WO2009003390A1 - Beta-ray soot concentration direct readout monitor and method for determining effective sample - Google Patents

Beta-ray soot concentration direct readout monitor and method for determining effective sample Download PDF

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Publication number
WO2009003390A1
WO2009003390A1 PCT/CN2008/071397 CN2008071397W WO2009003390A1 WO 2009003390 A1 WO2009003390 A1 WO 2009003390A1 CN 2008071397 W CN2008071397 W CN 2008071397W WO 2009003390 A1 WO2009003390 A1 WO 2009003390A1
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WIPO (PCT)
Prior art keywords
soot
sampling
tube
beta
ray
Prior art date
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PCT/CN2008/071397
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English (en)
French (fr)
Inventor
Hongjie Li
Hanyong Yao
Zhongquan Chen
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Wuhan Tianhong Instruments Co., Ltd.
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Publication date
Application filed by Wuhan Tianhong Instruments Co., Ltd. filed Critical Wuhan Tianhong Instruments Co., Ltd.
Priority to KR1020107002526A priority Critical patent/KR101408513B1/ko
Priority to JP2010513628A priority patent/JP5372924B2/ja
Priority to EP08757806.8A priority patent/EP2063251B1/en
Priority to US12/442,804 priority patent/US8106356B2/en
Publication of WO2009003390A1 publication Critical patent/WO2009003390A1/zh
Priority to HK09107408.2A priority patent/HK1128331A1/zh

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N1/00Sampling; Preparing specimens for investigation
    • G01N1/02Devices for withdrawing samples
    • G01N1/22Devices for withdrawing samples in the gaseous state
    • G01N1/2247Sampling from a flowing stream of gas
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N1/00Sampling; Preparing specimens for investigation
    • G01N1/02Devices for withdrawing samples
    • G01N1/22Devices for withdrawing samples in the gaseous state
    • G01N1/2202Devices for withdrawing samples in the gaseous state involving separation of sample components during sampling
    • G01N1/2205Devices for withdrawing samples in the gaseous state involving separation of sample components during sampling with filters
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N15/00Investigating characteristics of particles; Investigating permeability, pore-volume or surface-area of porous materials
    • G01N15/06Investigating concentration of particle suspensions
    • G01N15/0606Investigating concentration of particle suspensions by collecting particles on a support
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N23/00Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00
    • G01N23/02Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00 by transmitting the radiation through the material
    • G01N23/06Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00 by transmitting the radiation through the material and measuring the absorption
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N35/00Automatic analysis not limited to methods or materials provided for in any single one of groups G01N1/00 - G01N33/00; Handling materials therefor
    • G01N35/00009Automatic analysis not limited to methods or materials provided for in any single one of groups G01N1/00 - G01N33/00; Handling materials therefor provided with a sample supporting tape, e.g. with absorbent zones

Definitions

  • the invention relates to an environmental protection detecting device, in particular to a ⁇ -ray smoke concentration direct reading monitor capable of improving weighing accuracy and a method for determining whether a sampling sample is effective. Background technique
  • the filtration weighing method is the most widely used nowadays.
  • the basic principle is a certain volume of dusty flue gas. After passing through the filter cartridge of known weight, the dust particles in the flue gas are retained, according to the filter cartridge before and after sampling. The difference in weight and the sample volume are used to calculate the dust concentration. Because the gas in the flue has a certain flow rate and pressure, it also has a high temperature and humidity, and often has some corrosive gases, so the method of constant velocity sampling must be adopted. Due to the high accuracy and precision of the filtration weighing method, many countries in foreign countries have adopted this method as a standard method. China also uses this method as a criterion for identifying other analytical methods. Please refer to FIG.
  • the method includes: a soot collecting unit and a soot quality detecting unit, wherein the soot collecting unit comprises: a soot sampling gun
  • the soot sampling gun comprises: the collecting tube 11, the pitot tube and the sheath tube are directly covered on the filter paper 3 through the dust of the collecting tube, and are carried out by the ⁇ -ray source 52 analysis.
