CN207351752U - A kind of portable fluid depthkeeping Stratified Sampling device - Google Patents
A kind of portable fluid depthkeeping Stratified Sampling device Download PDFInfo
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- CN207351752U CN207351752U CN201721521870.9U CN201721521870U CN207351752U CN 207351752 U CN207351752 U CN 207351752U CN 201721521870 U CN201721521870 U CN 201721521870U CN 207351752 U CN207351752 U CN 207351752U
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- 238000005070 sampling Methods 0.000 title claims abstract description 118
- 239000012530 fluid Substances 0.000 title claims abstract description 52
- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 claims abstract description 50
- 230000007246 mechanism Effects 0.000 claims abstract description 41
- 238000003860 storage Methods 0.000 claims abstract description 33
- 229910052757 nitrogen Inorganic materials 0.000 claims abstract description 25
- 239000007789 gas Substances 0.000 claims abstract description 14
- 230000007423 decrease Effects 0.000 claims description 2
- 239000007787 solid Substances 0.000 claims description 2
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 abstract description 51
- 230000006870 function Effects 0.000 abstract description 15
- 238000012544 monitoring process Methods 0.000 description 7
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- 230000036541 health Effects 0.000 description 2
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- 241000372132 Hydrometridae Species 0.000 description 1
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- 238000003895 groundwater pollution Methods 0.000 description 1
- 239000001307 helium Substances 0.000 description 1
- 229910052734 helium Inorganic materials 0.000 description 1
- SWQJXJOGLNCZEY-UHFFFAOYSA-N helium atom Chemical compound [He] SWQJXJOGLNCZEY-UHFFFAOYSA-N 0.000 description 1
- 230000006872 improvement Effects 0.000 description 1
- 238000011835 investigation Methods 0.000 description 1
- 239000007788 liquid Substances 0.000 description 1
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- 230000004048 modification Effects 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 229910052754 neon Inorganic materials 0.000 description 1
- GKAOGPIIYCISHV-UHFFFAOYSA-N neon atom Chemical compound [Ne] GKAOGPIIYCISHV-UHFFFAOYSA-N 0.000 description 1
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Abstract
It the utility model is related to water sampling technical field, and in particular to a kind of portable fluid depthkeeping Stratified Sampling device.The device includes integrated depthkeeping Stratified Sampling cabinet, three sample connections are provided with it, each sample connection is connected with four mouthfuls of distributing T-pipe mechanisms of nested type, tube-in-tube and check valve in turn, and the lower end of each tube-in-tube is provided with storage stream container, and each sample connection is connected with sampling bottle;The shaft being horizontally set in the middle part of integrated depthkeeping Stratified Sampling cabinet, the middle part of each tube-in-tube are wrapped in shaft in the same direction;Nitrogen cylinder, nitrogen cylinder are sequentially connected gas pressurized interface and four-way, and four-way connects each four mouthfuls of distributing T-pipe mechanisms of nested type respectively.Portable fluid depthkeeping Stratified Sampling device provided by the utility model can realize the depthkeeping sampled functions of multiple layers of position at the same time, the depth selection of the sampling number of plies and each layer position can be selected and set according to technical staff, Stratified Sampling speed is fast, and performance is better than similar product.
Description
Technical field
It the utility model is related to water sampling technical field, and in particular to a kind of portable fluid depthkeeping Stratified Sampling dress
Put.
Background technology
Water body is that the quality of water head site water quality directly affects society an important factor for being related to earth's surface biological and human survival
Expanding economy and the life of resident.
Water sampling is the indispensable instrument of the environment and ecosystem scientific research such as survey for the purpose of locating hydrogeological resources, pollution assessment
One of.It is the smooth premise and base for carrying out every administration of research activities work for big deep water body collection, high-precision layered water sample
Plinth, such as studies river, lake, reservoir, the physics of phreatic water, biology, especially chemical parameters Characteristics of Vertical Distribution, interface
Neighbouring distribution characteristics research.
The water sampling in all kinds of waters such as phreatic water, rivers/lake, reservoir, water channel is water environment protection management etc.
