Desired Temperature Research Articles

Thermal modeling of greenhouse integrated semi-transparent photovoltaic thermal (GiSPVT) for sustainable aquaculture production: an experimental validation

ABSTRACT Temperature is the primary factor affecting the growth and survival of aquatic species. At low temperatures, the metabolic rate decreases significantly. As a result, energy levels and growth rates in fish slow down which reduces the overall aquaculture production. Therefore, a novel thermal model of GiSPVT in terms of design and climatic parameters has been developed. An analytical expression for fishpond temperature and electrical energy has been derived and validated using the special case of the proposed GiSPVT for a particular day. The solar radiation passing through the non-packing area of the semi-transparent PV modules was used to heat the water to maintain the desired temperature. However, for experimental validation, the growth performance of Labeo rohita (26.15 ± 2.4 g) was cultured (90 days) with different conditions: T1bgl, T2agl (inside the greenhouse), T3bgl, T4agl (outside the greenhouse). Specific growth rate (SGR), average weight and weight gain of fishes were significantly higher (p < .05) in the T1bgl group as compared to other groups. Moreover, the SGR was observed 32.6%, 20.2%, and 14.0%, higher in the T4agl as compared to T2agl, T3bgl, and T4agl respectively. Significantly increased growth performance of T1bgl group during winter may be due to the combined effect of geothermal and solar energy integrated systems.

Heat Transfer Performance Analysis of an E-Vehicle Cooling System Using a Hybrid Peltier System

Abstract: This research investigates the heat transfer performance of an electric vehicle (EV) cooling system utilising a hybrid Peltier as integrated system with advancements in EV battery technology, the demand for efficient cooling systems has become crucial for ensuring battery safety, longevity, and overall performance. Present research focus on the application of ethylene glycol as a coolant, exploring the thermal parameters, heat transfer rates, and overall effectiveness of the hybrid cooling system. A literature review highlights the significance of heat transfer enhancement techniques, emphasising the need for energyefficient methods in the automotive industry. The research methodology involves experimental work, analytical calculations, and the preparation of coolant samples to evaluate thermo-physical parameters. The results demonstrate the temperature drop, Overall heat transfer for different flow rates, Logarithmic Mean Temperature difference, and Comparative Power Consumption of different setup. The result showed that presence of ethylene glycol in water enhances the desirable temperature drop of the heat transfer fluid. The Overall heat transfer rate is increased by 58% for EG-100 sample as compared to pure water. Further an ANN model is also developed for prediction of temperature drop, the result showed 2 layer model with 8, 8 neurons as optimum model for prediction.

Analysis of the Energy Efficiency of Poultry Houses in Türkiye

Türkiye is an important producer, consumer and exporter in the poultry farming industry across the world. The poultry farming is one of the fastest growing sectors in the field of food and agriculture and has become one of the strongest sectors over time. Especially with the development of industrial sectors, the effective usage and management of energy, which is the most important issue of almost every business, has recently become an important structure in the building sector in Türkiye. This study examined optimum insulation layer thickness, energy savings, and emissions of CO2 for the exterior walls and roofs of poultry farming facilities. The study used the degree day method, which is widely used in standard insulation calculations, in accordance with broiler production. As the equilibrium temperature, the desired temperature values of broilers for each week in the 6-week period were taken as the basis (31, 29, 25, 23.50, 22.50, 20.50°C). Life cycle cost analysis (LCCA) was applied to identify the optimal values of insulation thickness in the facilities. Accordingly, the optimum insulation layer thickness, savings amount, and payback period for the walls and roofs ranged between 0.043-0.270 m and 0.022-0.094 m, 7.53-164.65 S/m2 and 12.85-319.62 S/m2, 1.19-2.19 years and 1.18-1.99 years, respectively. It has been calculated that a 70-80% reduction in CO2 emissions could be managed by applying the optimum insulation layer thickness.

Numerical and Experimental Analysis of the Vacuum Corn Seed Degassing System

Vacuum degassing of seeds is a basic preliminary stage of the treatment process to improve the viability of seeds of various crops. In this work, the degassing process of corn seeds was experimentally and numerically analyzed by removing air or other gases from around the seeds, specifically from the seed coating, in a rough vacuum chamber. Two complementary variants were employed to understand and optimize this process to improve the quality and germination rate of the seeds. The average germination percentage on the first day was about 98%, and the germination speed of 5.0 days. Several experiments were conducted with well-established durations of 10 min and masses of 5 kg and masses of corn seeds at different temperatures to observe and record the behavior of the system, facilitating the modeling of the degasification process in the vacuum compartment. Modeling the degasification operation in the vacuum chamber allowed for determining the pressure profiles on the vacuum chamber and its lid. Numerical simulations were either conducted using a simulation program developed in the Visual Basic Applications (VBA) language for Microsoft Excel to model the degassing process in the vacuum chamber or with the assistance of specialized software (transient structural analysis and simulation program in the ANSYS Workbench environment). Statistical analysis of the correlation between experimental and estimated pressure values revealed that both the proposed mathematical model and the solution method are well-chosen, with differences expressed through the absolute error (EA) being very small, only 1.425 mbar. Structural dynamic analysis carried through the Finite Element Method (FEM) highlights that the chosen materials for manufacturing the vacuum chamber vessel (316 stainless steel—yield strength 225 MPa and tangent modulus 2091 MPa) or the chamber lid (transparent acrylic plastic—yield strength 62.35 MPa and shear modulus 1445.3 MPa) are durable and capable of withstanding the desired pressure and temperature demands in the seed treatment process. Additionally, through structural dynamic analysis, it was possible to study the deformation of system components, providing a detailed perspective on their structural distribution. Thus, the paper aims to improve the quality and survival/germination rate of corn seeds as an important step to improve corn yield through simulations and analyses (numerical and experimental) of the vacuum corn seed degassing system. The degassing process of the vacuum chamber was simulated with a simulation program developed for Microsoft Excel for Microsoft 365 MSO (Version 2401 Build 16.0.17231.20236) 64-bit in the VBA language and software (transient structural dynamic analysis in the ANSYS environment through FEM). Vacuum degassing of corn seeds involves the removal of air or other gases around the seeds or products, which is crucial in various fields such as the food, pharmaceutical, or space technology industries.

