Министерство высшего и среднего специального образования республики узбекистан ўзбекистон республикаси

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Samples and measurement results
For the tests, with the light-optical moisture sensors following screed and mortar samples were
used:
1) calcium sulfate floor screed CAF-C25-F5 Maxit with 1.92 g / cm³ (dry)
2) cement mortar CEM I 42.5 R with w / c = 0.4 and 0.7; Natural sand with s / z = 3/1
The dry sand according to DIN standard EN196-1 has a grain size of about 0.15 to 1.5 mm (d50
= 0.7 mm). About a specially adapted for these investigations multimeter DT830 the readings were
read regularly manually. The power supply for the light emitting diode has been realized in the
multimeter as an integrated component. All sensors tensions were measured sequentially. For the
recording of measured values are about 5 sec. needed. The lab was air conditioned with a constant
temperature of 21
o
C and a relative moisture of about 55%.In Figure 2 the complete measurement
setup can be seen for a screed-examination. Here it was important to measure the moisture content at
different levels of a calcium sulfate screed. Two light-optical sensors have been installed. An L1
sensor was in the upper part (h = 4.5 cm), and a second L2 sensor in the lower region of the screed (h
= 0.5 cm) was applied. The total height of the screed was h = 5.0
cm. During the measurement by means of light-optical moisture
sensors, the ambient temperature and moisture were measured at
the same time. The moisture sensors are shown covered with
calcium sulfate screed. Understandably, only the upper part of
Fixbasket for the sensors and the electrical lines are seen. For the
studies were conducted in two different cement mortar (w / c =
0.5; 0.7), the same preparations performed with the metal basket,
as the CaSO4 screed, but with only one sensor each mortar
sample. The total height of the mortar was 8.0 cm. Each sensor
was located at a height of h = 4.0 cm. The mortar and screed
samples were checked gravimetrically during setting and
hardening. For all samples, the external water delivery was made
only on one side on the surface of the material layers.
In Figure 3, the photo-diode voltage can be seen as a function of time for the setting and
hardening of CaSO
4
screed. The diagrams show a different curve during hardening. Using the
calibration curve then the moisture penetration of the screed was determined. Both measurement
curves fall after a sensor-related balance-setting time (a few hours) due to the water consumption by
the setting reaction (s. Gl.2) from.
CaSO
4
+ 2H
2
O → CaSO
4
∙ 2H
2
O
(2)
The investigations show that the light-optical moisture sensors the moisture content can
significantly differentiate into different depths. This is a noticeable advantage of the LOF sensors over
other measuring methods, such as the
electric or ultrasonic measurements. The
sensors can be applied in the screed
targeted at the measuring location. Thus,
it was demonstrated that in different
depths of the screed, as expected, the
moisture content differences in the
timing takes (water transport in the
screed). One can clearly see how the
surface of the sample, the water
evaporates faster than the water content
in deeper areasdecreases. Both occupy
independent measuring methods that
CaSO
4
- screed sample "by dried" after
about 15 days.
Fig. 3: Photo diode voltage as a function of time in CaSO
4
screed
In studies in the cement mortar, the influence of w / c was - value placed on the timing of the
local moisture content at the center of considerations. In Fig. 4 the change in the normalized
photodiode voltage during the setting and hardening of the fresh mortar samples with different w / c

Fig. 2: fix the sensors in metal
basket at different depths

189
ratios is shown. The sensors are located approximately at an average height of 8 cm high cement
mortar layer. The studies show that
in the setting and hardening phase
LOF sensors after about 10 hours at
w / c = 0.4 and approximately 40 h
at w / c = 0.7, a drastic drop in the
measurement signal and for the local
moisture content (free mobile water)
identification.
Fig. 4: Temporal change of the
normalized
photodiode
voltage
during the setting and hardening of
cement mortar samples
This use of water is related to the setting reaction (CSH-phase binding). Fig. 5 now provides the
relative voltage waveforms in the cement mortar samples after 28 days again saturated with water
during the drying of the solidified microstructure. The decrease in the local moisture content (in the
middle sample height) must be held
immediately after the start of
measurement. After less than 12
hours, about half of the mobile water
is already escaped into the rigid,
solidified pores rock in follow fast
capillary transport of the samples.
Due to the larger pore volume and
thus higher water content in the
structure, the relative decrease of the
local water content in theexponential
curve is slightly slower than in the
sample with w / c = 0.4 in the
sample with the w / c ratio of 0.70.
Fig. 5: Normalized photodiode voltage of cement mortar sample after renewed water saturation

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