CN203350182U - Flue gas denitrification monitoring system - Google Patents

Abstract

The utility model provides a flue gas denitrification monitoring system. The system comprises a sampling device, a pretreating device, a gas chamber and an analyzer and further comprises a heating device and an isolating device, wherein the heating device is used for heating the pretreating device, the gas chamber and a pipeline connecting the pretreating device with the gas chamber; the isolating device is used for providing gases; the gases enter the gas chamber via gas inlets, form an isolation area on the side, adjacent to flue gases, of an optical part and then are exhausted from exhaust ports. The system has the advantages of quickness in detection, high precision, long continuous working time and the like.

Description

The denitrating flue gas monitoring system

Technical field

The utility model relates to gas-monitoring, particularly the denitrating flue gas monitoring system.

Background technology

In flue gas SCR (or SNCR) technique denitration technology, utilize ammonia to be reacted with oxides of nitrogen, generate water and nitrogen, thus meet the requirement of environmental protection.In order to control the amount that sprays into the raw material ammonia, prevent too much ammonia and ammonia gas react from generating solid matter and stop up air preheater or the optical window of rear end, need the escape ammonia in monitoring denitration outlet flue, form the ammonia spraying amount of closed-loop control denitrification apparatus.

In the monitoring of above-mentioned denitrating flue gas escape ammonia, operating mode is comparatively severe:

1, in flue gas, dust content is very large, reaches 30-50mg/m ³.In detection for the sampling pretreatment mode, high dust is easy to stop up probe, goes back severe contamination analysis meter, measuring cell.

2, in flue gas, water cut is high, if detect ammonia by the traditional analysis instrument, detection can be subject to the interference of water, and accuracy of detection is low.

Based on above-mentioned bad working environments; someone proposes to improve the precision of smoke filtration to reduce the dust content in flue gas; analysis meter, measuring cell have so effectively been protected; but greatly improved (extremely susceptible to plugging) and filtered the maintenance of popping one's head in; reduced the serviceable life of filtering probe; reduce the time of continuous monitoring simultaneously, had a strong impact on the closed-loop control of denitrating technique.

For these reasons, prior art be can't meet fast, the demand of flue gas under high precision, continuous monitoring denitration environment, can't reach the environment protection standard requirement.Therefore, realize in the denitration field continuously, high precision, fast monitored flue gas be a technical barrier in the urgent need to address.

The utility model content

In order to solve the deficiency in above-mentioned prior art scheme, the utility model provides a kind of denitrating flue gas monitoring system, solved in the denitrating flue gas field high dust, high-moisture and be difficult to the technical barrier detected, thereby realized in the denitration field continuously, the utility model purpose of composition in high precision, fast monitored flue gas.

The purpose of this utility model is achieved through the following technical solutions:

A kind of denitrating flue gas monitoring system, described denitrating flue gas monitoring system comprises sampler, pretreatment unit, gas compartment and analysis meter; Described denitrating flue gas monitoring system further comprises:

Heating arrangement, described heating arrangement is for heating the pipeline of described pretreatment unit, gas compartment, connection pretreatment unit and gas compartment;

Spacer assembly, described spacer assembly is for providing gas, this gas enters in described gas compartment from air intake opening, in a side of the contiguous flue gas of optics, forms isolated area, after from exhausr port Exhaust Gas chamber.

According to above-mentioned denitrating flue gas monitoring system, preferably, the both sides of described gas compartment arrange optical window, and at least 2 air intake openings are separately positioned on the side that described optical window closes on flue gas.

According to above-mentioned denitrating flue gas monitoring system, preferably, described flue gas enters described gas compartment between described air intake opening.

According to above-mentioned denitrating flue gas monitoring system, preferably, described exhausr port is arranged on the gas compartment between described air intake opening.

According to above-mentioned denitrating flue gas monitoring system, preferably, described exhausr port is at least 2, is separately positioned on described air intake opening and flue gas and enters between the gas compartment position.

According to above-mentioned denitrating flue gas monitoring system, preferably, the temperature of described pretreatment unit, pipeline and gas compartment is over 200 ℃.

