technology

right Environment See all product

Boiler and Cooling Tower Photometer

☆☆☆☆☆ ( 0 rates ) 508
Price : 540 USD

Code: #15256

Vietnamese version

Supplier: Hanna Instruments

HI83305 is a compact, multiparameter photometer intended for boiling and cooling tower applications for use in the lab or in the field. The meter is one of the most advanced photometers available with an innovative optical design that utilizes a reference detector and focusing lens to eliminate errors from changes in the light source and from imperfections in the glass cuvette. This meter has 30 different programmed methods measuring 18 key water quality parameters and also offers an absorbance measurement mode for performance verification and for users that would like to develop their own concentration versus absorbance curves. Parameters specific to boiling and cooling towers include oxygen scavengers and silica which are important for maintaining equipment.

rightMORE INFORMATION

  • The HI83305 benchtop photometer measures 18 different key water quality parameters using 30 different methods. This photometer features an innovative optical system that uses LEDs, narrow band interference filters, focusing lens and both a silicon photodetector for absorbance measurement and a reference detector to maintain a consistent light source ensures accurate and repeatable photometric readings every time.
    Specially designed for use with boilers and cooling towers, the HI83305 is a comprehensive way to maintain precise water conditions in systems. Problems such as corrosion, deposition, and microbial growth can occur if these key parameters, such as oxygen scavengers and silica, aren’t maintained. Oxygen scavengers are added to remove residual dissolved oxygen in boiler feed water that can cause corrosion in a steam generating plant. It is important that levels of oxygen scavengers be routinely checked to prevent against corrosion and ensure that equipment is working efficiently. Boiler water maintenance is necessary to prevent or control deposit formation as seen with silica. Silica contamination can reduce system efficiency and increase maintenance of equipment due to scaling.
    A digital pH electrode input allows the user to measure pH by a traditional glass electrode. The digital pH electrode has a built-in microchip within the probe that stores all of the calibration information. Having the calibration information stored in the probe allows for hot swapping of pH electrodes without having to recalibrate. All pH measurements are automatically compensated for temperature variations with a built-in thermistor located in the tip of the sensing bulb for fast and accurate temperature measurement.
    The HI83305 offers an absorbance measuring mode that allows for CAL Check standards to be used to validate the performance of the system. The absorbance mode allows the user to select one of the five wavelengths of light (420 nm, 466 nm, 525 nm, 575 nm, and 610 nm) to measure and plot their own concentration versus absorbance mode. This is useful for users with their own chemical method and for educators to teach the concept of absorbance by using the Beer-Lambert Law.
    Two USB ports are provided for transferring data to a flash drive or computer and to use as a power source for the meter. For added convenience and portability the meter can also operate on an internal 3.7 VDC Lithium-polymer rechargeable battery.

  • Parameter:

    Parameter

    Range

    Resolution

    Accuracy (at 25 °C)

    Method

    Wavelength

    Reagent Code

    Absorbance

    0.000 to 4.000 Abs

    0.001 Abs

    +/-0.003Abs @ 1.000 Abs

         

    Aluminum

    0.00 to 1.00 mg/L (as Al3+)

    0.01 mg/L

    ±0.04 mg/L ±4% of reading

    Adaptation of the aluminon method.

    525 nm

    HI93712-01

    Ammonia, Low Range

    0.00 to 3.00 mg/L (as NH3 -N)

    0.01 mg/L

    ±0.04 mg/L ±4% of reading

    Adaptation of the ASTM Manual of Water and Environmental Technology, D1426 Nessler method.

    420 nm

    HI93700-01

    Ammonia, Medium Range

    0.00 to10.00 mg/L (as NH3 -N)

    0.01 mg/L

    ±0.05 mg/L ±5% of reading

    Adaptation of the ASTM Manual of Water and Environmental Technology, D1426, Nessler method

    420 nm

    HI93715-01

    Ammonia, High Range

    0.0 to 100.0 mg/L (as NH3 -N)

    0.1 mg/L

    ±0.5 mg/L ±5% of reading

    Adaptation of the ASTM Manual of Water and Environmental Technology, D1426, Nessler method

    420 nm

    HI93733-01

    Bromine

    0.00 to 8.00 mg/L (as Br2 )

    0.01 mg/L

    ±0.08 mg/L ±3% of reading

    Adaptation of the Standard Methods for the Examination of Water and Wastewater, 18th edition, DPD method

    525 nm

    HI93716-01

    Chlorine Dioxide

    0.00 to 2.00 mg/L (as ClO2 )

    0.01 mg/L

    ±0.10 mg/L ±5% of reading

    Adaptation of the Chlorophenol Red method

    575 nm

    HI93738-01

    Chlorine Dioxide, Rapid Method

    0.00 to 2.00 mg/L (as ClO2 )

    0.01 mg/L

    ±0.10 mg/L ±5% of reading

    Adapted from Standard Methods for the Examination of Water and Wastewater,18 ed., 4500 ClO2 D.

