CN102435230A - Slope plot runoff flow measurement system of triangular weir - Google Patents
Slope plot runoff flow measurement system of triangular weir Download PDFInfo
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- CN102435230A CN102435230A CN2011102497975A CN201110249797A CN102435230A CN 102435230 A CN102435230 A CN 102435230A CN 2011102497975 A CN2011102497975 A CN 2011102497975A CN 201110249797 A CN201110249797 A CN 201110249797A CN 102435230 A CN102435230 A CN 102435230A
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Abstract
The invention discloses a slope plot runoff flow measurement system of triangular weir and belongs to the technical field of soil and water conservation. The system comprises a box body, a float gauge and a data collector connected with the float gauge, wherein the box body comprises a water inlet connected with the box body, and a triangular water outlet formed on the side wall of the box body; the float gauge is used for measuring the water level of the box body; and the data collector is used for reading and recording the value of the water level of the float gauge, and then measuring the flow of fluid flowing through the system. The slope plot runoff flow measurement system can be used for achieving automatic water level measurement and recording through the float gauge and data collector, and the data collector can be used for rapidly measuring the flow of fluid flowing through the system according to the measured value of the water level.
Description
Technical field
The present invention relates to the conservation technology field, the domatic sub-district of particularly a kind of triangular-notch weir runoff rate measuring system.
Background technology
Sub-district runoff rate measurement is the important content of quantitative examination soil erosion in the water and soil conservation test, in scientific research such as soil erosion qualitative assessment, soil and water conservation benefit evaluation and production practices, all has vital role.The sub-district runoff rate is measured for raising monitoring accuracy and monitoring reliability, the labour intensity that alleviates monitoring and reduction monitoring cost etc. automatically has remarkable meaning.
Receive the restriction of the singularity and the complicacy of field condition environment, water collecting basin method and porous shunting are generally adopted in runoff rate observation in domestic and international domatic sub-district.All there are certain problem in actual use in water collecting basin and part flow arrangement.What water collecting basin and porous shunting were realized is total discharge observation, can not obtain rainfall and produce husky process data.In addition, the design of water collecting basin and part flow arrangement can not be considered all rainfall situation, when heavy rain takes place, is easy to generate overflow, causes the data disappearance.
The runoff process is protected the measure actual benefit for research soil erosion mechanism with evaluation water and is had vital role, and automatic observation has also proposed corresponding requirement to runoff with administrative skill in the modern data transmission.To this, relevant scholar both domestic and external does excessive quantity research to the runoff automatic observation device.Wherein, The tipping bucket method is one of extensive principle that adopts of automatic flow meter; Promptly utilize mechanical measurement element (symmetrical tipping bucket chamber) continuously to be divided into the volume part of single equivalent to fluid, repeatedly be full of one by one and the number of times that discharges is measured fluid volume total amount and process according to measuring chamber.This method receives The Effect of Inertia Force and has nonlinearity erron in practical application.In addition, do not consider and estimation for the role and influence of silt carrying flow.People such as domestic expert Zhao Jun have developed a kind of flow automatic observation device to silt carrying flow; Its cardinal principle is the weight through the flow tube of the flexible link of pulling force sensor induction; Hydraulic model through having the mechanical analysis basis is calculated flow, and according to the influence of sediment charge convection cell weight the flow measurement result is proofreaied and correct.This method has certain application in reality, but the measurement range of existing design and model is limited, uses widely to be still waiting further theoretical expansion and experimental verification.
Triangular-notch weir is to use more a kind ofly during traditional weir flow is measured, and it is low to have a design and construction cost, the characteristics that measurement range is bigger.Traditional triangular-notch weir is through measuring the water level of sluice stream, according to predetermined computing formula calculated flow rate.Most of measurements needs artificial the survey to record water level, hand computation flow again.Grow measuring period, influenced by gauger's subjectivity, precision and reliability receive certain limitation, and simultaneously, time-consuming causing of operating process is difficult to measure enough data points to obtain approximately continuous runoff yield process.Utilize triangular-notch weir to measure flow fast, in real time, exactly and can solve the major issue in production practices and scientific research field, and can the important techniques support be provided for the robotization renewal of water and soil conservation monitoring system.
