CN203164193U - Continuous monitoring system for emission of flue gas form mercury - Google Patents
Continuous monitoring system for emission of flue gas form mercury Download PDFInfo
- Publication number
- CN203164193U CN203164193U CN 201320136100 CN201320136100U CN203164193U CN 203164193 U CN203164193 U CN 203164193U CN 201320136100 CN201320136100 CN 201320136100 CN 201320136100 U CN201320136100 U CN 201320136100U CN 203164193 U CN203164193 U CN 203164193U
- Authority
- CN
- China
- Prior art keywords
- mercury
- peristaltic pump
- links
- reactor
- gas
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn - After Issue
Links
Images
Landscapes
- Sampling And Sample Adjustment (AREA)
Abstract
The utility model relates to a continuous monitoring system for emission of flue gas form mercury. The continuous monitoring system comprises a sampling probe, a smoke dust filter, a reactor, a gas-water separating device, a mercury measuring device, a jet flow device and an air compressor which are connected in sequence through a pipeline, wherein the reactor is connected with a first container filled with a divalent mercury adsorption solution through a first peristaltic pump, the reactor is connected with a second container filled with divalent mercury reducing solution through a second peristaltic pump, the reactor is connected with a liquid waste barrel through a third peristaltic pump, the gas-water separating device is connected with the liquid waste barrel through a fourth peristaltic pump, and the sampling device, the first peristaltic pump, the second peristaltic pump, the third peristaltic pump, the fourth peristaltic pump, the mercury measuring device, the jet flow device and the air compressor are electrically connected with a control circuit, respectively. The continuous monitoring system provided by the utility model is in a simple structure, few reactors are adopted, and the utilized chemical reagent is nontoxic and harmless, thereby avoiding environmental pollution and guaranteeing high reliability, and the continuous monitoring system is capable of realizing online automatic continuous monitoring, improving the working efficiency and the measuring precision and lowering the cost.
Description
Technical field
The utility model relates to a kind of measuring system to mercury content in the flue gas, relates in particular to the flue gas form mercury emissions continuous monitor system of a kind of convenient test, reliability height and test environmental protection.
Background technology
Mercury, especially methyl mercury have great toxicity, can cause great harm to humans and animals, can cause irreversible infringement to nervous system.The residence time of nonvalent mercury in atmosphere reaches 0.5~2 year, can also move in the atmosphere medium and long distance, thereby cause global mercury pollution.
Coal is the main energy sources of China, and coal-fired yearly consumption is huge.The form of mercury is mainly discharged with the form of gas phase divalence mercury and gas phase nonvalent mercury in the flue gas of discharging behind the coal burning.The mercury of each form has its unique physicochemical property, and therefore, their discharging, propagation, deposition characteristics and method for catching are different.The concentration of mercury can be understood enterprise's coal-fired flue-gas mercury emissions situation at any time in the test flue gas, provide reliable data for exploring coal-fired flue-gas mercury control technology and formulating the discharging of regulation limitations mercury pollution, thereby reduce the influence that mercury pollution causes human health and ball ecological environment.
Mercury concentration in the test coal-fired flue-gas, the external classical way that adopts is Ontario method, Ontario method flue gas mercury test macro is mainly by the stopple coupon that links to each other successively, smoke filter and eight absorption bottles constitute, eight absorption bottles place ice bath, wherein in three absorption bottles in front Klorvess Liquid is housed, be used for absorbing divalence mercury, in the 4th absorption bottle nitric acid and hydrogen peroxide are housed, be used for absorbing nonvalent mercury, the 5th, in the 6th and the 7th absorption bottle potassium permanganate sulfuric acid solution is housed all, also be used for absorbing nonvalent mercury, in last absorption bottle discolour silica gel be housed, be used for absorbing the water vapour of flue gas.Sampling also will be cleared up the absorption liquid sample in each absorption bottle after finishing, and the hydrochloric acid solution with stannous chloride reduces then, distinguishes the mercury concentration in the working sample at last.Therefore, this method of testing has the following disadvantages: eight absorption bottles need consume a large amount of chemical reagent, and cost is higher; Use the chemical reagent of poisonous, harmful, severe corrosive in a large number, contaminated environment; Faults such as leakage easily take place in the system architecture complexity, and reliability is low; The sample collection capacity is more, bigger, and test process can only manual operations, can not on-line automaticization continuous monitoring, and work efficiency is lower, also influences measuring accuracy.
