Full Spectrum Direct Reading Spectrometer 9000

Full Spectrum Direct Reading Spectrometer 9000

Application Areas

The Full Spectrum Direct Reading Spectrometer 9000 is a product developed by our company by introducing European technology and adopting internationally recognized advanced CCD spectrometer technology, specifically designed for the analysis of non-ferrous metal materials. This product is widely used in metallurgy, casting, machinery, automotive manufacturing, aerospace, metal processing, and other fields for production process control, furnace front testing, and finished product inspection in central laboratories. The 9000 Full Spectrum Direct Reading Spectrometer features a compact size, excellent stability, low detection limits, fast analysis speed, low operating costs, and convenient operation and maintenance, making it an ideal choice for quality control.

Main Features

1. Advanced CCD full-spectrum spectrometer manufacturing technology with unlimited channels;

2. Easy upgrade for multiple matrices without hardware changes;

3. Excellent data stability, with good data consistency when analyzing the same sample at different times;

4. Compact size and lightweight, easy to move and install;

5. High integration, high reliability, and high stability;

6. Energy-saving and material-saving, with energy consumption only 50% of ordinary spectrometers;

7. High cost-effectiveness.

Functional Introduction

1. Capable of measuring various elements in non-ferrous metals, suitable for multiple metal matrices such as aluminum-based, copper-based, and zinc-based. Full-spectrum technology covers the entire elemental analysis range, allowing channel elements to be selected according to customer needs;

2. Fast analysis speed, completing the measurement of all channel elements within 20 seconds. For different analysis materials, by setting pre-ignition time and calibration lines, the instrument achieves optimal analysis results in a shorter time;

3. The optical system uses a constant temperature optical chamber. The arc flame generated during excitation is directly guided into the optical chamber by a lens, achieving a direct optical path, eliminating optical path loss, improving detection limits, ensuring accurate measurement results, and excellent reproducibility and long-term stability;

4. Special optical chamber structure design, compact and lightweight;

5. Automatic optical path calibration. The optical system automatically performs spectral line scanning to ensure correct reception, eliminating tedious peak scanning work. The instrument automatically identifies specific spectral lines, compares them with stored lines, determines the drift position, and finds the current pixel position of the analysis line for measurement;

6. Open electrode holder design with adjustable sample clamps, facilitating the analysis of samples of various shapes and sizes;

7. Calibration curves use international standard samples, with pre-made calibration curves that can be extended and expanded as needed. Each curve is generated by exciting dozens of standard samples, automatically deducting interference;

8. HEPS digital solid-state light source, adaptable to various materials;

9. Copper spark table base, improving heat dissipation and sturdiness;

10. Reasonable argon gas path design shortens the argon flushing time during sample excitation, saving argon for users. Argon consumption is less than half of ordinary spectrometers;

11. Tungsten material electrodes with longer service life, and designed with electrode self-purging function for easier cleaning;

12. High-performance DSP and ARM processors with ultra-high-speed data acquisition and control functions, automatically monitoring the operating status of the optical chamber temperature, vacuum level, argon pressure, light source, excitation chamber, and other modules in real-time;

13. Ethernet connection with the computer, with good anti-interference performance. External computer upgrades are independent of the instrument configuration, providing better applicability;

14. All core components are imported, ensuring excellent instrument quality.

Technical Parameters

1. Optical System

Optical structure: Flat-field optical system

Optical chamber temperature: Automatically controlled constant temperature: 35°C ± 0.5°C

Wavelength range: 200-500nm

Grating focal length: 350 mm

Spectral width: 25.4mm

Detector: High-performance linear array CCD

2. Excitation Table

Gas: Argon flushing type

Argon flow rate: 3-5L/min during excitation, no standby flow required during standby

Electrode: Tungsten jet electrode technology

Purging: Self-purging function

Compensation: Thermal deformation self-compensation design

Analysis gap: Sample table analysis gap: 4mm

3. Excitation Light Source

Type: HEPS digital solid-state light source

Frequency: 100-1000Hz

Discharge current: 1-80A

Special technology: Discharge parameter optimization design

Pre-ignition: High-energy pre-ignition technology

4. Data Acquisition System

Processor: High-performance ARM processor, high-speed data synchronous acquisition and processing

Interface: Ethernet data transmission based on DM9000A

5. Power Supply and Environmental Requirements

Input: 220VAC 50Hz

Power: 700W (max) during analysis, 40W in standby mode

Operating temperature: 10-30°C (temperature change within this range not exceeding 5°C/h)

Operating humidity: 20-80%

6. Dimensions and Weight

Main unit dimensions: 500*450*300mm

Weight: 30Kg