  • Chinese Patent No. 0 223 823 8.0 discloses a continuous monitoring device for soot ray particulate soot emissions, which is characterized in that it is a cantilever sampling tube, a compressor, a filter paper and a paper feeding device thereof, and a beta ray source (carbon 14 surface source), ⁇ -ray receiving Geiger counter (GE1GER-MULLER DETECTOR), S pitot tube, computer data processing device and cabin, the sampling tube is connected with the negative pressure source, and the filter paper is driven by the paper feeding device through the sampling tube cross section
  • the ⁇ -ray receiving Geiger counter is electrically connected with the computer data processing device, and the S-pilot is connected with the compressor to realize the pipeline, wherein the temperature sensor is connected with the ⁇ -ray receiving Geiger counter.
  • FIG. 2 is a structural diagram of a prior art soot dust concentration direct reading monitor smoke sampling gun; two sets of protective sleeves 13 ′, 13 ′′ are respectively set in the sampling tube 11 and the pitot tube 12, wherein a heating tube 45 and the sampling tube 11 are disposed in a sheath tube 13' for heating the soot, but due to uneven heating, the dehumidifying effect is not obvious, and condensing reflux is easily caused. , making the previous heating process meaningless.
  • the sampling area is equal to the test area
  • the sampling area quality overflow occurs;
  • the humidity in the smoke is high, which affects the detection of the soot quality;
  • the ⁇ -ray source (carbon 14-sided source) cannot penetrate at all, and is completely adsorbed by smoke.
  • An object of the present invention is to provide a beta beam soot concentration direct reading monitor and a method for confirming the effective sample thereof for overcoming the above drawbacks.
  • the soot quality detecting unit comprises: a beta ray counting detecting device and an experimental data processing device, Wherein the beta ray counting detecting device comprises: a beta ray source and a beta ray receiving cover counter; obtaining a soot detecting sample by the soot collecting unit, and finally obtaining soot data by the soot quality detecting unit;
  • An end chamber is disposed at an end of the collecting pipe of the soot sampling gun, and a lower cavity is disposed corresponding to the upper cavity, and the filter paper passes through the gap between the upper and lower cavities, under the a filter paper tray is arranged at the entrance of the cavity, and a smoke outlet is arranged at a lower portion of the lower cavity, wherein the sampling area of the upper cavity obtained by the dust is at least twice the actual detection area of the filter paper, so as to reduce the sampling resistance and Sampling per unit area to obtain the quality of soot;
  • the method further comprises: a heating and dehumidifying device, comprising: at least three heating rods respectively disposed on both sides of the ⁇ -ray source and one side of the sampling tube for drying the moisture of the soot collected on the filter paper.
  • a heating and dehumidifying device comprising: at least three heating rods respectively disposed on both sides of the ⁇ -ray source and one side of the sampling tube for drying the moisture of the soot collected on the filter paper.
  • the heating and dehumidifying device further comprises: a heating belt, the sampling tube and the pitot tube are bundled, the heating belt winding the sampling tube and the pitot tube, and loading the Inside the sheath tube; the heating belt also winds the upper cavity to achieve full heating of the soot to prevent condensation.
  • the sampling tube has a diameter of 4 to 6 mm for increasing the gas flow rate to prevent soot deposition and adsorption in the sampling tube.
  • a method for determining an effective soot detecting sample for determining whether the collected detecting sample of the ⁇ -ray soot concentration direct reading monitor is effective includes the following steps: Step a: starting the ⁇ -ray smoke Concentration direct reading monitor;
  • Step b testing the detected sample after the sampling is completed, and obtaining the output frequency of the beta ray receiving Geiger counter;
  • Step c determining whether the output frequency changes, if the change performs the following step d, if unchanged Perform the following steps e;
  • Step d testing the next set of test samples to obtain the output frequency of the beta ray receiving cover counter, and performing the above steps c;
  • Step e This set of test samples is valid.
