Considerations regarding of basaltic materials usage with mineralizers input in machine building.
Stefanescu, Werner ; Pugna, Adrian ; Pleniceanu, Aristica 等
1. INTRODUCTION
The economic development normally entails important changes in the
field of machine building, as well.
The machine building represents a branch of vital importance for
the national economy of any country. The increase of the machines park
brings abut the imperative of making machines building more efficient
through substantially reducing the expenses for raw materials and
various other materials, fuels and lubricants.
Such objectives can be attained by maintain the machines park in
good technical condition, by using high quality parts, by ensuring high
operating reliability.
At present, the endeavor to solve such problems consists in
replacing some classical materials, both deficient and energo-intensive,
with some new, unconventional materials, such as basalt.
The basalt products cam be obtained through casting, followed by a
thermal treatment of recrystalization, this procedure is used for
obtaining big parts with simple geometrical shapes, or through sintering
method of powders, recommended for obtaining small and medium parts with
complex configuration. Molten basalt cam be cast in various moulds,
resulting in polyfunctionnal and efficient parts for different
industrial fields, machine building included.
Researches have proved that basalt crystalline structures are not
submitted to the well-know aging phenomenon, as it happens with most
metallic materials and basaltic products obtained sintering are
characterized by high stability at the action of strong bases and acids,
as well as by high resistance to corrosion and wear.
The test made under operating conditions (Stefanescu &
Iancului, 2004) on several parts (gaskets; sleeves; disks;
chain-stretching rollers; etc.) manufactured of sintered basalt, along
with witness parts from current production have proved the following for
the sintered basalt parts:
--a very good resistance to wear, a doubled resistance, as compared
to that of classical parts;
--a highly superior value for parts reliability;
--an inferior wear seed, justified by the high hardness of sintered
(7,5-8 of MOHS scale of Hardness);
--the presence of hidden crazing due to manufacturing technologies
of sintered basalt parts;
--how resistance to dynamic loading.
Improving technology for the elaboration of parts sintered in a
basalt assumed a detailed study on the composition of elements of
identification at the rock, also for determining the composition,
structure and network parameters.
During the sintering experiments depending on the substances
included in the recipe and the temperature, the samples have been some
structural changes caused by chemical reactions and the results
coincided with theoretical determinations. For this reason, the results
of the chemical and theoretical methods, have requested an investigation
of the structure through a high resolution--X ray diffractometry
Analyzing each diffractogram--figure 1- it was ascertain a big
anorthit presence and frequency in the mass of basalt rocks and sintered
basalt parts, which confer them an under--cooling stable and rigid state
(lack of elasticity).
The under--cooling state it could be also the result of the
presence of olivine and magnetite; their presence being more than 10%,
which would favor the crystallization process and from here the vitreous state in the parts mass.
Using electronic microscope to examine the texture, contours and
the geometrical shapes of the sintered basalt parts the following
ascertained:
--existence of amorphous masses in each case due to the presence of
olivine and anorthit;
--imperfections in the parts mass (dislocations, micro cracks,
cleavages), due to manufacturing conditions and stresses with negative
consequences upon mechanical resistance;
--very good compactness, low porosity which demonstrate that the
parts were obtained through a "high sintering";
--pore elimination during sintering process determine a lower
mechanical resistance due to internal inter--granular stresses. The
technological experimental trials done on the samples showed that in the
process of obtaining sintered parts one must take in account the
following considerations:
--compactness, structure, basalt--leant mixture cohesion and also
compactness in sintering process are influenced by the pressuring forces
in the mold;
--samples quality are influenced by the pressure on which they were
formed and by the sintering velocity ;
--samples which followed the right thermal regime where free of
cracks, deformations and have dimensional stability.
[FIGURE 1 OMITTED]
2. METHOD AND EXPERIMENTAL RESULTS
The low resistance to dynamic loading of the parts that are used in
machine building proves the existence of inadequate manufacturing
technologies for sintered basalt parts and, implicitly, the development
of studies and researches of the component elements texture and
structure at the rock level, and part, respectively.
