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In this way, simulation studies aiming to increase energy efficiency can be useful for both retrofitting and greenfield projects. The effect of light sources (from 40 to 150 W) on the angular rotation speed of the plant leaf varies at 0.049–0.213 rad/s, respectively.Įnergy efficiency is relevant for the competitiveness and growth of global industries. The influence of light sources on the rotation angle of the plant leaf was studied when illuminating the active leaf area of 25.0 ± 1.0 cm2 of the plant with a 40 W power light source, after 11 s, the rotation angle reached 31°, 60 W-97°, 100 W-131° and 150 W-134°. The angular speed of plant leaf rotation was from 0.070–0.262 rad/s. When studying the dependence of plant leaf rotation movements on the area of the plant leaf, it was found that at a 150 W light source, the angle of rotation increased as the area of the plant leaf increased. After applying a light source flux to a plant leaf and inducing a temperature change in the tissues of the plant leaf, the rotational movements of a freely hanging plant leaf about the suspension axis were studied. The operation of the biological heat engine in a plant leaf was proven by indirect experimental measurements. The values of biological heat engine in a plant leaf and the associated processes are minute. The paper presents experimental research on thermal energy conversion into mechanical kinetic energy of the flow in plant leaf stomata. There is a biological prototype of a heat engine in the leaf, where leaf stomata convert thermal energy into mechanical kinetic energy of the flow with a change in leaf temperature. The shape of leaf stomata channels is much more sophisticated compared to gas flow transformation channels in energy production facilities. Leaf stomata perform a similar function in plant leaves. In the technical field, the potential energy of gas under pressure is converted into mechanical kinetic energy by means of special complex channels. The effect of airflow rates and positioning holes in the concentration leaks is also analyzed when the unit's refrigerant leak is indoors as the air conditioner works. The air and flow mass flow can affect the distribution and directly difluoromethane to the conditioned room. The slower 0.001 kg/s with 0.1 m/s airflows for the R-32 ends after 900 seconds (15 minutes). The moderate leak rate of 0.002 kg/s for R-32 is 450 seconds (7.5 minutes). CFD analysis in the transient system condition results from numerical simulation, indicating that the leak will run out after 180 seconds with 0.005 kg/s (0.5 m/s). Turbulent modeling uses K-Epsilon standards.
#Moran shapiro engineering thermodynamics pdf 6th software#
Numerical calculations are used in CFD ANSYS FLUENT software with a model developed by Species Transport, SIMPLE algorithm, solver using pressure-based, mesh type is the dominant quadrilateral (rectangle).
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The simulation uses three variations of mass flow rate (leakage) and three airflow rate variations: low, medium, and high cold airflow velocity. It discusses the distribution of flammable refrigerant R-32 (difluoromethane) in an air-conditioned room. This study investigates and analyzes flammable refrigerant difluoromethane distributions in the room affected by the A/C unit's leakage. Graphical abstract Abstract Hydrocarbon Refrigerant R-32 called difluoromethane is one alternative solution used for Air Conditioning (A/C) unit split, but the weakness is flame property.