CN205353109U - Fluid monitoring station - Google Patents
Fluid monitoring station Download PDFInfo
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- CN205353109U CN205353109U CN201620085833.7U CN201620085833U CN205353109U CN 205353109 U CN205353109 U CN 205353109U CN 201620085833 U CN201620085833 U CN 201620085833U CN 205353109 U CN205353109 U CN 205353109U
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Abstract
The utility model provides a fluid monitoring station contains a fluid sampling box, a detection device, a sampling tube, a solenoid valve, at least one a storage bottle and a controller. The detection device fluidic monitoring numerical value among the fluid sampling box that is used for measurationing. Sampling tube intercommunication fluid sampling box receives solenoid valve control. It sets up in the exit end of sampling tube to store the bottle to store the fluid that the sampling tube flows. Controller and detection device and solenoid valve electric connection, wherein the controller judges whether unusual the monitoring numerical value that detection device measurationed is to trigger the solenoid valve and open when monitoring numerical value is unusual, make unusual fluid pour into into via the sampling tube and store the bottle.
Description
[technical field]
This utility model is relevant a kind of fluid inspection station, particularly a kind of fluid inspection station that can automatically store abnormal fluid.
[background technology]
The process of industry manufacture will necessarily produce waste water.In order to meet environmental regulation, just the monitoring index of waste water needs conformance with standard value to discharge.In order to monitor whether manufacturer meets environmental regulation, regulatory bodies also need the water quality monitoring water of releasing using as management foundation.Water of releasing in the past is to carry out pre-treatment control inspecting in the way of artificial sample chemical examination, but, artificial sample chemical examination is to belong to stochastical sampling, does not therefore have ageing, and cannot set up long-term observation data.Additionally, artificial sample chemical examination labor intensive, and water analysis somewhat expensive, it is not inconsistent economic benefit.
Relatively more feasible scheme is then for setting up the monitoring station of automatization in Water-quality Monitoring Points, to measure water quality data for a long time.Although automatic measurement can set up long-term observation data, but instrument exception cannot be got rid of completely or measurement numerical exception that other factors causes, now need to be aided with and artificial review to confirm the result of measurement.In view of this, how sampling water body when measuring numerical value and occurring abnormal is the target that current pole need to be made great efforts.
[utility model content]
This utility model provides a kind of fluid inspection station, it arranges a probe tube and an electromagnetic valve at sampling fluids case, and electromagnetic valve can be opened when measurement numerical value occurs abnormal with the fluid injection storage tube abnormal via probe tube sampling, so can automatically deposit abnormal fluid when measuring numerical value and occurring abnormal, using the foundation as the artificial sample reviewed and inspection.
The fluid inspection station of this utility model one embodiment comprises a sampling fluids case, a detecting device, a probe tube, an electromagnetic valve, at least one reservoir bottle and a controller.Sampling fluids case samples a fluid to be detected and measures space to the one of sampling fluids case.Detecting device has at least one sensor, and it is in order to measure a monitoring numerical value of the fluid in space.Probe tube is communicated to measurement space.Electromagnetic valve is arranged at probe tube, to control a sampling amount of probe tube.Reservoir bottle is arranged at below a sampling outlet of probe tube, to store the abnormal fluid that probe tube flows out.Controller is electrically connected with detecting device and electromagnetic valve, its middle controller judges that whether the monitoring numerical value that detecting device measures is abnormal, and export an abnormal signal when monitoring numerical exception to trigger electromagnetic valve unlatching, make abnormal fluid inject reservoir bottle via probe tube.
Appended graphic elaborate is coordinated below, when being easier to understand the purpose of this utility model, technology contents, feature and the effect reached thereof by specific embodiment.
[accompanying drawing explanation]
Fig. 1 is a schematic diagram, the fluid inspection station of display this utility model first embodiment.
Fig. 2 is a schematic diagram, the fluid inspection station of display this utility model the second embodiment.
Fig. 3 is a schematic diagram, the fluid inspection station of display this utility model the 3rd embodiment.
