CN204594980U - A kind of device measuring pollutants in soil flux - Google Patents
A kind of device measuring pollutants in soil flux Download PDFInfo
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- CN204594980U CN204594980U CN201520134522.0U CN201520134522U CN204594980U CN 204594980 U CN204594980 U CN 204594980U CN 201520134522 U CN201520134522 U CN 201520134522U CN 204594980 U CN204594980 U CN 204594980U
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Abstract
A kind of device measuring pollutants in soil flux, it comprises the Simulated Soil device (1) of band irrigation liquid input end, the inside filling soil body of this Simulated Soil device, and the outside wall surface of this Simulated Soil device is equipped with runoff collecting device (2), bottom is provided with soil body penetration base for supporting (4); The bottom of this soil body penetration base for supporting is provided with leacheate collection hole (41) and leacheate gathering-device (6), this runoff collecting device and leacheate gathering-device are communicated with the recycling bin (9) be positioned at below this Simulated Soil device respectively, this recycling bin connects the input end of water pump (10), and the irrigation liquid input end that this water delivery side of pump connects this Simulated Soil device continues to irrigate.The utility model can determine the transport flux of pollutant in soil surface runoff and leacheate exactly, shortage of water resources and secondary pollution problem can be solved by circulating irrigation system simultaneously, and this Dynamic System is simple, except water pump needs power supply, there is no secondary energy consumption.
Description
Technical field
The utility model relates to farmland water and irrigates field, particularly a kind of device measuring pollutants in soil flux, to test pollutant in soil during sewage irrigation (as heavy metal) Transport easily.
Background technology
At present, utilize sewage to carry out agricultural irrigation at home and abroad ubiquity, on the one hand, sewage brings the nutrients such as abundant nitrogen, phosphorus, potassium to soil, and on the other hand, solving agricultural water carrys out source problem; But a large amount of rural sewage disposal farms causes the pollutant loads such as heavy metal in soil to increase, and is the one of the main reasons causing Farmland Soil Pollution.Long-term rural sewage disposal farm, content of beary metal in soil has exceeded soil sticking and Crop ability, soil pollution must be caused, occur that soil compaction, fertility decline, the imbalance of the 26S Proteasome Structure and Function of soil, soil ecosystem is balanced be damaged, cause soil environment to worsen, edaphone structure fails, diversity declines, and produces Environmental and ecological problems.
In order to study pollutant (as the heavy metal) migration situation on soil vertical direction and overland flow in sewage irrigation soil course, now conventional method is by carrying out spot sampling to soil in outdoor, the distribution situation of heavy metal in soil is studied with this, but such research often can only provide the heavy metal content in soil of some time points, it is a method of static testing, and outdoor needs drop into a large amount of manpower and materials, process tedious, therefore, wish to set up an indoor dynamic analog test, to overcome the defect of site test.
Utility model content
Technical problem to be solved in the utility model is: not enough for prior art, the utility model provides a kind of device measuring pollutants in soil flux, the transport flux of pollutant in soil in overland flow and vertical direction can be measured accurately, for the contaminant transportation in soil provides reference data by this device.
For solving the problems of the technologies described above, the technical solution adopted in the utility model is: a kind of device measuring pollutants in soil flux, it comprises the Simulated Soil device of band irrigation liquid input end, the inside filling soil body of this Simulated Soil device, and the outside wall surface of this Simulated Soil device is equipped with runoff collecting device, bottom is provided with soil body penetration base for supporting; The bottom of this soil body penetration base for supporting is provided with leacheate collection hole, this leacheate collection hole is communicated with leacheate gathering-device, this runoff collecting device and leacheate gathering-device are communicated with the recycling bin be positioned at below this Simulated Soil device respectively, this recycling bin connects the input end of water pump, and this water delivery side of pump is communicated with the irrigation liquid input end of this Simulated Soil device through the water inlet of water inlet pipe.
This Simulated Soil device is a tubbiness open-top receptacle.
This leacheate gathering-device is a conical container.
This runoff collecting device is arranged at outside the openend of this Simulated Soil device.
This runoff collecting device and leacheate gathering-device match with Simulated Soil device wall respectively, and are connected with Simulated Soil device by marine glue.