Summary of the invention
The technical matters that the utility model mainly solves original flue gas mercury emissions concentration measurement system complex structure, easily leaks, reliability is low; A kind of flue gas form mercury emissions continuous monitor system is provided, and it is simple in structure, and difficult the leakage improved the reliability of monitoring.
The utility model solves original flue gas mercury emissions concentration measurement system simultaneously need gather a large amount of samples, and test process can only manual operations, can not on-line automaticization continuous monitoring, and inefficiency also influences the technical matters of measuring accuracy; A kind of flue gas form mercury emissions continuous monitor system is provided, and its sample collection capacity is few, gathers and the test process full automation, realizes the continuous monitoring of on-line automaticization of flue gas mercury emissions concentration, and high efficiency also improves measuring accuracy.
The utility model solves original flue gas mercury emissions concentration measurement system again need consume the chemical reagent of poisonous, harmful, severe corrosive, both contaminated environment, cost technical problems of high again in a large number; A kind of flue gas form mercury emissions continuous monitor system is provided, and it needs to use a small amount of chemical reagent, and used chemical reagent is nontoxic, harmless, does not both pollute the environment, and reduces cost again.
Above-mentioned technical matters of the present utility model is mainly solved by following technical proposals: the utility model comprises sampler, reactor, gas and water separator, the mercury measurement device, first container, second container and control circuit, sampler links to each other with reactor by pipeline, reactor links to each other with gas and water separator by pipeline again, gas and water separator links to each other with the mercury measurement device by pipeline again, first container links to each other with described reactor through first peristaltic pump, second container links to each other with described reactor through second peristaltic pump, divalence mercury adsorbent solution is housed in first container, divalence mercury reducing solution is housed, described sampler in second container, first peristaltic pump, second peristaltic pump and mercury measurement device are electrically connected with described control circuit respectively.Gas and water separator is an airtight container.During monitoring, by first peristaltic pump divalence mercury adsorbent solution in first container is extracted in the reactor, sampler is gathered flue gas from tested flue, the flue gas that collects enters reactor, divalence mercury adsorbent solution in the reactor absorbs the divalence mercury in the flue gas, do not had mercuric flue gas to enter gas and water separator more then, entered the mercury measurement device again after removing water vapour, measured the concentration of nonvalent mercury in the flue gas by the mercury measurement device.Then by second peristaltic pump divalence mercury reducing solution in second container is extracted in the reactor, the divalence mercury of staying in the reactor is reduced to nonvalent mercury, the gas that has nonvalent mercury enters gas and water separator again, enter the mercury measurement device again after removing water vapour, measure the concentration of nonvalent mercury in this gas by the mercury measurement device, this concentration is mercuric concentration in the former flue gas.Like this, nonvalent mercury and the mercuric concentration in the discharged flue gas has all obtained monitoring in the tested flue.Because the mercury measurement device can only be measured nonvalent mercury, so the divalence mercury in the flue gas must be reduced into nonvalent mercury, could measure.This monitoring system is only used a reactor and a gas and water separator, and is simple in structure, reduced to leak the possibility that takes place, and improves reliability, low cost of manufacture, and operating cost is lower.Sampler, first peristaltic pump, second peristaltic pump and mercury measurement device be the automatic control of controlled circuit all, when start, when stop, finished work schedule in the control circuit, therefore whole test process need not be hand-manipulated, automatically finished by system entirely, be implemented in the line automation continuous monitoring, and to smoke sampling once, only need before and after the mercury measurement device two samples are measured, just can measure the concentration of form mercury in the flue gas, increase work efficiency greatly, also improve measuring accuracy.