According to above-mentioned denitrating flue gas monitoring system, preferably, described analysis meter is the laser spectral analysis instrument.

Compared with prior art, the beneficial effect the utlity model has is:

1, the gas barrier technology has creatively been proposed, keep apart optics and flue gas, farthest avoided the dust pollution optics in the flue gas, improved the tolerance of gas compartment to dust, so the filtrator that precision is lower is set in pre-service to be got final product, reduce the maintenance of filtrator, improved serviceable life, improved the stream time of system simultaneously.

2, flue gas was heated to always surpasses 200 ℃ before the Exhaust Gas chamber, made the moisture in flue gas keep gaseous state, had lowered the impact of moisture on detecting, and had correspondingly improved accuracy of detection.The selection absorption line that the laser spectral analysis technology adopts is ideally got rid of again the interference of water.

The accompanying drawing explanation

With reference to accompanying drawing, disclosure of the present utility model will be easier to understand.Those skilled in the art easily are understood that: these accompanying drawings are only for illustrating the technical solution of the utility model, and not are intended to protection domain of the present utility model is construed as limiting.In figure:

Fig. 1 is the structure diagram according to the denitrating flue gas monitoring system of the utility model embodiment 1;

Fig. 2 is the process flow diagram according to the denitrating flue gas monitoring method of the utility model embodiment 1.

Embodiment

Fig. 1,2 and following declarative description optional embodiment of the present utility model how to implement and to reproduce the utility model with instruction those skilled in the art.In order to instruct technical solutions of the utility model, simplified or omitted some conventional aspects.Those skilled in the art should understand that the modification that is derived from these embodiments or replace will be in scope of the present utility model.Those skilled in the art should understand that following characteristics can combine to form a plurality of modification of the present utility model in every way.Thus, the utility model is not limited to following optional embodiment, and only by claim and their equivalent, is limited.

Embodiment 1:

Fig. 1 has schematically provided the structure diagram of the denitrating flue gas monitoring system of the utility model embodiment, and as shown in Figure 1, described denitrating flue gas monitoring system comprises:

Sampler, pretreatment unit 2, gas compartment and analysis meter, these parts are all the state of the art, do not repeat them here.Sampler is arranged on flue 1.

Heating arrangement, described heating arrangement is for heating the pipeline 3 of described pretreatment unit 2, gas compartment, connection pretreatment unit 2 and gas compartment; Preferably, by heating, make flue-gas temperature in pretreatment unit 2, pipeline 3 and gas compartment over 200 ℃.

Spacer assembly, described spacer assembly is for providing gas, this gas enters in described gas compartment from air intake opening 61,62, a side at the contiguous flue gas of optics forms isolated area, keep apart optics and flue gas, at utmost avoided the dust pollution optics in the flue gas, improved the tolerance of gas compartment to dust, gas is from exhausr port Exhaust Gas chamber.

In order to improve the tolerance of gas compartment to dust, reduce the impact of dust on measuring, preferably, the both sides of described gas compartment arrange optical window, and at least 2 air intake openings 61,62 are separately positioned on the side that described optical window closes on flue gas.

According to above-mentioned denitrating flue gas monitoring system, preferably, described flue gas enters described gas compartment from the import 60 between described air intake opening.

According to above-mentioned denitrating flue gas monitoring system, preferably, on the gas compartment that described exhausr port 63,64 is arranged between described air intake opening.

According to above-mentioned denitrating flue gas monitoring system, preferably, described exhausr port is at least 2, is separately positioned on described air intake opening and flue gas and enters between the gas compartment position.

In order to reduce the adverse effect of moisture to measuring in flue gas, preferably, the temperature of described pretreatment unit, pipeline and gas compartment is over 200 ℃.

In order to improve accuracy that gas detects, shorten detection time, get rid of the interference of other gas, preferably, described analysis meter is the laser spectral analysis instrument, comprises laser instrument 4, detector 5 and analysis module.

