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(11) | EP 0 814 171 A1 |
| (12) | EUROPEAN PATENT APPLICATION |
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| (54) | Aluminum alloy casting |
| (57) This invention concerns an aluminum alloy casting characterized by an iron content
of less than about 0.5% by weight, and a gas content of less than or equal to 5 milliliters
(STP) per 100 grams of aluminum, said casting having a yield strength in tension (0.2%
offset) greater than or equal to 110 MPa and a free bend deformation greater than
or equal to 25 min. |
1. Composition of the material being die cast
2. Melting practice, including degasification and filtration of the melt
3. Supply of the molten material to the die casting machine
4. The fill chamber section
5. Lubricants and coatings for the fill chamber and die
6. The casting, including its cleanup, heat treatment and properties
1. Composition of the material being die cast
Si 9.5-10.5
Mg 0.11-0.18
Fe 0.4 maximum
Sr 0.015-0.030
Remainder Al.
| Si | 7.5 - 8.5 |
| Mg | 0.08-0.12 |
| Fe | 0.15 -25 |
| Sr | 0.015 - 0.25 |
| Remainder Al. |
2. Melting practice, including degasification and filtration of the melt
3. Supply of the molten material to the die casting machine
4. The fill chamber section
a. The piston
b. The fill chamber itself
c. Means for applying coatings or lubricants
5. Lubricants and coatings for fill chamber and die
6. The casting, including its cleanup and heat treatment and properties
Yield strength in tension (0.2% offset) ≧ 110 MPa
(Yield strength being typically 120-135 Mpa)
Elongation ≧ 10% (typically 15-20%)
Free bend test deformation ≧ 25 mm, even ≧ 30 mm
Total gas level ≦ 5 ml/10g metal
Weldability = A or B
Corrosion resistance ≧ EB
Yield strength and elongation determined according to ASTM Method B557.
| Run No. | 0.2% Yield Strength, MPa | Free Bend Test Deformation, mm | ||||
| Max. | Ave. | Min. | Min. | Ave. | Max. | |
| 3-5Q | 141 | 130 | 120 | 37 | 42 | 44 |
| 3-5R | 139 | 129 | 125 | 39 | 42 | 46 |
a. A die casting machine in general
b. Melting equipment
c. Inlet orifice
d. Sealing fill chamber to piston rod
e. Alternative pistons
f. Die-end lubricator
g. Controlling the piston to fill chamber clearance
h. Example
a. A die casting machine in general
Referring to Fig. 1, this figure shows, in the context of a cold chamber, horizontal,
self-loading, vacuum die casting machine, essentially only the region of the fixed-clamping
plate 1, or platen, with the fixed die, or mold, half 2 and the movable clamping plate
3, or platen, with the movable die, or mold, half 5 of the die casting machine, together
with the piston 4, suction tube 6 for molten metal supply, holding furnace 8, and
fill chamber 10.
The vacuum line 11, for removing air and other gases in the direction of the arrow,
is connected to the die in the area where the die is last filled by incoming molten
metal. Line 11 is opened and shut using valve 12, which may be operated via control
line 13 by control equipment (not shown).
Fig. 2 shows an example of an untrimmed die-cast piece, for example in the form of
a hat, with the gate region 14 separating the hat portion 15 from the sprue 16 and
biscuit 17. The vacuum connection appears as appendage 18. Desirably, gate region
14 is thin, e.g. ≦ 2 mm thick, such that it can be broken away from the cast part.
Also the vacuum appendage is sized for easy removal.
Referring again to Fig. 1, a conical, or spherical, projection 4a is provided at the
frontal face of the piston 4. The rear of the piston is connected to piston rod 21.
The rear region 10a of the fill chamber 10 shows a sealing device 90, which is explained
in detail below in the discussion of Fig. 6. The suction tube 6 is connected to the
fill chamber 10 by means of a clamp 22. This clamp 22 has a lower hook-shaped, forked
tongue 24 which passes underneath an annular flange 25 on the suction tube 6. From
the top, a screw 26 is threaded through the clamp 22. This enables a clamping of the
end of suction tube 6 to the inlet orifice of the fill chamber 10.