The top of this Simulated Soil device arranges rainfall simulator, and the top of this rainfall simulator is communicated with the water inlet of this water inlet pipe, and the bottom of this rainfall simulator arranges multiple rainwater hole communicated with the irrigation liquid input end of this Simulated Soil device.
Different depth position outside this Simulated Soil device arranges osculum.
Compared with prior art, the beneficial effect that the utility model has is:
1, use the utility model to carry out measuring the test operation of pollutant in soil matter transport flux simply, without the need to keeping an eye on for a long time, can use manpower and material resources sparingly, not easily break down.
2, the utility model installation cost is low, and except runoff collecting device and leacheate gathering-device need periodic cleaning, do not have other not need the material regularly replaced, and thus safeguards simple.
3, the test utilizing the utility model to carry out measuring pollutant in soil matter transport flux has cycle short, the feature such as sampling is convenient, not only this test regularly can draw sample at runoff collecting device and the sampling of leacheate gathering-device, conveniently be easy to get, and employing lab simulation, solve the factor impacts such as field irrigation place restriction.
4, the utility model can determine the transport flux of pollutant in soil surface runoff and leacheate exactly, shortage of water resources and secondary pollution problem can be solved by circulating irrigation system simultaneously, and this Dynamic System is simple, except water pump needs power supply, there is no secondary energy consumption.
Accompanying drawing explanation
Fig. 1 is that the utility model measures pollutant in soil matter transport flux device first example structure schematic diagram.
Fig. 2 is that the utility model measures pollutant in soil matter transport flux device second example structure schematic diagram.
Wherein: 1-Simulated Soil device, 2-runoff collecting device, 3-apopore, 4-soil body penetration base for supporting, 41-leacheate collection hole, the 5-soil body, 6-leacheate gathering-device, 7-pipeline, 8-connecting pipe, 9-recycling bin, 10-water pump, 11-water inlet pipe, 111-water inlet, 12-irrigation liquid input end, 13-valve, 14-osculum, 15-rainfall simulator, 151-rainwater hole.
Embodiment
As shown in Figure 1, a kind of device first embodiment measuring pollutants in soil flux of the utility model comprises the Simulated Soil device 1 of band irrigation liquid input end 12.The inside filling soil body 5 of this Simulated Soil device 1, and the outside wall surface of this Simulated Soil device 1 is equipped with runoff collecting device 2, bottom is provided with soil body penetration base for supporting 4.This soil body penetration base for supporting 4 is provided with multiple leacheate collection hole 41, and the bottom of this soil body penetration base for supporting 4 arranges leacheate gathering-device 6, makes leacheate collection hole 41 be communicated with this leacheate gathering-device 6.This runoff collecting device 2 and leacheate gathering-device 6 are communicated with the recycling bin 9 be positioned at below this Simulated Soil device 1 respectively, this recycling bin connects the input end of water pump 10, and the output terminal of this water pump 10 is communicated with the irrigation liquid input end 12 of this Simulated Soil device 1 through the water inlet 111 of water inlet pipe 11.
In this enforcement, this Simulated Soil device 1 is a tubbiness open-top receptacle, and this runoff collecting device 2 is arranged at outside the openend of this Simulated Soil device 1.But be not limited thereto, this runoff collecting device 2 also can be located at outer middle side part or the bottom of this Simulated Soil device 1.
In this enforcement, this leacheate gathering-device 6 is a conical container.
When the present embodiment uses, the leacheate inputting Simulated Soil device 1 from the water inlet 111 of water inlet pipe 11 flows through pipeline 7 through soil permeability and overland flow effect respectively by runoff collecting device 2 and leacheate gathering-device 6 and flows to recycling bin 9.Because the position of recycling bin 9 is lower than Simulated Soil device 1, thus collect from the overland flow liquid of Simulated Soil device 1 and leacheate by Action of Gravity Field.Meanwhile, the soil washing away out along with footpath flow liquid, leacheate is then stayed inside runoff collecting device 2 and leacheate gathering-device 6.The overland flow liquid collected in recycling bin 9 and leacheate are transported to Simulated Soil device 1 through water inlet pipe 11 by water pump 10 again to be continued to irrigate, and so circulates, and goes round and begins again.When cyclic irrigation water shortage, continue to irrigate by outer water receiving mode of movement.Regularly the soil and water (by apopore 3) in runoff collecting device 2 and leacheate gathering-device 6 is collected and analyzed the content of wherein pollutant, just can measure the transport flux of pollutant in soil in overland flow and vertical direction accurately, for the contaminant transportation in soil provides reference data.