Fig. 4 is a schematic diagram, the fluid inspection station of display this utility model the 4th embodiment.
[symbol description]
1 fluid inspection station
11 sampling fluids casees
111 flow inlet
111P influent stream pipe
111V influent stream valve
112 first row outlets
112P the first discharge pipe
112V the first dump valve
113 spoilers
114 second row outlets
114P the second discharge pipe
114V the second dump valve
115 first inclined-planes
116 second inclined-planes
12 lids
20 detecting devices
21 sensors
30 controllers
41 probe tubes
42 electromagnetic valves
43 reservoir bottle
44 carriers
441 abnormal fluid outlets
45 driving mechanisms
50 communication units
60 moisture barrier devices
70 generator units
80 chillers
81 heat-insulated cavities
P inflow pump
SPi influent stream space
SPm measures space
[detailed description of the invention]
Hereinafter will be described each embodiment of the present utility model, and coordinate graphic illustratively.Except the plurality of detailed description, this utility model also can be performed in other embodiment widely, and the replacement easily of any described embodiment, amendment, equivalence change are included in scope of the present utility model, and are as the criterion with claim.In the description of description, in order to make reader that this utility model to have more complete understanding, it is provided that many specific detail;But, this utility model is likely under the premise of clipped or whole specific detail, still can implement.Moreover, it is well known that step or element be not described in details, to avoid this utility model is formed unnecessary restriction.In graphic, same or similar element will represent with same or like symbol.It is specifically intended that the graphic use being only signal, size that not representation element is actual or quantity, some details is likely to not draw completely, in the hope of graphic succinct.
Refer to Fig. 1, the fluid inspection station 1 of an embodiment of the present utility model comprises sampling fluids case 11, detecting device 20, probe tube 41, electromagnetic valve 42, at least one reservoir bottle 43 and a controller 30.The available inflow pump P of sampling fluids case 11 extracts fluid to be detected and measures space S Pm to the one of sampling fluids case 11.In an embodiment, sampling fluids case 11 has a flow inlet 111 and first row outlet 112.Fluid to be detected extracts with inflow pump P and introduces sampling fluids case 11 via influent stream pipe 111P, after measuring the monitoring numerical value of fluid, discharges via first row outlet 112 and the first discharge pipe 112P.It should be understood that an influent stream valve 111V can be arranged to control influent stream amount in influent stream pipe 111P.In like manner, in the first discharge pipe 112P, one first dump valve 112V can be set to control output.So, sampling fluids case 11 i.e. sampled fluid measure the monitoring numerical value of fluid serially.
In an embodiment, sampling fluids case 11 comprises a spoiler 113.Sampling fluids case 11 is divided into influent stream space S Pi and measures space S Pm by spoiler 113, wherein the flow inlet 111 of sampling fluids case 11 is communicated to influent stream space S Pi, the first row outlet 112 of sampling fluids case 11 is communicated to measurement space S Pm, and the height of spoiler 113 is lower than the Sidewall Height of sampling fluids case 11.So, when the liquid level of influent stream space S Pi is higher than spoiler 113, namely fluid can overflow across spoiler 113 and flow into measurement space S Pm.By fluid to be detected from influent stream space S Pi overflow to measuring space S Pm, it is possible to decrease measure the fluid fluctuation of space S Pm, so can obtain relatively stable measurement numerical value.In an embodiment, sampling fluids case 11 comprises second row outlet 114 and is communicated to influent stream space S Pi, to be expelled upon the fluid of influent stream space S Pi.It is connected with this second row outlet 114 it is understood that one second discharge pipe 114P can be arranged, and in the second discharge pipe 114P, one second dump valve 114V is set to control the output of the second discharge pipe 114P.