As preferably, described flue gas form mercury emissions continuous monitor system comprises a refrigerating plant, and described reactor and gas and water separator are arranged in the refrigerating plant.Refrigerating plant generally adopts semiconductor cooling device, also can adopt other refrigeration plants certainly, as also reactor and gas and water separator being positioned in the ice bath.Stablize the chemical property of chemical reagent in flue gas and the reactor, be conducive to gas and water separator and remove water vapour in the flue gas, make the measurement data of mercury measurement device more reliable, more accurate.
As preferably, the divalence mercury adsorbent solution that is contained in described first container is Klorvess Liquid, is contained in the composite reduction solution of divalence mercury reducing solution for being made up of PH correctives and reductive agent in described second container.The technical program is only used two kinds of chemical reagent, and the use amount that significantly reduces chemical reagent is few, reduce cost, and used chemical reagent is nontoxic, harmless, does not also have severe corrosive, therefore, does not pollute the environment the test process environmental protection.
As preferably, described flue gas form mercury emissions continuous monitor system comprises waste liquid barrel, the 3rd peristaltic pump and the 4th peristaltic pump, described reactor links to each other with waste liquid barrel through the 3rd peristaltic pump, described gas and water separator links to each other with waste liquid barrel through the 4th peristaltic pump, and the 3rd peristaltic pump, the 4th peristaltic pump are electrically connected with described control circuit respectively.After nonvalent mercury was measured, the waste liquid in the gas and water separator was extracted in the waste liquid barrel by the 4th peristaltic pump, empties gas and water separator, improved the effect that gas and water separator is removed water vapour next time; After the divalence mercury measurement was good, the waste liquid in the reactor was extracted in the waste liquid barrel by the 3rd peristaltic pump, and the waste liquid in the gas and water separator is extracted in the waste liquid barrel by the 4th peristaltic pump, emptied reactor and gas and water separator, improved the accuracy of next time measuring.
As preferably, described sampler comprises sampling probe, smoke filter and air extractor, sampling probe links to each other with smoke filter, smoke filter links to each other by the air intake opening of trace pipe road and described reactor, the gas outlet of reactor links to each other by the air intake opening of pipeline and described gas and water separator, the gas outlet of gas and water separator links to each other by the air intake opening of pipeline with described mercury measurement device, and the gas outlet of mercury measurement device links to each other with described air extractor.Sampling probe, smoke filter, reactor, gas and water separator and mercury measurement device link to each other successively and constitute the gas passage of flowing through, air extractor is bled, and the flue gas in the tested flue enters sampling probe, the dust in smoke filter elimination flue gas, the trace pipe road of flowing through enters in the reactor.The controlled circuit control of air extractor, sampling is convenient, is finished automatically by system.
As preferably, described air extractor comprises fluidic device and air compressor machine, and air compressor machine links to each other with fluidic device, and fluidic device links to each other with the gas outlet of described mercury measurement device again, and described fluidic device, air compressor machine are electrically connected with described control circuit respectively.Air compressor machine produces pressurized air, and the blowback source of the gas is provided, and under the cooperating of fluidic device, produces draft, and the flue gas in the tested flue is extracted in the sampling probe.Fluidic device can adopt the heated jet device.
The beneficial effects of the utility model are: 1) monitoring system is simple in structure, only needs a reactor and a gas and water separator, has reduced the possibility that the device fault generation is leaked, and improves reliability; 2) each monitoring only needs to use nontoxic, harmless, the non-corrosive chemical reagent of minute quantity, avoids pollution on the environment; 3) low cost of manufacture, operating cost is lower; 4) monitor the sample sampling quantity seldom, collection and measurement are completely implemented at the line automation operation, have broken away from manual operations, increase work efficiency greatly, also improve measuring accuracy at every turn.
Description of drawings
Fig. 1 is a kind of system of the present utility model syndeton block diagram.
1. reactors among the figure, 2. gas and water separator, 3. mercury measurement device, 4. first container, 5. second container, 6. first peristaltic pump, 7. second peristaltic pump, 8. refrigerating plant, 9. waste liquid barrel, 10. the 3rd peristaltic pump, 11. the 4th peristaltic pumps, 12. sampling probes, 13. smoke filter, 14. trace pipe roads, 15. fluidic devices, 16. air compressor machine, 17. tested flues.