X rays diffraction method is one of the most modern and safe means
of determining the structural characteristics of basaltic materials
(Gheorghies, 1990).
[FIGURE 2 OMITTED]
The comparative study of rocks diffractograms for parts manufacture
and those of the basalt parts--figure 2--, proved that, during sintering
process, there appeared no new substances, and no significant structural
changes have been produced at the level of elementary cell so as to
determine changes of physical-mechanical propertiers (Suk-Joong L. Kang,
2005).
Complete sintering (Stefanescu, 2000) with proposed effects over
the basaltic granular materials, in solid stage, without liquid stage
forming, can be obtained:
--by thermal crystallization treatments, the temperatures rates of
which do not change the type of interatomic bond and the atomic
structure within the crystalline structure, on which the mechanical,
thermal and physical--chemical loading depends;
--by means of small additives and impurities, known as
mineralizers, whose role is to inhibit the granules growth and the
transfer of pores to the granules limit, where their elimination may
continue until the wanted porosity is obtained. The presence of
mineralisers (Becherescu, 1982) changes the real structure lattice by
disorganizing in and creates holes which favors the transfer of the
material from one part of the structure into another part, thus
influencing the physical--mechanical characteristics of the basaltic
parts used in machine building.
Consequently, experiments have been developed, in laboratories, on
witness samples made of basalt and on samples made of basalt and
mineralizes based on Ti and Mg oxides, with a 2 % ratio.
[FIGURE 3 OMITTED]
The samples whose number, from and dimensions were established
according to STAS 6200'9-91, as function of loading, were obtained
by pressing and were thermally treated at temperatures between
900-1100[degrees]C, temperatures required by oxiolic and mineralogical
composition of the basalt employed.
[FIGURE 4 OMITTED]
During the experiments there have been evaluated two parameters:
the mechanical resistances to compression and volumetrically contractions.
The experimental data--figure 3--showed an increase of the
volumetrically contraction for each sample separately, with the growth
of temperature. Samples without mineralisers have superior values as
compared to those with mineralisers, a fact which explains the presence
of interval strain because of the decrease of the crystalline degree and
the development of strained granules. By analysing the technical data
obtained with respect to mechanical resistance to compression--figure
4--there has been observed that basaltic samples without additions
display a weaker mechanical behaviour as compared to those with
additions. At inferior temperatures (900-1000[degrees]C), mechanical
resistances have low values; significant increases can be observed at
temperatures between 1050-1100[degrees]C, justified by the intensified
sintering processes.
3. CONCLUSION
The studies and the experimental results revealed the following
conclusions:
--mechanical resistances to compression and volume contractions
increase with sintering temperature growth;
--the use of mineralisers based on Mg and Ti oxides explains the
better mechanical behavior of sintered basalt parts, because of the
increase of the crystalline degree and the development of less strained
granules;
--the use of mineralisers in the manufacturing technology of
sintered basalt parts results in more reliable parts for machine
building.
4. REFERENCES
Becherescu, D.(1982). Physical methods used in chemistry, Ed.
Stiintifica si Enciclopedica, Bucuresti
Gheorghies, C. (1990). Diffraction spectrum and investigation
techniques, Ed. Tehnica, Bucuresti
Stefanescu, W. & Iancului, D. (2004). Studies concerning of
basaltic materials in agricultural machinery building, in USAB University from Timisoara, Scientifical Research & Horticultural, pp
325-329, ISSN 1453-1402
Stefanescu, W. (2000). Contribution to the study of structure
influence and physical-mechanic properties of basalt based components
over the system operational reliability of farm equipments. PhD;
Timisoara
Suk-Joong L. Kang (2005). Sintering Densification, Grain Growth and
Microstructure, Elsevier Ltd., ISBNS 978-0-7506-6385-4