  • the invention has the advantages that the measurement precision of the smoke is improved, and the interference of the moisture with the smoke measurement is prevented. DRAWINGS
  • FIG. 1 is a schematic diagram of the internal structure of a conventional ⁇ -ray smoke concentration direct reading monitor
  • FIG. 2 is a schematic structural view of a prior art ⁇ -ray soot concentration direct reading monitor soot sampling gun
  • FIG. 4 is a comparison diagram of the sampling area and the detection area of the filter paper of the present invention during the sampling process;
  • FIG. 5 is a schematic structural view of the soot sampling gun of the ⁇ -ray smoke concentration direct reading monitor according to the present invention; A cross-sectional view of the monitor soot sampling gun is read;
  • Fig. 7 is a flow chart of the method for determining an effective soot detecting sample by the ⁇ -ray soot concentration direct reading monitor of the present invention. detailed description
  • FIG. 3 is a schematic diagram of the internal structure of the ⁇ -ray smoke concentration direct reading monitor of the present invention, which has the general structure of the existing ⁇ -ray smoke concentration direct reading monitor, namely: the soot collecting unit and the soot
  • the soot collecting unit comprises: a soot sampling gun, a filter paper and a mechanically controlled automatic paper feeding structure, wherein the soot sampling gun comprises: a collecting tube 11, a pitot tube 12 and a sheath tube 13;
  • the soot quality detecting unit comprises: a beta ray counting detecting device, an experimental data processing device (not shown), wherein the beta ray counting detecting device package Included: a beta ray source 52 and a beta ray receiving cover counter 51; a soot detecting sample is obtained by the soot collecting unit, and finally the soot data is obtained by the soot quality detecting unit;
  • the present invention has made certain adjustments to the structure of the soot collecting unit and the soot quality detecting unit, and the purpose thereof is to improve the accuracy of the measurement;
  • FIG. 4 is an alignment diagram of the sampling area and the detection area of the filter paper of the present invention during the sampling process.
  • the sampling area 31 is at least the actual filter paper.
  • the detection area is twice as large, which solves the problem that the sampling unit area overflows and the ⁇ -ray cannot be measured. Since the ⁇ -ray is low energy, the penetration unit mass should not exceed 1.5 ⁇ 2.0 mg/cm 2 , after the above design. This problem has been solved. In addition, the air path resistance during sampling is greatly reduced, and the problem of sampling power and flow tracking is solved. If the sampling is performed according to the original sampling area, the sampling will increase rapidly, resulting in sampling. Unable to proceed.
  • a heating dehumidification device which comprises: three heating rods 41, 42, 43 and a heating belt 44, wherein for heating For the rods 41, 42, and 43, as shown in FIG. 3, a plurality of groups may be added for the purpose of achieving better drying of the dry water, and the heating rods 41, 42, and 43 are respectively disposed at the ⁇ -ray source.
  • the moisture in the soot collected by the filter paper 3 moving thereon is prevented from being prevented by the water.
  • FIG. 5 and FIG. 6 are respectively a structural diagram and a cross section of the soot sampling gun of the ⁇ -ray smoke concentration direct reading monitor of the present invention.
  • the skin tube 12 and the sampling tube 11 are bundled together, and the sampling tube 11 and the pitot tube 12 are wound by the heating belt 44 and loaded into the sheath tube 13
  • the heating belt 44 also winds the upper cavity 21 to achieve full heating of the soot to prevent condensation, and the heating temperature range is generally set between 120 degrees Celsius and 200 degrees Celsius.
  • the sampling tube 11 of the present invention has a diameter of 4 to 6 mm to increase the gas flow rate and prevent the deposition and adsorption of soot in the sampling tube 11.
  • C 14 is used as the detection source in the current beta dust meter, but it is not suitable to use C 14 in the smoke detection because its energy is weak. Only 0.155Mev, the penetration ability is only 1.5 ⁇ 2.0mg/cm 2 , usually the quality of the filter paper in the measuring instrument is about 6 ⁇ 8mg/cm 2 The soot to be sampled should be less than 2mg/cm 2 , due to the large dispersion of smoke. The detection of large particle dust is inaccurate because it cannot penetrate at all and is completely absorbed by the smoke. Therefore, in the present invention, a PM 147 source having an energy of 0.223 MeV and a penetration range of 0.2 to 20 mg/cm 2 is twice as high as C 14 .
  • the present invention provides a method for judging the above-mentioned ⁇ -ray smoke.