    525 nm

    HI96779-01

    Chlorine, Free

    0.00 to 5.00 mg/L (as Cl2 )

    0.01 mg/L

    ±0.03 mg/L ±3% of reading

    Adaptation of the EPA DPD method 330.5

    525 nm

    HI93701-01

    Chlorine, Total

    0.00 to 5.00 mg/L (as Cl2 )

    0.01 mg/L

    ±0.03 mg/L ±3% of reading

    Adaptation of the EPA DPD method 330.5

    525 nm

    HI93711-01

    Chromium (VI), Low Range

    0 to 300 µg/L (as Cr(VI))

    1 µg/L

    ±10 µg/L ±4% of reading

    Adaptation of the ASTM Manual of Water and Environmental Technology, D1687 Diphenylcarbohydrazide method

    525 nm

    HI93749-01

    Chromium (VI), High Range

    0 to 1000 µg/L (as Cr(VI))

    1 µg/L

    ±5 µg/L ±4% of reading at 25 °C

    Adaptation of the ASTM Manual of Water and Environmental Technology, D1687, Diphenylcarbohydrazide method

    525 nm

    HI93723-01

    Copper, Low Range

    0.000 to 1.500 mg/L (as Cu)

    0.001 mg/L

    ±0.010 mg/L ±5% of reading

    Adaptation of the EPA method

    575 nm

    HI95747-01

    Copper, High Range

    0.00 to 5.00 mg/L (as Cu)

    0.01 mg/L

    ±0.02 mg/L ±4% of reading

    Adaptation of the EPA method

    575 nm

    HI93702-01

    Hydrazine

    0 to 400 µg/L (as N2H4)

    1 µg/L

    ±4% of full scale reading

    Adaptation of the ASTM Manual of Water and Environmental Technology, method D1385, p-Dimethylaminobenzaldehyde method

    466 nm

    HI93704-01

    Iron, Low Range

    0.000 to 1.600 mg/L (as Fe)

    0.001 mg/L

    ±0.010 mg/L ±8% of reading

    Adaptation of the TPTZ Method

    575 nm

    HI93746-01

    Iron, High Range

    0.00 to 5.00 mg/L (as Fe)

    0.01 mg/L

    ±0.04 mg/L ±2% of reading

    Adaptation of the EPA Phenanthroline method 315B, for natural and treated waters

    525 nm

    HI93721-01

    Iron (II) - Ferrous

    0.00 to 6.00 mg/L Fe2+ )

    0.01 mg/L

    & plusmn;0.10 mg/L ±2% of reading

    Adaptation of Standard Methods for the Examination of Water and Wastewater, 3500-Fe B., Phenanthroline Method

    525 nm

    HI96776-01

    Molybdenum

    0.0 to 40.0 mg/L (as Mo6+)

    0.1 mg/L

    ±0.3 mg/L ±5% of reading

    Adaptation of the mercaptoacetic acid method

    420 nm

    HI93730-01

    Nitrate

    0.0 to 30.0 mg/L (as NO3 - N)

    0.1 mg/L

    ±0.5 mg/L ±10% of reading

    Adaptation of the cadmium reduction method

    525 nm

    HI93728-01

    Nitrite, Low Range

    0 to 600 µg/L (as NO2-N)

    1 µg/L

    ±20 µg/L ±4% of reading

    Adaptation of the EPA Diazotization method 354.1

    466 nm

    HI93707-01

    Nitrite, High Range

    0 to 150 mg/L (as NO2-)

    1 mg/L

    ±4 mg/L ±4% of reading

    Adaptation of the Ferrous Sulfate method

    575 nm

    HI93708-01

    Oxygen, Dissolved

    0.0 to 10.0 mg/L (as O2)

    0.1 mg/L

    ±0.4 mg/L ±3% of reading

    Adaptation of the Standard Methods for the Examination of Water and Wastewater, 18th edition, Azide modified Winkler method

    420 nm

    HI93732-01

    Oxygen Scavengers (Carbohydrazide)

    0.00 to 1.50 mg/L (as Carbohydrazide)

    0.01 mg/L

    ±0.02 mg/L ±3% of reading

    Adaptation of the iron reduction method

    575 nm

    HI96773-01

    Oxygen Scavengers (Diethylhydroxylamine)(DEHA)

    0 to 1000 µg/L (as DEHA)

    1 µg/L

    ±5 µg/L ±5% of reading

    Adaptation of the iron reduction method

    575 nm

    HI96773-01

    Oxygen Scavengers (Hydroquinone)

    0.00 to 2.50 mg/L (as Hydroquinone)

    0.01 mg/L

    ±0.04 mg/L ±3% of reading

    Adaptation of the iron reduction method

    575 nm

    HI96773-01

    Oxygen Scavengers (Iso-ascorbic Acid)

    0.00 to 4.50 mg/L (as Iso-ascorbic acid)

