and is tested with rain gage bucket orientation;Last instrument shows, records debugging, and setting data acquire
Frequency, test data is shown and operating status, guarantees that instrument operates normally.
(4) it measures and records: record practical flood discharge time started, end time, orientation label and coordinate position data, in
Between have flood discharge condition variation in time record the corresponding operating time;Monitoring feedback data in time, and this hair is observed using telescope etc.
Bright flood-discharge atomizing rainfall Stereometric device, judges its operating status, if any abnormal record correlation time in time, is convenient for data
Analysis and explanation.
(5) station transfer (when multimetering): previous if atomized rain Stereometric device of the present invention needs to measure multiple positions
Measuring point needs station transfer after measuring.After recording timing node, it is inverted the rainwater for emptying and collecting in storage rain chamber;And it installs in time
To next website, installation steps are the same as (2), (3), (4).Under the conditions of having positioning system, installation measuring point does not need to preset.
(6) it data export and processing analysis: after flood discharge, takes out atomized rain Stereometric device of the present invention and exports
Data are acquired, relative recording carries out data processing and analysis, defined herein comprehensive average rainfall intensity are as follows: I=∑ R/ when in conjunction with measurement
Sh。
The above is only a preferred embodiment of the present invention, it should be pointed out that: for the ordinary skill people of the art
For member, various improvements and modifications may be made without departing from the principle of the present invention, these improvements and modifications are also answered
It is considered as protection scope of the present invention.
Claims (11)
1. a kind of flood-discharge atomizing rainfall Stereometric device, it is characterised in that: the rain gage bucket (18) including measuring raininess, the rain
Graduated cylinder (18) includes rain trap (1), storage rain chamber (5), precipitation rain fall sensor (8), power supply and control module (9);
The rain trap (1) is mounted on above the storage rain chamber (5), including rain trap bottom plate (3) and several grade radiuses sectors every
Plate (2), the partition (2) are vertically installed on the rain trap bottom plate (3), and the rain trap (1) is divided into several collection rain chambers
Room;The rain trap bottom plate (3) is separated into corresponding fan-shaped region by the partition (2), and center of circle end is being leaned in each fan-shaped region
Open an intercommunicating pore (4);
The storage rain chamber (5) is cylinder, is equipped in storage rain chamber (5) corresponding with partition (2) of the rain trap (1)
Vertical baffle, storage rain chamber (5) is separated into several storage rain chambers corresponding with the collection rain chamber of the rain trap (1),
The storage rain chamber is distinguished the corresponding collection rain chamber and is connected to by the intercommunicating pore (4);
The precipitation rain fall sensor for recording each storage rain chamber depth of water in real time is equipped on each storage rain cham-ber floor
(8), it is equipped with power supply and control module (9) in the storage rain chamber (5) bottom, the power supply and control module (9) are the rainfall
Sensor (8) power supply.
2. flood-discharge atomizing rainfall Stereometric device according to claim 1, it is characterised in that: the rain trap (1)
The radial section of rain trap bottom plate (3) is that horizontal symmetrical places " V " type structure, outer diameter D1;The intercommunicating pore (4) is located at described
" V " the type tip of rain trap bottom plate (3);The diameter of the intercommunicating pore (4) is D3, D3/D1=0.1~0.3;The rain trap bottom
Plate (3) upper and lower surface by outer rim to center the gradient | i |=0.2~1.0.
3. flood-discharge atomizing rainfall Stereometric device according to claim 1, it is characterised in that: in the storage rain chamber (5)
Diameter is identical as the diameter of the rain trap bottom plate (3);Storage rain chamber (5) outer wall is higher by rain trap bottom plate (3) outer edge 1
60 ° of outer chamfer processing are made at~2cm, top.
4. flood-discharge atomizing rainfall Stereometric device according to claim 1, it is characterised in that: storage rain chamber (5)
The diameter of the bottom of chamber Chu Yu plate (7) is greater than storage rain chamber (5) diameter, in the storage of described storage rain chamber (5) wall surface exterior portion
Centrosymmetric two rain gage bucket spirit bubbles (12) and two compasses (13), the rain gage bucket water are set on rain bottom of chamber plate (7)
Leveling uses flat bubble (12) during installation, and the compass (13) determines that installation direction uses during installation.
