型号: | 土壤分析仪-COMPASS 200 |
产地: | 江苏 |
品牌: | 英飞思 |
评分: |
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英飞思科学Compass200-便携式 XRF土壤元素光谱分析仪
随身携带的便携式元素分析仪
具有快速、简单的报告和证书生成的无损元素分析
坚固的工业设计,适用于几乎任何天气条件、现场环境
实时、精确的土壤和矿物质现场元素分析
背景介绍
在具有潜在铅污染的住宅区收集的土壤样品通常使用火焰原子吸收光谱法 (FAAS) 或其他实验室方法进行分析。以前的工作表明,现场便携式 X 射线荧光 (XRF) 分析能够检测土壤铅含量,与 FAAS 在实验室中筛选到小于 125 μm 的样品中检测到的含量相当。如果可以开发一种不需要实验室消解和分析的实用现场方法,将会节省大量的经济和实验室报告时间。 XRF 方法还将提供即时结果,与传统实验室方法相比,这将有助于更快地向居民和其他相关方提供信息
在风险表征、评估和管理中,通常需要现场便携式方法来快速确定环境样品中的金属浓度。示例用于确定:土壤污染的“热点”、擦拭灰尘的铅含量是否符合住房入住标准以及工人呼吸防护等级。 30 多年来,便携式 X 射线荧光 (XRF) 分析仪一直可用于原位无损测量涂料中的铅。最近的进展使其可用于分析空气中的灰尘过滤器样品、土壤和灰尘擦拭物
XRF 方法可以通过最少的样品制备对土壤进行有效的定量元素分析。
特征:
>最少的样品制备:非常适合原位测试
>快速定性和定量分析
>与其他分析技术(ICP、WDXRF)相比,获取成本更低
>多功能解决方案:许多系统以最高的精度执行各种地质测试
>可实现微量元素分析
>先进的数据管理系统,具有灵活的多种数据传输方式,包括USB线连接、存储卡、Wi-Fi和蓝牙。
Compass 200能量色散X射线荧光(EDXRF)光谱仪实现了快速、准确分析土壤中的有害金属元素Pb(铅),As(砷),Cd(镉),Hg(汞),Cu(铜),Ni(镍),Zn(锌),Cr(铬)等,能够实时现场对厂区、矿区、重工业区周边的环境进行监测,从而进行控制排放和污染治理。
Compass 200光谱仪能同时检测钛、钒、铬、锰、铁、钴、镍、铜、锌、锆、铌、钼、钯、银、铟、锡、锑、钨 、铂、金、铅、 铋、硫等元素,基本涵盖了土壤样品测试的无机元素项目,并且可以根据客户需求进行定制再增加元素。
操作人员可以直接用Compass 200来分析现场的土壤样品,可通过采样,以袋装样品或者装入仪器标配的样品杯进行测试,在短时间内就可以取得和实验室同样的分析效果。
特点和优势
•便携,坚固,紧凑的设计,轻松实现现场高精度样品无损检测
•友好的软件界面和一键式启动测试
•常规分析培训只需几分钟
•大型8英寸触摸屏上显示的直观界面
•可选配大容量电池,无需外部供电情况下可实现长时间工作
应用领域
·土壤重金属普查,筛查
·可对含铅涂料进行检测
·可对过滤介质进行金属检测
·可用于检测经过铬化砷酸铜处理的木材、其他建筑材料、以及它们的碎层
·环境重金属污染分析
·矿产矿石分析:铜矿,铬矿,钼矿,钨矿,钽矿,铁矿,铅锌矿,稀土,锰矿,镍矿,贵金属矿产等
·食品,化妆品和药品重金属测试
·催化剂中贵金属元素铂钯铑分析
技术参数
探测器 | 高分辨率SDD检测器 |
激发源 | 4瓦微型一体化光管 50kv Max,200uA Max |
工作温度 | -20 to 50 °C |
测量时间 | 30-200秒(用户可自定义测试时间) |
样品类型 | 液体,固体和粉末 |
仪器校准 | 开机自动校准 |
元素分析范围 | Mg12-U92镁到铀 |
可分析含量范围 | 1ppm- 99.99% |
标定曲线 | 环境土壤 |
仪器尺寸 | 270mm*320mm*230mm(长*宽*高) |
仪器重量 | 9.4kg |
显示屏(分辨率1280*800) | 8英寸 Win10操作系统 |