Die end lubricator 170 is used to apply lubricant to the bore of fill chamber 10 from
the die end of the fill chamber, when the movable die and platen, plus ejector die
(not shown) have separated from the fixed die and platen. Reference may be had to
Fig. 9 for added information concerning this lubricator.
Operation of the die casting machine of Fig. 1 generally involves a first two phases,
and a subsequent, third phase can be included. In Phase 1, vacuum is applied to evacuate
the die and fill chamber and to suck the metal needed for the casting from the holding
furnace into the fill chamber. Phase 1 further includes movement of the piston at
a relatively slow speed for moving the molten charge toward the die cavity. Phase
2, which is marked by a high velocity movement of the piston for injecting the molten
metal into the die cavity, is initiated at, or somewhat before, the time when the
metal reaches the gate where the metal enters into the cavity where the final part
is formed. Phase 3 involves increased piston pressure on the biscuit; piston movement
has essentially stopped in Phase 3.
Further details of the various aspects of the machinery shown in Fig. 1 will be explained
below.
b. Melting equipment
Fig. 3 illustrates an example of melting equipment used for providing a suitable supply
of molten alloy, for instance AlSi10Mg.1, for die casting.
Solid metal is melted in melting furnace 40 and fluxed, for example using a 15 minute
flow of argon + 3% by volume chlorine from the tanks 42 and 44, followed by a 15 minute
flow of just argon. A volume flow rate and gas distribution system suitable for the
volume of molten metal is used.
As needed to make up for metal cast, metal is caused to flow from melting furnace
40 into trough 46, where strontium addition is effected from master alloy wire 48.
The metal flowing from the trough is filtered through an inlet filter 50 as it enters
the holding furnace 8 and subsequently through an exit filter 54, before being drawn
through suction tube 6. Alternatively, filter 50 may be provided in a separate unit
within the holding furnace 8. The filter pore sizes can be the same or different.
For instance, inlet filter 50 can be a coarse-pored ceramic foam filter and exit filter
54 a fine-pored particulate filter. Alternatively, both filters can be fine-pored
particulate filters. The filter pore sizes are chosen to provide the above-specified
metal quality with respect to inclusion content in the castings. Filter 54 could be
placed on the bottom of tube 6 and subcompartment 56 eliminated, but the structure
as shown is advantageous in that it permits the use of a larger expanse of fine-pored
filter 54 this making it easier to assure adequate supply of clean molten metal for
casting.
c. Inlet orifice
Fig. 4 shows details of an embodiment of the inlet orifice 60 in fill chamber 10.
Three important aspects of this embodiment are guarding against 1) metal freezing
onto the walls of the inlet orifice, 2) erosion of the walls of the inlet orifice
by the molten metal flow, and 3) loss of vacuum within the fill chamber.
A boron nitride insert 62 contributes particularly to aspects 1 and 2.
Primary seals 64 and 66 contribute particularly to aspect 3, sealing the inlet orifice
at seating ring 68, nipple 70, and ceramic liner 72.
Heat is fed into nipple 70 by heating coil 71, for instance an electrically resistive
or inductive heating coil.
Crushable, graphite-fiber seal 74 squeezed between fill chamber 10 and nipple 70 guards
against air leakage at the primary seals.
Pancake heater 80 is formed of a grooved ring 82. The groove carries an electrical
resistance heating coil 84. The heater is held against plane 86, which is a flat surface,
machined on the exterior of exterior surface of the fill chamber. Steel bands 88 encircle
the fill chamber to bold the heater in place.
Flange 25 is provided, in order that clamp 22 of Fig. 1 may hold the end of the suction
tube tightly sealed against the fill chamber 10.
Fig. 5 shows details of a second embodiment of the inlet orifice 60 in fill chamber
10. This embodiment illustrates the use of an air-filled moat 76 surrounding the inlet
orifice. Alternatively, the moat 76 can be filled with an insulating material other
than air. The moat mitigates the heat-sink action of the walls of the fill chamber,
in order to counteract a tendency of melt to freeze and block the inlet orifice.
The embodiment of Fig. 5 also illustrates the idea of a ceramic, or replaceable steel
liner 78 for the bore of the fill chamber.