The important content of government function part work, is to concern the people's livelihood and the public welfare content of resource environment, the life with each of us
Living and descendants is closely bound up.The water quality monitoring at the water source emphasis as environmental protection all the time, in order to strengthen water environment
Quality monitoring, grasps water quality situation situation in time, determines the distribution situation of pollutant in water body, and then traces coming for pollutant
Source/pollution channel and influence to health are, it is necessary to carry out substantial amounts of sampling of water quality monitoring in situ, in the hope of water quality data
Timeliness and accuracy.The quality of its water quality is directly related to the national economic development and people's health.Water quality monitoring is
The main contents of national environmental protection supervision, the waters/water source especially influenced be subject to sewage discharge.
Existing a variety of commercialized water samplers at present, but there are it is different degrees of the problem of, such as traditional Beile manages, sampling
Finite volume, repeated sampling are complicated, are difficult to control sampling rate, are unable to reach requirement;Partial hierarchical sample devices is more for sea
Foreign research work design, needs special vessel and lifting equipment, there are the shortcomings that complicated, operation difficulty is big, is not suitable with Hu Ku
Light ship is the sample activity of carrier.In conclusion there are many technical problems or the inconvenience used for traditional sampler
Property, it is specifically described as follows:
1) sampling container, lid, bar composition this kind of sampling equipment the disadvantage is that, thief rod without scale mark, it is impossible to realize
Accurate depthkeeping sampling, component assembling is complicated, cumbersome during Stratified Sampling;
2) the Stratified Sampling equipment set based on container is caused point easily because operational issue bottle cap or trigger valve are opened in advance
Layer sampling failure or sample do not possess representativeness, and repeated sampling is complicated, is not suitable for long term monitoring;
3) vacuum type or suction type sampler due in bottle air pressure there is larger, the sample rate that makes water enter bottle internal resistance
Slowly, water sample is polluted;
4) existing sampler not enough automates, it is impossible to fully meets water body hierarchical synchronization efficient sampling requirement, etc..
The evolution properties or monitoring water quality for studying water body long-term sequence often need to be synchronous to different water levels or different water sample points
Water sample is gathered, water body material vertical demixing is especially studied and boundary material exchanges.Due to gas dissolved water (such as CO2、CH4、
N2O) had a great influence be subject to environmental factors such as temperature, partial pressures, the changes in environmental conditions in sampling or when sample dispenses can
Analysis measuring accuracy can be seriously affected, it is necessary to accomplish the folding and sealing in situ of different depth.Therefore, in quick measure water body
The concentration and spatial distribution of dissolved gas need to develop a kind of disposable acquisition easy to operation, being adapted to field condition, in situ
Different depth representative sample, the high-precision depthkeeping Stratified Sampling device that can identify dissolved gas.
Utility model content
To solve the deficiencies in the prior art, the utility model provides a kind of portable fluid depthkeeping Stratified Sampling device.
Technical solution provided by the utility model is as follows:
A kind of portable fluid depthkeeping Stratified Sampling device, including:
Integrated depthkeeping Stratified Sampling cabinet, in the integrated depthkeeping Stratified Sampling cabinet being respectively arranged with first takes
Sample interface, the second sample connection and the 3rd sample connection, first sample connection are connected with four mouthful three of the first nested type in turn
Logical diversion mechanism, vertically arranged soft the first tube-in-tube and the first check valve, second sample connection are connected with turn
Second four mouthfuls of nested type distributing T-pipe mechanism, vertically arranged the second soft tube-in-tube, the second check valve and the first plummet, institute
The 3rd sample connection is stated to be connected with turn in four mouthfuls of distributing T-pipe mechanisms of the 3rd nested type, vertically arranged the 3rd soft pipe
Pipe, the 3rd check valve and the second plummet, the lower end of first tube-in-tube are provided with the first storage stream container, second tube-in-tube
Lower end be provided with the second storage stream container, the lower end of the 3rd tube-in-tube is provided with the 3rd storage stream container, first sampling
Interface is connected with the first sampling bottle, and second sample connection is connected with the second sampling bottle, and the 3rd sample connection is connected with
3rd sampling bottle;
The horizontal shaft being arranged in the middle part of the integrated depthkeeping Stratified Sampling cabinet, it is first tube-in-tube, described
The middle part of second tube-in-tube and the 3rd tube-in-tube is in the same direction to be wrapped in the shaft, the rotation equal length of the shaft
Lifting or decline first tube-in-tube, second tube-in-tube and the 3rd tube-in-tube lower end height;
Nitrogen cylinder, the nitrogen cylinder are sequentially connected gas pressurized interface and four-way, and the four-way connects described first respectively
Four mouthfuls of distributing T-pipe mechanisms of nested type, second nested type, four mouthfuls of distributing T-pipe mechanisms and described 3rd nested type, four mouthfuls of threeways
Diversion mechanism.
