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Acta Polytechnica Vol. 52 No. 4/2012

Holding Pressure and Its Influence on Quality in PIM Technology

Pavel Petera1

1
Department of Engineering Technology, Faculty of Mechanical Engineering, Technical University of Liberec,
Studentská 2, Liberec, Czech Republic

Correspondence to: pavel.petera@tul.cz

Abstract

The PIM (powder injection molding) process consists of several steps in which faults can occur. The quality of the part

that is produced usually cannot be seen until the end of the process. It is therefore necessary to find a way to discover the

fault earlier in the process. The cause of defects is very often “phase separation” (inhomogeneity in powder distribution),

which can also be influenced by the holding pressure. This paper evaluates the powder distribution with a new method

based on density measurement. Measurements were made using various holding pressure values.

Keywords: PIM, holding pressure, phase separation.

1 Introduction

Powder injection molding technology (PIM) is a very
effective and precise technology, especially for pro-
ducing small metal and ceramic parts with complex
shapes in large-scale production. The technology it-
self consists of two subcategories, CIM (ceramic injec-
tion molding) and MIM (metal injection molding). A
clear difference between CIM and MIM is in the use of
different feedstocks, where a different powder is used
(either metal-based or ceramic-based). The powder
is mixed with a polymeric binder and is granulated.
The processing is very similar to standard injection
molding, but due to the highly abrasive properties
of the powder it is necessary to use a suitable ma-
chine with abrasion-resistant parts (screw, cylinder
etc.) After the injection-molding stage of the pro-
cess, it is necessary to take out the binder. There are
various ways to remove the polymeric binder, includ-
ing catalytic debinding, water dissolving or thermal
debinding. The last stage of production is sinter-
ing, which produces a part with high density and is
accompanied by considerable shrinkage. The shrink-
age is dependent on several factors, e.g. the material
(the ratio between powder and binder in the feed-
stock, the type of binder, the material of the pow-
der, grain size, etc.), processing conditions, mold,
machine, etc. The quality is often influenced by a
range of factors, but the influence of holding pres-
sure remains not well described. The aim of our
project is to study the influence of holding pres-
sure on the quality of the molded part. This paper
describes the influence of holding pressure on pow-
der distribution in various places in the specimen
characterised by a new method — density measure-
ment.

2 Materials and methods

2.1 Preparation of the specimens

Inmafeed 1008 feedstock, produced by Inmatec (Ger-
many), was selected as a material for the specimens.
The exact composition of this material is protected,
but it is based on Al2O3 and consists of powder
(about 81–90 %) and a binder (about 10–19 %). The
powder composition is min 96 % of Al2O3 and up
to 4 % of inorganic flux additives. It uses two-step
debinding (water and thermal). The Sintering tem-
perature is 1 620 ◦C. The binder is based on a poly-
olefin and wax mixture. A cavity with dimensions
120 × 10 × 4 mm was selected for the specimens, of
which was the density evaluated in various places.
These specimens were produced by powder injection-
molding technology, where the mold has a gate from
the shorter side. An Arburg Allrounder 270S injec-
tion molding machine was used. The processing con-
ditions were set according to the material sheet with
two different holding pressure values (see Table 1).

Table 1: Processing parameters for injection molding
of the specimens

Processing temperature From feeding zone 159
◦
C

to nozzle tip 162
◦
C

Mold temperature 60
◦
C

Injection speed 80 ccm/s

Dose volume 30 ccm

Holding pressure 300/150 bar

Switching to holding pressure 11 ccm

Cooling time 10 s

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Acta Polytechnica Vol. 52 No. 4/2012