Structural details in Fig. 5 which are the same or essentially similar to those in
the embodiment of Fig. 4 have been given the same numerals used in Fig. 4.
It will be evident from the discussions of Figs. 4 and 5 that a main theme there is
maintaining a sufficiently high temperature at the inlet orifice. Fig. 5A illustrates
an embodiment caring for this concern of temperature maintenance in a unique way.
According to this embodiment, the suction tube 6 is relatively short, compared to
its length in the embodiments of Figs. 4 and 5, and the reservoir 130 of molten metal
is brought up near to the inlet orifice 60 such that heat transfer from the molten
metal in the reservoir keeps the inlet orifice 60 clear of solidified metal. The reservoir
is provided in the form of a trough, through which molten metal circulates in a loop
as indicated by the arrows. Pumping and heat makeup is effected at station 132. All
containers may be covered (not shown) and holes provided for access, for instance
for suction tube 6. Metal makeup for the loop comes from the coarse filter 50 of Fig.
3, and the fine filter 54, is provided as shown, in order to effect a continuous filtering,
of the recirculating metal.
d. Sealing fill chamber to piston rod
Fig. 6 illustrates several features, one feature in particular being an especially
advantageous seal for sealing the piston-fill chamber interface against environmental
air and dirt.
In Fig. 6, there is shown piston 4 seated in fill chamber 10 at the fill chamber end
farthest from the die. Inlet orifice 60 appears in the drawing. It will be evident
that the piston as shown in Fig. 6 is in the same, retracted, or rear, position in
which it sits in Fig. 1. Rather than, or in addition to, packing which might be provided
at the interface between chamber 10 and piston 4, the embodiment of Fig. 6 provides
a seal 90 extending between the fill chamber 10 and the piston rod 21.
Proceeding from the fill chamber, seal 90 comprises several elements. First, there
is a fill chamber connecting ring 92 bolted to the fill chamber. A gasket (not shown)
occupies the interface between ring 92 and the fill chamber, for assuring gas tightness,
despite any surface irregularities between the two.
Hermetically welded between ring 92 and a follower connecting ring 93 is flexible,
air-tight envelope 94. As illustrated, envelope 94 is provided in the form of a bellows.
Ring 93 in turn is bolted, also with interposition of a gasket, to piston rod follower
96. An air-tight packing 98 lies between follower 96 and rod 21.
Also forming a part of seal 90 are a line 100 from envelope 94 to a source of vacuum,
a line 102 to a source of argon, and associated valves 104, 106, controlled on lines,
as shown, by programmable controller 108, to which are input on line 110 signals indicating
the various states of the die casting machine.
Seal 90 operates as follows. Follower 96 rides on rod 21 as the piston executes its
movement in the bore of fill chamber 10 to and from the die. Either from influences
such as banana-like curvature of the bore of fill chamber 10 or due to flexing of
the piston rod under the loading of its drive (not shown), and even as influenced
by possible articulation of the piston to the piston rod (as provided in embodiments
described below), there can be a tendency for the piston rod to want to rotate about
axes perpendicular to it. Because of the flexible envelope, these rotational tendencies
are easily permitted to occur without adverse effect on the sealing provided by packing
98. The follower simply moves up and down in Fig. 6, or into or out of Fig. 6, to
follow the piston rod in whatever way it might deviate from the axes of the piston
and fill chamber bore.
With respect to controller 108, it serves the following function. When the piston
is in the retracted position as shown, controller 108 holds valve 104 open and valve
106 closed. Vacuum reigns both in the bore of the fill chamber and within envelope
94. The required amount of molten metal enters the bore through inlet orifice 60,
whereupon piston rod 21 is driven to move piston 4 forwards toward the die. The supplying
of molten metal is terminated as the piston moves into position to close the inlet
orifice. If the piston were to move further toward the die such that it would move
beyond the inlet orifice and open it to the interior of envelope 94 while the interior
were still under vacuum, molten metal would be drawn through the inlet orifice into
the interior of the envelope and there solidify, to ruin the envelope. The programmable
controller prevents this by using the information on machine state from line 110 to
close valve 104 and open valve 106. Argon fills envelope 94 to remove the vacuum and
prevent melt from being sucked through inlet orifice 60.