The portable fluid depthkeeping Stratified Sampling device that above-mentioned technical proposal is provided can realize determining for multiple layers of position at the same time
Deep sampled functions, the depth selection of each layer position can be selected and set according to technical staff, and Stratified Sampling speed is fast, and performance is better than
Similar product.
Specifically, first tube-in-tube includes the first outer tube and the first inner tube being arranged in first outer tube.
Specifically, first outer tube is connected with the described first storage stream container, and first inner tube runs through described first
Store up stream container.
Specifically, described first nested type, four mouthfuls of distributing T-pipe mechanisms are included in the first inner tube access port and described first
Pipe access port connection the first inner tube exit, the first outer tube access port and connected with the first outer tube access port first outside
Pipe exit, first sampling bottle connect the first inner tube access port, the first inner tube exit connection described first
Inner tube, the four-way connect the first outer tube access port by a port, described in the first external pipe connection outlet
One outer tube.
Specifically, second tube-in-tube includes the second outer tube and the second inner tube being arranged in second outer tube.
Specifically, second outer tube is connected with the described 3rd storage stream container, and second inner tube runs through the described 3rd
Store up stream container.
Specifically, described second nested type, four mouthfuls of distributing T-pipe mechanisms are included in the second inner tube access port and described second
Pipe access port connection the second inner tube exit, the second outer tube access port and connected with the second outer tube access port second outside
Pipe exit, second sampling bottle connect the second inner tube access port, the second inner tube exit connection described second
Inner tube, the four-way connect the second outer tube access port by a port, described in the second external pipe connection outlet
Two outer tubes.
Specifically, the 3rd tube-in-tube includes the 3rd outer tube and the 3rd inner tube being arranged in the 3rd outer tube;Institute
State the 3rd outer tube to connect with the described second storage stream container, and the 3rd inner tube is through the described second storage stream container.
Specifically, described 3rd nested type, four mouthfuls of distributing T-pipe mechanisms are included in the 3rd inner tube access port and the described 3rd
Pipe access port connection the 3rd inner tube exit, the 3rd outer tube access port and connected with the 3rd outer tube access port the 3rd outside
Pipe exit, the 3rd sampling bottle connect the 3rd inner tube access port, the 3rd inner tube exit connection the described 3rd
Inner tube, the four-way connect the 3rd outer tube access port by a port, described in the 3rd external pipe connection outlet
Three outer tubes.
Specifically:
Height of the height of first check valve higher than second check valve and the 3rd check valve;
Second check valve is different with the height of the 3rd check valve.
Specifically:
First tube-in-tube, second tube-in-tube and the 3rd tube-in-tube constrain in described first by the first pipe collar
Transverse shifting in pipe collar;
Second tube-in-tube and the 3rd tube-in-tube constrain in transverse shifting in second pipe collar by the second pipe collar;
Second pipe collar is located at the solid lower section of first pipe collar.
Further, the top of the integrated depthkeeping Stratified Sampling cabinet can be rolled over around horizontal pivot center to lower part
It is folded.
First sample connection, the second sample connection, the 3rd sample connection take to be arranged on integrated depthkeeping layering
Quick coupling inside model machine case, the first sampling bottle, the second sampling bottle, the 3rd sampling bottle, the sampling are connected by pipe joint
Interface can select the more ripe PU Series Pneumatic quick connectors of in the market.
