[0001] This invention relates to a permanent mould, such as a die casting mould and/or an
injection mould, and to a process for controlling the temperature distribution in
such a mould and in the parts cast or moulded thereby when it is used repetitively.
[0002] The life of a die, a permanent mould or a die casting mould and as well as the microstructure
and the dimensional stability of a part cast or injected into it are dependent on
the temperature distribution of the different points of the casting and mould.
[0003] Usually dies are metallic and their cooling is achieved by water or other fluids
circulating through cooling tubes or circuits bored inside them.
[0004] There are also known systems in which the cooling is controlled by optical (e.g.
infrared) pyrometers and realised by external water jets. This is the case, for instance,
in US-A-3 506 060, upon which the preamble of claim 1 is based, FR-A-2 085 409 and
EP-A-0 286 977. In the method referred in the first two publications, cooling is done
on the external side of rotative dies used for centrifugal casting. The third publication
considers the direct cooling of the hotter side of the permanent mould, i.e., the
side that has been in contact with the metal poured in it.
[0005] The systems disclosed in those publications employ water as the cooling fluid. None
has the flexibility necessary to search, very quickly, the hotter parts of a die or
to search the hotter surfaces of a cast piece, whatever shape it has. EP-A-0 286 977
expressly states that both the temperature detecting carriage and the sprayer carriage
are preferably displaceable at a constant speed.
[0006] Differently, however, according to the process of the present invention, the search
of the hotter surface areas is done very quickly and the cooling of them may be effected
with a slow motion of the blowing system or even with this system stopped and pointing
to the hotter points during the time necessary to cool them.
[0007] The present invention provides a process for controlling the temperature of a permanent
mould, comprising scanning areas of the mould by means of at least one optical pyrometer
in order to measure the temperatures of those areas, comparing the measured values
of said temperatures with desired values, and directing heat carrier fluid streams
at the said areas in order to reduce any difference between the measured and desired
values, characterised in that the heat carrier fluid is air, the process steps being
carried out immediately after the removal of the casting or moulding from the permanent
mould.
[0008] The use of air has the advantage of avoiding the dispersing of water around the work
station.
[0009] The present invention provides a process for cooling and/or controlling the temperature
distribution of a permanent mould, e.g. a die casting mould, and of a cast or injected
part, using optical pyrometry in combination with the localized blowing of air (adjustable
flows and adjustable amounts) so that the process may be optimized.
[0010] According to the invention, an optical pyrometer or a plurality of optical pyrometers
scan at convenient distances the different parts of a permanent mould immediately
after the removal of the casting or moulding and measure the temperature of each area
thereof and, if necessary, also the temperature of each point of the casting or moulding,
e.g. a cluster of cast parts.
[0011] The measurements of the optical pyrometer(s) are converted into one or more electrical
signals which are fed to an information processing system that treats them according
to a predetermined program. Depending on the temperature readings and according to
said program, one or more blowing systems are operated so that a controlled flow rate
or flow rates of one or more cooling or heating air jets are impinged in controlled
amounts against the area or the areas, the temperatures of which are being read or
have just been read by the pyrometer(s).
[0012] In this way, the temperatures of said areas are controlled.
[0013] The present invention provides a system which improves the life of a permanent die
casting mould as it avoids its overheating or its excessively heterogeneous heating.
On the other hand, this process adjusts the temperature of each area of the permanent
die casting mould so that a subsequent casting or injection run may be made and undue
heterogeneity, warpings and/or any other defects of the die, caused by its heating,
and of the castings, caused by the solidification process, may be avoided. At least,
the process according to this invention can also be used whenever the produced castings
or the injected parts have to be homogeneously cooled, for instance, when the direct
austempering of cast iron after the casting is intended. The inventive process will
control effectively the cooling of the cast parts.
[0014] The process according to this invention can be used together with the classical systems
of temperature control of permanent moulds, including those having channels for the
circulation of cooling (or heating and cooling) fluids, in order to reduce deviations
in relation to the previewed or desired local temperatures. But the process can also
be used alone, replacing the traditional cooling systems.
[0015] It has the advantages of being simpler and of acting locally in dependence on the
temperature and the real conditions existing at each point and at each time.
[0016] The process here disclosed also has the advantage that it can be used not only with
metallic moulds, but also for the cooling of ceramic permanent moulds, and moulds
made totally or partially of any porous and/or low heat conducting materials, eliminating
the excess of heat by the side of the permanent moulds that is directly heated during
the pouring or the injection casting, and preventing the absorption of water.