The presence of argon in the system is utilized for monitoring effectiveness of seals.
Helium is an alternative gas which may be used in this way. For instance, the tightness
of the sliding fit between fill chamber bore and piston may be monitored and/or con-rolled.
Helium sensors in the vacuum lines connected to the die and fill chamber and a knowledge
of where helium has been introduced allow tracing and determination of the piston
to fill chamber seal. Metal fusion gas analysis utilizing mass spectrometer technology
allows detection of argon in a casting, and, with acknowledge of where argon was present
during the casting process, information can be gathered on the tightness of the intervening
seals.
In an alternative embodiment shown in Fig. 6A, line 102 is replaced or augmented by
one or more longitudinal slots 103 on the outer diameter of piston rod 21. An alternative
or supplement of the effect of slots may be achieved by a reduction in the diameter
of the rod. Use of the reduction in diameter is advantageous as compared to the slot,
because the edges of the slot can cut the packing, unless they are rounded off. The
slots or reduction are placed such that, just as piston 4 is about to clear inlet
orifice 60, whereupon molten metal would be sucked into envelope 94, the slots open
a bypass of the seal provided by packing 98. The bypass provided by slots 103 opens
to the air of the environment.
In the alternative of Fig. 6B, the slots 103 open to the interior of basically a duplicate
90A of the structural items 92, 93, 96, 90 containing argon essentially at atmospheric
pressure on the basis of line 102 and valve 106. Pressures somewhat above atmospheric
pressure may be used, for instance if argon replenishment through line 102, as the
volume gets bigger due to the access provided by slots 103, is not rapid enough to
otherwise maintain the necessary pressure to drop, and keep, the metal level below
the inlet orifice 60. The flexible envelope 94 of the duplicate and the length of
slots 103 are sufficiently long that argon can feed into cylinder 10 right through
to the stopping of the piston against the biscuit. The duplicate of 92 is connected
to the follower 96 of the structure of Fig. 6. The envelope of this duplicate structure
is also chosen sufficiently long that the slot 103 does not open the argon chamber
(which it provides) to outside air when the piston is in its retracted position, i.e.
in its position as shown in Fig. 6B.
Other features of Fig. 6 include a supplementary seal 112 on follower 96. The piston
presses against seal 112 when the piston is in its retracted position.
Also shown in Fig. 6 are the concentric supply and return lines 114, 116 for cooling
fluid (for instance, water and ethylene glycol) to the piston. Thermocouples (not
shown) in the fill chamber walls, piston metal-contact and bore-contact walls (the
leads of these thermocouples are threaded back through the cooling fluid lines), and
in the water stream are used or open or closed loop stabilizing of the sliding, fit
between fill chamber bore and piston. Other factors, such as force needed to move
the piston (this being a measure of the friction between bore and piston), or the
amount of argon appearing in the vacuum lines connected to die and fill chamber, may
as well be used in monitoring and control schemes for stabilizing the sliding fit
to minimize gas leakage through the interface between piston and bore.
Another feature is illustrated in Fig. 6. The back edge of the piston has been provided
with a flash, or solder reaction product, remover 118. This remover is made of a harder
material which will retain the sharpness of its edge 120 better than the basic piston
material which is selected on the basis of other design criteria, such as high heat
conductivity. On the piston retraction stroke, remover 118 operates to scrape, or
cut, loose flash or solder left during the forward, metal feeding stroke of the piston.
Attention is given to keeping the forward edge 122 sharp too, but, as indicated, this
is an easier task in the case of remover 118.
e. Alternative pistons
Fig. 7 shows a second embodiment of a piston. This piston, numbered 4' to indicate
the intent that it serve as a replacement for piston 4, includes a flexible skirt
140 for fitting against variations in the bore of the fill chamber.
