Technical Field
[0001] The present invention relates to a mold for continuous casting of steel, such as
low carbon steel, high carbon steel, stainless steel, special steel, etc. and more
particularly to a mold for continuous casting of steel which has an extended useful
life.
Background Art
[0002] The mold for continuous casting of steel is so designed that molten steel poured
from its top end is solidified by cooling and the resulting product is withdrawn from
its lower end in a continuous sequence. As such, from productivity points of view,
the mold is required to have a long service life. The long-life continuous casting
mold heretofore known is the one disclosed in Japanese Examined Patent Publication
No. 40341/1980. This mold comprises a copper or copper alloy body and has formed on
the internal surface thereof which is to be exposed to molten steel, (A) an intermediate
plating layer comprising at least one member selected from the group consisting of
nickel and cobalt and (B) a surface alloy plating layer formed from either 3 to 20
weight % of phosphorus or 2 to 15 weight % of boron or both and the balance of at
least one member selected from the group consisting of nickel and cobalt. The reasons
why this mold has a long life are allegedly as follows. One of the reasons is that
the provision of said intermediate layer (A) serves to flatten the gradient of hardness
between the copper or copper alloy mold body which is very low in hardness and the
alloy layer (B) which has a high hardness to thereby increase the bond between the
three members, viz the body metal, intermediate layer and alloy layer. The other reason
is that the alloy layer has high resistances to heat and wear at high temperature.
[0003] As improved versions of the above-mentioned mold, there also are known the mold carrying
a chromium plating layer in superimposition on said alloy layer (B) (Japanese Examined
Patent Publication No. 50734/1977) and the mold carrying an oxide layer as formed
by oxidizing said alloy layer (B) (Japanese Examined Patent Publication No. 50733/1977).
The chromium plating layer and the oxide layer in these molds serve to preclude deposition
of molten steel splashes evolved at the start of casting on the mold surface and eliminates
chances for breakout troubles. Thanks to this feature and the above-mentioned increased
intimacy of the three members, namely the mold body, intermediate layer and alloy
layer and the high wear resistance of the alloy layer at high temperature, these molds
have serviceable lives even longer than the life of the first-mentioned mold described
in Japanese Examined Patent Publication No. 40341/1980.
[0004] The above-mentioned molds carrying two or three protective layers essentially have
an intermediate layer comprising at least one member of the group consisting of nickel
and cobalt and, as disposed thereon, an alloy layer and, in the case of three-layer
molds, further a chromium plating layer or an oxide layer, and, as such, require complicated
manufacturing procedures and high production costs.
[0005] JP-A-55 100 851, upon which the preamble of claim 1 is based, discloses a mold formed
from a substrate of copper or copper alloy having a first layer formed on said substrate
and composed of at least one of nickel and cobalt, and a second layer formed on the
first and composed of an alloy containing 1 to 2 wt.% of phosphorus, or 0.7 to 1.5
wt.% of boron, and at least one of nickel and cobalt forming the balance.
[0006] JP-A-5 954 444 describes a mold having a plating layer of Ni-W-B wherein the tungsten
content is significant being in the range of 3 to 10 wt.%
[0007] FR-A-2 314 001 (US-A-4 037 646) also describes a mold protected by a bilayer, the
first layer of which consists essentially of at least one of Ni and Co, whilst the
second layer formed on the first again consists of at least one of Ni and Co, and
at least one of P and B.
[0008] Considering molds of the type wherein the molten metal is charged at the top of the
mold and solidified product is withdrawn from its bottom, the inventor carried out
intensive research to improve such molds, particularly with a view to developing a
structurally simple and easy to manufacture protective layer for a mold substrate
body. As a consequence the inventor discovered that contrary to the widely accepted
notion that nickel-boron alloy plating in general is poorly bonded to substrates of
copper or copper alloy, a nickel-boron alloy plating layer with a low boron content
within a certain specific range has a good ability to bond to substrates of copper
or copper alloy and serves on its own as an excellent protective layer even without
the provision of an intermediate layer as used in the prior art molds.
