Labwares
The large hexagonal base prevents the cylinder from rolling. The base is equipped with three knobs which increase its stability. The cylinders have uniform wall thickness over the entire measurement range, so wedge errors are avoided. Calibration is based on the poured in volume (“In”) at a +20 °C reference temperature. Measuring cylinder accuracy limits conform to DIN and ISO standards (class B).
The large hexagonal base prevents the cylinder from rolling. The base is equipped with three knobs which increase its stability. The cylinders have uniform wall thickness over the entire measurement range, so wedge errors are avoided. Calibration is based on the poured in volume (“In”) at a +20 °C reference temperature. Measuring cylinder accuracy limits conform to DIN and ISO standards (class B).
The large hexagonal base prevents the cylinder from rolling. The base is equipped with three knobs which increase its stability. The cylinders have uniform wall thickness over the entire measurement range, so wedge errors are avoided. Calibration is based on the poured in volume (“In”) at a +20 °C reference temperature. Measuring cylinder accuracy limits conform to DIN and ISO standards (class B).
The large hexagonal base prevents the cylinder from rolling. The base is equipped with three knobs which increase its stability. The cylinders have uniform wall thickness over the entire measurement range, so wedge errors are avoided. Calibration is based on the poured in volume (“In”) at a +20 °C reference temperature. Measuring cylinder accuracy limits conform to DIN and ISO standards (class B).
The large hexagonal base prevents the cylinder from rolling. The base is equipped with three knobs which increase its stability. The cylinders have uniform wall thickness over the entire measurement range, so wedge errors are avoided. Calibration is based on the poured in volume (“In”) at a +20 °C reference temperature. Measuring cylinder accuracy limits conform to DIN and ISO standards (class B).
The large hexagonal base prevents the cylinder from rolling. The base is equipped with three knobs which increase its stability. The cylinders have uniform wall thickness over the entire measurement range, so wedge errors are avoided. Calibration is based on the poured in volume (“In”) at a +20 °C reference temperature. Measuring cylinder accuracy limits conform to DIN and ISO standards (class B).
The large hexagonal base prevents the cylinder from rolling. The base is equipped with three knobs which increase its stability. The cylinders have uniform wall thickness over the entire measurement range, so wedge errors are avoided. Calibration is based on the poured in volume (“In”) at a +20 °C reference temperature. Measuring cylinder accuracy limits conform to DIN and ISO standards (class B).
The large hexagonal base prevents the cylinder from rolling. The base is equipped with three knobs which increase its stability. The cylinders have uniform wall thickness over the entire measurement range, so wedge errors are avoided. Calibration is based on the poured in volume (“In”) at a +20 °C reference temperature. Measuring cylinder accuracy limits conform to DIN and ISO standards (class B).
Numbering from the top down. Calibration is based on the poured out volume (“Ex”) at a +20 °C reference temperature. Due to the scale, variable volumes can be held and then dispensed in the same or differing increments. Typical applications: accurate measurement and decanting of liquids.
Numbering from the top down. Calibration is based on the poured out volume (“Ex”) at a +20 °C reference temperature. Due to the scale, variable volumes can be held and then dispensed in the same or differing increments. Typical applications: accurate measurement and decanting of liquids.
Numbering from the top down. Calibration is based on the poured out volume (“Ex”) at a +20 °C reference temperature. Due to the scale, variable volumes can be held and then dispensed in the same or differing increments. Typical applications: accurate measurement and decanting of liquids.
Numbering from the top down. Calibration is based on the poured out volume (“Ex”) at a +20 °C reference temperature. Due to the scale, variable volumes can be held and then dispensed in the same or differing increments. Typical applications: accurate measurement and decanting of liquids.
Numbering from the top down. Calibration is based on the poured out volume (“Ex”) at a +20 °C reference temperature. Due to the scale, variable volumes can be held and then dispensed in the same or differing increments. Typical applications: accurate measurement and decanting of liquids.
Numbering from the top down. Calibration is based on the poured out volume (“Ex”) at a +20 °C reference temperature. Due to the scale, variable volumes can be held and then dispensed in the same or differing increments. Typical applications: accurate measurement and decanting of liquids.
Numbering from the top down. Calibration is based on the poured out volume (“Ex”) at a +20 °C reference temperature. Due to the scale, variable volumes can be held and then dispensed in the same or differing increments. Typical applications: accurate measurement and decanting of liquids.
blue inscription, Blow-out, zero at top, graduated to tip (total delivery), with main graduations as circular divisions and cotton plug, with certificate of conformity and batch certificate
blue inscription, Blow-out, zero at top, graduated to tip (total delivery), with main graduations as circular divisions and cotton plug, with certificate of conformity and batch certificate
blue inscription, Blow-out, zero at top, graduated to tip (total delivery), with main graduations as circular divisions and cotton plug, with certificate of conformity and batch certificate
blue inscription, Blow-out, zero at top, graduated to tip (total delivery), with main graduations as circular divisions and cotton plug, with certificate of conformity and batch certificate