Skirt 140 is made, for instance, of the same material as the piston itself. It is
flexible in that it is thin compared to the rest of the piston and it is long. Its
thickness may be, for example 0.038 cm (0.015 inches) all of which stands out beyond
the rest of the piston; i.e. outer diameter of the skirt is e.g. 0.076 cm (0.030 inches)
greater than the outer diameter of the rest of the piston. Preferably, the skirt has
an outer diameter about 0.0025 cm (0.001) inch greater than the inner diameter of
the bore of fill chamber 10; i.e. there is nominally a slight interference fit is
the skirt with the bore. The flexibility of the shirt avoids any binding.
It will be understood that skirt 140 is relatively weak in compression. In order that
solder buildup, or flash, not collapse the skirt on the rearwards stroke of the piston,
the skirt includes a hem 142. The inner diameter of hem 142 is less than that of a
neighboring shelf 144 on the body of the piston. Should the skirt encounter any major
resistance on the rearward piston stroke that would otherwise compressively load the
skirt, the hem transfers such loading to the body of the piston and thus protects
the skirt from any danger of collapse.
Threading at 146 and 148 is used for assembling the piston. Holes 150 provide for
use of a spanner wrench.
Before assembly, metal spinning techniques may be used to provide an outward bulging
of the thin portion of skirt 140. Metal spinning involves rotating the skirt at high
speed about its cylindrical axis and bringing a forming tool, for instance a piece
of hardwood, into contact with the interior of the thin portion of skirt 140, to expand
the diameter outward. While this acts to increase the nominal interference with the
fill chamber bore, the thinness of the material prevents binding of the piston in
the bore This added bulging increases the sealing effect of the skirt.
Fig. 8 shows a third embodiment of a piston. This piston 4" provides some features
in addition to those shown for piston 4' in Fig. 7. For instance, piston 4" includes
a ball-, or swivel-, joint articulation 160 of the piston rod to the piston. This
includes a spherical-segment cap 162 welded in place along circular junction 164 to
assure containment of cooling fluid.
The hem and shelf facing surfaces in Fig. 8 are machined as conical surfaces in Fig.
8 for providing improved reception as the skirt deflects up to approximately 0.90°
maximum rotation, as indicated at A in the drawing.
Assembly of piston 4" is carried out as follows. The socket of the ball joint is supplied
by piston face 266 and piston side wall 268, which are joined by threads 269. Shim,
or spacer, 270 controls, by its thickness, the amount by which the threads engage,
in order to provide proper fit between the ball and the socket. Tightening of the
threaded engagement is obtained by applying a clamp wrench to the outer diameter of
face portion 266 and a spanner wrench to the slots 272 cut longitudinally into the
rear of side wall 268.
Collar 274 is next threaded onto the tail 276 of the ball, using a spanner wrench
in holes 278. Thee ball is prevented from turning relative to the collar by insertion
of the hexagonal handle of an Allen wrench inserted into its bore 280 also of hexagonal
cross section.
Next in the assembly is placement of the skirt 282 into threaded engagement with side
wall 268, using threads 284.
Piston rod 285, with flash remover ring 286 in place, is threaded into engagement
collar 274. Annular recess 288 in the bore of the collar assures that there is a tight
engagement between tail 276 and piston rod 285. O-ring 290 seals against leakage of
coolant fluid.
f. Die-end lubricator
Fig. 9 shows a general view of the die-end lubricator 170. It is attached to the fixed
clamping plate 31 and can be rotated by hydraulic or pneumatic cylinder 172 into the
operative position shown by the dot-dashed representation when the die halves have
been opened. In the operative position, a head in the form of nozzle 174 is ready
to be run into the fill chamber bore to execute its applicator, drying, and sweeping
functions.
Fig. 10 shows the die-end lubricator in greater detail. Programmable controller 108
has already received information from the die-casting machine via line 110 that the
machine is in the appropriate state (i.e. the die halves are open and the last casting
has been ejected) and has interacted with the fluid pressure unit 176 via line 178
to cause the hydraulic cylinder to move the lubricator into its operative position.
Additionally, the controller has subsequently instructed servo-motor 180 on line 182
to drive timing belt 184, thereby turning pulley 186 and the arm 188 rigidly connected
to the pulley, in order that the nozzle 174 has moved into the bore of fill chamber
10.
Interconnection of nozzle 174 to arm 188 involves e.g. a length of flexible tubing
190 which carries four tubes 192, hereinafter referenced specifically 192a, 192b,
192c and 192d, which serve various purposes to be explained.
