solar collectors, with and without

solar collectors, with and without honeycomb, has been carried out. In this paper some innovative results have been reached:
 - natural convection can be suppressed using honeycomb between the glazing and absorber plate;
 - the bottom gap thickness is more influent than the top gap thickness;
 - the honeycomb panel in the field of solar thermal collectors can reduce the transmission of solar radiation and the top heat loss (of 52%).
For values of the reduced temperature less than 0.026, the optical efficiency of the collectors with honeycomb panel is less than that of the collectors without honeycomb (of about 14%), for values of the reduced temperature higher than 0.026, the thermal efficiency of the collectors with honeycomb panel is higher than the one of the collectors without (at reduced temperature of 0.03, the value of the efficiency is 40% and 30% respectively).
Al-Madani [23] evaluated the performance of a cylindrical solar water heater. The proposed model consists of a cylindrical glass receiver, with a copper coil. After describing the physical characteristics of the glass tube as receiver and of the copper coil as collector, measures of the thermal efficiency have been performed and the maximum value of the obtained averaged efficiency was 41.8%, during a year with a maximum temperature of 45.6 °C and with a minimum temperature of 8 °C.
Ozgen et al. [24] carried out an experimental investigation about thermal performance of a double-flow solar air heater (SAH), with aluminum cans. Three types of solar thermal collectors have been analyzed:
- Type I: cans placed as zigzag on the absorber plate;
 - Type II: cans arranged in order on the absorber plate;
 - Type III: absorber plate without cans.

By introducing aluminum cans on the plate absorber, the heattransfer area is increased and a good airflow over and under the absorber plates is ensured, because cans create turbulence and reduce the dead zones in the collector. Experimental data of the efficiencies for two different mass flow rates (0.05 and 0.03 kg/s) have been recorded for the three types of solar thermal collectors. The first type of the proposed model has the maximum value of efficiency of 72% at 0.05 kg/s mass flow rate. The second type, with cans arranged in orderon the absorber plate,has a lower efficiency (59%) than the first one and it has higher efficiency than the third model at 0.05 kg/s mass flow rate.
The same trend is presented at 0.03 kg/s mass flow rate. This phenomenon is due to the high turbulence created by cans on the absorber plate.
Peng et al. [25] evaluated the performance of a novel solar air collector with pin-fin integrated absorber. Authors developed an original model of collector, which presents some advantages:

1. low cost;
2. high durability;
3. high thermal efficiency,
due to high heat transfer coefficient even at lower air mass flow rates and low heat losses;
4. flexibility in applications of fin-pins.

This new model of solar collector contains an absorber with pin fins arrays of different lengths. From recorded data, the heat transfer coefficients of pin-fin arrays and flat plate collector have been obtained for a determined value of the air volume flow rate (19 m3/h). From theoretical model, the formula of the maximum thermal efficiencies ηmax of 25 kinds of pin-fin collectors is given as in Eq. (1) at ambient temperature:

ηmax ¼0:65
s d
 0:224 h d  0:149

Aldabbagh et al. [26] discussed about single and double pass solar air heaters (SAH), with wire mesh as packing bed. The schematic views of the single and double pass air collectors are shown in Fig. 3. The solar air system is composed by:

1. glass cover;
2. back box;
3. wire mesh layers as absorber
4. digital thermometer;
5. thermocouples;
6. manometer;
7. speed controller;
8. fan;
9. orifice meter.