The solar tunnel dryer (Fig.3) cons

The solar tunnel dryer (Fig.3) consists of a plastic sheet-covered flat plate solar col1ector, a
drying tunnel and three smal1 axial flow fans (5). To simplify construction and reduce costs,
the solar col1ector is connected directly to the drying tunnel without any additional air ducts.
Plastic foam sandwiched between two paral1el metal sheets is used as a back insulator for
both the col1ector and drying tunnel. This insulator also functions as the structure of the
dryer. The top surface of the insulator in the col1ector is painted black to absorb solar
radiation. The col1ector is covered with a transparent u. v .-stabilized PE plastic sheet that is
fixed to the col1ector frame using reinforced plastic clamps. For the drying tunnel, a wire
mesh is placed on top of the insulators. A sheet of plastic net, on which the product to be
dried are spread, is placed on top of the wire mesh. This arrangement allows drying air to flow
around the whole surface of the product being dried. The drying tunnel is also covered with a
u. v .-stabilized air bubble plastic sheet. One side of this sheet is fixed to the tunnel frame and
the other side is fixed to a metal tube allowing the sheet to be rolled up and down for loading
and unloading the dryer. Fastening plastic profiles, as shown in Fig. 4, are used to fix the
sheet to the tube and also to the drying tunnel frame. This fixing method is designed to
facilitate the replacement of the sheets. In general, the transparent sheet can be used for 1-2 yr
and the air bubble sheet lasts for 3-5 years. Three small fans powered by a 53 W solar cell
module are installed in the back of the collector to suck ambient air into the collector as
shown in Fig. 5. The fans are intentionally installed below the solar module to constantly
reduce its temperature, thus maintaining its efficiency. Both the collector and the drying
tunnel are installed on concrete block substructures. All parts of the dryer, including the back
insulator and metal frames, are designed using a modular concept, which facilitates the
transport and installation of the dryer. This solar tunnel dryer uses solar energy both in the
thermal form for the drying process and the electrical form for driving the fans, by means of
the solar collector and solar module respectively. Therefore, the dryer could be used in rural
areas where there is no supply of electricity.
A rock-bed dryer is shown in Fig. 6. In this dryer, air, drawn by natural convection through an
air inlet (A), circulates the heat collected by the primary solar energy collector (B),
throughout the drying chamber (C) which is packed with limestone rocks of relatively
uniform diameter. The heat would then stratify across the rock bed but, since rocks are poor
thermal conductors, temperature differences would slowly disappear when air is not moving
through the rock bed. Thus samples positioned above the rock-bed can continue drying during
the night. This type of a solar dyer requires very little maintenance (6).