Described four mouthfuls of distributing T-pipe mechanisms of nested type, are nonstandard customization part, its connection mode is to connect tube-in-tube, and
The nesting type structure of its inner tube set outer tube is split into inner tube nitrogen cylinder is connected by four-way, the sampled interface connection of appearance corresponds to
Sampling bottle;Its function is by four mouthfuls of threeway elements while controls two kinds of mutually different fluids (to refer to respectively herein
Nitrogen and water), while realize diverter function, a kind of detailed visible utility model patent " four mouthfuls of distributing T-pipe mechanisms of nested type "
(CN201520642354.6)。
The shaft, its function are (winding, fixed, reading depth etc.) three different pipeline systems can be separately controlled
System.Its structure is the adjustable locating slots of flywheel and position that three pairs of setting each independently rotates, and pipeline is realized in the rotation of flywheel
Winding, folding and unfolding and the fixed function of system, and different flywheels can be matched by adjusting positioning groove location, so as to fulfill shaft point
Open the function of the different pipeline systems of control three.Its concrete operating principle is that three pairs of rotating flywheels of independence correspond to first respectively
Tube-in-tube, the second tube-in-tube, the 3rd tube-in-tube, the locating slot in shaft realize of different flywheels by moving left and right position
Match somebody with somebody, and then manually rotating shaft realizes three independent pipeline systems of adjustment control successively.
First pipe collar, the second pipe collar, are market prior art, its role is to more pipelines of fixation and it is fixed compared with
The element of weight, such as the first storage stream container, the second storage stream container, the 3rd storage stream container, the first plummet, the second plummet.Wherein, first
Pipe collar also selectively attaches float function, and the weight that can have carried other elements is swum on the water surface.
The check valve is market prior art, only allows fluid one-way conduction, inversely then closes;
First plummet, the second plummet are conventional products, and its role is to the pipe-line system connected and each member
Part precipitation is into the bottom, its way of realization can use stainless steel cone processing, its specific weight is according to the sky for storing up stream container
Between determine.
Each tube-in-tube, is published Stratified Sampling series of patents technology, its connection mode is outside inner tube set
The nesting type structure of pipe, its operation principle are based on gas push formula fluid sampling technology, and inner tube is filled with the indifferent gas of certain pressure
Body, be limited to the inverse closing function of tube-in-tube front end check valve, so as to will be stored in the annular space outside inner tube in outer tube
Underground fluid displacement comes out, and enters corresponding sampling bottle through sampling surface mouth, refers to a kind of utility model patent " tube-in-tube underground
Fluid layering sampler (CN201510338566.X) ".
The nitrogen cylinder is existing procucts, it is desirable to is not acted on target fluid generation chemical reaction and physical mixed lazy
Property gas, such as helium, neon, nitrogen, it is most economical it is common be nitrogen, consider field sampling it is portable, the mark of the optional 5L of volume
Accurate small-sized nitrogen cylinder, configures the pressure maintaining valve of suitable range, the pressure value for keeping constant the compressed nitrogen of output.
The utility model is compared with the prior art, and its advantage and advantage are:
1st, the device can realize the Stratified Sampling function of different depth fluid, based on gas push formula fluid sampling principle,
Using newest tube-in-tube sampling technique, while obtain the fluid sample of multiple layers of position;
2nd, the device can realize the depthkeeping sampled functions of multiple layers of position at the same time, and the depth selection of each layer position can be according to technology
Personnel selection and set, Stratified Sampling speed is fast, and performance is better than similar product;
3rd, the device is widely applicable, for environmental pollution surveys and water resource, possess extraordinary business promotion value and
Application prospect.Suitable for survey for the purpose of locating hydrogeological resources, lake and reservoir water source etc. water body Multi-layer synchronous sampling it is fine with the layering of water quality
Monitoring, phreatic water environment geology survey and pollution are followed the trail of, and gas dissolved water measure and layering assessment, large oil tank etc. are big
The Stratified Sampling of type liquid chemical is inspected by random samples, especially the fine sampling analysis of underground water of machine people well investigation, river, lake, reservoir
The fields such as situation of change, Shallow Groundwater Pollution situation and its range of scatter and migration velocity Deng surface water body water quality.
Brief description of the drawings
Fig. 1 is the overall structure diagram of portable fluid depthkeeping Stratified Sampling device provided by the utility model.
Fig. 2 is the partial structural diagram of portable fluid depthkeeping Stratified Sampling device provided by the utility model.
Fig. 3 is the fundamental diagram of portable fluid depthkeeping Stratified Sampling device provided by the utility model.
