[0001] This invention relates to piezoelectric materials and to methods for producing such
materials. The invention has particular reference to polymeric materials exhibiting
piezoelectric properties and to the production of such materials for use in electro-acoustic
transducer devices.
[0002] It has been found that certain polymeric materials, for example polyvinylidene fluoride
(hereinafter referred to as PVF
2), exhibit piezoelectric properties, and that these properties can be enhanced considerably
by exposing the material to treatment known as "poling". Poling usually involves the
application to the material, whilst at an elevated temperature, of a high voltage
electric field.
[0003] In practice, the material, usually in the form of a film, has electrodes applied
to both faces is placed in an oven and when at the required temperature a polarising
voltage is applied across the electrodes. Typically, temperatures in the range of
from 100
00-120
0C are used in conjunction with voltages in the order of one megavolt per centimetre
of film thickness.
[0004] The enhanced level of piezoelectricity produced in the film is a function of the
magnitude of both the treatment temperature and the applied electric field. However,
the extent to which the treatment temperature can be raised is limited by the melting
point of the material, whilst the extent to which the applied electric field can be
increased in limited by the dielectric strength of the film. Defects in the film for
example bubbles, pin holes, scratches and included foreign bodies constitute weak
spots in the film and electrical breakdown of the film is liable to occur at such
spots. When breakdown occurs, damage is caused to the film and to the electrodes and
results sometimes in the rejection of a length of film which is thus wasted. Breakdowns
are more frequent at higher applied electric fields and elevated temperatures.
[0005] Thus, although it is known that greater enhancement of piezoelectric activity is
obtainable by using higher applied electric fields
and elevated temperatures, it has not been possible to take full advantage of this
for the reasons set out above.
[0006] According to the present invention a method of enhancing the piezoelectric properties
of a polymeric material exhibiting such properties is characterised in that, before
subjecting the material to a "poling" treatment, the material is exposed whilst in
an atmosphere inert with respect to the material and at substantially room temperature
to a quantity of gamma (y) radiation lying within the range of from 1 Mrad to 200
Mrads (both limits included).
[0007] Specifically, the invention also provides a method of enhancing the piezoelectric
activity of polyvinylidene fluoride by exposing the latter whilst in an atmosphere
inert with respect thereto and at substantially room temperature to a quantity of
y radiation lying within the range of from 1 Mrad to 200 Mrads (both limits included)
after which the material is subjected to a poling treatment.
[0008] The improved enhancement of the piezoelectric properties of the material renders
the material more useful in nearly all of its applications. For example, it improves
the sensitivity of an electro-acoustic transducer fitted with a piezoelectric material
according to the invention.
[0009] In one method embodying the invention the polyvinylidene fluoride is in the physical
form of a biaxially orientated film.
[0010] The phrase "in an atmosphere inert with respect to the material", or "in an atmosphere
inert with respect thereto" is intended to include irradiation in a vacuum in which
the air pressure does not exceed 10
-3 mm Hg (0.13 N/m
2) as well as irradiation in an atmosphere that does not cause embrittlement of the
material undergoing irradiation. It has been found that it is important to exclude
oxygen from the atmosphere. An example of an inert atmosphere is a nitrogen atmosphere
and this can be obtained by flushing out with nitrogen the chamber in which irradiation
is to be effected to remove all air.
[0011] The quantity of y radiation to which the material is exposed preferably lies in the
range of from 1 Mrad to 99 Mrads (both limits included). The enhancement of the piezoelectric
properties of the material is particularly pronounced at these lower exposure levels.
[0012] The invention also provides a polymeric material exhibiting piezoelectric properties
which have been enhanced by a method as defined above.
[0013] By way of example only, a method of enhancing the piezoelectric activity of biaxially
orientated polyvinylidene fluoride film will now be described with reference to Figure
1, the accompanying drawing, which is a schematic sectional view of a sample of the
film being irradiated.
[0014] Prior to irradiation, vacuum evaporated
aluminium electrodes are formed on both sides of the film using conventional techniques.
