Electric heating – Inductive heating – Specific heating application
Reexamination Certificate
2000-12-05
2001-10-30
Leung, Philip H. (Department: 3742)
Electric heating
Inductive heating
Specific heating application
C219S673000, C219S676000, C219S659000, C264S403000, C264S486000, C425S17480E
Reexamination Certificate
active
06310333
ABSTRACT:
TECHNICAL FIELD
The present invention relates to an induction heating method for a manifold in a hot runner mold.
BACKGROUND ART
In a hot runner mold, it is necessary to maintain material within the runner in a molten condition by heating the runner. Heater heating and induction heating have been known as methods for heating the runner. The induction heating can heat the material to a desired temperature in a shorter time than the heater heating. Further, the induction heating has the advantage that it is superior in controllability of temperature and power consumption is also small.
FIG. 10
is for showing a prior art of the present invention and is a schematic side view of a manifold heated by induction heating.
A manifold
10
has a sprue portion
11
for introducing molten material sent from an injection cylinder (not shown) into the manifold
10
and a runner portion
12
for distributing the molten material as flown from the sprue portion
11
to nozzles
20
. The manifold
10
is disposed within a space formed between a fixed mold plate
1
of the hot runner mold and a back plate
2
mounted to a rear surface thereof. At a time of injection molding, a large mold clamping force acts on the fixed mold plate
1
, the nozzles
20
and the back plate
2
. For this reason, the manifold
10
is supported by heat-insulating supporting members
16
at a plurality of portions between the fixed mold plate
1
and the back plate
2
so as to prevent the manifold
10
from being distorted or displaced due to the clamping force.
Coils
15
for induction heating are wound around an outer periphery of the manifold
10
at portions at which the manifold is not supported by the supporting members
16
. When voltage is applied to the induction heating coils
15
, the material within the runner is heated at portions where the induction heating coils
15
are wound.
In the above-described induction heating method there are the following drawbacks.
(1) In order to heat material uniformly, it is preferable to wind the coils
15
over the entire length of the runner portion
12
. However, portions where the coils
15
may be wound will be limited by the supporting members
16
for supporting the manifold
10
. Therefore, there is a drawback that variations occur in temperature of the molten material within the runner to result in irregularities in qualities of injection-molded articles and in pouring deficiencies.
(2) In case of injection molding of molten metal having a high melting point and exhibiting favorable thermal conductivity, such as magnesium, it will be required to heat the material located at portions where induction heating is performed to a temperature that is remarkably higher than the melting point thereof. This consequently increases the possibility of run-out or thermal distortion and also shortens the life of the coils themselves.
(3) As one method for solving the above drawback, it is considered to form through holes on the supporting members and to wind the induction heating coils around the periphery of the manifold
10
through these through holes. However, forming the through holes into the supporting members formed of material such as ceramics will result in higher cost. The through holes will further weaken the strength of the supporting members.
(4) The respective coils
15
are connected by lead wires each other. These lead wires are connected to an external power supply source through the back plate
2
. A drawback is accordingly presented that the coils
15
are hard to be detached from the manifold
10
at a time of performing exchange, inspection or repair of the manifold
10
and thus worsens the workability.
The present invention has been made in view of these drawbacks, and it is an object thereof to provide an induction heating method for a manifold of a hot runner mold and a coil unit for induction heating with which it is possible to uniformly heat material over the entire length of a runner without weakening the strength of a supporting member and in which the coil may be easily attached to and detached from the manifold.
DISCLOSURE OF THE INVENTION
Clamping force acts onto the manifold
10
in a direction identical to a clamping direction thereof (which is a direction indicated by arrow X in FIG.
10
). The inventors of the present invention have completed the present invention in view of the fact that no clamping force acts onto a side surface
10
b
of the manifold
10
that is parallel to the clamping direction. In other words, the manifold
10
only needs to be supported by the supporting members
16
at a surface
10
a
that is orthogonal to the clamping direction, and a space in a length direction may be secured over the entire length of the runner portion
12
on the side surface
10
b.
More particularly, the present invention relates to an induction heating method for a manifold of a hot runner mold including a fixed mold and a movable mold, the induction heating method comprising the steps of: providing a space along a side surface on which no clamping force is applied by the fixed mold and the movable mold of the manifold; winding a coil to the side surface along an axial line of a runner of the manifold; and performing induction heating of the manifold from the side surface.
According to this method, the material within the manifold may be uniformly heated over the entire length thereof. Attaching and detaching the coil to and from the manifold will also become easy.
Also, a method may be employed where the coil is wound to extend in a spiral manner from the side surface to a surface orthogonal to the clamping direction, and the manifold is induction-heated from the side surface and the surface orthogonal to the claming direction by this spiral coil.
According to this method, induction heating of the manifold may be performed not only from the side surface but also from the surface orthogonal to the clamping direction so that the temperature of the material may be made more uniform. Attaching and detaching the coil to and from the manifold will also become easy.
Furthermore, a method may be employed where the manifold is partitioned into a plurality of portions to divide each portion into a single region and the spiral coil is wound for each region to perform induction heating.
With using spiral coils, it will be possible to easily wind a coil around an arbitrary portion and to perform induction heating of the manifold from the side surface. It will further be possible to adjust temperature of the material of each portion to a desired temperature.
An induction heating coil unit according to the present invention is a unit for a manifold of a hot runner mold including a fixed mold and a movable mold, comprising a coil holding body that is provided to be attachable and detachable to and from the manifold and disposed within a space formed along a side surface on which no clamping force is applied by the fixed mold and the movable mold of the manifold, and a coil that is held by the coil holding body and is wound to the side surface along an axial line of a runner of the manifold, wherein the manifold is heated from the side surface.
With this arrangement, the material may be uniformly heated over the entire length of the runner. The coil may further be easily attached to and detached from the manifold.
Alternatively, the coil holding body may be provided on both of opposing side surfaces of the manifold astride the surface orthogonal to the clamping direction wherein a coil is held by the coil holding body in a spiral manner.
With this arrangement, induction heating of the manifold may be performed not only from the side surface but also from the surface orthogonal to the clamping direction so that the temperature of the material may be made more uniform. Attaching and detaching the coils to and from the manifold will also become easy.
REFERENCES:
patent: 4544519 (1985-10-01), Schilke
patent: 4940870 (1990-07-01), Shibata et al.
patent: 5989003 (1999-11-01), Gray et al.
patent: 0 445 313 (1991-09-01), None
patent: 0 551 830 (1993-07-01), No
Edagawa Shinichi
Munakata Tamotsu
Sekiguchi Ryoichi
Shibata Itsuo
Toki Hitoshi
Ju-Oh Inc.
Kanesaka & Takeuchi
Leung Philip H.
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