Gas Chromatography KGC/SP/500
Gas Chromatography KGC/SP/500
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Portable Water Quality Analyzer KWQ/P/10
Portable Water Quality Analyzer KWQ/P/10
Gas Chromatography-Mass Spectrometry KGC/M/15
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Gas Chromatography-Mass Spectrometry KGC/M/15

Kiparma

Features:

  • Wide temperature RF power supply can better adapt to various laboratory environments, and instrument performance is more stable.
  • High precision all metal quadrupole, ensuring good resolution.
  • Quadrupole mass analyzer with pre quadrupole, quadrupole has stronger anti-pollution ability.
  • Electronic multiplier with high-energy conversion dynode, ensuring excellent sensitivity.
  • Adopting high-performance turbo molecular pump, with high pumping speed and stable operation, ensuring long-term high vacuum environment for mass spectrometry.
  • High temperature inert ion source has high ionization efficiency, reduces pollution, and is equipped with dual filaments, providing twice the usage time.
  • Configured with automatic sampler, blow trap, thermal analyzer, headspace sampler to achieve sample analysis of different states.
Specification
Kiparma Model KGC/M/15
Main performance indicators:
Sensitivity: 1 pg, OFN S/N≥1500:1
Quality range: 1.5-1250 amu
Quality stability: ± 0.10 amu/48 hours
Quality accuracy: ± 0.10 amu
Maximum scanning speed: 20000 amu/s, with adjustable speed throughout the entire process
Resolution: 0.4-4amu adjustable
Dynamic range: 107
Peak area reproducibility: < 2% RSD
Scanning methods: full scan, selective ion monitoring, full scan and selective ion synchronous monitoring, alternating scanning.
Ion source:
Type of ion source: Electron impact source (EI)
Ion source configuration: Inert ceramic ion source, dual filament software switching
Filament current: 0-500 μA
Ionization energy: 5-100 eV
Ion source temperature: 50℃ to 350℃

Equipped with a filament observation window to visually judge the working status of the filament
Interface temperature: 50 to 350℃
Quality analyzer: equipped with high-precision all metal quadrupole with pre quadrupole

The quadrupole is optimized for temperature control, which can ensure quality stability indicators without the need for temperature control

Pre quadrupole detachable and washable to avoid contamination of the main quadrupole

The quadrupole has optimized ion energy technology, which optimizes the speed of ions passing through the quadrupole and improves signal quality
Detector: Long lifespan level 13 dispersed dynode electronic multiplier

Equipped with a 10kV conversion dynode and a lens system for removing neutral noise
Vacuum system:
Front stage pump, speed: ≥4 m³/h
Configure a high-performance turbo molecular pump, speed: ≥250 L/s
Maximum allowable chromatographic column flow rate: 5 ml/min (He)
Split/non split injector:
Maximum using temperature: 450˚C
Gas control mode: constant pressure, constant flow rate, program up/down pressure, program up/down flow, pulse injection
Program boosting/current raising: 10th order
Pressure setting range: 0-1035 kPa (0-150 psi)
Maximum split ratio: 9999.9:1
Flow setting range: 0-200 mL/min (N2)
Flow setting range: 0-1000 mL/min (H2)
Column oven:
Operating temperature range: RT to 450˚C
Temperature Setting Accuracy: 0.1˚C
Temperature control accuracy: 0.01˚C
Temperature Stability: ≤0.5%
Temperature uniformity: ≤2.5%
Environmental sensitivity: When the ambient temperature changes by 1˚C, better than 0.01℃
Heating Rate: ≥100˚C /min
Programmed Heating Repeatability: ≤1%
Programmed Heating Order: 32
Cooling Time (from 450℃ to 50℃): ≤4 min
Maximum Running Time: 9999.999 min

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    Features & Compatibility

    Gas Chromatography-Mass Spectrometry KGC/M/15 (GC-MS): The Ultimate Tool for Advanced Chemical Analysis

    In the realm of analytical chemistry, Gas Chromatography-Mass Spectrometry KGC/M/15 (GC-MS) stands out as a gold standard technique, offering unparalleled precision, sensitivity, and versatility in identifying and quantifying complex chemical compounds. By combining the separation capabilities of Gas Chromatography (GC) with the powerful detection of Mass Spectrometry (MS), GC-MS has become an essential tool across a wide range of industries, including pharmaceuticals, environmental science, food safety, forensics, and beyond.

    What is Gas Chromatography-Mass Spectrometry (GC-MS)?

    Gas Chromatography-Mass Spectrometry (GC-MS) is an advanced analytical method that combines two techniques to provide detailed information about the molecular composition of a sample. The process begins with Gas Chromatography, where a sample is vaporized and carried by an inert gas through a capillary column. Inside the column, the sample’s components are separated based on their volatility and interaction with the column’s stationary phase.

    Once the components are separated, they are introduced into the Mass Spectrometer. Here, each compound is ionized, usually by electron impact, and then fragmented into charged particles (ions). The Mass Spectrometer measures these ions based on their mass-to-charge ratio (m/z), creating a mass spectrum that acts as a unique fingerprint for each compound. This allows for both qualitative and quantitative analysis of complex mixtures, even at trace levels.