数据传输 | USB Port, 蓝牙, Wi-Fi, GPS |
安全防护 | 辐射指示灯 内置射线保护装置(自动切断) 软件警示 |
报告格式 | Excel, PDF |
配件及耗材 | 样品杯测试薄膜 土壤专用测试杯 取样勺 测试窗口专用薄膜 |
可选配件 | 电池:连续工作八小时 压片机 干燥箱 磨样机 150目筛子 |
无需每日校准即可获得高精度结果。自带工厂标定曲线,客户可直接测量样品
Compass 200土壤重复性测试 | ||||||||||
含量单位: mg/kg | 测试时间: 200秒 样品类型:土壤国家标样 | |||||||||
测量 次数 | 标定曲线 |
| Cr铬 | Co钴 | Ni镍 | Cu铜 | Zn锌 | As砷 | Pb铅 | Cd镉 |
1 | Soil | 96.2 | 64.6 | 16.0 | 20.5 | 26.0 | 695.1 | 54.3 | 116.3 | 5.0 |
2 | Soil | 96.0 | 67.5 | 16.3 | 25.4 | 28.1 | 688.8 | 52.1 | 118.4 | 4.4 |
3 | Soil | 99.0 | 69.3 | 16.3 | 23.6 | 29.2 | 683.7 | 55.5 | 116.7 | 4.9 |
4 | Soil | 96.1 | 63.6 | 16.4 | 21.7 | 28.1 | 692.1 | 54.5 | 119.1 | 4.7 |
5 | Soil | 98.6 | 66.4 | 16.3 | 28.0 | 25.2 | 689.8 | 51.5 | 118.8 | 4.5 |
6 | Soil | 93.8 | 66.1 | 16.3 | 29.0 | 22.5 | 683.6 | 55.1 | 117.4 | 3.7 |
7 | Soil | 96.0 | 70.4 | 16.7 | 23.7 | 30.5 | 692.5 | 56.6 | 120.0 | 4.4 |
8 | Soil | 97.7 | 63.5 | 16.5 | 27.3 | 26.0 | 685.9 | 52.5 | 116.4 | 3.9 |
9 | Soil | 97.4 | 65.9 | 16.6 | 24.9 | 31.3 | 697.7 | 54.3 | 118.7 | 3.4 |
10 | Soil | 99.8 | 74.4 | 16.6 | 22.1 | 26.6 | 686.8 | 55.3 | 118.2 | 3.6 |
11 | Soil | 97.3 | 66.9 | 16.5 | 22.0 | 26.5 | 682.2 | 56.4 | 116.9 | 5.7 |
平均值 | 97.1 | 67.2 | 16.4 | 24.4 | 27.3 | 688.9 | 54.4 | 117.9 | 4.4 | |
标准偏差Sn | 1.61 | 3.07 | 0.18 | 2.67 | 2.39 | 4.79 | 1.62 | 1.18 | 0.64 | |
相对标准偏差RSD | 1.655% | 4.567% | 1.082% | 10.961% | 8.754% | 0.695% | 2.972% | 0.997% | 14.655% |
我们提供全方位的技术支持,帮助您保持仪器正常运行
我们的服务包括
>工厂工程师的现场安装和服务
进行深入的培训和技术支持
>远程诊断
通过互联网提供在线支持,以快速响应您的问题
>预防性维护
确保分析仪长期稳定正常工作
>终身免费软件升级
保证用户始终使用最新版本程序
>耗材和配件
从样品制备到校准标样
典型应用:
土壤测试/环境分析
有害物质鉴定,EPA 方法 6200
矿石分析和采矿应用
贵金属检测、稀土分析
地质样品中的氧化物分析
矿物和矿物产品应用
什么是 XRF能量色散荧光光谱仪?
