Polyvinylidene Fluoride (PVDF) - Material Properties & Other Info

What is PVDF?

Polyvinylidene fluoride (PVDF) or polyvinylidene difluoride (PVF₂) is a semi-crystalline thermoplastic fluoropolymer. It has a high purity with service temperatures up to 150°C.

The polymer chain has alternating CH₂ and CF₂ groups. The polarity of these groups leads to:

Insolubility
Electrical properties

Molecular Structure of Polyvinylidene Fluoride (PVDF)

PVDF has become the largest volume of fluoropolymers after PTFE. Thanks to its excellent combination of properties and processability. It is commercially available in a wide range of melt flow rates and with various additives. This enhances the processing or end-use properties.

How to produce PVDF?

PVDF is generally synthesized by the free radical polymerization of 1,1-difluoroethylene (CH₂=CF₂). The polymerization takes place in the suspension or emulsion at:

Temperature: 10-150°C
Pressure of 10-300 atm

The material obtained is then processed into film or sheets.

Chlorotrifluoroethylene (CTFE) or hexafluoropropene (HFP) are most commonly employed to prepare PVDF copolymers.

PVDF copolymers with HFP contain increased flexibility over PVDF homopolymer grades.
Copolymers with CTFE are among the most flexible PVDF products. The show excellent low-temperature performance and low shrinkage.

Copolymers are ideal for wire & cable and tubing applications, which require enhanced flexibility.

What are the properties of PVDF?

Crystal structure

It is typically a semi-crystalline polymer that is approximately 50% amorphous. It has a highly regular structure with most of the VDF units joined head-to-tail. A very less percentage of these monomer units joined head-to-head.

This fluoroplastic exists in four possible conformations named α, β, γ, and δ phases.

The C–F bonds are polar. The highest dipole moment is obtained with the alignment of all dipoles of the polymer in the same direction. This corresponds to the β-phase of the PVDF. β-phase is the desired phase for the piezoelectric characteristics of the polymer.
The dipole moments of α crystallites are oriented in opposite directions. This results in zero net polarization.

Alpha- and Beta-phase Structure of PVDF
(Source: Royal Society of Chemistry)

Physical properties

It has one of the lowest melting points of commercial fluoropolymers. But has the highest heat deflection temperature under load.

Polymer	Deflection Temperature, °C		Melting Point, °C
Polymer	0.5 MPa	1.8 MPa	Melting Point, °C
PVDF	148	113	178
PCTFE	126	75	218
PTFE	121	56	327
ECTFE	116	77	240
ETFE	104	74	270
PFA	73	48	310
FEP	70	51	270

PVDF provides very low permeation values compared to other fluoropolymers. This is due to high crystallinity and surface tension properties. PVDF shows low permeabilities to gases and liquids. Though, the permeability of PVDF is influenced by:

the crystalline degree and
the modification of crystalline parts.

Mechanical properties

PVDF shows the following characteristics when compared to ETFE and ECTFE.

PVDF has similar tensile modulus but lower impact strength.
Modification with HFP or CTFE lowers the modulus but increases elongation and impact strength.
When exposed to flame, PVDF is non-flammable and non-dripped. It is self-extinguishing – It is TL V0 compliant. The LOI is 44%.
It also exhibits good resistance to UV light.

Property (Standard)	PVDF values	vs. ETFE values	vs. ECTFE values
Melting point, °C, ASTM D 3418	154-184	250-275	236-246
Specific gravity, g/cm³, ASTM D 792 (Solid)	1.75-1.80	1.72	1.7
Tensile Strength @ 23°C, MPa, ASTM D 638	36-56	38-48	45-60
Elongation @ 23°C, %, ASTM D638	25-500	100-350	150-250
Tensile Modulus @ 23°C, MPa, ASTM D 638	1340-2000	830	-
Izod impact strength @ 23°C, J/m, ASTM D 256	160-530	no break	no break
Coefficient of thermal expansion, ASTM D 696	~10^-4	9 x 10^-5	5 x 10^-5
Processing temp. range, °C	200-300	300-345	260-300
Dielectric constant, (1 kHz), ASTM D 150	7.5-13.2	2.6	2.6
Dielectric strength, kV/mm, ASTM D 149	260-950	59	80-90
Dissipation factor, (1 kHz), ASTM D 150	0.0163-0.019	0.0008	0.0024
LOI, %, ASTM D 2863	44	30	64
Get more information about polymer properties here »

Chemical resistance

The chemical inertness varies between the different fluoropolymers.

PTFE, FEP, PFA, and MFA exhibit chemical inertness to a wider range of chemicals.
Partially fluorinated polymers show chemical inertness to a narrower range of chemicals. Examples of partial fluoropolymers include CTFE, PCTFE, and ECTFE.

At elevated temperatures, PVDF can be dissolved in organic solvents such as esters and amines. This allows PVDF to be applied as corrosion-resistance coatings on chemical process equipment and architectural panels.

Parts made of PVDF display great resistance to:

mineral and organic acids,
aliphatic and aromatic hydrocarbons,
alcohols and halogenated solvents.

View the complete range of PVDF grades that show good resistance to chemicals.

Electrical properties

Electrical and Piezoelectric Properties of PVDF

PVDF is primarily used in wire and cable isolation. Thanks to its high dielectric constant and dissipation factor. However, their poor electrical properties allow the production of PVDF films with:

piezoelectric behavior and
pyroelectric behavior

These films are prepared from extruded films in B-phase conformation. Both surfaces of the film are metalized and then subjected to high voltage. This leaves it permanently polarized. Such films generate a voltage when stretched or compressed (piezoelectricity) or heated (pyroelectricity) at a temperature close to the melting point. The polymer films also show some ferroelectricity.