[0009] Accordingly this invention provides a copper or copper alloy mold for continuous
casting of steel comprising a copper or copper alloy mold having formed on its internal
surface a plating layer, characterised in that the plating layer is a nickel-boron
alloy plating layer having a boron content of from 0.06 to 0.3 weight % and having
a thickness of from 50 µm to 2 mm. Manufacture of such a mold provides for a service
life at least equal to or longer than that of a prior art mold having two or three
superposed protective layers.
[0010] Referring, now, to the accompanying drawings,
Fig. 1 is a vertical section view showing an example of the mold having a nickel-boron
alloy plating layer in a tapered fashion according to the invention;
Fig. 2 to 5 are vertical section views showing other examples of the mold having a
nickel-boron plating layer according to the invention;
[0011] The present invention provides a mold for continuous casting of steel which is characterized
in that the mold has a nickel-boron alloy plating layer containing 0.05 to 1.5 weight
% of boron on its inner surface.
[0012] In accordance with the present invention, the simple structure of a substrate mold
body and a nickel-boron alloy plating layer with a boron content in the above specific
range as formed over the substrate mold body assures a mold life which is at least
comparable or even longer than the lives of the conventional molds having two or three
superposed protective layers. This is quite unexpected in view of the facts that a
nickel-boron alloy plating layer was believed to have a poor ability to bond to substrate
copper or copper alloy, that a boron content not more than 2 weight % was considered
to be inadequate in terms of heat resistance and hardness, and that it was considered
essential to form a chromium plating layer on the alloy layer or to oxidize the alloy
layer to form an oxide layer in order that the deposition of splashes may be positively
precluded.
[0013] While the detailed reason why the mold of the invention has such an extended life
is not fully clear, it is presumably based on the following: the nickel-boron alloy
layer containing 0.05 to 1.5 weight % of boron has a high ability to bond to the substrate
copper or copper alloy of the mold and has a coefficient of thermal expansion similar
to that of the substrate copper or copper alloy, and this alloy layer has a microvickers
hardness of about 500 to 800 HV, high wear resistance at high temperature, high lubricating
property at high temperature, remarkably high heat conductivity to allow a rapid dissipation
of heat which prevents formation of a major temperature gradient, and a low affinity
for molten steel which tends to preclude deposition of splashes.
[0014] In addition to the extended life of the mold, the following advantages are achieved
by the present invention.
(a) In the prior art mold disclosed in Japanese Examined Patent Publication No. 40341/1980,
the alloy layer has a high boron content of 2 to 15 weight % and is so hard as to
give rise to a strain by stress. Moreover, it has a low thermal conductivity and therefore
may cause a large temperature gradient. Therefore, there was a likelihood that cracks
are formed. In contrast, the alloy layer according to the invention has a low risk
of cracking and assures a high reliability of the mold.
(b) Since the alloy layer according to the invention has a very high thermal conductivity,
it achieves a very high cooling efficiency.
[0015] In the mold for continuous casting of steel according to the invention, the substrate
body of the mold is made of copper or copper alloy. This copper alloy may be virtually
any of the alloys heretofore used in the art. For example, alloys of copper with small
amounts, particularly about 0.02 to 0.12 weight %, of at least one element selected
from the group consisting of silver, iron, tin, zirconium, phosphorus, etc. can be
mentioned. Particularly preferred copper alloys are deoxidized coppers containing
small amounts of phosphorus and copper alloys containing 0.1 weight % of iron, 0.04
weight % of tin and 0.03 weight % of phosphorus.
[0016] In the present invention, the foregoing specific nickel-boron alloy layer is formed
on the above-mentioned substrate mold body. The method usable for this purpose is
not limited but includes the following as an example. First, the surface of the mold
body is pretreated in the conventional manner. This pretreatment may, for example,
be conducted by serially conducting electrolytic degreasing for 30 minutes at 10A/dm²
using an iron plate as the cathode, rinsing with water, rinsing with 50% hydrochloric
acid, rinsing with water and rinsing with 3% sulfamic acid. After the above pretreatment,
the above-mentioned nickel-boron alloy plating layer with a specified low boron content
is formed. If the boron content of the alloy layer is less than 0.05 weight %, the
microvickers hardness of the layer is reduced and the wear resistance and lubricating
property at high temperature also tend to be lowered. Conversely if the boron content
exceeds 1.5 weight %, the coefficient of thermal expansion tends to be decreased to
cause inadequate bond to the substrate metal, and the resulting decreased thermal
conductivity and poor dissipation of heat tends to increase internal stress of the
alloy layer and consequent likelihood of cracking. From the standpoints of high temperature
wear resistance, lubricating property, thermal conductivity and resistance to cracking,
the boron content is preferably in the range of about 0.05 to 0.7 weight % and more
preferably in the range of about 0.06 to 0.3 weight %.