  • FIG. 7 includes the following steps:
  • Step a starting the direct reading monitor for the beta ray soot concentration
  • Step b testing the detected sample after the sampling is completed, and obtaining the output frequency of the beta ray receiving Geiger counter;
  • Step c determining whether the output frequency changes, if there is a change, perform the following step d, if the following step e is not performed;
  • Step d testing the next set of test samples to obtain the output frequency of the beta ray receiving gate counter, and performing the above step C;
  • Step e This set of test samples is valid.

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Description

一种 p射线烟尘浓度直读监测仪及其确认有效样本的方法 技术领域
本发明涉及的是一种环保检测设备, 特别涉及的是一种能够提高称量 准确性的 β射线烟尘浓度直读监测仪以及如何确定采样样本是否有效的方 法。 背景技术
由于工业锅炉、 电厂锅炉及工业窑炉等污染源所造成的环境污染是相 当严重的, 世界各国都对此进行了深入研究并加以控制, 这就需要对其排 放的颗粒状烟尘浓度进行监测。 目前常用的监测方法有不透明度法、 光透 射法、 激光后向散射法、 电荷法、 β射线吸收法 (烟道内测试) 等。
其中, 过滤称重法是现在使用最为广泛的, 其基本原理是一定体积的 含尘烟气, 通过已知重量的滤筒后, 烟气中的尘粒被阻留, 根据采样前后 滤筒的重量差和采样体积, 算出含尘浓度。 因烟道中的气体具有一定的流 速和压力, 还具有较高的温度和湿度, 且常有一些腐蚀性气体, 所以必须 采用等速采样的方法。 由于过滤称重法准确度高、 精密度好, 国外许多国 家将此方法定为标准方法。 我国也将此方法作为鉴定其它分析方法的标准。 请参阅图 1所示, 其为现有技术的 β射线烟尘浓度直读监测仪的内部结构 简图; 其包括: 烟尘收集单元和烟尘质量检测单元, 所述的烟尘收集单元 包括: 烟尘采样枪、 滤纸和机械控制自动走纸结构, 其中, 所述的烟尘采 样枪包括: 采集管 11、 皮托管以及护套管通过采集管的烟尘直接覆盖在滤 纸 3上, 通过 β射线光源 52对此进行分析。
中国专利 02238238.0公开了一种 β射线颗粒物烟尘排放连续监测仪, 其特征在于它是由悬臂的采样管、压缩机、滤纸及其走纸装置、 β射线源(碳 14面源)、 β射线接收盖格计数器 (GE1GER— MULLER DETECTOR), S 皮托管、 计算机数据处理装置和机厢组成, 采样管与负压源相通, 滤纸由 走纸装置带动经过采样管横截面后, 再从 β射线源与 β射线接收盖格计数 器之间经过, β射线接收盖格计数器与计算机数据处理装置实现电联接, S 皮托管与压缩机实现管路相联, 其中的温度传感器与计算机数据处理装置 实现电联接。 请参阅图 2所示, 其为现有技术的 β射线烟尘浓度直读监测 仪烟尘采样枪的结构简图; 采用两个护管套 13'、 13"分别套设在采样管 11 以及皮托管 12上, 其中采用了加热管 45与所述的采样管 11设置在一个护 套管 13'中,用以对烟尘加热,但是由于其加热不均匀, 除湿的效果不明显, 并且容易造成冷凝回流, 使前面的加热过程失去意义。