Embodiment
Below by embodiment, and by reference to the accompanying drawings, the technical solution of the utility model is described in further detail.
Embodiment: a kind of flue gas form mercury emissions continuous monitor system of present embodiment, as shown in Figure 1, comprise the sampler that constituted by sampling probe 12, smoke filter 13, fluidic device 15 and air compressor machine 16 and reactor 1, gas and water separator 2, mercury measurement device 3, refrigerating plant 8, first container 4, second container 5, waste liquid barrel 9, first peristaltic pump 6, second peristaltic pump 7, the 3rd peristaltic pump 10, the 4th peristaltic pump 11 and control circuit.Sampling probe 12 is installed in the tested flue 17, sampling probe 12 links to each other with smoke filter 13, smoke filter 13 links to each other by the air intake opening of trace pipe road 14 and reactor 1, the gas outlet of reactor 1 links to each other by the air intake opening of pipeline with gas and water separator 2, the gas outlet of gas and water separator 2 links to each other by the air intake opening of pipeline with mercury measurement device 3, the gas outlet of mercury measurement device 3 links to each other with fluidic device 15, and fluidic device 15 links to each other with air compressor machine 16.Sampling probe 12, smoke filter 13, reactor 1, gas and water separator 2 and mercury measurement device 3 link to each other successively and constitute the flue gas passage of flowing through.Reactor 1 and gas and water separator 2 are arranged in the refrigerating plant 8, and this refrigerating plant is semiconductor cooling device.First container 4 links to each other by the import of pipeline with first peristaltic pump 6, the outlet of first peristaltic pump 6 links to each other with the opening that is positioned at reactor 1 bottom by pipeline, second container 5 links to each other by the import of pipeline with second peristaltic pump 7, and the outlet of second peristaltic pump 7 also links to each other with the opening that is positioned at reactor 1 bottom by pipeline.Divalence mercury adsorbent solution is housed in first container 4, and this divalence mercury adsorbent solution is Klorvess Liquid, and divalence mercury reducing solution is housed in second container 5, and this divalence mercury reducing solution is the composite reduction solution of being made up of PH correctives and reductive agent.Stretched into a waste liquid in the waste liquid barrel 9 and entered pipe, the opening that is positioned at reactor 1 bottom also links to each other by the import of pipeline with the 3rd peristaltic pump 10, and the outlet of the 3rd peristaltic pump 10 enters pipe by pipeline and waste liquid and links to each other.An opening is also arranged at the bottom of gas and water separator 2, and this opening links to each other by the import of pipeline with the 4th peristaltic pump 11, and the outlet of the 4th peristaltic pump 11 enters pipe with waste liquid and links to each other.Fluidic device 15, air compressor machine 16, first peristaltic pump 6, second peristaltic pump 7, the 3rd peristaltic pump 10, the 4th peristaltic pump 11 and mercury measurement device 3 link to each other with control circuit by cable respectively.
Observation process is as follows:
1, under the control of control circuit, first peristaltic pump starts, with Klorvess Liquid (the divalence mercury adsorbent solution) injecting reactor that is contained in first container;
2, under the control of control circuit, air compressor machine produces pressurized air, fluidic device starts, produce draft, process is by sampling probe, smoke filter, reactor, gas and water separator and the mercury measurement device gas that the constitutes passage of flowing through that links to each other successively, flue gas in the tested flue is extracted in the sampling probe, the flue gas that the collects smoke filter of flowing through again enters reactor, in reactor, divalence mercury in the flue gas is absorbed by the Klorvess Liquid in the reactor, be absorbed mercuric flue gas and entered gas and water separator again, gas and water separator is removed the water vapour in the flue gas, the flue gas of having removed water vapour enters the mercury measurement device again, is gone out the concentration of nonvalent mercury in the flue gas by the mercury measurement measurement device;
3, under the control of control circuit, the 4th peristaltic pump starts, and the waste liquid in the gas and water separator is entered in the waste liquid barrel;
4, under the control of control circuit, second peristaltic pump starts, with composite reduction solution (the divalence mercury reducing solution) injecting reactor that is contained in second container, in reactor, the divalence mercury that is chlorinated the potassium solution absorption is reduced into nonvalent mercury, the gas that has nonvalent mercury enters gas and water separator again, gas and water separator is removed the water vapour in this gas, the gas of having removed water vapour enters the mercury measurement device again, go out the concentration of nonvalent mercury in this gas by the mercury measurement measurement device, the concentration of this nonvalent mercury is mercuric concentration in the former flue gas;
5, under the control of control circuit, the 3rd peristaltic pump and the 4th peristaltic pump start, and by the 3rd peristaltic pump the waste liquid in the reactor are entered in the waste liquid barrel, by the 4th peristaltic pump the waste liquid in the gas and water separator are entered in the waste liquid barrel.
