KULIM Kht Advantages of optical tensiometry Contact Angle Measurements.

Advantages of optical tensiometryDEMO ON RUBBER GLOVE MOULD.

Optical tensiometry is the best choice when liquid-solid interactions and/or solid properties (such as surface free energy) are

 measured on samples that are not homogeneous and regular in size and shape. The main benefits are following: Small liquid volume demanded (only some microliters) Solid substrate can be asymmetrical (e.g. rubber glove mould) Both sides of the sample don’t need to be similar (coating and surface modification characterization) Contact angle mapping over the surface enables heterogeneity  and cleanliness characterization Roughness correction possible e.g. by using 3D Topography module

Kulim Kht Cortest ASME HPHT Autoclave systems

HPHT Autoclave systems are used for high pressure and high temperature test applications. We offers both standard system designs as well as custom configurations to meet the most demanding of applications. Our autoclave systems can be used for a variety of different tests including: corrosion inhibitor analysis, electrochemical studies, performance evaluation of coatings, corrosion studies using weigh loss coupons, shear stress analysis, slow strain rate tests, and much more. Each pressure vessel is designed in accordance to the ASME Section VIII Div. 1 standard. PED, CSA, CE, DOSH, and the China Special Equipment Manufacture License certificates are available upon request.

Kulim Kht Critical micelle concentration (CMC)

Introduction
Critical micelle concentration (CMC) is defined as the
concentration of surfactants in which micelles are spontaneously
formed. Below the CMC point surfactant molecules tend
to accumulate at the interface, reducing surface tension. At
CMC, the surface tension of the solution does not change but
remains constant, as the gas-liquid interface is already saturated
with the surfactant molecules. Above the CMC point most of
the surfactant molecules are inside the bulk, aggregating into
micelles. When this occurs, the addition of surfactants just
increases the number of micelles and the surface tension becomes
independent of surfactant concentration.
There are several factors affecting the CMC point of a surfactant.
These include the amphiphile chain length, dissolved salts, the
structure of the head group, temperature, the structure of the
alkyl chain and polar additives. The effects of chain length, salts
and alcohol on the critical micelle concentration have been
widely studied [1]. The exact molar weight and impurities in
the surfactant also influence the CMC, and therefore a careful
purification of the surfactant is relevant. A common and much
studied surfactant found in many detergents is sodium dodecyl
sulfate (SDS). SDS is easily hydrolyzed to dodecanol, which can be
seen as a possible contaminant [2].
The critical micelle concentration is a useful measure also in
pharmacology. Silicon surfactants are important in pharmaceutical
and cosmetic industry due to their low price and technological
advantages [3]. Liposomes can be used to carry non-polar drug
molecules in blood where as polymeric nanoparticles are found
to be useful in selective delivery of cancer drugs [4]. Studies on
interfacial properties of these drug carrying compounds require
the full understanding of the molecule’s CMC.