    0.01 mg/L

    ±0.03 mg/L ±3 % of reading

    Adaptation of the iron reduction method

    575 nm

    HI96773-01

    pH

    6.5 to 8.5 pH

    0.1 pH

    ±0.1 pH

    Adaptation of the Phenol Red method

    525 nm

    HI93710-01

    Phosphate, Low Range

    0.00 to 2.50 mg/L (as PO4 3-)

    0.01 mg/L

    ±0.04 mg/L ±4% of reading

    Adaptation of the Ascorbic Acid method

    610 nm

    HI93713-01

    Phosphate, High Range

    0.0 to 30.0 mg/L (as PO4 3-)

    0.1 mg/L

    ±1.0 mg/L ±4% of reading

    Adaptation of the Standard Methods for the Examination of Water and Wastewater, 18th edition, Amino Acid method

    525 nm

    HI93717-01

    Silica, Low Range

    0.00 to 2.00 mg/L (as SiO2 )

    0.01 mg/L

    ±0.03 mg/L ±3% of reading

    Adaptation of the ASTM Manual of Water and Environmental Technology, D859, Heteropoly Molybdenum Blue method

    610 nm

    HI93705-01

    Silica, High Range

    0 to 200 mg/L (as SiO2)

    1 mg/L

    ±1 mg/L ±5% of reading

    Adaptation of the USEPA Method 370.1 for drinking, surface and saline waters, domestic and industrial wastes and Standard Method 4500-SiO2

    466 nm

    HI96770-01

    Zinc

    0.00 to 3.00 mg/L (as Zn)

    0.01 mg/L

    ±0.03 mg/L ±3% of reading

    Adaptation of the Standard Methods for the Examination of Water and Wastewater, 18th edition, Zincon method

    575 nm

    HI93731-01

    ** Reagents for 50 tests.† Unless noted otherwise, all reagent codes ending with -01 are for 100 tests.

     

    General Meter

    Wavelength Accuracy

    ±1 nm

    Light Source

    5 LEDs with 420 nm, 466 nm, 525 nm, 575 nm, and 610 nm narrow band interference filters

    Spectral bandwidth

    8 nm

    Input Channels

    1 pH electrode input and 5 photometer wavelengths

    pH Electrode

    digital pH electrode (not included)

    Logging Type

    log on demand with user name and sample ID optional input

    Logging Memory

    1000 readings

    Connectivity

    USB-A host for flash drive; micro-USB-B for power and computer connectivity

    GLP

    calibration data for connected pH electrode

    Display

    128 x 64 pixel LCD with backlight

    Battery Type / Life

    3.7 VDC Li-polymer rechargeable battery / >500 photometric measurements or 50 hours of continuous pH measurement

    Power Supply

    5 VDC USB 2.0 power adapter with USB-A to micro-USB-B cable (included)

    Environment

    0 to 50.0 oC (32 to 122.0 oF); 0 to 95% RH, non-condensing

    Dimensions

    206 x 177 x 97 mm (8.1 x 7.0 x 3.8")

    Weight

    1.0 kg (2.2 lbs.)

    Photometer/Colorimeter Light Detector

    silicon photodetector

    Cuvette Type

    round, 24.6 mm

    Number of Methods

    128 max.

    Ordering Information

    HI83305 is supplied with sample cuvettes and caps (4 ea.), cloth for wiping cuvettes, USB to micro USB cable connector, power adapter and instruction manual.

     

  • High Efficiency LED Light Source
    A LED light source offers superior performance as compared to a tungsten lamp. LEDs have a much higher luminous efficiency, providing more light while using less power. They also produce very little heat, which could otherwise affect the optical components a electronic stability. LEDs are available in a wide array of wavelengths, whereas tungsten lamps are supposed to be white light (all wavelengths of visible light) but actually have a poor blue/violet light output.
    High-Quality Narrow Band Interference Filters
    The narrow band interference filter not only ensure greater wavelength accuracy (+/- 1 nm) but are extremely efficient. The filters used allow up to 95% of the light from the LED to be transmitted as compared to other filters that are only 75% efficient. The higher efficiency allows for a brighter, stronger light source. The end result is higher measurement stability and less wavelength error.
    Reference Detector for a Stable Light Source
    A beam splitter is used as part of the internal reference system of the HI83305 photometer. The reference detector compensates for any drift due to power fluctuations or ambient temperature changes. Now you can rely on a stable source of light between your blank (zero) measurement and sample measurement.
    Large Cuvette Size
    The sample cell of the HI83305 fits a round, glass cuvette with a 25 mm path length. Along with the advanced optical components, the larger size of the cuvette greatly reduces errors in rotation from the indexing mark of the cuvettes. The relatively long path length of the sample cuvette allows the light to pass through more of the sample solution, ensuring accurate measurements even in low absorbance samples.
    Focusing Lens for Greater Light Yield
    Adding a focusing lens to the optical path allows for the collection of all of the light that exits the cuvette and focusing the light on the silicon photo detector. This novel approach to photometric measurements cancels the errors from imperfections and scratches present in the glass cuvette eliminating the need to index the cuvette.

 
Scroll