In attached drawing 1,2,3, the structure list representated by each label is as follows:
1st, integrated depthkeeping Stratified Sampling cabinet, the 2.1, first sample connection, the 2.2, second sample connection, the 2.3, the 3rd takes
Sample interface, the 3.1, first four mouthfuls of nested type distributing T-pipe mechanism, the 3.2, second four mouthfuls of nested type distributing T-pipe mechanism, the 3.3, the 3rd
Four mouthfuls of distributing T-pipe mechanisms of nested type, 4, four-way, 5, gas pressurized interface, 6, shaft, the 7.1, first pipe collar, the 7.2, second pipe
Hoop, the 8.1, first storage stream container, the 8.2, second storage stream container, the 8.3, the 3rd storage stream container, the 9.1, first check valve, 9.2, second
Check valve, the 9.3, the 3rd check valve, the 10.1, first plummet, the 10.2, second plummet, the 11.1, first tube-in-tube, the 11.2, second pipe
Middle pipe, the 11.3, the 3rd tube-in-tube, the 12.1, first sampling bottle, the 12.2, second sampling bottle, the 12.3, the 3rd sampling bottle, 13, nitrogen
Bottle.
Embodiment
The principle and feature of the utility model are described below, illustrated embodiment is served only for explaining the utility model,
It is not intended to limit the scope of the utility model.
Portable fluid depthkeeping Stratified Sampling device provided by the utility model, as shown in Figure 1, the device well head part is extremely
It is few include integration depthkeeping Stratified Sampling cabinet 1, the first sampling bottle 12.1, the second sampling bottle 12.2, the 3rd sampling bottle 12.3 and
Nitrogen cylinder 13.Its specific connection mode is that the first sample connection 2.1 built in integrated depthkeeping Stratified Sampling cabinet 1 connects
First sampling bottle 12.1, the second sample connection 2.2 connect the second sampling bottle 12.2, the 3rd sampling of the 3rd sample connection 2.3 connection
Bottle 12.3, gas pressurized interface 5 connect nitrogen cylinder 13.Its operating function is that the compressed nitrogen of nitrogen cylinder 13 is connected by four-way 4
Four mouthfuls of distributing T-pipe mechanisms 3.1 of the first nested type for connecing, four mouthfuls of distributing T-pipe mechanisms 3.2 of the second nested type, the 3rd nested type four
Mouthful distributing T-pipe mechanism 3.3 pressurizes at earth's surface well head, and the fluid of different depth enters the by the first sample connection 2.1 respectively
One sampling bottle 12.1, the second sample connection 2.2 enter the second sampling bottle 12.2, the 3rd sample connection 2.3 enters the 3rd sampling bottle
12.3, so as to fulfill the sampling operation of the different depth underground fluid of setting.
As shown in structure chart 2, integrated depthkeeping Stratified Sampling cabinet 1 is positioned over desire sample point.Wherein, integrated depthkeeping point
Integrated layered sampling module built in layer sampling cabinet 1 includes:First sample connection 2.1, the sampling of the second sample connection the 2.2, the 3rd
Interface 2.3, four mouthfuls of distributing T-pipe mechanisms 3.1 of the first nested type, four mouthfuls of distributing T-pipe mechanisms of the second nested type the 3.2, the 3rd are nested
Four mouthfuls of distributing T-pipe mechanisms 3.3 of formula, four-way 4, gas pressurized interface 5, shaft 6, the first pipe collar 7.1, the second pipe collar 7.2, first
Store up stream container 8.1, second and store up the storage of stream container the 8.2, the 3rd stream container 8.3, the first check valve 9.1, the second check valve the 9.2, the 3rd
Check valve 9.3, the first plummet 10.1, the second plummet 10.2, the first tube-in-tube 11.1, the second tube-in-tube 11.2, the 3rd tube-in-tube
11.3 etc..Its specific connection mode is that the first sample connection 2.1 is connected by four mouthfuls of distributing T-pipe mechanisms 3.1 of the first nested type
Connect the first tube-in-tube 11.1, another interface of four mouthfuls of distributing T-pipe mechanisms 3.1 of the first nested type intends connecting integration by four-way 4
Nitrogen cylinder 13 outside depthkeeping Stratified Sampling cabinet 1;First tube-in-tube 11.1 is wound in shaft 6, continues to flow with the first storage downwards