Referring to Figure 1, a strip of the film 1 having, for example, a thickness of 25
µm, a width of about 30 cm and a length of a few hundred metres, is then wound onto
a reel 2 and placed in a dessicator 3, maintained at room temperature and exhausted
to 10-
5mm Hg (1.3.x 10
-3 N/m
2), oxygen being excluded. The dessicator is in turn placed in a concrete bunker 5
and irradiated from a source of radiation 6, for example Cobalt 60. The film 1 is
exposed to a preselected quantity of radiation lying within the range of from 1 to
200 Mrads and illustrated schematically by arrows 4 in Figure 1; the direction and
intensity of radiation incident on the film depends on the position of the dessicator
3 in the bunker. After irradiation, the dessicator 3 is removed from the bunker, the
reel 2 is removed from the dessicator and the film is poled by application across
the electrodes of an electric field while the film is at an elevated temperature.
[0015] In the method described above, the aluminium electrodes are formed on the film before
irradiation but the formation of electrodes may be deferred until after irradiation
if desired.
[0016] Samples of films treated in various ways have been tested. In the tests the film
was that produced by the firm Kureha Kagaku Kogyo Kabushiki Kaisha of Tokyo, Japan
and is of 25 pm thickness. Prior to treatment vacuum evaporated aluminium electrodes
were formed on both sides of the film using conventional techniques.
[0017] The sample was then placed in a vacuum chamber maintained at room temperature and
exhausted to 10
-5mm Hg (1.3 x 10
-3N/m
2), oxygen being excluded. The chamber was then removed to a source ofy radiation,
namely Cobalt 60. After irradiation, the sample was removed. Subsequently, the sample
was "poled" by application across the electrodes of an electric field while the sample
was at an elevated temperature.
[0018] After poling the sample was subjected to tests to measure its piezoelectric activity.
The activity was measured by stressing the sample in a direction lying along the machine
or roll direction of the film.
[0019] The following table shows the piezoelectric activity of the film. The first column
of the table sets out the irradiation treatment to which the portion of film was exposed,
whilst the second column gives details of the "poling" treatment. Of the details given
in the second column, the first figure is the poling field, the second is the poling
temperature and the third is the duration of the poling treatment. The third column
gives the measured value of the piezoelectric coefficient for stress applied along
the machine direction.
[0020] It will be observed that there is a substantial increase in piezoelectric activity
in certain of the samples as a result of the pre-poling irradiating treatment. be
[0021] It will/appreciated that a given level of piezoelectric activity may be produced
by employing the irradiation treatment in conjunction with a poling treatment employing
lower levels of polarising potential than would be necessary to produce that level
of piezoelectric activity employed without irradiation. Such a combination will enable
material which would previously have been rejected as defective to be utilised.
[0022] Polymeric materials, other than polyvinylidene fluoride, which exhibit latent piezoelectricity
may also be treated by processes embodying the invention. While not constituting a
limitation in the scope of the invention, such other materials would importantly include
copolymers of polyvinylidene fluoride, e.g. copolymer of ethylene and vinylidene fluoride,
copolymer of vinylidene fluoride and tetrafluoroethylene, copolymer of vinylidene
fluoride and vinyl fluoride, copolymer of vinylidene fluoride and trifluoromonochloroethylene,
and the like. Also included are such halogen containing polymers as polyvinyl fluoride,
polyvinyl chloride and the like.
[0023] In addition, it is not essential that the material be in film form or in the form
of a biaxially orientated film.
[0024] As piezoelectrical properties are intimately linked with pyro-electrical properties,
it is likely that the above described treatment will also enhance the pyroelectric
coefficient of the material.
[0025] The treated material is suitable for use in microphone transmitters, receivers and
pressure transducers.
1. A method of enhancing the piezoelectric properties of a polymeric material (1)
exhibiting such properties, the method including the step of subjecting the material
to a "poling" treatment, characterised in that, before the "poling" treatment, the
material (1) is exposed whilst in an atmosphere inert with respect to the material
and at substantially room temperature to a quantity of y radiation (4) lying within
the range of from 1 Mrad to 200 Mrads (both limits included).
2. A method as claimed in claim 1, further characterised in that the material (1)
is polyvinylidene fluoride.
3. A method as claimed in claim 2, further characterised in that the polyvinylidene
fluoride is in the form of a biaxially orientated film.
4. A method as claimed in any preceding claim, further characterised in that the inert
atmosphere is a vacuum in which the air pressure does not exceed 10-3 mm Hg (0.13 h/m2).
5. A method as claimed in any preceding claim, further characterised in that the quantity
of y radiation (4) to which the material (1) is exposed lies in the range of from
1 Mrad to 99 Mrads (both limits included).
6. A polymeric material exhibiting piezoelectric properties characterised in that
the pieozelectric per- perties of the material (4) have been enhanced by a method
as claimed in any preceding claim.