Summary of the invention
The technical matters that (one) will solve
The technical matters that the present invention will solve is: how a kind of domatic sub-district of the triangular-notch weir runoff rate measuring system that can measure and write down water level automatically is provided.
(2) technical scheme
For solving the problems of the technologies described above; The present invention provides the domatic sub-district of a kind of triangular-notch weir runoff rate measuring system; Said system comprises casing 100, and said casing 100 comprises connected water inlet 101, and said casing 100 also comprises the triangle water delivering orifice 102 that is arranged on its sidewall;
Said system also comprises: interconnected float gauge 200 and data acquisition unit 300;
Said float gauge 200 is used to measure the water level in the said casing 100;
Said data acquisition unit 300 is used to read and write down the water level value of said float gauge 200, and according to the fluid flow of this water level value calculated flow through said system.
Preferably, said float gauge 200 comprises pulley 201, float 202 and vertical 203;
The disk of said pulley 201 is fixedly connected with said casing 100, and the minimum point of said disk is higher than the sidewall upper edge of said casing 100;
The two ends of the rope of said pulley 201 connect said float 202 and vertical 203 respectively.
Preferably, said float gauge 200 also comprises housing 204; Said housing 204 is fixedly connected with said casing 100, and the bottom of said housing 204 and 100 conductings of said casing; Said pulley 201, float 202 and vertical 203 all are arranged on the inside of said housing 204.
Preferably, said float gauge 200 is connected with said data acquisition unit 300 through data line.
Preferably, the triangle drift angle of said triangle water delivering orifice 102 down, and drift angle is 30 °.
Preferably, the distance from bottom of the said casing 100 of the perigee distance of said triangle water delivering orifice 102 is 1.6cm.
Preferably, said casing 100 is the hollow rectangular parallelepiped of upper shed, and its length and width height is of a size of 30 centimetres of 50 cm x, 50 cm x.
(3) beneficial effect
The domatic sub-district of triangular-notch weir according to the invention runoff rate measuring system; Through float gauge and data acquisition unit are set; Realized automatic measurement and record, and data acquisition unit can calculate the fluid flow of the system of flowing through fast according to the survey water level value to water level.
Description of drawings
Fig. 1 is the partial structurtes synoptic diagram of the domatic sub-district of the described triangular-notch weir of embodiment of the invention runoff rate measuring system;
Fig. 2 is the vertical view of the domatic sub-district of the described triangular-notch weir of embodiment of the invention runoff rate measuring system;
Fig. 3 is the result curve figure of regretional analysis.
Embodiment
Below in conjunction with accompanying drawing and embodiment, specific embodiments of the invention describes in further detail.Following examples are used to explain the present invention, but are not used for limiting scope of the present invention.
Fig. 1 is the partial structurtes synoptic diagram of the domatic sub-district of the described triangular-notch weir of embodiment of the invention runoff rate measuring system; Fig. 2 is the vertical view of the domatic sub-district of the described triangular-notch weir of embodiment of the invention runoff rate measuring system.Like Fig. 1, shown in 2, said system comprises casing 100, float gauge 200 and data acquisition unit 300.
Said casing 100 is the hollow rectangular parallelepiped of open upper end, and its length and width height is of a size of 30 centimetres of 50 cm x, 50 cm x.This casing 100 comprises water inlet 101 and water delivering orifice 102.Said water inlet 101 is fixedly connected with the right side wall of said casing 100, and it is communicated with sub-district runoff inlet through outside mozzle or diversion trench, is used for water is introduced said casing 100.Said water delivering orifice 102 is arranged on the left side wall of said casing 100, said water delivering orifice 102 be shaped as drift angle isosceles triangle down, drift angle is 30 °, and the distance from bottom of the said casing 100 of the perigee distance of said water delivering orifice 102 is 1.6m.