    Key Features of GC-MS

    1. Comprehensive Analysis: GC-MS offers both separation and identification of compounds, enabling detailed analysis of complex mixtures in a single run.
    2. High Sensitivity and Specificity: GC-MS can detect and quantify trace amounts of compounds with high precision, even in the presence of complex matrices.
    3. Wide Range of Analytes: GC-MS is capable of analyzing a broad spectrum of volatile and semi-volatile organic compounds, making it suitable for diverse applications.
    4. Mass Spectral Libraries: GC-MS systems come with extensive spectral libraries, allowing for the rapid identification of unknown compounds by comparing their spectra to known references.
    5. Quantitative and Qualitative Capabilities: GC-MS provides both qualitative identification of compounds and quantitative measurement of their concentrations, offering comprehensive data for decision-making.
    6. Automated Operation: Modern GC-MS systems feature automation options that streamline sample preparation, analysis, and data processing, enhancing throughput and reproducibility.

    Benefits of Using GC-MS

    1. Unmatched Accuracy: GC-MS provides highly accurate identification and quantification of compounds, even in complex matrices, making it the preferred method for critical analyses.
    2. Versatility Across Applications: From environmental testing to drug analysis, GC-MS is versatile enough to meet the analytical needs of various industries and research fields.
    3. Enhanced Sensitivity: GC-MS excels in detecting trace-level contaminants and impurities, ensuring compliance with stringent regulatory standards and improving product quality.
    4. Forensic Analysis: In forensic science, GC-MS is indispensable for analyzing biological samples, drugs, and toxic substances, providing definitive evidence in legal cases.
    5. Food and Beverage Testing: GC-MS plays a crucial role in ensuring food safety by detecting contaminants, verifying ingredient authenticity, and monitoring flavor and fragrance compounds.
    6. Pharmaceutical Quality Control: In the pharmaceutical industry, GC-MS is used to analyze active pharmaceutical ingredients (APIs), detect impurities, and validate the stability of formulations, ensuring that products meet regulatory standards.
    7. Environmental Monitoring: GC-MS is essential for monitoring environmental pollutants, such as volatile organic compounds (VOCs), pesticides, and persistent organic pollutants (POPs), helping to protect public health and the environment.

    Applications of Gas Chromatography-Mass Spectrometry

    1. Environmental Testing: GC-MS is widely used to analyze air, water, and soil samples for pollutants like VOCs, pesticides, and polycyclic aromatic hydrocarbons (PAHs). Its sensitivity and specificity make it ideal for tracking environmental contamination and assessing compliance with environmental regulations.
    2. Pharmaceutical Analysis: In pharmaceuticals, GC-MS is used to ensure the purity and potency of APIs, detect residual solvents, and monitor the stability of drugs. It is also vital in drug development, where it helps identify and quantify impurities and degradation products.
    3. Forensic Toxicology: Forensic laboratories rely on GC-MS to analyze biological samples for drugs, alcohol, poisons, and other toxic substances. Its ability to provide definitive identifications makes it a critical tool in criminal investigations and legal proceedings.
    4. Food Safety and Quality: GC-MS is employed in the food industry to detect contaminants, such as pesticides and adulterants, verify the authenticity of ingredients, and analyze flavor and fragrance compounds. This ensures that food products are safe, high-quality, and compliant with regulations.
    5. Petrochemical Analysis: In the petrochemical industry, GC-MS is used to analyze complex hydrocarbon mixtures, monitor the composition of fuels and lubricants, and detect impurities in raw materials and finished products.
    6. Biotechnology and Research: GC-MS is essential in biotechnology and research laboratories for studying complex biological samples, analyzing metabolic profiles, and investigating chemical reactions.
    7. Clinical Diagnostics: In clinical settings, GC-MS is used to analyze blood, urine, and other biological samples for diagnostic purposes. It is particularly valuable for detecting metabolic disorders and monitoring therapeutic drug levels.

    Choosing the Right GC-MS System

    When selecting a GC-MS system, it is important to consider the specific requirements of your application. Key factors include the type of samples you will be analyzing, the need for sensitivity and specificity, and the range of analytes of interest. If your work involves complex mixtures or trace-level detection, a system with advanced ionization techniques, such as Electron Impact (EI) or Chemical Ionization (CI), might be necessary.

    Additionally, consider the system’s automation capabilities, data processing software, and spectral library access, as these can greatly impact the efficiency and accuracy of your analyses. For high-throughput environments, look for systems with robust automation options and user-friendly interfaces to streamline your workflow.

    The support and service provided by the manufacturer, including training, maintenance, and technical support, are also crucial considerations to ensure that your GC-MS system operates reliably over the long term.

    Conclusion

    Gas Chromatography-Mass Spectrometry (GC-MS) is the ultimate tool for advanced chemical analysis, offering unmatched precision, sensitivity, and versatility. Whether you are working in environmental science, pharmaceuticals, food safety, or forensics, GC-MS provides the detailed and accurate data you need to make informed decisions.

    With its ability to separate and identify complex mixtures, detect trace-level contaminants, and provide both qualitative and quantitative analysis, GC-MS is indispensable for ensuring product quality, regulatory compliance, and scientific discovery. Explore our selection of GC-MS systems to find the perfect match for your analytical needs, and take your laboratory’s capabilities to the next level.

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    Brand

    Kiparma

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