Fig. 2 has schematically provided the process flow diagram of the denitrating flue gas monitoring method of the utility model embodiment, and as shown in Figure 2, described denitrating flue gas monitoring method comprises the following steps:

(A1) flue gas in environment to be measured is transferred to gas compartment by pipeline after sampling, filtration, and flue gas is heated in this sampling, filtration and transmitting procedure;

(A2) gas enters described gas compartment from air intake opening, in a side formation isolated area of the contiguous flue gas of optics, keeps apart flue gas and optics, afterwards from exhausr port Exhaust Gas chamber; Analysis meter detects the content of flue gas in described gas compartment; Flue gas in gas compartment described in testing process is heated.

In order to reduce the adverse effect of moisture to measuring in flue gas, preferably, described flue gas is heated to over 200 ℃.

In order to improve accuracy that gas detects, shorten detection time, get rid of the interference of other gas, preferably, described analysis meter adopts the laser spectral analysis technology.

According to above-mentioned denitrating flue gas monitoring method, preferably, described air intake opening is arranged on a side of the contiguous flue gas of optical window.

According to above-mentioned denitrating flue gas monitoring method, preferably, described flue gas is from entering between air intake opening in described gas compartment.

According to above-mentioned denitrating flue gas monitoring method, preferably, described exhausr port is arranged on the gas compartment between air intake opening.

The benefit reached according to denitrating flue gas monitoring system and the method for the present embodiment 1 is: gas forms isolated area in a side of the contiguous flue gas of optics, farthest avoided the dust pollution optics in the flue gas, improved the tolerance of gas compartment to dust, so the filtrator that precision is lower is set in pre-service to be got final product, reduced the maintenance of filtrator, improve serviceable life, improved the stream time of system simultaneously.Flue gas was heated to always surpasses 200 ℃ before the Exhaust Gas chamber, made the moisture in flue gas keep gaseous state, had lowered the impact of moisture on detecting, and had correspondingly improved accuracy of detection.The selection absorption line that the laser spectral analysis technology adopts is ideally got rid of again the interference of water.

Embodiment 2:

Denitrating flue gas monitoring system and the application examples of method in the escape ammonia monitoring according to the utility model embodiment 1.

In the denitrating flue gas monitoring system of this application examples, pretreatment unit adopts porcelain filter, and filtering accuracy is 8 μ m; The electrical heating piece is set in pretreatment unit, electric-heating belt is set on pipeline, the cylinder that gas compartment adopts stainless steel to make, be arranged in the case with electrical heating piece.The two ends of gas compartment arrange respectively optics window, catoptron, be provided for passing into the air intake opening of isolation with gas on the gas compartment of a side of the contiguous flue gas of described optics window, catoptron, on the gas compartment between two air intake openings, (as the centre of the gas compartment with air intake opening the same side) arranges gas approach, two exhausr ports are separately positioned on the gas compartment between gas approach and air intake opening, more close air intake opening, and and air intake opening (and gas approach) both sides in gas compartment respectively.Analysis meter adopts laser gas analyzer, the absorption line of the ammonia that the laser instrument emission wavelength disturbs corresponding to gases such as can getting rid of water, laser instrument, detector are arranged on the same side and the outside in described case of gas compartment, and analysis module also, outside case, is avoided the impact of being heated.By the heating of heating arrangement, make the flue-gas temperature in pretreatment unit, pipeline and gas compartment surpass 200 ℃, as 250 ℃, 280 ℃ etc.The gas of isolation use adopts pressurized air.

The denitrating flue gas monitoring method is specially:

Flue gas in flue, through sampling probe, pre-service, is transferred to gas compartment by pipeline afterwards; By the heating of heating arrangement, make the flue-gas temperature in pretreatment unit, pipeline and gas compartment surpass 200 ℃, as 250 ℃, 280 ℃ etc.;

Pressurized air enters in gas compartment from air intake opening, a side at optics window and the contiguous flue gas of catoptron forms the air insulated district respectively, keep apart flue gas and optics window (and catoptron), prevent dust pollution optics window, catoptron in flue gas, together discharge from exhausr port with the indoor flue gas of gas afterwards; The light of the measurement corresponding to the ammonia absorbing wavelength that laser instrument sends enters in gas compartment through the optics window is laggard, through reflecting for being reflected mirror after air, flue gas, air, again pass afterwards the air of catoptron side air, flue gas, diaphragm side, through being detected device after described optics window, receive afterwards, signal send analysis module, and analysis module draws the content of ammonia in flue gas gas according to the DLAS technology.

