Chemicals & Polymers Blog

Uses for Neopentyl Glycol (NPG) Applications | Gantrade

Written by Gantrade | April 3, 2018

At Gantrade, we offer an array of diols and polyols, a group of  versatile hydroxyl-functional intermediates used in a broad range of applications and industries.

Neopentyl Glycol, NPG (2, 2-dimethylpropane-1, 3-diol) is the standard diol for high performance coating resins. The polyesters synthesized by NPG with saturated or unsaturated di-acids offer a great ingredient for paints, lubricants, plasticizers and fiberglass-reinforced plastics applications. NPG enhances stability toward heat, light, and water.  NPG achieves high performance of resins due to its resistance to oxidation, its non-polar chemical nature, and steric retardation of hydrolysis. Most polyester resin formulations contain NPG as the sole glycol component, or feature NPG in conjunction with a modifying glycol to achieve the desired properties.

NPG is a white crystalline solid with a melting point of 127⁰C. This solid flake form has a tendency to fuse together and form a block, becoming difficult to separate, transfer, and handle.

There are several forms of NPG available for selection, depending on conditions specified for manufacturing and application:

  • Molten NPG,transported at high temperature, ships in heated tank trucks. For molten NPG to arrive at the plant intact  it is necessary for the heated storage tank to maintain a temperature at or above 140⁰C.

  • A slurry / suspension form of NPG in water (90% NPG by weight) is a liquid at or above 38°C. This form of NPG ships in bulk at temperatures ranging from 50 – 70⁰C, enabling storage at a much lower temperature than molten NPG, at around 55 – 60⁰C.

  • The flake form arrives in bags with the potential to agglomerate on storage.

NPG has a combination of great properties but is rather complicated to handle; thus, we are continuously searching for a way to make handling easier. In contrast, we have found that MPO(2-methyl-1, 3-propanediol) has an equivalent resistance against UV light combined with humidity.

Conventional wisdom previously held that the degradation process through oxidation occurred  via UV-initiated radical chain propagation. Instead of a cleaving C-C bond, we have found that  the liability of related C-H bond impacts the propagation rate and ultimately the rate of damage to a polymer film. A FMOC analysis indicated the C-H bond next to the ester links are the most vulnerable to oxidation attack. This theory offers only a minor difference between NPG and MPO in weatherability,  confirmed by accelerated aging tests.

The below charts illustrate that NPG-based polyester formulation PE-100 is equal-to-less effective in gloss retention than MPO-based PE-200 and PE-2186 in a QUV-340 and QUV-B313 accelerated weathering test.  This result confirmed MPO’s equally effectived weatherability in coating formulations.   

We can compensate for any possible differences in MPO by adjusting the hydrophobicity and glass transition temperature of the final coating.

With this encouraging find, we looked into other properties of NPG.  Another performance highlight of NPG-based polyester is its hydrolysis resistance.  To make an apples-to-apples comparison, we synthesized polyester polyols using Adipic Acid to achieve a molecular weight 1000 polymerized diol.  We mixed several such polyester polyols  each with 10% weight of water and heated to 90⁰C separately.  Also, we titrated acid value  hourly to monitor the decomposition of each polyester polyol to form acid.

The test showed that NPG-based polyester polyol (orange line) is better for hydrolysis resistance  than some polyester-diols but has similar or a little less hydrolytic stability than MPO-based (grey line) polyester-diol. A similar result should prove true when other di-acids are used to form the polyester, like Isophthalic Acid, Terephthalic Acid etc.

Hot water degradation test

over 12hrs @ 90°C (10% Water = 90% Polyol)


MPO has other very user friendly characteristics:

The illustrated performance makes MPO appealing as an economical alternative  for NPG, especially for coatings requiring a cold weather performance.  This low Tg comes from the very low freezing temperature of MPO (-54⁰C).

  • Low viscosity (178 cps) for ease of pouring and pumping.

  • Water-clear color.

  • Fast reaction speed dueto its sterically less-hindered structure versus that of NPG.

  • Low tendency to pick up moisture from the environment, for easier process control.

  • The low melting point of the monomer MPO translates to a lower Tg of a MPO adipate.

An experimental test revealed a good compatibility with a high percentage of NPG that can form a stable mixture with MPO.  This compatibility will give users the following benefits:

  • Ability to pump and pour at room temperature without expensive heated storage and transportation.

  • All components will react into final product without extracting and disposal of extra water (from the NPG/water slurry/suspension).

  • Built-in process aid to wash sublimed NPG off the reactor dome to improve efficiency.  

  • Lower reactor temperatures or shorter reaction times affording low color resins and reduced energy requirements.

With further trials using MPO in polyester applications, we find even more benefits:

  • Good shock resistance at hot and cold temperatures.

  • Good cracking resistance in can & coil coating.

  • Good adhesion and flexibility in powder coating.

With confirmed positive feedback in paints, coating and plasticizer applications, we are further investigating MPO’s feasibility in other NPG applications like lubricants, hydraulic oils, etc using its unique properties in low viscosity, oxidation and hydrolytic stability.

For more information on MPO available at Gantrade, contact us today.