[0001] This invention relates to the use of treated niobium or tantalum as a connector and
such a . connector and has particular reference to the treatment of niobium or tantalum
to improve its resistance to a previously unknown crevice corrosion attack.
[0002] It has already been proposed to use niobium as a connector, particularly for use
in a saline solution such as seawater. Such a connector is described in detail in
British published Application No 2 001 807A. Niobium is chosen as a particularly suitable
material for such a connector for a number of reasons. The purpose of the connector
is to permit a dismantlable connection to be made in an electrical line feeding positive
current to an underseas anode in an impressed current cathodic protection system.
[0003] The electrical connector proposed in Patent Specification No 2 001 807A has a number
of distinct advantages over previous electrical connectors in that it is easily dismantlable
and assemblable and by comparison to previous connectors is comparatively inexpensive.
Niobium is chosen as a particularly suitable material for such an electrical connector
as it is normally recognised that niobium can be connected and operated as an anode
in a saline solution, such as seawater, without corroding at anodic voltages less
than approximately 100 volts. The anodic properties of niobium are well-known and
it is well-known that niobium forms a resistant and insulating niobium oxide film
at applied voltages of up to 100 volts. Above that voltage, known as the breakdown
voltage, the film fails and the material corrodes rapidly. Before the present invention,
however, it was considered that bulk niobium was self-passivating at voltages below
the breakdown voltage. Unexpectedly, however, it was found that when connectors formed
of niobium were tested they could, in certain conditions, corrode rapidly. Why this
should happen was not to be found in any literature known to the applicants. An answer
to the problem has now been found and basically the solution, which forms one feature
of the present invention, is to pre-treat the niobium by pickling to remove contamination
and surface oxide films and subsequently to form ah oxide film on the surface of the
niobium.
[0004] As a result of investigations carried out by the applicants it has been found that
such a pre-treatment is known per se but has only been proposed as a method of forming
a smooth surface, for example in the treatment of superconductor cavity resonators.
[0005] Thus, in British Patent Specification No 1 335 165 there is described the treatment
of the internal niobium surface of a superconducting cavity resonator by pickling
in a mixture of nitric acid and hydrofluoric acid and subsequently anodising the resonator
surface in an aqueous ammonia solution. There is no indication, however, from this
prior patent specification that the material so treated is particularly suitable for
use as a connector in a saline solution or that such a material would be resistant
to corrosion. It is apparent, therefore, that the inventors have discovered an unexpected
property of niobium when treated in a manner known per se. The fact that the niobium
is, when in use, connected as an anode and yet can suffer from corrosion, increases
the novelty of the invention insofar as a pre-treatment comprising pickling and anodisation
substantially prevents corrosion at a later date.
[0006] It has also been found, as a result of work carried out by the inventors, that pickling
alone is not sufficient, nor is anodisation alone sufficient. Thus, it is necessary
to have the combination of steps before the beneficial effects of the invention are
to be found.
[0007] It is, of course, well-known to anodise niobium, as is described, for example, in
British Patent Specification No 1 228 939 or US Patent Specification No 3 496 076,
and it is also known to pickle and subsequently anodise niobium for use as a superconducting
cavity resonator as is described in British Patent Specification No 1 335 165 referred
to above.
[0008] It appears that the particular problem associated with the use of niobium as a connector
occurs when the niobium is located in a saline solution and is connected anodically.
Thus, when niobium is inserted in a cold saline solution but is not connected as an
anode it does not corrode. However, when connected as an anode, in certain circumstances
it has been found that corrosion can occur. To the best of the inventors' knowledge
this fact was never known prior to the making of the present invention.
[0009] In US Patent Specification No 3 730 856 there is described a method of anodising
titanium or niobium to remove surface ion contamination so as to improve the corrosion
resistance of chemical plant where the metal surfaces are in contact with hydrogen.
However, there is no reference to the particular advantages to be obtained from using
pickled and anodised niobium as a connector in a saline environment.
[0010] It has also been proposed - see, for example, British Patent Specification No 1 430
185, to reduce the susceptibility of titanium to crevice corrosion by abrading and
pickling in hydrofluoric and nitric acid mixtures to remove ion surface contamination.
However, this specification does not point out the advantages of the present treatment
of niobium.
[0011] In US Patent Specification No 3 876 136 niobium (ie columbium) is used in place of
titanium where titanium is said to be susceptible to crevice attack. The specification
does not draw the conclusion that pickling and anodisation of the niobium is necessary.
In other words, from this specification it will be concluded that niobium is itself
resistant to crevice corrosion without the need for any treatment of it.
[0012] In US Patent Specification No 3 469 975 it is stated that the problem of containing
halide solutions is complicated by the complete unpredictability of susceptibility
(of materials) to crevice corrosion. This reference is to be found in column 2, lines
1 to 3, of the specification. In lines 27 to 32 there is further reference to the
complete unpredictability of materials to crevice corrosion.