Container 8.1, the first check valve 9.1 connect.Second sample connection 2.2 is connected by four mouthfuls of distributing T-pipe mechanisms 3.2 of the second nested type
Connect the second tube-in-tube 11.2, another interface of four mouthfuls of distributing T-pipe mechanisms 3.2 of the second nested type intends connecting integration by four-way 4
Nitrogen cylinder 13 outside depthkeeping Stratified Sampling cabinet 1;Second tube-in-tube 11.2 is wound in shaft 6, continues to flow with the second storage downwards
Container 8.2, the second check valve 9.2, the first plummet 10.1 connect.3rd sample connection 2.3 passes through the four mouthfuls of threeways of the 3rd nested type
Diversion mechanism 3.3 connects the 3rd tube-in-tube 11.3, another interface of four mouthfuls of distributing T-pipe mechanisms 3.3 of the 3rd nested type passes through four-way
4 intend the nitrogen cylinder 13 outside connecting integration depthkeeping Stratified Sampling cabinet 1;3rd tube-in-tube 11.3 is wound in shaft 6, continue to
It is lower to be connected with the 3rd storage stream container 8.3, the 3rd check valve 9.3, the second plummet 10.2.Wherein, the first pipe collar 7.1 is positioned over first
The top of stream container 8.1 is stored up, the first tube-in-tube 11.1, the second tube-in-tube 11.2, the 3rd tube-in-tube at this are fixed outside pipe
11.3, float function is provided simultaneously with, pipe-line system is kept afloat at first pipe collar 7.1 when being positioned over underwater, easy to obtain
Close to the first layer fluid of the water surface;Second pipe collar 7.2 is positioned over the top of the second storage stream container 8.2, for fixing at this
Two tube-in-tubes 11.2, the 3rd tube-in-tube 11.3.
Shown in integrated structure Fig. 2 and operation principle Fig. 3, a kind of portable fluid depthkeeping Stratified Sampling device, its
Depthkeeping Stratified Sampling operating procedure is as follows:The first step, obtains the first layer fluid close to the water surface, the control of the first tube-in-tube 11.1
First storage stream container 8.1 floats on the water surface to obtain the first layer representativeness fluid close to the water surface by the first pipe collar 7.1, and leads to
Cross shaft control length of pipeline and read its depth selection;Second step, obtains innermost third layer fluid (close to water bottom such as
Underground water well shaft bottom, earth's surface river river bed, reservoir lake lakebed, or required maximum depth selection) third layer fluid, the 3rd
The maximum sampling that the 3rd storage stream container 8.3 that tube-in-tube 11.3 controls is deposited in water bottom by the first plummet 10.1 or specifies
Depth, so as to obtain most deep third layer representativeness fluid, and controls length of pipeline to read its depth selection by shaft;3rd
Step is the second layer fluid for obtaining intermediate layer position, passes through the of the third layer fluid of maximum depth selection and minimum sample depth
One layer fluid judges, chooses suitable intermediate layer second layer depth selection, and such as maximum depth selection and minimum sample depth are put down
Average, or the setting value that technical staff judges according to actual conditions, control the second tube-in-tube 11.2 to make the second storage fluid capacitance by shaft 6
8.2 and second check valve 9.2 of device reaches designated depth waters, the second layer representativeness fluid of this layer of bit depth is obtained, so that complete
Into the depthkeeping Stratified Sampling operation of three different layers positions.
It is worth noting that in the utility model, to illustrate the depthkeeping Stratified Sampling for conveniently only giving 3 different layers positions
The embodiment of device, the depthkeeping that 2-10 layers of even more multilayer position can be obtained by same design philosophy and method processing divide
Layer sampler;Corresponded to respectively in addition, the implementation case provides 3 different depth selections:(first layer) at the water surface, water-bed (the
Three layers) and corresponding intermediate depth (second layer), only illustrate as case, the specific depth selection of actually each layer position can be according to skill
Art personnel's will is arbitrarily selected on the premise of no more than range.
