Analysis of Thermodynamic Events Taking Place during Vacuum Drying of Corn
Abstract
:1. Introduction
2. Material and Methods
Vacuum Drying of Corn under Laboratory Conditions
- Preparation of a corn sample;
- Heating of the corn sample in a vacuum chamber;
- Evaporation of water from corn kernels in the vacuum chamber;
- Drying of the corn sample on a sieve.
- tc—temperature of the corn sample;
- tg—temperature of the selected corn grain;
- th—temperature of the electrically heated coils;
- t—temperature of moist air in the vacuum chamber;
- p—pressure of moist air in the vacuum chamber.
- mc1—at the beginning of the measurement;
- mc2—after removing the sample from the vacuum chamber;
- mc3—after drying the sample on the sieve.
- Pressure p1 in the vacuum chamber during the heating of a corn sample;
- Pressure p2 in the vacuum chamber during the evaporation of water from the corn sample;
- Changes in the temperature tc2 of the corn sample due to the regulation of the power input by the coils during the evaporation of water from the corn sample;
- Time τ2 of heating during the evaporation of water from the corn sample;
- Number of cycles of evaporation of water from the corn sample to reduce moisture.
- wc1 = 10.487% for measurements no. 1 to no. 9 carried out in February 2022;
- wc1 = 8.858% for measurements no. 10 to no. 14 carried out in April 2022.
- The difference in the corn moisture content wc1 at the beginning of the measurement and wc3 after drying the sample on the sieve:
- The relative moisture difference of the corn sample as defined by the proportion of the difference and the moisture content of the corn sample wc1 at the beginning of the measurement:
3. Results
3.1. Effect of Vacuum Chamber Pressure on Reduction in Moisture during Heating of Corn Sample
3.2. Effect of Vacuum Chamber Pressure on Reduction in Moisture during Evaporation of Water from Corn Sample
3.3. Effect of Heating Time on Reduction in Moisture during Evaporation of Water from Corn Sample
- During measurement no. 13 after a heating time τ2 of 0:42 h of vacuum drying, the moisture content decreased to a value of wc3 = 8.492%, which corresponded to a moisture difference of 0.366%, and relative moisture difference = 4.132%;
- During measurement no. 14 after a heating time τ2 of 0:58 h of vacuum drying, the moisture content decreased to a value of wc3 = 8.485%, which corresponded to a moisture difference of 0.373%, and relative moisture difference = 4.212%.
3.4. Effect of Number of Cycles of Water Evaporation on Reduction in Moisture
4. Discussion
4.1. Effect of Vacuum Chamber Pressure on Reduction in Moisture during Heating of Corn Sample
4.2. Effect of Vacuum Chamber Pressure on Reduction in Moisture during Evaporation of Water from Corn Sample
4.3. Effect of Controlling the Power Input of Coils on Reduction in Moisture during the Evaporation of Water from Corn Kernels
4.4. Effect of Heating Time on Reduction in Moisture during Evaporation of Water from Corn Sample
4.5. Effect of Number of Cycles of Water Evaporation on Reduction in Corn Moisture
5. Conclusions
- Heat the corn sample at a higher pressure value in the vacuum chamber using better heat transfer for more intense heat convection;
- Carry out the drying phase in the pressure range of 9–10 kPa, and, when drying at a lower pressure, a higher moisture content of corn is achieved;
- Continuously heat the corn sample during the entire drying phase so that the temperature of the corn sample changes minimally;
- Choose a heating time in the range of 40–45 min and a heating intensity corresponding to the rate of heat transfer in the given environment;
- Due to the dynamics of the drying process, it is advantageous to carry out the drying process with a low intensity over several cycles.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
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Measurement No. | p1 | tc1max tc2max | pavg | tc avg | tc2min | (tc2–ts)min | τ2 | mc1 | mc2 | mc3 |
---|---|---|---|---|---|---|---|---|---|---|
(kPa) | (°C) | (kPa) | (°C) | (°C) | (°C) | (h:min) | (g) | (g) | (g) | |