综上, 现有 β射线烟尘浓度监测仪仍有以下缺陷需要解决:
在采样面积与测试面积等同的情况下, 出现采样面积质量溢出; 烟尘中湿度较高, 影响了对烟尘质量的检测;
对于烟尘分散度大、 大颗粒尘的检测不准确, β射线源 (碳 14面源) 其根本无法穿透, 完全被烟尘吸附了。
为解决上述问题, 本发明创作人经过长时间的研究和试验, 终于获得 了本创作。 发明内容
本发明的目的在于, 提供一种 β射线烟尘浓度直读监测仪及其确认有 效样本的方法, 用以克服上述的缺陷。
为实现上述目的, 本发明采用的技术方案在于, 首先提供一种 β射线 烟尘浓度直读监测仪, 其包括: 烟尘收集单元和烟尘质量检测单元, 所述 的烟尘收集单元包括: 烟尘采样枪、 滤纸和机械控制自动走纸结构, 其中, 所述的烟尘采样枪包括: 采集管、 皮托管以及护套管;
所述烟尘质量检测单元包括: β射线计数检测装置、实验数据处理装置, 其中,所述的 β射线计数检测装置包括: β射线源以及 β射线接收盖格计数 器; 由所述的烟尘收集单元获得烟尘检测样本, 并最终由所述烟尘质量检 测单元获得烟尘数据;
所述的烟尘采样枪的采集管末端设有一上腔体, 与所述的上腔体对应 设有一下腔体, 所述的滤纸在所述的上下腔体的间隙中通过, 在所述下腔 体的入口处设有滤纸托栅, 所述下腔体下部设有烟气出口, 其中, 所述上 腔体获得烟尘的采样面积至少为滤纸实际检测面积的 2倍, 以减少采样阻 力和单位面积上采样获得烟尘的质量;
较佳的, 还包括: 一加热除湿装置, 其包括, 至少三根加热棒, 分别 设置在 β射线源的两侧以及采样管的一侧, 用以烤干滤纸上采集到的烟尘 的水分。
较佳的, 所述的加热除湿装置还包括: 一加热带, 所述的采样管和皮 托管捆在, 所述的加热带将所述的采样管和皮托管缠绕起来, 装入所述的 护套管内; 所述的加热带也将所述的上腔体缠绕起来, 用以实现对烟尘的 全程加热, 防止冷凝。
较佳的,所述的 β射线源采用 ΡΜ147源,用以消除烟尘颗粒直径大对测 量的影响。
较佳的, 所述采样管的直径为 4一 6毫米, 用以提高气体流速, 防止烟 尘在所述采样管中沉积和吸附。
其次提供一种确定有效烟尘检测样本的方法, 其用以判断上述 β射线 烟尘浓度直读监测仪的采集到的检测样本是否有效, 其包括的步骤为: 步骤 a: 启动所述的 β射线烟尘浓度直读监测仪;
步骤 b: 对采样结束后的检测样本进行测试, 获得 β射线接收盖格计数 器的输出频率;
步骤 c : 判断所述输出频率是否变化, 若变化执行下述步骤 d, 若不变 执行下述步骤 e;
步骤 d: 对下一组检测样本进行测试, 获得 β射线接收盖格计数器的输 出频率, 执行上述步骤 c;
步骤 e: 此组检测样本是有效的。
本发明的优点在于, 提高了对烟尘的测量精度, 防止了水气对烟尘测 量的干扰。 附图说明
图 1为现有技术的 β射线烟尘浓度直读监测仪的内部结构简图; 图 2为现有技术的 β射线烟尘浓度直读监测仪烟尘采样枪的结构简图; 图 3为本发明 β射线烟尘浓度直读监测仪的内部结构简图;
图 4为本发明滤纸在采样过程中采样面积和检测面积的比对图; 图 5为本发明 β射线烟尘浓度直读监测仪烟尘采样枪的结构简图; 图 6本发明 β射线烟尘浓度直读监测仪烟尘采样枪的截面图; 图 7为本发明 β射线烟尘浓度直读监测仪确定有效烟尘检测样本方法 的流程图。 具体实施方式
以下结合附图, 对本发明上述的和另外的技术特征和优点作更详细的 说明。
请参阅图 3所示, 其为本发明 β射线烟尘浓度直读监测仪的内部结构 简图, 其具有现有的 β射线烟尘浓度直读监测仪的一般结构, 即包括: 烟 尘收集单元和烟尘质量检测单元, 所述的烟尘收集单元包括: 烟尘采样枪、 滤纸和机械控制自动走纸结构, 其中, 所述的烟尘采样枪包括: 采集管 11、 皮托管 12以及护套管 13 ; 所述烟尘质量检测单元包括: β射线计数检测装 置、 实验数据处理装置 (图中未示), 其中, 所述的 β射线计数检测装置包 括: β射线源 52以及 β射线接收盖格计数器 51 ; 由所述的烟尘收集单元获 得烟尘检测样本, 并最终由所述烟尘质量检测单元获得烟尘数据;