Said float gauge 200 comprises pulley 201, float 202, vertical 203 and housing 204.
The left side shrouding of said housing 204 is connected with the front side wall of said casing 100; The back side seal board of said housing 204 is connected with the right side wall of said casing 100; The right side shrouding of said housing 204 is connected with the right side wall upper edge of said casing 100, and the upper sealing plate of said housing 204 connects said left side shrouding, back side seal board and right side shrouding.The bottom of the left side shrouding of said housing 204 is provided with opening, said casing 100 of conducting and housing 204, and the water level of said like this casing 100 and housing 204 maintains an equal level all the time.Housing 204 has weakened the image of casing 100 interior current fluctuations to level measuring simultaneously, has improved measuring accuracy.
The disk of said pulley 201 is fixedly connected with the right side wall of said casing 100 through said housing 204; And the minimum point of said disk is higher than the sidewall upper edge of said casing 100; To guarantee that float gauge 200 still can accurately be measured the water level in the casing 100 under the fair situation of the sidewall of water level and said casing 100.
The two ends of the rope of said pulley 201 connect said float 202 and vertical 203 respectively, and when injecting water said casing 100 in, said float 202 goes up and down along with fluctuation in stage, with the said casing 100 interior water level values of real-time measurement.
Said data acquisition unit 300 connects said pulley 201 through data line, is used to read and writes down said water level value, and calculate the current value of the said casing 100 of flowing through according to said water level value.
Recommend according to " weir notch flow measurement standard ", when crest of weir angle (being the drift angle of triangle water delivering orifice) between π/9-5 π/9 (20 °-100 °) time, the formula that was calculated the weir flow amount by the water level of standard triangular-notch weir is:
Wherein, Q was the weir flow amount, and unit is cubic metre/hour; C
DBe coefficient of flow; h
eBe effective water level, unit is a rice; h
e=h+K
h, K
hFor considering the corrected value of viscous force and surface tension combined influence, unit is a rice, and h is a rice for actual measurement head (being the distance of water surface distance water delivering orifice 102 minimum points), unit; θ is crest of weir angle π/6 (promptly 30 °),
Expression
The tan value; G is an acceleration of gravity, 9.82 meter per seconds
2
For the standard triangular-notch weir, " weir notch flow measurement standard " provides chart, can query flows coefficient C
DWith water level compensation coefficient K
hThe said system of the embodiment of the invention does not adopt the unified standard of weir notch design, but specifically designs with automatic scope installation requirement according to the flow measurement condition of sub-district runoff.Therefore, flow coefficient C
DAnd h
eThe power value must confirm through calibration experiment.According to " weir notch flow measurement standard ", when crest of weir angle (being the drift angle of triangle water delivering orifice 102) when being 30 °, water level compensation coefficient K
hValue 2.3 * 10
-6About rice, the water level difference of this and actual observation is bigger, in the discharge model of this system, can ignore.Therefore, it is following to set up the relation formula model of flow Q and water level h:
Q=bh
a (2)
A wherein, b is a constant coefficient.
In order to demarcate the said system of the embodiment of the invention, promptly confirm the relation of flow Q and water level h, seminar has carried out one group of flume experiment in China Agricultural University's fluid mechanics laboratory design.Experimental trough is equipped with the standard volume mill weir; The tank end of this standard volume mill weir imports current through simple and easy guiding device the water inlet 101 of the said system of the embodiment of the invention; With the ascending variation of flow, read the water level of casing 100 inside through the data acquisition unit 300 that is connected with float gauge 200 during test.Simultaneously, measure actual flow through said standard volume mill weir, as flow reference value.