5. flood-discharge atomizing rainfall Stereometric device according to claim 1, it is characterised in that: in the storage rain chamber (5)
Outside is equipped with atmospherium (14), and the atmospherium (14) is mounted on upright bar (15), and the upright bar (15) passes through collateral support (16)
It is fixed on the bucket wall (6) of storage rain chamber (5).
6. flood-discharge atomizing rainfall Stereometric device according to claim 5, it is characterised in that: in the storage rain chamber (5)
Barrel (6) be equipped with display screen (11), the display screen (11) connect with the power supply and control module (9), the power supply
It is the display screen (11) power supply with control module (9), and output information to the display screen (11) are shown;The display screen
(11) it is divided into several sub-regions, the rainfall and the atmospherium of several storage rain chambers for showing time, the storage rain chamber
(14) meteorologic parameter measured.
7. flood-discharge atomizing rainfall Stereometric device according to claim 6, it is characterised in that: in the meteorologic parameter
Eight orientation of wind direction are corresponding, and eight chambers, and the atmospherium (14) initial orientation and rainfall is arranged in the rain trap (1)
It is consistent that cylinder places orientation;Atmospherium (14) the measurement wind direction is divided into " east, the southeast, south, southwest, west, northwest, north, northeast " eight
A orientation.
8. flood-discharge atomizing rainfall Stereometric device according to claim 1, it is characterised in that: in the power supply and control
It is additionally provided with positioning system (17) in module (9), the positioning system (17) is being established in coordinate control net, records the mist in real time
Change the spatial coordinated information of rainfall Stereometric device, connect display terminal and saves and transfer data in database.
9. flood-discharge atomizing rainfall Stereometric device according to claim 1, it is characterised in that: the rain gage bucket (18) is logical
It crosses mounting seat (19) to be mounted on observation point position, mounting seat (19) shape is cylindrical body, and top surface recessing is described
Rain gage bucket (18) bottom nesting is in the groove;The groove upper limb raised support pier (20) sets on the support pier (20)
It sets clamp (21), the clamp (21) is buckled on the bottom of chamber Chu Yu plate (7);Mounting seat (19) top levels are set
Bottom set seat spirit bubble (24), bottom are hinged with hinged leg (22), above and below knob of the hinged leg (22) by adjusting hinged place
It goes up and down and fixed.
10. flood-discharge atomizing rainfall Stereometric device according to claim 1, it is characterised in that: the precipitation rain fall sensor
It (8) is note pressure sensor or capacitance water level sensor certainly.
11. a kind of flood-discharge atomizing rainfall using any flood-discharge atomizing rainfall Stereometric device of claim 1~10
Stereoscopic measurement method, it is characterised in that: comprising steps of
(1) maximum magnitude is influenced according to flood-discharge atomizing and establishes observing and controlling region using existing coordinate system or newly-built coordinate system
Interior coordinate information net, and using the accuracy of the built coordinate system of known point verifying;
(2) possible observation point is preselected in flood-discharge atomizing rainfall coverage, to observation point pretreatment, has described let out
The mounting condition of big vast atomized rain Stereometric device;
(3) the flood-discharge atomizing rainfall Stereometric device is installed to observation point, and tests the flood-discharge atomizing rainfall
Data acquiring frequency is arranged in the various functions of Stereometric device, and test data is shown and operating status, guarantees that instrument is normally transported
Row;
(4) practical flood discharge time started, end time, orientation label and coordinate position data are recorded, there is the change of flood discharge condition in centre
Change the record corresponding operating time in time;And flood-discharge atomizing rainfall Stereometric device described in remote reviewing, judge its operating status,
If any abnormal record correlation time in time;
(5) it if the flood-discharge atomizing rainfall Stereometric device needs to measure multiple positions, is carried out after previous measuring point measurement
Station transfer;After recording timing node, it is inverted the rain collected in the storage rain chamber for empty the flood-discharge atomizing rainfall Stereometric device
Water, and it is installed to next website, installation steps are the same as (2), (3), (4);
(6) it after flood discharge, takes out the flood-discharge atomizing rainfall Stereometric device and exports acquisition data, in conjunction with measurement phase
It closes record and carries out data processing and analysis, defined herein comprehensive average rainfall intensity are as follows:
I=∑ R/Sh;
Wherein, ShFor the surface area for the outer profile that the partition is formed, R is each storage rain chamber rainfall, R=Sb× h, Sb
For each storage rain chamber bottom surface net area, h is the depth of water h of each storage rain chamber.
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