In the beginning, to understand the

In the beginning, to understand the detailed structures of electric
field developed inside a rectangular waveguide, the numerical
simulation of the rectangular waveguide is filled with the heated sample
with heating times of 15 minutes
Fig. 3.Temperature rise at the center of the hardened cement paste sample
during heating by microwave energy at 1200 W for 15 minutes.
4. Comparison of predictions and experimental results of
temperature rise during microwave heating
Fig. 4 shows the numerical simulation of electric field in TE
10
mode
along the center axis (x = 54.6 mm) of rectangular waveguide after
10,000 time steps at microwave power 1200 W for 15 minute. In the
figures, the vertical axis represents the intensity of the electric field Ey
,
which is normalized to the amplitude of the input electromagnetic wave,
Eyin
. Itis shown that the distribution of the electric field when a hardened
cement paste is inserted in the rectangular waveguide. Within the
sample, the electric field attenuates owing to energy absorption, and the
absorbed energy is then converted to the thermal energy, which
increases the sample temperature. In the figure, the electric field with a
small amplitude is formed within the sample waveguide. Furthermore,
focusing attention of field pattern outside the sample (left hand side), a
stronger standing wave with a larger amplitude is formed by interference
between the forward wave and waves reflected from the surface of
sample due to the different of dielectric properties of material (air and
sample) at this surface
Due to a high lossy material in the paste at the age of 24 hours after
the cement particles and water are mixed together, microwaves’
penetrating irradiation occurs at a smaller depth than the depth of
sample. Consequently, a larger part of the microwaves is absorbed by
the sample. It is observed from the figure that the resonance of standing
wave configuration inside the small sample is weak.
Fig. 5 exhibits temperature in cement paste between heating by
microwave energy. The temperature distributions correspond to the
electric field distribution in the processed sample. This is because
attenuation of the electric field when travels through the sample owing to
energy absorption and thereafter the absorbed energy are converted to
heat resulted in increase the temperature of the heated cement paste. For
example, in addition the temperature distributions are shown for time of
application of microwave for 15 minutes brings about the maximum
temperature approaches to around 223.5
0
C. It is observed that the
temperature distributions within the paste display a weak wavy behavior
due to the penetration depth of microwave drops dramatically and the
wavelength is short. Since the reflected wave from the lower surface of
the paste is almost negligible, a weak resonance is formed within the
paste.
Regarding to tendency of temperature rise within the cement paste,
the temperature rise is increased continuously when the heating time of
microwave energy increased. The feature trend of temperature increment
consists of high rate at the early-age and continuous decrease. It is
caused by the effect of penetration depth of absorbed microwave energy
and the amount of water content at the surface of the heated sample. This
means that before setting of cement paste, the cement particles settled as
gravitational force lead to high porosity or capillary pores with soaked
surface near contacting surface to microwave energy.
Fig. 4. Distribution of electric field for the hardened cement paste sample
inserted in the rectangular waveguide (t = 15 min,
x = 54.6 mm, Power = 1200 W).
Fig. 5Temperature distribution (
o
C).