Embodiment 3:

Denitrating flue gas monitoring system and the application examples of method in the escape ammonia monitoring according to the utility model embodiment 1.

In the denitrating flue gas monitoring system of this application examples, pretreatment unit adopts the silk floss filtrator, and filtering accuracy is 6 μ m; The electrical heating piece is set in pretreatment unit, electric-heating belt is set on pipeline, the cylinder that gas compartment adopts stainless steel to make, be arranged in the case with electrical heating piece.The two ends of gas compartment arrange respectively the first optics window, the second optical window, be provided for passing into the air intake opening of isolation with gas on the gas compartment of a side of described the first optics window, the contiguous flue gas of the second optics window, on the gas compartment between two air intake openings, (as the centre of the gas compartment with air intake opening the same side) arranges gas approach, two exhausr ports are separately positioned on the gas compartment between gas approach and air intake opening, more close air intake opening, and and air intake opening (and gas approach) both sides in gas compartment respectively.Analysis meter adopts laser gas analyzer, the absorption line of the ammonia that the laser instrument emission wavelength disturbs corresponding to gases such as can getting rid of water, laser instrument, detector are separately positioned on both sides and the outside in described case of gas compartment, and analysis module also, outside case, is avoided the impact of being heated.By the heating of heating arrangement, make the flue-gas temperature in pretreatment unit, pipeline and gas compartment surpass 200 ℃, as 220 ℃, 260 ℃ etc.The gas of isolation use adopts compressed nitrogen.

The denitrating flue gas monitoring method is specially:

Flue gas in flue, through sampling probe, pre-service, is transferred to gas compartment by pipeline afterwards; By the heating of heating arrangement, make the flue-gas temperature in pretreatment unit, pipeline and gas compartment surpass 200 ℃, as 220 ℃, 260 ℃ etc.;

Compressed nitrogen enters in gas compartment from air intake opening, a side at the first optics window and the contiguous flue gas of the second optics window forms the nitrogen isolated area respectively, keep apart flue gas and optics window, prevent dust pollution optics window in flue gas, together discharge from exhausr port with the indoor flue gas of gas afterwards; The light of the measurement corresponding to the ammonia absorbing wavelength that laser instrument sends enters in gas compartment through the first optics window is laggard, pass for nitrogen, flue gas, nitrogen, through being detected device after described the second optics window, receive afterwards, signal send analysis module, and analysis module draws the content of ammonia in flue gas gas according to the DLAS technology.

Claims (7)

1. a denitrating flue gas monitoring system, described denitrating flue gas monitoring system comprises sampler, pretreatment unit, gas compartment and analysis meter; It is characterized in that: described denitrating flue gas monitoring system further comprises:

Heating arrangement, described heating arrangement is for heating the pipeline of described pretreatment unit, gas compartment, connection pretreatment unit and gas compartment;

Spacer assembly, described spacer assembly is for providing gas, this gas enters in described gas compartment from air intake opening, in a side of the contiguous flue gas of optics, forms isolated area, after from exhausr port Exhaust Gas chamber.

2. denitrating flue gas monitoring system according to claim 1, it is characterized in that: the both sides of described gas compartment arrange optical window, and at least 2 air intake openings are separately positioned on the side that described optical window closes on flue gas to be measured in gas compartment.

3. denitrating flue gas monitoring system according to claim 2, it is characterized in that: described flue gas enters described gas compartment between described air intake opening.

4. denitrating flue gas monitoring system according to claim 3, it is characterized in that: described exhausr port is arranged on the gas compartment between described air intake opening.

5. denitrating flue gas monitoring system according to claim 4, it is characterized in that: described exhausr port is at least 2, is separately positioned between described air intake opening and gas approach.

6. denitrating flue gas monitoring system according to claim 1, it is characterized in that: the temperature of described pretreatment unit, pipeline and gas compartment is over 200 ℃.

7. denitrating flue gas monitoring system according to claim 1, it is characterized in that: described analysis meter is the laser spectral analysis instrument.

Images