[0017] With this system, the opening of cooling channels in the interior of the permanent
moulds is no longer necessary and the risk of cracking of the dies and of leakage
of cooling liquids are avoided.
[0018] It has still the advantage that it can be also used to cool, in a controlled way,
the cast pieces, namely when they are poured in dies or made by injection casting.
[0019] With the present process, it is possible to homogenize and control the temperature
and the cooling of the parts, in order to avoid warping, guarantee predetermined structures,
prepare the cast pieces for subsequent heat treatments, or even to accomplish the
heat treatments by using an adequately strong cooling rate when the temperatures are
convenient for this purpose.
[0020] The fluid used is air, including mixtures with lubricants, anti-adherents, thermal
insulating materials, and so on. Such additives, besides cooling the permanent moulds,
may prepare them for the next pouring or injection casting operation, being deposited
on the area against which the stream of fluid is directed.
[0021] This process of temperature control can be used in the die casting of cast irons,
in the die and injection casting of aluminium and other alloys, and in the injection
moulding of polymers and of other materials.
[0022] Although designed, in principle, to cool permanent moulds or to cool the pieces poured
in dies or injected in permanent moulds, the same process can also be used to heat
the permanent moulds (and, in some cases, even the pieces poured or injected in them)
when the blowing fluids are conveniently heated.
[0023] It is a process that is quite simple, can be automated, and has a very wide application.
[0024] For controlling the temperatures of a permanent die casting mould and cast or injected
parts, by optical pyrometry in combination with the local blowing of a fluid in dependence
on the temperature measured in each area, one or a plurality of optical pyrometers
scan (at a certain distance) the surface of a die casting permanent mould, made of
a metallic, ceramic composite, coated material, or any other, with or without cores,
and, if necessary, scan also the cast or injected part and, depending on the temperatures
read in each area, open or close more or less one or more valves of a blowing system,
blowing one or more jets of air as a heat carrier, in controlled amounts, towards
the areas that need to be cooled or heated, so that the temperatures become the desired
ones, in order to improve the life of the permanent die casting moulds, including
eventually cores, and in order also to guarantee good conditions for the subsequent
casting or injection operation of the next piece in the same die, or in order also
to reach the convenient temperatures in the die-cast or injection-moulded parts, for
a subsequent heat treatment (austempering or any other), in order to avoid warping,
and also in order to achieve desired microstructures.
1. A process for controlling the temperature of a permanent mould, comprising scanning
areas of the mould by means of at least one optical pyrometer in order to measure
the temperatures of those areas, comparing the measured values of the said temperatures
with desired values, and directing heat carrier fluid streams at the said areas in
order to reduce any difference beween the measured and desired values, characterised
in that the heat carrier fluid is air, the process steps being carried out immediately
after the removal of the casting or moulding from the permanent mould.
2. A process as claimed in claim 1, in which the heat carrier fluid contains an additive,
e.g. a lubricant or anti-adherent, which is deposited on the area at which the stream
is directed.
3. A process as claimed in claim 1 or 2, further comprising scanning areas of a cast
or injection moulded part or cluster of parts by means of at least one optical pyrometer
in order to measure the temperatures of those areas immediately after the removal
from the mould, comparing the measured values of those temperatures with desired values,
and directing heat carrier air streams at those areas in order to reduce any difference.
4. A process as claimed in any preceding claim, in which temperature measurement by optical
pyrometry is done in combination with air blowing and the flow rate of the air and
the amount of air which is directed towards the said areas are controlled as a function
of the local and actual temperatures measured and as a function of the mould temperature
desired for the next pouring or injection.
5. A process as claimed in any preceding claim, in which signals from the optical pyrometer(s)
are fed to a processing system which controls one or more blowing systems for directing
the heat carrier fluid streams at the said areas.
6. A process as claimed in claim 5, in which the blowing systems comprise valves which
are closed or opened more or less, as a function of the signals.