So far, finish a flue gas form mercury emissions monitoring, repeating step 1~5 can carry out continuous monitoring to the flue gas form mercury emissions in the tested flue.
Claims (6)
1. flue gas form mercury emissions continuous monitor system, it is characterized in that comprising sampler, reactor (1), gas and water separator (2), mercury measurement device (3), first container (4), second container (5) and control circuit, sampler links to each other with reactor (1) by pipeline, reactor (1) links to each other with gas and water separator (2) by pipeline again, gas and water separator (2) links to each other with mercury measurement device (3) by pipeline again, first container (4) links to each other with described reactor (1) through first peristaltic pump (6), second container (5) links to each other with described reactor (1) through second peristaltic pump (7), divalence mercury adsorbent solution is housed in first container (4), divalence mercury reducing solution is housed, described sampler in second container (5), first peristaltic pump (6), second peristaltic pump (7) and mercury measurement device (3) are electrically connected with described control circuit respectively.
2. a kind of flue gas form mercury emissions continuous monitor system according to claim 1 is characterized in that comprising a refrigerating plant (8), and described reactor (1) and gas and water separator (2) are arranged in the refrigerating plant (8).
3. a kind of flue gas form mercury emissions continuous monitor system according to claim 1, it is characterized in that the divalence mercury adsorbent solution that is contained in described first container (4) is Klorvess Liquid, be contained in the composite reduction solution of divalence mercury reducing solution for being formed by PH correctives and reductive agent in described second container (5).
4. according to claim 1 or 2 or 3 described a kind of flue gas form mercury emissions continuous monitor systems, it is characterized in that comprising waste liquid barrel (9), the 3rd peristaltic pump (10) and the 4th peristaltic pump (11), described reactor (1) links to each other with waste liquid barrel (9) through the 3rd peristaltic pump (10), described gas and water separator (2) links to each other with waste liquid barrel (9) through the 4th peristaltic pump (11), and the 3rd peristaltic pump (10), the 4th peristaltic pump (11) are electrically connected with described control circuit respectively.
5. according to claim 1 or 2 or 3 described a kind of flue gas form mercury emissions continuous monitor systems, it is characterized in that described sampler comprises sampling probe (12), smoke filter (13) and air extractor, sampling probe (12) links to each other with smoke filter (13), smoke filter (13) links to each other by the air intake opening of trace pipe road (14) and described reactor (1), the gas outlet of reactor (1) links to each other by the air intake opening of pipeline with described gas and water separator (2), the gas outlet of gas and water separator (2) links to each other by the air intake opening of pipeline with described mercury measurement device (3), and the gas outlet of mercury measurement device (3) links to each other with described air extractor.