[0013] Although crevice corrosion of materials is well-known for materials such as steel
- see, for example, a paper published by W D France Jr in a symposium presented at
the Seventy-Fourth Annual Meeting of the American Society for Testing and Materials,
27 June to 2 July 1971, published as ASTM Special Technical Publication 516, pages
164 to 196 - there was no indication that niobium was a material which could suffer
such a corrosion. Furthermore, in a publication by the Centre Belge d'Etude de la
Corrosion published in Brussels, June 1957, reference NZ.55 JVM.144, entitled "Electrochemical
Resistance of Niobium" by-J Van Muylder, N de Zoubor and M Pourbaix it is stated that
the resistance of niobium to corrosion is that of a refractory metal, unattacked in
air, oxygen and water, that it is not attacked by normal acids, such as hydrochloric,
sulphuric and nitric acids or their mixtures, that aqua regia has no action and that
the same is true of caustic alkali solutions. Because it is so inert to reactive chemicals
it is necessary to use fused caustic alkalis or alkaline carbides or their complex
solutions to attack it.
[0014] The paper goes on to say that hydrofluoric acid attacks niobium only slowly but the
rate of attack can be increased if the niobium is touched with platinum. Alternatively,
the rate of attack can be increased by adding nitric acid to the hydrofluoric acid.
It is believed that the niobium forms complex fluorides or oxy-fluorides.
[0015] The paper concludes by saying that the known resistance of niobium to the action
of chemical agents gives rise to the conclusion that the niobium oxide which forms
on the metal constitutes an effective protective oxide. The paper ends by stating
that in. the absence of complexing substances the metal niobium is virtually non-corrodable.
[0016] Thus, contrary to the prior art discussed above, it has been found that the treatment
of niobium known per se can give unexpected increases in the resistance of niobium
to crevice corrosion, particularly when anodically connected as an electrical connector
in a saline solution.
[0017] By the present invention there is provided the use of niobium or tantalum, having
been treated in a manner known per se by pickling to remove contamination and surface
oxide films, and subsequently forming an oxide film on its surface, as a connector
in a saline solution. The present invention also provides for the use of niobium in
which the oxide is formed by anodisation in a manner known per se. The connector may
be used when anodically polarised in the saline solution. The saline solution may
be an aqueous saline solution and the niobium may be polarised at a voltage in the
range 30-100 volts. The present invention further provides a niobium or tantalum member
exposed, in use, to a saline solution and having been treated by pickling to remove
contaminated surface oxide films and subsequently having formed on its surface an
oxide film.
[0018] . The present invention further provides a cathodic protection system incorporating
such a connector.
[0019] By way off example the treatment of niobium and the advantages to be obtained thereby
will be described below.
[0020] A piece of extruded niobium was partially covered with a piece of plastics tape and
was inserted in a hot saline solution and connected as an anode at 50 volts. It was
found that after a short period of time white niobium oxide corrosion products were
to be found adjacent the piece of plastics tape. Two similar pieces of niobium were
then treated in the following manner. A first piece was treated by a method not in
accordance with the present invention. It was pickled-in a solution of hydrofluoric
acid and nitric acid and then washed in water. The material was then again wrapped
in tape and connected as an anode at 44 volts in a saline solution containing 250g/l
NaCl at a pH of 2. Again, corrosion products were found on the surface.
[0021] The second piece of niobium was then pickled in a hydrofluoric acid and nitric acid
mixture to remove 40 microns of niobium, washed in water and subseqently anodised
in an ammonium sulphate solution at 40 volts to form an anodic film on the surface
of the niobium.
[0022] This sample was then partially wrapped with a plastics tape and treated in the manner
of the first sample mentioned above. This piece of niobium, which had been treated
in accordance with the present invention, was found to suffer no attack whatsoever.
[0023] By way of comparison third and fourth samples of extruded niobium were merely anodised
in aqueous NaCl containing 20g/l and 220g/l NaCl at 40 volts and covered with plastics
tape. These samples were then tested in accordance with the first-mentioned sample.
This sample, again not in accordance with the present invention, was also found to
corrode.
[0024] It can thus be seen that the combination of pickling and forming the oxide layer
- which could be formed by air oxidation of the niobium - leads to unexpected improvements
in the corrosion resistance of niobium when used as a connector, particularly as an
electrical connector in a saline solution, such as seawater. It will be realised that
hot water was used to accelerate the effect of corrosion. Tantalum behaves in a similar
manner to niobium, having a similar normal breakdown potential.
[0025] The connectors were particularly useful for cathodic protection installations.
1. Use of niobium or tantalum, having been treated in a manner known per se by pickling
to remove contamination and surface oxide films and subsequently forming an oxide
film on its surface, as a connector in a saline solution.
2. Use of niobium as claimed in Claim 1 in which the oxide is formed by anodisation
in a manner known per se.
3. Use of niobium as claimed in Claim 1 or Claim 2 in which the connector is anodically
polarised in the saline solution.
4. Use of niobium as claimed in any one of Claims 1 to 3 in which the saline solution
is an aqueous saline solution and in which the niobium is anodically polarised at
a voltage in the region of 10 to 100 volts.
5. An electrical connector including a niobium or tantalum member exposed, in use,
to a saline solution and having been treated by pickling to remove contamination and
surface oxide films and subsequently forming an oxide film on its surface.
6. An electrical connector as claimed in Claim 5 in which the oxide film is formed
by anodisation.
7. A cathodic protection system incorporating an electrical connector as claimed in
Claim 6 or Claim 7.