1 | 100.76 | 55.2 | 5.82 | 45.6 | 38.8 | 1.9 | 1:06 | 1300.00 | 1293.78 | 1292.70 |
2 | 102.77 | 50.9 | 5.91 | 43.9 | 38.9 | 2.1 | 0:45 | 1300.00 | 1295.00 | 1293.93 |
3 | 102.45 | 52.7 | 6.62 | 44.9 | 39.1 | 2.3 | 0:54 | 1300.00 | 1294.80 | 1293.65 |
4 | 101.95 | 60.3 | 9.19 | 52.4 | 46.9 | 1.7 | 0:37 | 1300.00 | 1292.82 | 1291.60 |
5 | 101.66 | 60.6 | 9.81 | 53.8 | 48.4 | 0.6 | 0:34 | 1300.00 | 1292.00 | 1290.45 |
6 | 101.28 | 59.8 | 9.51 | 53.8 | 48.8 | 3.0 | 0:33 | 1300.00 | 1291.49 | 1290.20 |
7 | 102.06 | 61.6 | 9.35 | 61.6 | 62.7 | 17.6 | 0:57 | 1300.00 | 1294.20 | 1293.00 |
8 | 101.95 | 62.6 | 9.26 | 61.5 | 60.2 | 15.6 | 0:56 | 1300.00 | 1290.36 | 1289.29 |
9 over 2 cycles | 101.93 | 60.5 | 8.66 | 54.1 | 48.6 | 4.6 | 1:26 | 1300.00 | 1282.93 | 1281.80 |
9 in 1st cycle | 101.93 | 60.5 | 9.02 | 54.0 | 48.7 | 3.6 | 0:40 | 1300.00 | 1289.80 | 1289.80 |
9 in 2nd cycle | 101.69 | 60.4 | 8.31 | 54.1 | 48.6 | 5.5 | 0:46 | 1289.80 | 1282.86 | 1281.80 |
10 | 100.74 | 60.0 | 9.74 | 54.2 | 48.7 | 2.6 | 0:48 | 1300.00 | 1295.00 | 1294.10 |
11 | 9.90 | 44.7/61.4 | 9.70 | 55.2 | 48.5 | 2.2 | 1:29 | 1300.00 | 1297.11 | 1295.90 |
12 | 102.08 | 60.0 | 8.41 | 59.5 | 59.5 | 16.9 | 0:28 | 1300.00 | 1296.86 | 1295.80 |
13 | 101.95 | 60.5 | 9.42 | 60.7 | 59.6 | 14.2 | 0:42 | 1300.00 | 1295.80 | 1294.80 |
14 | 100.00 | 60.1 | 8.73 | 61.0 | 62.8 | 18.2 | 0:58 | 1300.00 | 1295.90 | 1294.70 |
Conditions for Determining the Metrological Accuracy of the Hygrometer | |
---|---|
Pre-drying temperature (°C) | 60 ± 1 |
Pre-drying time (min) | 360 |
Sample weight (g) | 10 |
Kernel | whole |
Drying temperature (°C) | 130 ± 1 |
Drying time (min) | 240 |
Sample weight (g) | 5 |
Kernel | ground |
Corn Water Content Measurement Period | February 2022 | April 2022 |
---|---|---|
Weight of corn sample, mc (g) | 10,000 | 9996 |
Sample weight after pre-drying (g) | 9800 | 9866 |
Sample weight before drying (g) | 5000 | 5002 |
Sample weight after drying (g) | 4567 | 4619 |
Weight of dry matter in the sample, md (g) | 8951 | 9111 |
Water content of the corn sample, wc (%) | 10,487 | 8858 |
Measurement No. | md | wc1 | wc2 | wc3 | Δwc | Δwc rel |
---|---|---|---|---|---|---|
(g) | (%) | (%) | (%) | (%) | (%) | |
1 | 1163.67 | 10.49 | 10.06 | 9.98 | 0.51 | 4.82 |
2 | 1163.67 | 10.49 | 10.14 | 10.07 | 0.42 | 4.00 |
3 | 1163.67 | 10.49 | 10.13 | 10.05 | 0.44 | 4.19 |
4 | 1163.67 | 10.49 | 9.99 | 9.90 | 0.58 | 5.55 |
5 | 1163.67 | 10.49 | 9.93 | 9.82 | 0.66 | 6.32 |
6 | 1163.67 | 10.49 | 9.90 | 9.81 | 0.68 | 6.48 |
7 | 1163.67 | 10.49 | 10.09 | 10.00 | 0.48 | 4.62 |
8 | 1163.67 | 10.49 | 9.82 | 9.74 | 0.74 | 7.09 |
9 over 2 cycles | 1163.67 | 10.49 | 9.30 | 9.22 | 1.27 | 12.12 |
9 in 1st cycle | 1163.67 | 10.49 | 9.78 | 9.78 | 0.71 | 6.75 |
9 in 2nd cycle | 1163.67 | 9.78 | 9.29 | 9.22 | 0.56 | 5.76 |
10 | 1184.85 | 8.86 | 8.51 | 8.44 | 0.42 | 4.69 |
11 | 1184.85 | 8.86 | 8.65 | 8.57 | 0.29 | 3.26 |
12 | 1184.85 | 8.86 | 8.64 | 8.56 | 0.295 | 3.335 |
13 | 1184.85 | 8.86 | 8.56 | 8.49 | 0.366 | 4.132 |
14 | 1184.85 | 8.86 | 8.57 | 8.48 | 0.373 | 4.212 |
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Šooš, Ľ.; Urban, F.; Čačková, I.; Kolláth, Ľ.; Mlynár, P.; Čačko, V.; Bábics, J. Analysis of Thermodynamic Events Taking Place during Vacuum Drying of Corn. Sustainability 2024, 16, 879. https://doi.org/10.3390/su16020879
Šooš Ľ, Urban F, Čačková I, Kolláth Ľ, Mlynár P, Čačko V, Bábics J. Analysis of Thermodynamic Events Taking Place during Vacuum Drying of Corn. Sustainability. 2024; 16(2):879. https://doi.org/10.3390/su16020879
Chicago/Turabian StyleŠooš, Ľubomír, František Urban, Iveta Čačková, Ľudovít Kolláth, Peter Mlynár, Viliam Čačko, and Jozef Bábics. 2024. "Analysis of Thermodynamic Events Taking Place during Vacuum Drying of Corn" Sustainability 16, no. 2: 879. https://doi.org/10.3390/su16020879
APA StyleŠooš, Ľ., Urban, F., Čačková, I., Kolláth, Ľ., Mlynár, P., Čačko, V., & Bábics, J. (2024). Analysis of Thermodynamic Events Taking Place during Vacuum Drying of Corn. Sustainability, 16(2), 879. https://doi.org/10.3390/su16020879