According to the result of flume experiment, the water level h that flow Q that the standard volume mill weir is observed and systematic observation of the present invention are read brings formula (2) into, carries out regretional analysis, and the value that obtains constant coefficient a is 1.9, and the value of constant coefficient b is 0.002.Therefore calibrated formula (2) is as follows:
Q=0.002h
1.9 (2)
Fig. 3 is the result curve figure of regretional analysis; As shown in Figure 3; The up-and-down boundary (two dotted lines among Fig. 3) of 95% fiducial interval can be found out from figure: the water level of system of the present invention (promptly surveying head) presents extraordinary correlationship with flow, and relevant definite coefficient is 0.98.It can also be seen that from Fig. 3: most of observation station is in 95% fiducial interval, and particularly when flow during less than 5 cubic metres/hour, the scope of fiducial interval is very little; When flow during greater than 5 cubic metres/hour, the uncertainty of model increases with flow.This is because in the discharge model derivation, supposes that the water level compensation coefficient is 0, has promptly ignored velocity of approach.Therefore, at flow hour, flow rate of water flow is less, and the error that model hypothesis causes is less; After flow velocity is along with flow increase and increase, ignore the water level error increase that velocity of approach causes.But in general, the flow simplified model all just has stable predicting the outcome at 10 cubic metres/hour with interior.What extensively adopt in the world at present all is 20 meters * 5 meters standard sub-district runoff, under 100 millimeters/hour raininess condition, does not consider that vegetation is held back and soil infiltration, and the peak runoff that can produce is that 2400 milliliters/second are 8.64 cubic metres/hour.Therefore, the said system of this inventive embodiments fully can be used for calculated flow rate when runoff plots is used in the open air, and its precision can satisfy engineering request.
Also there is reliable and stable observed result in the said system of this inventive embodiments to the flow above 8.64 cubic metres/hour.The flow that we plan to measure expands 15 cubic metres/hour to, is equivalent to the runoff yield of 200 millimeters/hour clean rainfalls in standard sub-district.To bigger non-standard runoff plots or the bigger area of storm intensity, can adopt this recording geometry equally, just when the sub-district area was bigger, the size of system was bigger possibly.Need other calibrational capacity model simultaneously or the said discharge model of formula (2) is done certain correction.
The domatic sub-district of the said triangular-notch weir of embodiment of the invention runoff rate measuring system; Through float gauge and data acquisition unit are set; Automatic measurement and record have been realized to water level; And data acquisition unit can calculate the fluid flow of the system of flowing through fast according to the survey water level value, thereby upgrade for the robotization of water and soil conservation monitoring system the important techniques support is provided.
Above embodiment only is used to explain the present invention; And be not limitation of the present invention; The those of ordinary skill in relevant technologies field under the situation that does not break away from the spirit and scope of the present invention, can also be made various variations and modification; Therefore all technical schemes that are equal to also belong to category of the present invention, and scope of patent protection of the present invention should be defined by the claims.
Claims (7)
1. the domatic sub-district of triangular-notch weir runoff rate measuring system, said system comprises casing (100), and said casing (100) comprises connected water inlet (101), and said casing (100) also comprises the triangle water delivering orifice (102) that is arranged on its sidewall;
It is characterized in that said system also comprises: interconnected float gauge (200) and data acquisition unit (300);
Said float gauge (200) is used to measure the water level in the said casing (100);
Said data acquisition unit (300) is used to read and write down the water level value of said float gauge (200), and according to the fluid flow of this water level value calculated flow through said system.
2. the system of claim 1 is characterized in that, said float gauge (200) comprises pulley (201), float (202) and vertical (203);
The disk of said pulley (201) is fixedly connected with said casing (100), and the minimum point of said disk is higher than the sidewall upper edge of said casing (100);
The two ends of the rope of said pulley (201) connect said float (202) and vertical (203) respectively.