[0017] The thickness of this alloy layer can be chosen from a broad range according to the
particular application of the mold, and the like. Generally, it is about 50 µm to
2 mm, preferably about 50 µm to 1.5 mm, and more preferably about 100 µm to 1 mm uniformly
throughout the whole surface area of the substrate mold body. If the thickness of
the alloy layer is less than 50 µm, local wear may develop due to operational damage
to adversely affect the mold life. On the other hand, increasing the thickness beyond
2 mm is not rewarded with further improved effect but is uneconomical.
[0018] According to the research by the inventor, the thickness of said nickel-boron alloy
plating layer of the mold of the invention may be about 50 µm to about 2 mm, preferably
about 50 µm to about 1.5 mm, and more preferably about 100 µm to about 1 mm in the
lower half of the inner surface of the mold body. In the area corresponding to the
upper half of the mold, the thickness of the alloy plating layer may be less than
50 µm or even there may be no alloy layer with the substrate copper or copper alloy
remaining exposed. In the present invention, therefore, it is possible to finish the
mold body (1) in such a manner that its thickness decreases continually from its top
end to its bottom end and deposit the alloy layer (2) in a tapered fashion such that
its thickness increases continually from said top end to said bottom end as illustrated
in Fig. 1. In this connection, the gradient of the taper can be chosen from a broad
range but it is generally preferable to assure that the thickness of the alloy layer
of the invention is about 0 to about 100 µm at the top end, and about 150 µm to about
2 mm and preferably about 200 µm to about 1 mm at the bottom end. More desirably,
the alloy plating layer has a taper such that the difference between its top end thickness
and its bottom end thickness is about 500 to 1000 µm. Alternatively, as illustrated
in Figs. 2 and 3, the alloy layer (2) may be formed in such a fashion that it is thin
in the upper half and thick in the lower half of the mold. Furthermore, as shown in
Figs. 4 and 5, the alloy layer (2) may be formed only in the area corresponding to
the lower half of the mold body. In any case, the alloy layer (2) may be formed in
such a manner that as in the case illustrated in Fig. 1, its thickness is about 50
µm to 2 mm in the area corresponding to the lower half of the mold body.
[0019] The formation of the above nickel-boron alloy plating layer may be effected by the
conventional electroplating technique or the conventional non-electrolytic plating
technique. When the thickness of the alloy layer is to be large, the electroplating
process is more advantageous. For the formation of said alloy layer by the non-electrolytic
plating technique, the following plating bath may, for example, be employed.
- Nickel sulfate
- 20 - 30 g/ℓ
- Sodium potassium tartarate
- 30 - 40 g/ℓ
- Sodium borohydride
- 2.0 - 2.5 g/ℓ
- pH
- 12.0 - 12.5
- Temperature
- 45 - 50°C
[0020] For the formation of the alloy layer by the electroplating technique, the following
plating bath, for instance, may be employed.
- Nickel sulfate
- 250 - 300 g/ℓ
- Nickel chloride
- 20 - 25 g/ℓ
- Boric acid
- 30 - 40 g/ℓ
- Dimethylamineborane
- 0.01 - 0.3 g/ℓ
- Stress reducing agent
- 0 - suitable amount
- Surfactant
- 0 - 1.5 g/ℓ
- pH
- 3.0 - 4.0
- Bath temperature
- 40 - 45°C
- Current density
- 1 - 3A/dm²
[0021] In addition to the above plating baths, any other plating bath capable of yielding
a nickel-boron alloy plating layer with the specified boron content can also be employed.