Nozzle 174 carries a polytetrafluoroethylene (PTFE) collar 194 to guide it in the
bore of the fill chamber 10. The collar has a generally polygonal cross section, for
example the square cross section shown in Fig. 11, and it only contacts the bore at
the polygonal corners, thus leaving gaps 196 for purposes which will become apparent
from what follows.
Fig. 12 shows that the flexible conduit 190 is constrained to move in a circular path
by channel 198 containing PTFE tracks 200, 201, 202, as it is driven by arm 188. Fig.
12 also shows the four tubes which will now be specified. Tubes 192a and b are feed
and return lines for e.g. water-based lubricant or coating supply to nozzle 174. Tube
192c is the nozzle air supply, and tube 192d is a pneumatic power supply line for
a valve 204 (Fig. 13) in nozzle 174. The tubes 192 extend between nozzle 174, through
the conduit 190, to their starting points at location 206 inwards toward the pivot
point for arm 188. At location 206, flexible tubing (not shown) is connected onto
the tubes 192, the flexible tubing extending to air and lubricant supply vessels (not
shown).
Fig. 13 shows greater detail for the nozzle 174 of the die-end lubricator. Nozzle
head 208, which is circular as viewed in the direction of arrow B, has a sufficient
number of spray orifices 210 distributed around its circumference that it provides
an essentially continuous conical sheet of backwardly directed spray. An example for
a nozzle head diameter of 5.71 cm (2.25 inches) is 18 evenly spaced orifices each
having a bore diameter of 0.061 cm (0.024 inches). Angle C is preferably about 40°.
Angles from 30° to 50°, preferably in the range 35 to 45°.
The nozzle mixing chamber 212 receives e.g. water-based lubricant or coating from
tube 214 and air from tube 216, or just air from tube 216, depending on whether valve
204 has opened or closed tube 214 as directed by pneumatic line 192d.
The nozzle 174 is joined to the flexible tubing at junction 218. Line 192c, goes straight
through to tube 216. Lines 192a and b are short-circuited at the junction, in order
to provide for a continual recirculating of lubricant or coating, this being helpful
for preventing settling of suspensions or emulsions. The short-circuiting 220 is shown
in Fig. 14. Tube 214 is continually open to the short-circuit, but only draws from
that point as directed by valve 204, at which time controller 108 causes a solenoid
valve (not shown) ill the return line to close, in order to achieve maximum feed of
lubricant or coating to the nozzle.
Programmable controller 108 of Fig. 10 interacts with the pneumatic pressure supply
for line 192c to send air to open valve 204, such that a lubricant or coating aerosol
is sprayed onto the bore of the fill chamber as the nozzle moves toward the die in
the bore. The controller does not operate the servo-motor to drive the nozzle so far
that it would spray lubricant down the inlet orifice 60. The nozzle is stopped short
of that point, but sufficient aerosol is expressed in the region that part of the
bore at the inlet orifice does get adequately coated. The controller additionally
provides the ability to vary nozzle speed along the bore, in order to give trouble
points more coating should such be desired.
Once the nozzle has gone as far as it should go, just short of the inlet orifice,
it is then retracted. During retraction, the controller has caused pneumatic valve
204 to turn the lubricant coating supply off, so that only air from line 192c, tube
216, exits through the orifices 210. This air drys water from water-based lubricant,
coating, on the bore, and sweeps it, in gasified form, together with loose solder,
or flash, from the bore. When the nozzle is back in its retracted position, as shown
by the dot-dashed representation in Fig. 9, controller 108 then operates cylinder
172 to swing the lubricator back out of the way, the die halves are closed, and the
die-casting machine is ready to make the next casting.
The gaps 196 allow space such that the gas flow out of the nozzle can escape at the
die end of the fill chamber.
g. Controlling the piston fill chamber clearance
This invention departs from the work of Miki et al. described in the above-mentioned
patent 4,563,579 ('579) by focussing on the fit between piston and fill chamber during
the metal feed stroke of the piston as a source of gas in castings made in vacuum
die casting machines.