A kind of operation principle of portable fluid depthkeeping Stratified Sampling device provided by the utility model is as follows:
Connected by the utility model embodiment, open nitrogen cylinder, the high pressure nitrogen of constant output pressure passes through four promoting menstruations
Respectively enterd after first nested type diversion mechanism, the second nested type diversion mechanism, the 3rd nested type diversion mechanism the first tube-in-tube,
Second tube-in-tube, the 3rd tube-in-tube, and then the representative fluid of first layer, the second layer, third layer different depth is obtained at the same time.Its
The specific sampling work principle of individual layer illustrates so that the second layer samples as an example:The representative fluid of designated depth is single by second in water body
To valve enter second storage stream container, through the second tube-in-tube enter high pressure nitrogen because the second check valve of setting only allow by down toward
Upper one-way flow function restriction and by the fluid displacement in the second storage stream container to earth's surface, the fluid is through four mouthfuls of the second nested type
Distributing T-pipe mechanism and the second sample connection enter the second sampling bottle, so as to obtain the representative fluid of the second layer depth.To sum up
It is described, equipment is connected by the requires of the utility model and is set, nitrogen cylinder is opened and pressurizes, each sampling bottle at earth's surface obtains three at the same time
The representative fluid of a different depth, so as to complete depthkeeping Stratified Sampling.
The above is only the preferred embodiment of the present invention, is not intended to limit the utility model, all in this practicality
Within new spirit and principle, any modification, equivalent replacement, improvement and so on, should be included in the guarantor of the utility model
Within the scope of shield.
Claims (10)
- A kind of 1. portable fluid depthkeeping Stratified Sampling device, it is characterised in that including:Integrated depthkeeping Stratified Sampling cabinet (1), first is respectively arranged with the integrated depthkeeping Stratified Sampling cabinet (1) Sample connection (2.1), the second sample connection (2.2) and the 3rd sample connection (2.3), first sample connection (2.1) is successively It is connected with four mouthfuls of distributing T-pipe mechanisms (3.1) of the first nested type, vertically arranged soft the first tube-in-tube (11.1) and first Check valve (9.1), second sample connection (2.2) are connected with four mouthfuls of distributing T-pipe mechanisms (3.2) of the second nested type in turn, erect To soft the second tube-in-tube (11.2), the second check valve (9.2) and the first plummet (10.1) of setting, the 3rd sampling connects Mouth (2.3) is connected with four mouthfuls of distributing T-pipe mechanisms (3.3) of the 3rd nested type, vertically arranged the 3rd soft tube-in-tube in turn (11.3), the 3rd check valve (9.3) and the second plummet (10.2), the lower end of first tube-in-tube (11.1) are provided with the first storage Stream container (8.1), the lower end of second tube-in-tube (11.2) are provided with the second storage stream container (8.2), the 3rd tube-in-tube (11.3) lower end is provided with the 3rd storage stream container (8.3), and first sample connection (2.1) is connected with the first sampling bottle (12.1), second sample connection (2.2) is connected with the second sampling bottle (12.2), the 3rd sample connection (2.3) connection There is the 3rd sampling bottle (12.3);The horizontal shaft (6) being arranged in the middle part of the integrated depthkeeping Stratified Sampling cabinet (1), first tube-in-tube (11.1), what the middle part of second tube-in-tube (11.2) and the 3rd tube-in-tube (11.3) was in the same direction is wrapped in the shaft (6) on, lifting or decline first check valve (9.1), second check valve that the shaft (6) can be contour are rotated (9.2) and the 3rd check valve (9.3) height;Nitrogen cylinder (13), the nitrogen cylinder (13) are sequentially connected gas pressurized interface (5) and four-way (4), and the four-way (4) is respectively Connect described first nested type, four mouthfuls of distributing T-pipe mechanisms (3.1), second nested type, four mouthfuls of distributing T-pipe mechanisms (3.2) and Described 3rd nested type, four mouthfuls of distributing T-pipe mechanisms (3.3).
- 2. portable fluid depthkeeping Stratified Sampling device according to claim 1, it is characterised in that:First tube-in-tube (11.1) the first outer tube and the first inner tube being arranged in first outer tube are included;First outer tube is flowed with the described first storage Container (8.1) connects, and first inner tube is through the described first storage stream container (8.1).
