2. Materials and methodsAll the req

2. Materials and methods
All the required plant materials for drying experiments were
acquired from a local farm and the flowers were separated from
stem. Then, the samples were packed inside separate plastic bags
and were refrigerator at 4 ± 1 C. In this state the total moisture
content of the flowers was about 83% on wet weight basis. During
the drying experiments, mean range of ambient temperature
variation was 30 ± 2 C and mean relative humidity was 28 ± 3%.
Air parameters were adjusted by measuring temperature and
velocity using a thermometer (Lutron, Taiwan), anemometer
(Anemometer, Lutron-YK, Taiwan) and humidity meter (Testo
650, 05366501, German). A digital balance (AND, model EK600i,
Japan, ±0.01 g) was used for weighing the samples. Also, a solar
power meter (TES 1333R, Taiwan) measured the solar radiation
intensity on the collector surface, during the tests. A pressure
gauge (PVR 0606A81, Italy) was used to measure the inner
pressure of the oven (vacuum and microwave–vacuum dryer)
and calibrated with vacuum measuring device, PVR.
Experiments were conducted with Roman chamomile in the
microwave dryer (ME 3410W, Samsung, Thailand) were performed
at ten power levels (100, 200, . . . , 1000 W) and in the vacuum
dryer (Memmert GMBH D-91126, Germany) at four temperatures
(40, 50, 60 and 70 C) and four absolute pressure (25, 250, 500
and 750 mbar). In the microwave–vacuum dryer four levels of
microwave power (130, 260, 380 and 450 W) and four levels of
absolute air pressure (25, 250, 500 and 750 mbar) were used. Also
experiments in the microwave–convective dryer were performed
at constant air velocity (1 m/s), 3 power levels (100, 200 and
300 W) and two air temperature (40 and 50 C).
Experiments were conducted in the infrared dryer at constant
air temperature (30 C), three radiation intensity levels of 0.49,
0.31 and 0.22 W/cm2, and three levels of air velocity (0.5, 1 and
1.5 m/s); in the hot air dryer at three temperatures (40, 50,
60 C) and three air velocities (0.5, 1 and 1.5 m/s). The experiments
were also performed in combined convective–IR dryer at three
levels of radiation intensity (0.49, 0.31 and 0.22 W/cm2), three air
temperatures of 40, 50 and 60 C, and three air velocity levels
(0.5, 1 and 1.5 m/s).
In the hybrid photovoltaic/thermal solar dryer, three levels of
air temperature (40, 50, 60 C), three levels of air velocity (0.5, 1
and 1.5 m/s), with and without the heat pump were used.
A laboratory microwave–vacuum dryer (consisting of a Kawake
Airvac JP-120 h vacuum pump, and an AEG Micromat 725
microwave oven (Germany) having 1200W nominal power,
2450 MHz frequency and internal chamber dimensions of
23  32  36 cm) was used for microwave–vacuum drying. All
dryer are shown in Fig. 1. System absolute pressure was measured
using a PVR VT1 NP vacuum gauge (Italy). Finally, for rotating the
sample chamber inside within the microwave device, a BUCHI
RE120 Rotary (Switzerland) was used for uniform dispersion of
waves, condensation of vapor and prevention of increase in chamber
pressure. A digital balance (AND, model EK600i, Japan, ±0.01 g)
was used for weighing the samples.
Drying of medicinal plants is a temperature-sensitive process.
Direct use of sunlight and high temperature of drying process leads
to the destruction of plant essential oils. Thus drying treatments in
different dryer were determined using references number [2].
2.1. Energy consumption
2.1.1. Convective dryer
Energy consumption in the convective dryer is obtained from
the sum of energy consumed by the heaters (thermal energy)
and the blower (mechanical energy). Thermal energy consumed
by the heaters was calculated using Eq. (1) [3,4,40]:
EUter ¼ ðA  m  qa  Ca  DTÞ  3600 ð1Þ
where qa was calculated as [64,65]:
qa ¼
101:325
0:287T ð2Þ
Specific heat capacity of the inlet air in the convective dryer was
calculated using Eq. (3) [65]:
Ca ¼ 1009:26  0:0040403ðT  273:16Þ
þ 0:00061759ðT  273:16Þ2
 0:0000004097ðT  273:16Þ3 ð3Þ
Eq. (4) was generally used to convert the relative humidity to
humidity ratio of the inlet air [65,66].
RH ¼
101:3w
0:62189Pvs þ wPvs
ð4Þ
Pvs ¼ 0:1 exp 27:0214 
6887
T  5:31 ln
T
273:16
  
ð5Þ
The mechanical energy consumed by the blower was calculated
using Eq. (6) [40]:
EUmec ¼ DP Mair  t ð6Þ
2.1.2. IR and convective–IR dryer
These dryers exploit three energy sources to meet their energy
demands, including energy from the IR-lamps, heaters (thermal
energy), and energy consumed by the blowers (mechanical
energy). Thermal energy consumed by the heaters and the IR lamps
was calculated using Eq. (7) [3,4]:
EUter ¼ ðA  m  qa  Ca  DT þ K  tÞ  3600 ð7Þ
Also, energy consumption by the blower during drying can be
calculated using Eq. (6).
2.1.3. Microwave dryer
The energy consumption (thermal energy) of the microwave
dryer was calculated using Eq. (8) [67,68]:
EUter ¼ P  t  3600 ð8Þ
2.1.4. Microwave–vacuum dryer
Total energy consumption in the microwave–vacuum dryer is
obtained from the sum of energy consumption by the microwave
oven (thermal energy) and the vacuum pump (mechanical energy).