3. system as claimed in claim 2 is characterized in that, said float gauge (200) also comprises housing (204); Said housing (204) is fixedly connected with said casing (100), and the bottom of said housing (204) and said casing (100) conducting; Said pulley (201), float (202) and vertical (203) all are arranged on the inside of said housing (204).
4. the system of claim 1 is characterized in that, said float gauge (200) is connected with said data acquisition unit (300) through data line.
5. the system of claim 1 is characterized in that, the triangle drift angle of said triangle water delivering orifice (102) down, and drift angle is 30 °.
6. the system of claim 1 is characterized in that, the distance from bottom of the said casing of perigee distance (100) of said triangle water outlet (102) is 1.6cm.
7. the system of claim 1 is characterized in that, said casing (100) is the hollow rectangular parallelepiped of upper shed, and its length and width height is of a size of 30 centimetres of 50 cm x, 50 cm x.
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| Application Number | Priority Date | Filing Date | Title |
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| CN2011102497975A CN102435230A (en) | 2011-08-26 | 2011-08-26 | Slope plot runoff flow measurement system of triangular weir |
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| CN2011102497975A CN102435230A (en) | 2011-08-26 | 2011-08-26 | Slope plot runoff flow measurement system of triangular weir |
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Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104599567A (en) * | 2015-02-02 | 2015-05-06 | 江苏农林职业技术学院 | Multifunctional fluid mechanics experimental device |
| CN105403269A (en) * | 2015-12-03 | 2016-03-16 | 中国科学院测量与地球物理研究所 | Adjustable surface runoff monitoring device |
| CN106052973A (en) * | 2016-07-27 | 2016-10-26 | 扬州大学 | Dam pipe surge and seepage intensity detecting device and its testing method |
| CN108426613A (en) * | 2018-01-23 | 2018-08-21 | 中国地质大学(武汉) | Water flow automated watch-keeping facility |
| CN111397585A (en) * | 2020-04-10 | 2020-07-10 | 黄河勘测规划设计研究院有限公司 | Water delivery open channel three-section flow measurement method based on energy conservation principle |
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| CN86207061U (en) * | 1986-09-22 | 1988-04-13 | 李松汉 | Recorder for measuring the flow of water |
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| CN2227825Y (en) * | 1995-01-13 | 1996-05-22 | 蒋浩强 | Oil metering device for oil tank |
| CN101694395A (en) * | 2009-10-16 | 2010-04-14 | 华南理工大学 | Flow measuring and transmitting device of dam infiltration flow of reservoir |
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Patent Citations (5)
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| CN85204118U (en) * | 1985-09-29 | 1986-06-18 | 河北省平山县滹北灌区管理处 | Electronic water flow meter |
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| CN2150533Y (en) * | 1992-12-18 | 1993-12-22 | 中国科学院水利部西北水土保持研究所 | Automatic recording device for sloping surface runoff |
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Cited By (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104599567A (en) * | 2015-02-02 | 2015-05-06 | 江苏农林职业技术学院 | Multifunctional fluid mechanics experimental device |
| CN105403269A (en) * | 2015-12-03 | 2016-03-16 | 中国科学院测量与地球物理研究所 | Adjustable surface runoff monitoring device |
| CN105403269B (en) * | 2015-12-03 | 2018-10-30 | 中国科学院测量与地球物理研究所 | Adjustable rainwash monitoring device |
| CN106052973A (en) * | 2016-07-27 | 2016-10-26 | 扬州大学 | Dam pipe surge and seepage intensity detecting device and its testing method |
| CN108426613A (en) * | 2018-01-23 | 2018-08-21 | 中国地质大学(武汉) | Water flow automated watch-keeping facility |
| CN111397585A (en) * | 2020-04-10 | 2020-07-10 | 黄河勘测规划设计研究院有限公司 | Water delivery open channel three-section flow measurement method based on energy conservation principle |
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Application publication date: 20120502 |