People are also much more concerned

People are also much more concerned about environmental
issues and demand sustainable solutions for all aspects of
their daily life.

Reusing, recycling and saving are terms learnt by
children at an early age.

The present world economic crisis also
requires contention, and new affordable and sustainable products
are desirable.

On the other hand, the quality of these products also
has to be guaranteed.

Affordability, sustainability and quality are
therefore the three main vectors which should dictate the design
of such product.

To fulfill these three requirements is the big challenge.

Using organic materials and low technological processes is a
good option to achieve the above requirements [1–3].

These organic
materials have to be preferentially abundant and local.


In the building industry, a big range of products and building
solutions based on raw organic materials have been applied.

Perhaps wood, wood engineered products, cork and cork engineered
products are the most traditional ones.

However, different agricultural
products have also been reported as possible raw organic
building materials [4–9].

Some examples of these agricultural
products are bagasse, cereal, straw, corn stalk, corn cob, cotton stalks, kenaf, rice husks, rice straw, sunflower hulls and stalks,
banana stalks, coconut coir, bamboo, durian peel, oil palm leaves,
among others.

Particleboards, hardboards and fiberboards are
some examples of building products that may be processed using
those materials and they have mainly been studied as possible
alternative thermal and acoustic insulation solutions.


Among the above identified agricultural products corn cob belongs
to the set which has the additional advantage of not colliding
with the worldwide food stock and of being generally considered
as agricultural waste.

A recent research work [9] has reported that
the corn cob may have a similar microstructure and chemical elementary
composition to the extruded polystyrene (XPS).


The main scope of this research work consists on analyzing the
potential use of corn cob granulate (without containing any corn,
i.e. an agricultural waste) as a sustainable aggregate solution of
lightweight concrete and as an alternative to commonly applied
products such as: expanded clay, particles of expanded polystyrene
(EPS), particles of cork or other lignocelluloses wastes [10].

Since corn cob is generally considered an agricultural waste, an interesting
economic and sustainable benefit may be achieved through this
proposed technological solution.

Within the authors’ knowledge the utilization of corn cob in concrete is quite novel, and the only known use is that of corn cob ash in blended cement concretes [11–13].

The lightweight corn cob concrete, presented in this paper, was
designed mainly for using on the regularization of layers of pavements.


Some of the expected requirements of a regularization
layer building solution are: lightweight, insulation capacity (thermal
and/or acoustic), and durability and being economic.

Therefore,
the density, the compressive strength and the thermal
insulation performance were the material properties assessed of
the proposed corn cob concrete within this research work.

In order to evaluate and compare the performance of corn cob concrete, in
parallel, conventional lightweight concrete using expanded clay
was developed and tested.

This paper is structured as follows, firstly, some possible lightweight
concrete applications are presented and also some common
lightweight aggregates are identified.

Secondly, the compressive strength of corn cob and expanded clay concrete samples are assessed.
The sample preparation and used equipment are described,and the experimental results obtained are presented and discussed.

Thirdly, an alternative expedite experimental setup for thermal insulation performance assessment of lightweight concrete samples is proposed.

The inherent facility, the sample preparation, the equipment used and the test preparation are presentedand described in detail.

The experimental results obtained are presented,analyzed and discussed, and the thermal transmission coefficient of the two lightweight concrete samples is quantified.

Finally, the main conclusions of this research work are drawn.