但是本发明与现有的技术相比较, 其烟尘收集单元以及烟尘质量检测 单元结构都做出了一定的调整, 其目的是为了提高测量的精度;
首先, 为防止了采样单位面积质量溢出, 使 β射线无法测量, 我们采 用的技术方案是, 在所述的烟尘采样枪的采集管末端设有一上腔体 21, 与 所述的上腔体 21对应设有一下腔体 22,所述的滤纸 3在所述的上下腔体的 间隙中通过, 在所述下腔体 22的入口处设有滤纸托栅 23, 所述下腔体 22 下部设有烟气出口 23, 其中, 所述上腔体 21获得烟尘的采样面积至少为滤 纸实际检测面积 31的 2倍,以减少采样阻力和单位面积上获得烟尘的质量; 通过开阔的喇叭状结构达到这一点。
请参阅图 4所示, 其为本发明滤纸在采样过程中采样面积和检测面积 的比对图, 可以看出在以滤纸作实际采样和检测烟尘的载体而言, 采样面 积 31至少为滤纸实际检测面积的 2倍, 这样解决了, 采样单位面积质量溢 出, 使 β射线无法测量的问题, 由于 β射线为低能源, 其穿透单位质量不 宜超过 1.5~2.0mg/cm2, 经过上述的设计, 这一问题得到了解决, 另外, 还 大大减少了采样时的气路阻力, 解决了采样动力和流量跟踪的问题, 如果 按照原有的采样面积进行采样, 则会由于阻力迅速增加, 造成采样无法进 行。
其次, 为了防止烟尘中含有的水分, 给测量带来的不利因素, 在结构 设计上, 我们增加了一个加热除湿装置, 其包括: 三根加热棒 41、 42、 43 以及加热带 44, 其中对于加热棒 41、 42、 43而言, 请参阅图 3所示, 为达 到较佳的烤干水分的目的, 也可以增设多组, 所述的加热棒 41、 42、 43, 分别设置在 β射线源 52的两侧以及采样管 11的一侧的采样滤纸托块 32中, 通过对其上面移动的滤纸 3采集到的烟尘中水分的烘烤, 达到防止由于水 分原因所造成的测量偏高的隐患; 对于加热带 44的运用, 请参照图 5、 图 6所示,其分别为本发明 β射线烟尘浓度直读监测仪烟尘采样枪的结构简图 以及截面图; 所述的皮托管 12以及所述的采样管 11捆在一起, 用所述的 加热带 44将所述的采样管 11和皮托管 12缠绕起来,装入所述的护套管 13 内; 所述的加热带 44也将所述的上腔体 21缠绕起来, 用以实现对烟尘的 全程加热, 防止冷凝, 加热的温度范围一般设置在 120摄氏度至 200摄氏 度之间。
再次, 对于采样管 11 口径的设计, 本发明采样管 11的直径为 4~6毫 米, 用以提高气体流速, 防止烟尘在所述采样管 11中沉积和吸附。
再次, 对于 β射线源 52的选择来看, 正如上面所述目前 β射线测尘仪 中都使用 C14作为检测源, 但在烟尘检测中使用 C14是不适合的, 因为它的 能量较弱仅有 0.155Mev, 穿透能力差仅有 1.5~2.0mg/cm2, 通常测量仪中滤 纸的质量约为 6~8mg/cm2允许采样的烟尘应小于 2mg/cm2, 由于烟尘分散 度大、 大颗粒尘的检测是不准确的, 因为其根本无法穿透, 完全被烟尘吸 附了。 所以在本发明中采用 PM147源, 它的能量为 0.223Mev, 穿透范围为 0.2~20mg/cm2比 C14高出 1倍。
最后, 为了有效的获得准确的烟尘质量, 则必须要求滤纸上获得烟尘 的样本是有效的, 即水分必须最低 (应该已经烤干), 为此本发明提供了一 种用以判断上述 β射线烟尘浓度直读监测仪的采集到的检测样本是否有效 的方法, 请参阅图 7所示, 其包括的步骤为:
步骤 a: 启动所述的 β射线烟尘浓度直读监测仪;
步骤 b: 对采样结束后的检测样本进行测试, 获得 β射线接收盖格计数 器的输出频率;