[0022] The above nickel-boron alloy plating layer varying in thickness from the top end
to the bottom end can be formed, for example, by carrying out the plating procedure
with the anode inclined and, then, finishing the resulting plating layer by machining
if necessary.
[0023] The mold of the invention having, on its substrate copper or copper alloy mold body,
and a nickel-boron alloy plating layer can be used in the continuous casting of steel
into slabs, blooms, billets and other products and invariably assures an extended
life.
[0024] The following examples are further illustrative of the present invention.
Example 1
[0025] A short side mold body (250 mm wide x 900 mm high) made of pure copper for continuously
casting steel whose section perpendicular to its horizontal axis is substantially
rectangular and having a tapered configuration with the thickness at the bottom end
thereof being smaller than that at the top end by 300 µm was masked over the surface
thereof except the area to be exposed to molten steel and then subjected to 30-minute
electrolytic degreasing at 10 A/dm² using an iron plate as the anode. The degreased
mold body was rinsed with water, 50% hydrochloric acid, water, and 3% sulfamic acid
in the order mentioned for pretreatment.
[0026] The mold body was finally rinsed with water and, then, using the following plating
bath, a tapered nickel-boron alloy plating layer with a boron content of 0.3 weight
% was formed on the mold body at a current density of 1 to 3 A/dm², pH 3.0 - 4.0 and
a temperature of 40 to 45°C.
- Nickel sulfate
- 250 g/ℓ
- Nickel chloride
- 20 g/ℓ
- Boric acid
- 30 g/ℓ
- Dimethylamineborane
- 0.2 g/ℓ
[0027] The thickness of the alloy layer was 100 µm at the top end and 400 µm at the bottom
end (See Fig. 1).
Then, the masking was removed.
[0028] On the other hand, a long side mold body (2200 mm wide x 900 mm high) for continuously
casting steel whose section perpendicular to its horizontal axis is substantially
rectangular and having a tapered configuration with the thickness at its bottom end
being smaller than that at the top end by 150 µm was masked over the surface thereof
except the area to be exposed to molten steel and, then, using the following nickel
plating bath, a nickel plating layer having a thickness of 300 µm was formed as an
under layer over the entire surface of the mold body at a bath temperature of 50°C,
pH 3.0 and a cathode current density of 2.0 A/dm².
- Nickel sulfamate
- 250 g/ℓ
- Nickel bromide (50%)
- 10 cc/ℓ
- Boric acid
- 20 g/ℓ
[0029] Then, on this under layer, a tapered nickel-boron alloy plating layer with a boron
content of 0.3 weight % was formed in a tapered fashion using the same nickel-boron
alloy plating bath as used for the plating of the short side mold body above. The
thickness of this alloy plating layer was 50 µm at the top end and 200 µm at the bottom
end. The masking was then removed.
[0030] By using the mold comprising the thus plated short sides and long sides, 1300 charges
of steel slabs free of any defect were produced without breakout. The mold appeared
to be further usable but the production was discontinued for safety's sake. The condition
of the alloy layers on the short and long sides of the above molds after use showed
slight scratch marks but the mold was still useful.
Example 2
[0031] A continuous steel casting mold bodies made of pure copper whose section perpendicular
to its horizontal axis is substantially rectangular and having a tapered configuration
with the thickness at the bottom end being smaller than that at the top end by 150
µm (short side: 250 mm wide x 700 mm high; long side: 2200 mm wide x 700 mm high)
were pretreated in the same manner as described in Example 1.
[0032] After the final aqueous rinse, a 300 µm-thick nickel plating layer was formed by
electroplating using a nickel sulfamate plating bath of the following composition
at a temperature of 50°C, pH 3.0 and a cathode current density of 2.0 A/dm² for 18
hours.
- Nickel sulfamate
- 250 g/ℓ
- Nickel bromide (50%)
- 10 cc/ℓ
- Boric acid
- 20 g/ℓ
[0033] After aqueous rinse and cooling, the nickel plating surface was finished so as to
adjust its degree of precision by means of a stretch gauge, filler gauge and disk
grinder.