How to process PVDF?

PVDF grades are available in a wide range of melt viscosities as powders and pellets. It can be processed using techniques applicable to standard thermoplastics:

Extrusion
Injection, compression and transfer molding
Machining

Drying of resin before processing is usually not necessary Care must be taken to eliminate "hang-up" areas where molten resin can collect and thermally decompose if residence time is excessive

Processing temperature: 190 to 280°C

Injection Molding

Melt temperature should be between 200-270°C
A mold temperature of 50-95°C is recommended
The relatively high melt viscosity of PVDF makes proper mold design an important factor in injection molding
The shrinkage (3-4 %) of injected molded pieces, has to be take into consideration during conception

View all PVDF grades processed by injection molding.

Extrusion

In extrusion, attention should be paid to the elimination of dead spots where degradation of polymer can start
Extrusion temperature : from 230 to 290°C
No extrusion aids, lubricants, or heat stabilizers are needed to extrude PVDF
L/D ratio of at least 20 is recommended

View all PVDF grades processed by extrusion.

What are the uses of PVDF membranes?

PVDF Membranes are Widely Used for Waste Water Treatment

PVDF is one of the most used membrane materials. It has received great attention due to its outstanding properties. PVDF is ideally used in biomedical membrane applications and waste-water treatment. This is due to properties such as thermal stability, chemical resistance, and processability.

Thank to these features, applications of PVDF membranes are currently found in:

Pressure-driven water- and waste-treatment treatment (e.g., microfiltration, ultrafiltration, and membrane bioreactor)
Membrane contactors operations (e.g., membrane distillation, acid gas absorption and stripping, volatile organic compounds removal)

Today, most commercial membranes are produced via the phase inversion method. This is mainly because of its simplicity and flexible production scales. Hence, there is a low cost of production.

But there are certain drawbacks associated with PVDF membranes such as wetting or fouling which can be easily solved by:

enhancing surface roughness or
increasing the hydrophilic nature of the membrane.

Though it cannot be absolutely prevented even with modification.

Is PVDF recyclable?

Yes, PVDF (Polyvinylidene fluoride) is recyclable. It can be melted and reprocessed multiple times. Thus, it doesn't lead to any significant degradation of its properties. However, it's important to note that the recycling of PVDF might not be as readily available as common materials (e.g., PET or HDPE).

Are PVDF resins toxic?

PVDF is generally considered safe for many applications. It is a thermoplastic polymer that has a high resistance to chemicals, UV radiation, and extreme temperatures. This makes it suitable for various industries. In terms of human health, PVDF is generally regarded as non-toxic and biocompatible. Hence, it has been used in medical applications such as implants, prosthetics, and drug delivery systems.

Key Properties

	Property	PVDF
Chemical Resistance
Aromatic hydrocarbons @ 20°C	Satisfactory
Ethanol @ 96%, 20°C	Satisfactory
Acetone @ 100%, 20°C	Limited
Ammonium hydroxide @ 30%, 20°C	Limited
Benzene @ 100%, 20°C	Satisfactory
Butylacetate @ 100%, 20°C	Satisfactory
Chlorinated solvents @ 20°C	Satisfactory
Chloroform @ 20°C	Satisfactory
Dioctylphtalate @ 100%, 100°C	Satisfactory
Dioctylphtalate @ 100%, 20°C	Satisfactory
Ethyleneglycol (Ethane diol) @ 100%, 100°C	Satisfactory
Gasoline	Satisfactory
Glycerol @ 100%, 20°C	Satisfactory
Hydrogen peroxide @ 3%, 20°C	Satisfactory
Kerosene @ 20°C	Satisfactory
Methanol @ 100%, 20°C	Satisfactory
Methylethyl ketone @ 100%, 20°C	Limited
Mineral oil @ 20°C	Satisfactory
Phenol @ 20°C	Satisfactory
Sodium hydroxide @ 10%, 20°C	Limited
Sodium hydroxide @ 10%, 60°C	Limited
Sodium hypochlorite @ 20%, 20°C	Limited
Sodium hypochlorite @ 20%, 20°C	Satisfactory
Toluene @ 20°C	Non Satisfactory
Xylene @ 20°C	Non Satisfactory
Electrical
Arc Resistance, sec	50-70
Dielectric Constant	6-9
Dielectric Strength, kV/mm	10-27
Dissipation Factor x 10^-4	200-1700
Volume Resistivity x 10¹⁵, Ohm.cm	5-14
Mechanical
Elongation at Break, %	50-300
Elongation at Yield, %	2-16
Flexural Modulus, Gpa	1.5-2
Hardness Rockwell M	75
Hardness Shore D	65-82
Strength at Break (Tensile), MPa	40-50
Strength at Yield (Tensile), MPa	20-56
Toughness, J/m	130-400
Young's Modulus, GPa	1.5-2
Physical
Density, g/cm³	1.7-1.8
Gamma Radiation Resistance	Good
Glass Transition Temperature, °C	-42--25
Shrinkage, %	2-4
Sterilization Resistance (Repeated)	Excellent
UV Light Resistance	Good
Water Absorption 24 hours, %	0.03-0.05
Service Temperature
Ductile / Brittle Transition Temperature, °C	-62--30
HDT @0.46 Mpa (67 psi), °C	70-150
HDT @1.8 Mpa (264 psi), °C	50-125
Max Continuous Service Temperature, °C	70-150
Min Continuous Service Temperature, °C	-40
Thermal
Coefficient of Linear Thermal Expansion x 10^-5, /°C	8-15
Fire Resistance (LOI), %	44-83
Flammability, UL94	V0
Thermal Insulation, W/m.K	0.18

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Comprehensive Guide on Polyvinylidene Fluoride (PVDF)