1. Verfahren zur Regelung der Temperatur in einer Kokille, das folgende Schritte aufweist:
Abtasten von Bereichen der Kokille mit Hilfe mindestens eines optischen Pyrometers,
um die Temperaturen dieser Bereiche zu messen, Vergleich der Temperaturmeßwerte mit
Sollwerten und Lenken von Wärmeträgerfluidströmen auf die Bereiche, um jede Differenz
zwischen den Meßwerten und den Sollwerten zu verringern, dadurch gekennzeichnet, daß
das Wärmeträgerfluid Luft ist, wobei die Verfahrensschritte unmittelbar nach der Entnahme
des Gußstücks oder Formteils aus der Kokille ausgeführt werden.
2. Verfahren nach Anspruch 1, wobei das Wärmeträgerfluid einen Zusatz enthält, z. B.
ein Schmiermittel oder Trennmittel, das auf dem Bereich abgeschieden wird, auf den
der Strom gerichtet ist.
3. Verfahren nach Anspruch 1 oder 2, das ferner die folgenden Schritte aufweist: Abtasten
von Bereichen eines Gußstücks oder Spritzgußteils oder einer Gießtraube von Teilen
mit Hilfe mindestens eines optischen Pyrometers, um die Temperaturen dieser Bereiche
unmittelbar nach der Entnahme aus der Form zu messen, Vergleich der Temperaturmeßwerte
mit Sollwerten und Lenken von Wärmeträgerfluidströmen auf die Bereiche, um jede Differenz
zu verringern.
4. Verfahren nach irgendeinem der vorstehenden Ansprüche, wobei die Temperaturmessung
durch optische Pyrometrie in Kombination mit einem Ausblasen mit Luft erfolgt und
die Strömungsgeschwindigkeit der Luft sowie die auf die Bereiche gelenkte Luftmenge
in Abhängigkeit von den gemessenen lokalen und aktuellen Temperaturen und in Abhängigkeit
von der Solltemperatur der Kokille für den nächsten Guß oder Spritzguß geregelt werden.
5. Verfahren nach irgendeinem der vorstehenden Ansprüche, wobei Signal vom dem (den)
optischen Pyrometer(n) einem Verarbeitungssystem zugeführt werden, das ein oder mehrere
Gebläsesysteme steuert, um die Wärmeträgerfluidströme auf die genannten Bereiche zu
lenken.
6. Verfahren nach Anspruch 5, wobei die Gebläsesysteme Ventile aufweisen, die in Abhängigkeit
von den Signalen mehr oder weniger geöffnet oder geschlossen werden.
1. Procédé pour régler la température d'un moule permanent, comprenant le fait de balayer
des zones du moule au moyen d'au moins un pyromètre optique afin de mesurer les températures
de ces zones, de comparer les valeurs mesurées desdites températures aux valeurs désirées
et de diriger des courants de fluide caloporteur sur lesdites zones afin de réduire
toute différence entre les valeurs mesurées et les valeurs désirées, caractérisé en
ce que le fluide caloporteur est de l'air, les étapes opératoires étant réalisées
immédiatement après le retrait de la pièce coulée ou moulée du moule permanent.
2. Procédé selon la revendication 1, dans lequel le fluide caloporteur contient un additif,
par exemple un lubrifiant ou un anti-adhérant qui est déposé sur la surface sur laquelle
est dirigé le courant.
3. Procédé selon la revendication 1 ou 2, comprenant en outre le fait de balayer des
zones d'une pièce coulée ou d'une pièce moulée par injection ou encore d'un groupe
de pièces, au moyen d'au moins un pyromètre optique afin de mesurer les températures
de ces zones immédiatement après le retrait du moule, de comparer les valeurs mesurées
de ces températures aux valeurs désirées et de diriger des courants d'air caloporteur
sur ces zones afin de réduire toute différence.
4. Procédé selon l'une quelconque des revendications précédentes, dans lequel la mesure
de la température par pyrométrie optique est réalisée en combinaison avec un soufflage
d'air, et le débit de l'air, ainsi que la quantité d'air dirigée vers lesdites zones,
étant réglés en fonction des températures locales et réelles, mesurées, et en fonction
de la température du moule désirée pour la coulée ou l'injection ultérieure.
5. Procédé selon l'une quelconque des revendications précédentes, dans lequel des signaux
provenant du ou des pyromètres optiques sont acheminés à un système de traitement
qui règle un ou plusieurs systèmes de soufflage pour diriger les courants de fluide
caloporteur sur lesdites zones.
6. Procédé selon la revendication 5, dans lequel les systèmes de soufflage comprennent
des vannes qui sont plus ou moins fermées ou ouvertes en fonction des signaux.