[0034] After electrolytic degreasing and activation, a tapered nickel-boron alloy plating
layer with a boron content of 0.3 weight % was formed using a plating bath of the
following composition under the conditions of pH 3.0 - 4.0, bath temperature 40 -
45°C and current density 1.5 A/dm². The thickness of the alloy plating layer was 50
µm at the top end and 200 µm at the bottom end. The masking was then removed.
- Nickel sulfate
- 250 g/ℓ
- Nickel chloride
- 20 g/ℓ
- Boric acid
- 30 g/ℓ
- Dimethylamineborane
- 0.2 g/ℓ
[0035] Using the mold thus obtained, 1000 charges of slabs free of any defect were produced
without breakout. The mold appeared to be still useful but the production was discontinued
for safety's sake. The condition of the alloy layers of the above molds showed slight
scratch marks but the mold was still useful.
Example 3
[0036] The mold used in this example was a continuous bloom casting mold (inside dimension:
612 mm x 392 mm, 900 mm high) which was made of copper alloy containing 0.1 weight
% of iron, 0.04 weight % of tin and 0.03 weight % of phosphorus and which had substantially
a rectangular section perpendicular to its horizontal axis and had a taper with the
thickness at the bottom end being smaller than that at the top end by 400 µm.
[0037] The inside cavity of the mold was filled with an electrolytic degreasing solution
and electrolytic degreasing was carried out in the same manner as Example 1. The degreased
mold was rinsed with water, 50% hydrochloric acid, water and 3% sulfamic acid in the
order mentioned for pretreatment.
[0038] Then, from an external service tank, a plating bath of the following composition
was circulated into the cavity of the mold and electroplating was carried out at a
current density of 3.0 A/dm², bath temperature of 40°C and pH 4.0.
- Nickel sulfate
- 250 g/ℓ
- Nickel chloride
- 20 g/ℓ
- Boric acid
- 30 g/ℓ
- Dimethylamineborane
- 0.1 g/ℓ
[0039] By gradually lowering the liquid level of the plating bath, a nickel-boron alloy
layer with a boron content of 0.06 weight % was formed in a tapered fashion with the
thickness increasing from the top end to the lower end. Then, the surface was finished
by machining to provide a tapered nickel-boron alloy layer with an evenly increasing
thickness from 100 µm at the top end to 500 µm at the bottom end.
[0040] By using the mold thus obtained at a casting speed of 0.6 to 0.7 m/min, 1000 charges
of blooms free of any defect were produced without breakout.
[0041] While the mold appeared to be still useful, the production was discontinued to be
on the safe side. The internal surface of the mold after use revealed only slight
scratch marks and no exfoliation or cracking of the nickel-boron alloy plating layer
was observed, indicating that the mold was still useful.
Example 4
[0042] In a round tubular mold made of deoxidized copper containing a trace amount of phosphorus
(213 mm⌀ inside diameter x 900 mm high; wall thicknesses: 14.02 mm at the top end
and 15.17 mm at the bottom end), a plating bath of the following composition was circulated
and electroplating was carried out at a current density of 2.0 A/dm², bath temperature
of 40°C and pH 4.0.
- Nickel sulfate
- 250 g/ℓ
- Nickel chloride
- 20 g/ℓ
- Boric acid
- 30 g/ℓ
- Dimethylamineborane
- 0.2 g/ℓ
[0043] In this manner, a nickel-boron alloy plating layer (boron content 0.18 weight %)
with a uniform thickness of 75 µm from the top end to the bottom end was formed.
[0044] By using the above mold at a casting speed of 1.9 m/min, 300 charges of carbon steel
billets free of any defect were produced without breakout. While the mold appeared
to be further usable, the production was discontinued to be on the safe side.
[0045] Observation of the internal side of the mold revealed only slight scratch marks and
no exfoliation or cracking of the nickel-boron alloy layer was observed, indicating
that the mold was still useful.
[0046] With a mold fabricated as above except that a nickel plating layer was used in lieu
of the above nickel-boron alloy layer, only 120 charges of carbon steel billets could
be produced and the mold after production revealed a wear of the nickel layer, with
local exposure of the substrate copper, and could not be further usable.