In an embodiment, the bottom of the measurement space S Pm of sampling fluids case 11 can comprise at least one first inclined-plane 115.According to this structure, Shen Dian can concentrate on the relative low points of the first inclined-plane R1 in the impurity measured bottom space S Pm or mud along the first inclined-plane R1, so can be easier to remove impurity or the mud of bottom.For example, first row exports the setting of 112 be located proximate to the relative low points on the first inclined-plane 115 and can discharge and measure impurity bottom space S Pm or mud and the suction discharged by fluid reduces impurity or Mud up-floating.Same, first row outlet 112 is arranged at the minimum point measured bottom space S Pm can avoid the situation of hydrops.
Same, the bottom of the influent stream space S Pi of sampling fluids case 11 can comprise at least one second inclined-plane 116.According to this structure, Shen Dian impurity bottom influent stream space S Pi or mud can concentrate on the relative low points on the second inclined-plane 116 along the second inclined-plane 116, so can be easier to remove impurity or the mud of bottom.It is understood that the relative low points that the setting of second row outlet 114 is located proximate to the second inclined-plane 116 can discharge the impurity bottom influent stream space S Pi or mud and the suction by fluid discharge reduces impurity or Mud up-floating.Same, second row outlet 114 minimum points being arranged at bottom influent stream space S Pi can avoid the situation of hydrops.
Detecting device 20 has at least one sensor 21, in order to measure the monitoring numerical value of the fluid in space S Pm.In an embodiment, sensor 21 measures the monitoring numerical value of the fluid of the measurement space S Pm of sampling fluids case 11 via the detection mouth of lid 12.For example, detecting device 20 can measure one or more index in pH value, suspended solid material (SuspendedSubstance, SS), electric conductivity, temperature, COD (ChemicalOxygenDemand, COD), heavy metal.
Probe tube 41 is communicated to the measurement space S Pm of sampling fluids case 11.Electromagnetic valve 42 is arranged at probe tube 41, to control a sampling amount of probe tube 41.Reservoir bottle 43 is then arranged at below a sampling outlet of probe tube 41, to store the fluid that probe tube 41 flows out.For example, open electromagnetic valve 42 and probe tube 41 can be made to draw the fluid measured in space S Pm, and inject reservoir bottle 43 to preserve fluid.In the embodiment shown in Fig. 1, probe tube 41 is the measurement space S Pm being communicated to sampling fluids case 11.But being not limited to this, refer to Fig. 2, in an embodiment, probe tube 41 can be communicated to the influent stream space S Pi of sampling fluids case 11, to sample the fluid in influent stream space S Pi.It is understood that fluid inspection station of the present utility model also can arrange many group probe tubes 41 and electromagnetic valve 42, with the fluid in the influent stream space S Pi of separately sampled sampling fluids case 11 and measurement space S Pm.
Controller 30 is electrically connected with detecting device 20 and electromagnetic valve 42.Controller 30 can determine whether that whether the monitoring numerical value that detecting device 20 measures is abnormal, and whether the monitoring numerical value measured according to detecting device 20 produces an abnormal signal extremely.For example, controller 30 exports an abnormal signal when the monitoring numerical value that detecting device 20 measures occurs abnormal and opens to trigger electromagnetic valve 42, so, fluid can inject reservoir bottle 43 to preserve abnormal fluid when monitoring numerical value occurs abnormal via probe tube 41, reviews for subsequent artefacts.Can avoiding additionally arranging the electronic components such as peristaltic pump it is understood that utilize electromagnetic valve 42 to control sampling abnormal fluid, therefore, fluid inspection station of the present utility model can not only reduce energy consumption and can reduce hardware and maintenance cost.
In an embodiment, fluid inspection station of the present utility model more comprises carrier 44 and a driving mechanism 45.Carrier 44 comprises multiple supporting region, and each supporting region can place a reservoir bottle 43.Driving mechanism 45 is connected with carrier 44, and driving mechanism 45 is electrically connected with controller 30 and is subject to controller 30 and controls.Driving mechanism 45 can drive carrier 44, makes different reservoir bottle 43 be positioned at below the sampling outlet of probe tube 41.For example, after one of them reservoir bottle 43 fills abnormal fluid, driving mechanism 45 can drive carrier 44, makes the reservoir bottle 43 of sky be positioned at below the sampling outlet of probe tube 41, to preserve abnormal fluid when monitoring next time numerical value occurs abnormal.In an embodiment, driving mechanism 45 can be that the actuated elements such as a motor and gear are to drive carrier 44 to rotate.