步骤 c: 判断所述输出频率是否变化, 若有变化执行下述步骤 d, 若不 变执行下述步骤 e; 步骤 d: 对下一组检测样本进行测试, 获得 β射线接收盖格计数器的输 出频率, 执行上述步骤 C ;
步骤 e: 此组检测样本是有效的。
其是通过软件对机械控制自动走纸机构以及 β射线接收盖格计数器 51 的控制实现的。
综上, 经过本发明创作人的改进, 获得的所述 β射线烟尘浓度直读监 测仪及其确认有效样本的方法, 确实可以达到预计的技术效果, 因此依法 提出专利申请。
以上所述仅为本发明的较佳实施例, 对本发明而言仅仅是说明性的, 而非限制性的。 本专业技术人员理解, 在本发明权利要求所限定的精神和 范围内可对其进行许多改变, 修改, 甚至等效, 但都将落入本发明的保护 范围内。

Claims

权利要求书
1、 一种 β射线烟尘浓度直读监测仪, 其包括: 烟尘收集单元和烟尘质 量检测单元, 所述的烟尘收集单元包括: 烟尘采样枪、 滤纸和机械控制自 动走纸结构, 其中, 所述的烟尘采样枪包括: 采集管、 皮托管以及护套管; 所述烟尘质量检测单元包括: β射线计数检测装置、实验数据处理装置, 其中,所述的 β射线计数检测装置包括: β射线源以及 β射线接收盖格计数 器; 由所述的烟尘收集单元获得烟尘检测样本, 并最终由所述烟尘质量检 测单元获得烟尘数据;
其特征在于, 所述的烟尘采样枪的采集管末端设有一上腔体, 与所述 的上腔体对应设有一下腔体, 所述的滤纸在所述的上下腔体的间隙中通过, 在所述下腔体的入口处设有滤纸托栅, 所述下腔体下部设有烟气出口, 其 中, 所述上腔体获得烟尘的采样面积至少为滤纸实际检测面积的 2倍, 以 减少采样阻力和单位面积上采样获得烟尘的质量。
2、 根据权利要求 1所述的 β射线烟尘浓度直读监测仪, 其特征在于, 还包括: 一加热除湿装置, 其包括, 至少三根加热棒, 分别设置在 β射线 源的两侧以及采样管的一侧, 用以烤干滤纸上采集到的烟尘的水分。
3、 根据权利要求 2所述的 β射线烟尘浓度直读监测仪, 其特征在于, 所述的加热除湿装置还包括: 一加热带, 所述的采样管和皮托管捆在, 所 述的加热带将所述的采样管和皮托管缠绕起来, 装入所述的护套管内; 所 述的加热带也将所述的上腔体缠绕起来, 用以实现对烟尘的全程加热, 防 止冷凝。
4、 根据权利要求 1 所述的 β射线烟尘浓度直读监测仪, 其特征在于, 所述的 β射线源采用 ΡΜ147源, 用以消除烟尘颗粒直径大对测量的影响。
5、 根据权利要求 1所述的 β射线烟尘浓度直读监测仪, 其特征在于, 所述采样管的直径为 4一 6毫米, 用以提高气体流速, 防止烟尘在所述采样 管中沉积和吸附。
6、 一种确定有效烟尘检测样本的方法, 其用以判断上述 β射线烟尘浓 度直读监测仪的采集到的检测样本是否有效, 其特征在于,
步骤 a: 启动所述的 β射线烟尘浓度直读监测仪;
步骤 b: 对采样结束后的检测样本进行测试, 获得 β射线接收盖格计数 器的输出频率;
步骤 c: 判断所述输出频率是否变化, 若变化执行下述步骤 d, 若不变 执行下述步骤 e;
步骤 d: 对下一组检测样本进行测试, 获得 β射线接收盖格计数器的输 出频率, 执行上述步骤 c;
步骤 e: 此组检测样本是有效的。
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JP5372924B2 (ja) 2013-12-18
CN101101256A (zh) 2008-01-09
KR20100057595A (ko) 2010-05-31
US20090321635A1 (en) 2009-12-31
US8106356B2 (en) 2012-01-31
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EP2063251A4 (en) 2014-12-03
CN100526854C (zh) 2009-08-12

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