X 射线荧光光谱使用高能光子(X 射线)轰击原子
并激发围绕原子运行的电子。其中一些光子有足够的能量
射出一个与原子核结合的电子。当内轨道
电子从原子中射出,来自更高能量轨道的电子将
转移到低能轨道。在这个转变过程中,光子(X 射线)可能
从原子发射。这个过程被称为荧光,发射的 X 射线
从原子将是该特定元素的特征。能量(因此
光子的波长)将是电子的两个轨道之间的差异
进行过渡。由于两个特定轨道之间的能量差异,在一个
给定的元素,总是相同的,那么从特定元素发出的光子(X 射线)
元素将始终具有相同的能量。
Compass200-Porable XRF Soil Analyzer
Simply the Best
> Your Portable Element Analyzer that goes anywhere
> Non-destructive element analysis with fast, simple reporting and certificate generation
>Robust industrial design for nearly any weather condition, field environment
>Real-time and precise on-site element analysis in soils and minerals
Background and Introduction
Soil samples collected in housing areas with potential lead contamination generally are analyzed with flame atomic absorption spectrometry (FAAS) or other laboratory methods. Previous work indicates that field-portable X-ray fluorescence (XRF) analysis is capable of detecting soil lead levels comparable to those detected by FAAS in samples sieved to less than 125 μm in a laboratory. A considerable savings, both economical and in laboratory reporting time, would occur if a practical field method could be developed that does not require laboratory digestion and analysis. The XRF method also would provide immediate results that would facilitate the provision of information to residents and other interested parties more quickly than is possible with conventional laboratory methods
Field portable methods are often needed in risk characterization, assessment and management to rapidly determine metal concentrations in environmental samples. Examples are for determining: "hot spots" of soil contamination, whether dust wipe lead levels meet housing occupancy standards, and worker respiratory protection levels. For over 30 years portable X-Ray Fluorescence (XRF) analyzers have been available for the in situ, non-destructive, measurement of lead in paint. Recent advances made possible their use for analysis of airborne dust filter samples, soil, and dust wipes
The XRF method makes it possible to perform efficient quantitative element analysis of soils with a minimum of sample preparation
Features:
>Minimal Sample Preparation: great for in-situ testing
>Fast Qualitative and Quantitative Analysis
>Lower Cost of Acquisition when compared to other analytic techniques (ICP, WDXRF)
>Versatile Solution: many systems perform a variety of geologic tests with top precision
>Trace Elements Analysis is achievable
>Advanced data management system with flexible multiple data transport methods including USB cable connection, storage card, Wi-Fi and Bluetooth.
>Extensive, Editable grade library for accurate alloy identification
Typical Applications:
Soil Testing / Environmental Analysis
hazardous substance identification, EPA Method 6200
Ore Analysis and Mining Applications
precious metal testing, rare earth analysis
Oxide Analysis in Geological Samples
Mineral and Mineral Product Applications
What is XRF?
X-ray fluorescence spectroscopy uses high energy photons (x-rays) to bombard an atom
and excite electrons orbiting the atom. Some of these photons have sufficient energy to
eject an electron which is bound to the nucleus of the atom. When an inner orbital
electron is ejected from an atom, an electron from a higher energy orbital will be
transferred to the lower energy orbital. During this transition, photons (x-rays) may be
emitted from the atom. This process is known as fluorescence, and the x-rays emitted
from the atom will be characteristic of that particular element. The energy (and therefore
wavelength) of the photon will be the difference between the two orbitals of the electron
making the transition. Because the energy difference between two specific orbitals, in a
given element, is always the same then the photon (x-ray) emitted from a particular
element will always have the same energy. Thus by measuring the energy of the photons
emitted, the XRF can determine the element that is emitting the photons, and the
concentration of element in the soil.
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