It is understood that probe tube 41 is likely to remain previous sampled fluid.In an embodiment, the opening time of electromagnetic valve 42 can be controlled, make probe tube 41 residual fluid after sampling reduce.Or, in an embodiment, carrier 44 more comprises an abnormal fluid outlet 441.Before sampling abnormal fluid, driving mechanism 45 can drive carrier 44, the abnormal fluid outlet 441 making carrier 44 is positioned at below sampling outlet, and now opens solenoid valve 42 can discharge the abnormal fluid of residual in probe tube 41, and discharges via the abnormal fluid outlet 441 of carrier 44.
Referring again to Fig. 1, the monitoring numerical value that detecting device 20 measures can be stored in storage device built-in in fluid inspection station 1, for instance memorizer, hard disk, CD, tape etc..Or, the monitoring numerical value that detecting device 20 measures also can be uploaded to the server of far-end.In an embodiment, fluid inspection station 1 of the present utility model more comprises a communication unit 50, and itself and controller 30 are electrically connected.The monitoring numerical value of fluid that detecting device 20 measures and abnormal signal can be sent to the server of far-end by communication unit 50.For example, communication unit 50 may utilize the modes such as wired area network, radio area network, Mobile Communications network and transmits the data server to far-end.
In order to save space, in an embodiment, the electronic installation such as detecting device 20 and controller 30 may be disposed at the top of sampling fluids case 11.Preferably, can arrange a moisture barrier device 60 between detecting device 20 electronic installation such as grade and sampling fluids case 11.Moisture barrier device 60 can prevent dampness from entering in detecting device 20 electronic installation such as grade, to avoid dampness to cause electronic installation to damage, and then increases the reliability at fluid inspection station 1 and reduces maintenance frequency.
In an embodiment, fluid inspection station 1 of the present utility model more comprises a generator unit 70, and itself and controller 30 are electrically connected.Generator unit 70 can self-generating, to produce the power supply needed for fluid inspection station 1.For example, generator unit 70 can be solar module, wind-driven generator, hydroelectric generator or above combination.
Refer to Fig. 3, in an embodiment, fluid inspection station of the present utility model more comprises a chiller 80.Chiller 80 can cool down reservoir bottle 43 to predetermined temperature, to avoid the abnormal fluid of storage to make the monitoring numerical value of abnormal fluid change because of high ambient temperature or microbial reproduction.For example, chiller 80 can cool down carrier 44 or pass into coolant, for instance frozen water, to cool down reservoir bottle 43.Or, refer to Fig. 4, in an embodiment, carrier 44 is positioned in a heat-insulated cavity 81, and chiller 80 controls temperature in heat-insulated cavity 81 to a predetermined temperature, so can reduce the temperature of reservoir bottle 43 to predetermined temperature.
Summary, fluid inspection of the present utility model stands in sampling fluids case and arranges a probe tube and an electromagnetic valve, and electromagnetic valve can be opened when measurement numerical value occurs abnormal with the fluid injection storage tube abnormal via probe tube sampling, so can automatically deposit abnormal fluid when measuring numerical value and occurring abnormal, using the foundation as the artificial sample reviewed and inspection.
Embodiment described above is only for technological thought of the present utility model and feature are described, its purpose will appreciate that the content of this utility model and implements according to this making those skilled in the art, when can not with restriction the scope of the claims of the present utility model, namely the equalization generally made according to the spirit that this utility model is disclosed changes or modifies, and must be encompassed in the scope of the claims of the present utility model.