As is evident from Fig. 5 of '579 and the discussion in the text of that patent, the
prior practice has involved considerable upward deviation of the temperature of the
piston, or plunger, relative to the temperature of the fill chamber bore, i.e. the
sleeve, as the piston moves through the metal feed stroke for injecting molten metal
into the die. Thus, with reference to Fig. 5 of '579, from a point in time at which
the temperatures of piston and fill chamber bore are approximately the same, the temperature
of the bore rises to a peak and then falls, while the piston temperature rises to
a much higher peak, thence to fall with the bore temperature back to a state where
the temperatures are approximately equal. As noted in '579 the relative temperature
rise of the piston as compared to the bore can cause the two to attain an interference
fit, such that retraction of the piston is delayed until cooling releases the interference
fit.
The fit between the piston and bore during the feed stroke of the piston is controlled
for resisting gas leakage through the piston-bore interface into the metal which is
being forced while under vacuum by the piston into the die. Different measures may
be taken to achieve this control. One measure is to regulate the cooling of the piston
such that the temperature swing of the piston over the course of a casting cycle is
lessened. Thus, while a locked interference fit cannot be accepted, the cooling may
be regulated to maintain the piston temperature such that a sliding, gas-leakage minimizing
fit is achieved, rather than a looser, gas-admitting fit.
A second measure, which may be used in conjunction with the first measure, includes
providing ar interference or an otherwise close or sliding fit of she piston in the
fill chamber bore at some reference temperature, for instance room temperature, aid
heating the fill chamber to make the piston movable with tight fit in the fill chamber
bore. With the fill chamber being heated, the piston temperature will swing less upward
relative to the bore temperature and a tighter, gas-resisting fit can be maintained
during the metal feed stroke.
Both measures can be adapted depending on the particular materials of construction,
and thus, for instance, on the coefficients of thermal expansion characterizing the
materials. The underlying basis for adaptation is the concept of keeping the clearance
between piston and fill chamber bore gas-tight during the feed stroke of the piston,
balanced with requirements for the force needed to move the piston and control of
wear of piston and fill chamber bore.
Figs. 17A to 17D illustrate control of the piston to fill chamber clearance. Piston
4 is internally cooled or heated by water or other fluid entering through supply line
114 and return line 116. Provision is made for continual flow of water through a by-pass
line 300 containing a manually operable valve 302 and a check-valve 304. Controller
306 operates an on-off, or variable-position (for use in the case of proportional,
proportional-integral, PID, etc., control), valve 308, based on its program and information
received from thermocouple 310, whose leads may be threaded out of lines 114 or 116
to the controller. Optionally, a heater or cooler 312 is provided on the fill chamber
10 and controlled from the controller 306 using thermocouple 314.
Figs. 17B to 17D are examples of different control schemes which may be used for controlling
piston temperature. In general, it is preferred to control the piston to fill chamber
clearance by way of interactions with the piston, since it responds quicker than the
fill chamber, due to its copper material and its smaller size.
With reference to Fig. 17B, the control may be a closed-loop control using piston
temperature information from thermocouple 310. Illustrated is an on-off control with
hysteresis. The operator selects the piston temperature set point Tsp, as well as
the temperature deviations Δ2 and Δ1 which together sum to determine the differential
gap. In a variation on the control according to Fig. 17B, a closed-loop control based
on piston outlet water temperature is used, there thus being a set point for the water
temperature. Piston outlet water temperature is the feedback signal.
Figs. 17c and 17d illustrate open-loop control with variable pulse widths τ1 and τ2
input by the operator. The time point 320 is vacuum start or Phase 2 start, Phase
2 being the portion of the piston metal feed stroke where a higher piston travel speed
is used, once the metal has reached, or is about to reach, the gate(s) into the portion
of the mold cavity where the actual part will be formed. The time point 322 is vacuum
end.
h. Example.
Further illustrative is the following example:
Example I
| Yield Strength MPa | Ultimate Strength MPa | Elongation % | Free Bend mm | |
| Avg | 115 | 195 | 15.3 | 37 |
| Min | 110 | 187 | 9.5 | 33 |
| Max | 121 | 201 | 22.0 | 39 |