The interface of each parts of the present embodiment all fills marine glue and is fixed in case leak-stopping water.
The present embodiment runoff collecting device 2 and leacheate gathering-device 6 match with the wall of Simulated Soil device 1 respectively, and are connected with Simulated Soil device 1 by marine glue.
As shown in Figure 2, the utility model is a kind of, and to measure device second example structure of pollutants in soil flux substantially identical with the first example structure, difference is only: the top of this Simulated Soil device 1 arranges rainfall simulator 15, and the outside different depth position of this Simulated Soil device 1 arranges osculum 14.The top of this rainfall simulator 15 is communicated with the water inlet 111 of this water inlet pipe 11, the bottom of this rainfall simulator 15 arranges multiple rainwater hole 151, the leacheate entering this rainfall simulator 15 can be flowed in the soil body 5 in this Simulated Soil device 1 as the shape that rains through the rainwater hole 151 of bottom, make the utility model can study the rule of pollutant Transport And Transformation in soil under simulated rainfall conditions.Closed osculum 14 is set in the different depth side of Simulated Soil device 1, makes the utility model can study the Transport of pollutant at different depth.
Claims (6)
1. one kind measures the device of pollutants in soil flux, it is characterized in that the Simulated Soil device (1) comprising band irrigation liquid input end (12), the inside filling soil body (5) of this Simulated Soil device, and the outside wall surface of this Simulated Soil device is equipped with runoff collecting device (2), bottom is provided with soil body penetration base for supporting (4); The bottom of this soil body penetration base for supporting is provided with leacheate collection hole (41), this leacheate collection hole is communicated with leacheate gathering-device (6), this runoff collecting device and leacheate gathering-device are communicated with the recycling bin (9) be positioned at below this Simulated Soil device respectively, this recycling bin connects the input end of water pump (10), and the water inlet (111) of this water delivery side of pump through water inlet pipe (11) is communicated with the irrigation liquid input end of this Simulated Soil device.
2. a kind of device measuring pollutants in soil flux according to claim 1, is characterized in that, this Simulated Soil device is a tubbiness open-top receptacle.
3. a kind of device measuring pollutants in soil flux according to claim 1, is characterized in that, this leacheate gathering-device is a conical container.
4. a kind of device measuring pollutants in soil flux according to claim 1, it is characterized in that, this runoff collecting device is arranged at outside the openend of this Simulated Soil device.
5. a kind of device measuring pollutants in soil flux according to claim 1, it is characterized in that, the top of this Simulated Soil device arranges rainfall simulator (15), the top of this rainfall simulator is communicated with the water inlet of this water inlet pipe, and the bottom of this rainfall simulator arranges multiple rainwater hole (151) communicated with the irrigation liquid input end of this Simulated Soil device.
6. a kind of device measuring pollutants in soil flux according to claim 1, is characterized in that, the different depth position outside this Simulated Soil device arranges osculum (14).
Priority Applications (1)
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CN201520134522.0U CN204594980U (en) | 2015-03-10 | 2015-03-10 | A kind of device measuring pollutants in soil flux |
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CN201520134522.0U CN204594980U (en) | 2015-03-10 | 2015-03-10 | A kind of device measuring pollutants in soil flux |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104655824A (en) * | 2015-03-10 | 2015-05-27 | 湖南农业大学 | Device for measuring transfer flux of pollutants in soil |
CN107167576A (en) * | 2017-05-09 | 2017-09-15 | 武汉大学 | Unsaturated soil disorderly scattered kinetic coefficient assay method and device |
-
2015
- 2015-03-10 CN CN201520134522.0U patent/CN204594980U/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104655824A (en) * | 2015-03-10 | 2015-05-27 | 湖南农业大学 | Device for measuring transfer flux of pollutants in soil |
CN107167576A (en) * | 2017-05-09 | 2017-09-15 | 武汉大学 | Unsaturated soil disorderly scattered kinetic coefficient assay method and device |
CN107167576B (en) * | 2017-05-09 | 2020-02-14 | 武汉大学 | Unsaturated soil turbulence kinetic coefficient measuring method and device |
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CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20150826 Termination date: 20160310 |
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CF01 | Termination of patent right due to non-payment of annual fee |