- 3. portable fluid depthkeeping Stratified Sampling device according to claim 2, it is characterised in that:First nested type Four mouthfuls of distributing T-pipe mechanisms (3.1) connect including the first inner tube access port, the first inner tube connected with the first inner tube access port Outlet, the first outer tube access port and the first outer tube exit connected with the first outer tube access port, first sampling bottle (12.1) the first inner tube access port is connected, the first inner tube exit connects first inner tube, and the four-way (4) is logical Cross a port and connect the first outer tube access port, the first outer tube described in the first external pipe connection outlet.
- 4. portable fluid depthkeeping Stratified Sampling device according to claim 1, it is characterised in that:Second tube-in-tube (11.2) the second outer tube and the second inner tube being arranged in second outer tube are included;Second outer tube is flowed with the described 3rd storage Container (8.3) connects, and second inner tube is through the described 3rd storage stream container (8.3).
- 5. portable fluid depthkeeping Stratified Sampling device according to claim 4, it is characterised in that:Second nested type Four mouthfuls of distributing T-pipe mechanisms (3.2) connect including the second inner tube access port, the second inner tube connected with the second inner tube access port Outlet, the second outer tube access port and the second outer tube exit connected with the second outer tube access port, second sampling bottle (12.2) the second inner tube access port is connected, the second inner tube exit connects second inner tube, and the four-way (4) is logical Cross a port and connect the second outer tube access port, the second outer tube described in the second external pipe connection outlet.
- 6. portable fluid depthkeeping Stratified Sampling device according to claim 1, it is characterised in that:3rd tube-in-tube (11.3) the 3rd outer tube and the 3rd inner tube being arranged in the 3rd outer tube are included;3rd outer tube is flowed with the described second storage Container (8.2) connects, and the 3rd inner tube is through the described second storage stream container (8.2).
- 7. portable fluid depthkeeping Stratified Sampling device according to claim 6, it is characterised in that:3rd nested type Four mouthfuls of distributing T-pipe mechanisms (3.3) connect including the 3rd inner tube access port, the 3rd inner tube connected with the 3rd inner tube access port Outlet, the 3rd outer tube access port and the 3rd outer tube exit connected with the 3rd outer tube access port, the 3rd sampling bottle (12.3) the 3rd inner tube access port is connected, the 3rd inner tube exit connects the 3rd inner tube, and the four-way (4) is logical Cross a port and connect the 3rd outer tube access port, the 3rd outer tube described in the 3rd external pipe connection outlet.
- 8. portable fluid depthkeeping Stratified Sampling device according to claim 1, it is characterised in that:Height of the height of first check valve (9.1) higher than second check valve (9.2) and the 3rd check valve (9.3) Degree;Second check valve (9.2) is different with the height of the 3rd check valve (9.3).
- 9. portable fluid depthkeeping Stratified Sampling device according to claim 8, it is characterised in that:First tube-in-tube (11.1), second tube-in-tube (11.2) and the 3rd tube-in-tube (11.3) are by the first pipe collar (7.1) the interior transverse shifting of first pipe collar (7.1) is constrained in;Second tube-in-tube (11.2) and the 3rd tube-in-tube (11.3) constrain in second pipe by the second pipe collar (7.2) Bind round (7.2) interior transverse shifting;Second pipe collar (7.2) is located at the solid lower section of first pipe collar (7.1).
- 10. portable fluid depthkeeping Stratified Sampling device according to any one of claims 1 to 9, it is characterised in that:Described one The top of body depthkeeping Stratified Sampling cabinet (1) can be around horizontal pivot center to lower folded.
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CN107843461A (en) * | 2017-11-13 | 2018-03-27 | 刘学浩 | A kind of portable fluid depthkeeping Stratified Sampling device |
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CN107843461A (en) * | 2017-11-13 | 2018-03-27 | 刘学浩 | A kind of portable fluid depthkeeping Stratified Sampling device |
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Effective date of registration: 20231127 Address after: 430000 No. 69, Guanggu Avenue, Donghu New Technology Development Zone, Wuhan, Hubei Patentee after: Wuhan Geological Survey Center of China Geological Survey (Central South Geological Science and Technology Innovation Center) Address before: No.69 Guanggu Avenue, Donghu New Technology Development Zone, Wuhan City, Hubei Province 430205 Patentee before: Liu Xuehao |