Claims (11)
1. a fluid inspection station, it is characterised in that comprise:
One sampling fluids case, it samples a fluid to be detected and measures space to the one of this sampling fluids case;
One detecting device, it has at least one sensor, in order to measure a monitoring numerical value of this fluid in this measurement space;
One probe tube, it is communicated to this sampling fluids case;
One electromagnetic valve, it is arranged at this probe tube, to control a sampling amount of this probe tube;
At least one reservoir bottle, it is arranged at below a sampling outlet of this probe tube, to store the abnormal fluid that this probe tube flows out;And
One controller, it is electrically connected with this detecting device and this electromagnetic valve, wherein this controller judges that whether this monitoring numerical value that this detecting device measures is abnormal, and export an abnormal signal when this monitoring numerical exception to trigger the unlatching of this electromagnetic valve, make this abnormal fluid inject this reservoir bottle via this probe tube.
2. fluid inspection station as claimed in claim 1, it is characterised in that more comprise:
One carrier, it comprises multiple supporting region, and this supporting region of each of which places this reservoir bottle;And
One driving mechanism, it is electrically connected with this controller and is connected with this carrier, and wherein this driving mechanism is subject to the control of this controller to drive this carrier, makes this reservoir bottle of sky be positioned at below this sampling outlet.
3. fluid inspection station as claimed in claim 2, it is characterized in that, this carrier more comprises an abnormal fluid outlet, and in discharging this probe tube during this abnormal fluid of residual, this driving mechanism drives this carrier, makes this abnormal fluid outlet be positioned at below this sampling outlet.
4. fluid inspection station as claimed in claim 1, it is characterised in that more comprise:
One chiller, it is in order to cool down this reservoir bottle to a predetermined temperature.
5. fluid inspection station as claimed in claim 1, it is characterised in that the bottom in this measurement space comprises at least one first inclined-plane.
6. fluid inspection station as claimed in claim 1, it is characterised in that this sampling fluids case comprises a spoiler, and this sampling fluids case is divided into an influent stream space and this measurement space by it, and this fluid is to measure from this influent stream space overflow to this measurement space.
7. fluid inspection station as claimed in claim 6, it is characterised in that this probe tube be communicated to this influent stream space of this sampling fluids case and this measurement space at least one.
8. fluid inspection station as claimed in claim 6, it is characterised in that the bottom in this influent stream space comprises at least one second inclined-plane.
9. fluid inspection station as claimed in claim 1, it is characterised in that more comprise:
One communication unit, it is electrically connected with this controller, in order to transmit this monitoring numerical value of this fluid and this abnormal signal to a server.
10. fluid inspection station as claimed in claim 1, it is characterised in that more comprise:
One generator unit, it is in order to produce power supply required when this fluid inspection station operates.
11. fluid inspection station as claimed in claim 1, it is characterised in that this detecting device and this controller are arranged at the top of this sampling fluids case, and arrange a moisture barrier device between this detecting device and this controller and this sampling fluids case.
Priority Applications (1)
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CN201620085833.7U CN205353109U (en) | 2016-01-28 | 2016-01-28 | Fluid monitoring station |
Applications Claiming Priority (1)
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CN201620085833.7U CN205353109U (en) | 2016-01-28 | 2016-01-28 | Fluid monitoring station |
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CN205353109U true CN205353109U (en) | 2016-06-29 |
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CN201620085833.7U Active CN205353109U (en) | 2016-01-28 | 2016-01-28 | Fluid monitoring station |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107015012A (en) * | 2016-01-28 | 2017-08-04 | 台湾欧多贝斯股份有限公司 | Fluid inspection station |
CN109444108A (en) * | 2018-12-26 | 2019-03-08 | 中国原子能科学研究院 | Flow cell |
-
2016
- 2016-01-28 CN CN201620085833.7U patent/CN205353109U/en active Active
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107015012A (en) * | 2016-01-28 | 2017-08-04 | 台湾欧多贝斯股份有限公司 | Fluid inspection station |
CN109444108A (en) * | 2018-12-26 | 2019-03-08 | 中国原子能科学研究院 | Flow cell |
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