6. a kind of flue gas form mercury emissions continuous monitor system according to claim 5, it is characterized in that described air extractor comprises fluidic device (15) and air compressor machine (16), air compressor machine (16) links to each other with fluidic device (15), fluidic device (15) links to each other with the gas outlet of described mercury measurement device (3) again, and described fluidic device (15), air compressor machine (16) are electrically connected with described control circuit respectively.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201320136100 CN203164193U (en) | 2013-03-22 | 2013-03-22 | Continuous monitoring system for emission of flue gas form mercury |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201320136100 CN203164193U (en) | 2013-03-22 | 2013-03-22 | Continuous monitoring system for emission of flue gas form mercury |
Publications (1)
Publication Number | Publication Date |
---|---|
CN203164193U true CN203164193U (en) | 2013-08-28 |
Family
ID=49025370
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN 201320136100 Withdrawn - After Issue CN203164193U (en) | 2013-03-22 | 2013-03-22 | Continuous monitoring system for emission of flue gas form mercury |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN203164193U (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103293326A (en) * | 2013-03-22 | 2013-09-11 | 杭州超距科技有限公司 | A mercury-containing fumes emission continuous monitoring system and a monitoring method thereof |
CN104535725A (en) * | 2014-12-31 | 2015-04-22 | 力合科技(湖南)股份有限公司 | Monitoring system |
-
2013
- 2013-03-22 CN CN 201320136100 patent/CN203164193U/en not_active Withdrawn - After Issue
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103293326A (en) * | 2013-03-22 | 2013-09-11 | 杭州超距科技有限公司 | A mercury-containing fumes emission continuous monitoring system and a monitoring method thereof |
CN103293326B (en) * | 2013-03-22 | 2014-02-05 | 杭州超距科技有限公司 | Mercury-containing fumes emission continuous monitoring system and monitoring method thereof |
CN104535725A (en) * | 2014-12-31 | 2015-04-22 | 力合科技(湖南)股份有限公司 | Monitoring system |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN103293326B (en) | Mercury-containing fumes emission continuous monitoring system and monitoring method thereof | |
CN207248581U (en) | A kind of sampling system for being used to measure escape ammonia density total in flue gas | |
CN109959538B (en) | Device and method for testing sulfur trioxide and condensable particles emitted by fixed pollution source | |
CN103149271A (en) | Method for simultaneously measuring heavy metals with different forms in coal-fired flue gas | |
CN201628641U (en) | Continuous automatic sampling device for monitoring water quality | |
CN204043965U (en) | A kind of gas mercury comprehensively sampling device | |
CN207007705U (en) | A kind of flue gas inspection device for ship tail gas desulfurizer | |
CN106568897A (en) | Device and measuring method used for continuous measuring of content of mercury of different valence states in flue gas | |
CN106706375A (en) | Device and method for performing liquid drop sampling and measurement in wet flue gas | |
CN203164193U (en) | Continuous monitoring system for emission of flue gas form mercury | |
CN204632227U (en) | A kind of atmosphere environment supervision and Treatment process comprehensive training system | |
CN103680647A (en) | Fuel sipping inspection environmental simulation device | |
CN204287105U (en) | A kind of karl Fischer moisture teller adds pumping equipment automatically | |
CN206838686U (en) | Esr analyzer cleaning device and the Wei Shi esr analyzers comprising the cleaning device | |
CN206818487U (en) | A kind of Multifunctional tobacco bicycle pump automatic sampling system | |
CN204065045U (en) | Denitration demercuration catalyst activity assessment device | |
CN205003004U (en) | Automatic calibration device of coal fired power plant flue gas mercury measuring apparatu | |
CN208366946U (en) | The device that gas is analyzed in a kind of pair of high-sulfur atmosphere | |
CN215953122U (en) | Multipurpose flue gas sampling system | |
CN109387595B (en) | Continuous monitoring of SO 3 Apparatus and method for concentration of (a) | |
CN209280659U (en) | Continuous monitoring SO3Concentration device | |
CN105203355A (en) | Coke oven gas sampling device and method | |
CN103884821B (en) | A kind of thermal power plant generating tail gas nitrogen oxide component measurement mechanism and measuring method thereof | |
CN203772611U (en) | Mixer for measuring flue gas ingredients of power station boiler | |
CN209117651U (en) | A kind of SO3Concentration on-line measuring device |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
AV01 | Patent right actively abandoned |
Granted publication date: 20130828 Effective date of abandoning: 20140205 |
|
RGAV | Abandon patent right to avoid regrant |