2.2 Evaluation of the density in
different places

The decision was taken to measure the average den-
sity in 28 different places (4 rows on the shorter side
of the sample and 7 rows on longer side, where es-
pecially close to the gate and at the end of the part
the measuring points were placed more densely be-
cause higher influence of the holding pressure was
expected). More details are shown in Figure 1. All
specimens were conditioned according to EN ISO 291
before measuring the density. In places where the
measurements were to be made, the tested sample
was cut into small pieces 2 × 2 mm in dimensions,
while the thickness remained constant (4 mm). This
means that the variations in properties across the
thickness were not considered. The Archimedean im-
mersion method was selected as the testing method
(according to EN ISO 1183). An A&D GF-300 bal-
ance was used for weighing the samples. Due to the
high density of the feedstock that was used, the im-
mersion fluid was distilled water. It was necessary to
use a surfactant to reduce the high surface tension.
The sample then immersed much more easily.

The results were calculated according to the
Archimedes principle, and the results are shown in
the graphs in Figures 2 and 3.

Figure 1: Specimen with 28 measuring points:
On the shorter side, all distances are 2 mm
and on the longer side the points are placed
2/4/8/40/80/114/118 mm from the gate

Figure 2: Average density in each of 28 points on the specimen, where the holding pressure was 300 Bar

Figure 3: Average density in each of 28 points on the specimen, where the holding pressure was 150 Bar

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3 Results and discussion

In the case of PIM, the flow properties are sig-
nificantly different from the case of conventional
injection-molding, because of the smaller amount of
polymeric material and the combination with inor-
ganic grains. These inorganic grains have much worse
fluidity than standard polymeric material, and also
have an abrasive effect on the machine and on the
mold. The effect of the holding pressure is also dif-
ferent. It causes different coordination of the two
components of the melt in different places and, as a
result, also different properties, shrinkage etc. It is
then quite difficult to set up the machine, especially
the holding pressure.

It can be seen from these graphic relations, which
show the density across the sample, that where there
was higher holding pressure the distribution of the
density values was more homogeneous. This means
that the distribution of the ceramic powder should
also be more homogeneous. If we focus on specific
places, the density values were also more constant in
the middle of the specimens (longitudinal direction)
than in the area close to the gate or at the end of the
sample. In these places with more constant values, it
is likely that a quality surface can be obtained after
sintering. It can also be seen that with higher hold-
ing pressure the average density is also higher. This
indicates a higher content of ceramic particles, which
are of higher density than the polymeric binder.

4 Conclusion

PIM technology is quite sensitive as far as changing
the holding pressure is concerned, but the influence
on the properties of PIM parts has not yet been de-
scribed properly. The approach of evaluating the in-
fluence of the holding pressure on quality, represented
by powder distribution, which was quantified by den-
sity measurements, is a new way to predict the distri-
bution of ceramic (or metal) powder and binder in in-
jection molded part by using a different holding pres-
sure. This could be useful for discovering any defects
before sintering has been performed, and therefore
avoiding wasting time, material, energy, etc., in the

subsequent steps (recycling can still be done in the
“green part” step). The experimental measurements
showed that samples produced with higher holding
pressure showed more homogeneous density distribu-
tion, and generally also higher density values, this
could indicate that there was a greater content of ce-
ramic powder, which has a higher density than the
polymeric binder. Also, as anticipated, the densities
were slightly more homogeneous in the middle of the
specimen than in the area of the gate or at the end of
the specimen. The method is quite simple and pro-
vides visual results, but its accuracy is limited even
when the work is carried out with great precision. It
is therefore necessary to continue investigating this
topic, to seek new approaches and methods, and to
make further measurements.

Acknowledgement

The topic has been solved under the terms of so-
lution of the research program SGS 2822.

References

[1] Li, Y., Lou, J., Yue, J.: Analysis and evaluation
of effects of processing steps on dimensional toler-
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[2] Laddha, S., Wu, C., Vallury, S., Lingam, G.:
Characterisation of alumina feedstock with poly-
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powder injection moulding. In PIM International,
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[3] Barriere, T., Gelin, J., Dvořák, P., Liu: Exper-
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[4] German, R., Bose, A.: Injection Moulding
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