Application study of radiant floor compo site air-conditioning system for heating and cooling

Radiant floor air-conditioning systems are characterized by energy efficiency and comfort. However, at higher sensible heat loads and higher humidity conditions, problems such as condensation, poor comfort, slow thermal response, and difficulty in zoning control may occur. To mitigate these limitations, this study presents a composite air-conditioning system for radiant flooring that includes an air source heat pump., an underfloor coil, a fan coil and a dehumidifier for fresh outdoor air. The composite system was experimentally tested and analyzed for indoor thermal comfort under various operation modes in summer and winter in a specific thermal zone. On the basis of the experiments, the composite system comprises multiple energy supply points, and varying combinations between these functional endpoints can fulfill the comfort needs of the human body even in year-round working conditions. The radiant floor temperature varies from the dew point air temperature by roughly 7°C. Following the test day, summer radiant systems take approximately 30 minutes to reach the set indoor temperature and humidity level.. An hour after the indoor air has reached the desired temperature and humidity, the winter radiation system is activated.

Determining features in the application of redundancy for the thermistor cubic transformation function using computer simulation

The object of research is the process of temperature measurement with a platinum thermistor. We have conducted studies on the cubic transformation function of the thermistor when using redundancy that yielded the equation of redundant measurements of the desired temperature. Owing to this, it became possible to directly apply the resulting equation without additional measures to linearize the function of the thermistor transformation. In addition, the obtained value of the desired temperature does not depend on the values of the parameters of the cubic transformation function and their deviations from the nominal values. Experimental studies have proven that the value of the normalized temperature T0 has a greater influence on the result of redundant measurements and the value of the normalized temperature DT on the entire range of measured temperatures Tx is almost unaffected. The best accuracy results (value of relative error δ=0.02 %) were obtained at T0 values lower than –60 °C. When the error of reproduction of normalized temperatures increased from ±0.02 °C to ±0.1 °C, the best accuracy results (value of relative error δ=0.06 %) were obtained at values of normalized temperature T0 below –130 °C. Analysis of results of the absolute error DT revealed that with an error of reproduction of normalized temperatures of ±0.02 °C and at T0=–180 °C, its value does not exceed 0.02 °C, that is, it is within the error of reproduction of normalized temperatures. This allows us to state that it is recommended to use sources of standardized temperatures of high accuracy during measurement control. Thus, there are reasons to assert the prospect for redundant measurements when directly measuring temperature with a thermistor with a cubic transformation function with high accuracy

Positivity preserving density matrix minimization at finite temperatures via square root.

We present a Wave Operator Minimization (WOM) method for calculating the Fermi-Dirac density matrix for electronic structure problems at finite temperature while preserving physicality by construction using the wave operator, i.e., the square root of the density matrix. WOM models cooling a state initially at infinite temperature down to the desired finite temperature. We consider both the grand canonical (constant chemical potential) and canonical (constant number of electrons) ensembles. Additionally, we show that the number of steps required for convergence is independent of the number of atoms in the system. We hope that the discussion and results presented in this article reinvigorate interest in density matrix minimization methods.

Can the Brain's Thermostatic Mechanism Generate Sleep-Wake and NREM-REM Sleep Cycles? A Nested Doll Model of Sleep-Regulating Processes.

Evidence is gradually accumulating in support of the hypothesis that a process of thermostatic brain cooling and warming underlies sleep cycles, i.e., the alternations between non-rapid-eye-movement and rapid-eye-movement sleep throughout the sleep phase of the sleep-wake cycle. A mathematical thermostat model predicts an exponential shape of fluctuations in temperature above and below the desired temperature setpoint. If the thermostatic process underlies sleep cycles, can this model explain the mechanisms governing the sleep cyclicities in humans? The proposed nested doll model incorporates Process s generating sleep cycles into Process S generating sleep-wake cycles of the two-process model of sleep-wake regulation. Process s produces ultradian fluctuations around the setpoint, while Process S turns this setpoint up and down in accord with the durations of the preceding wake phase and the following sleep phase of the sleep-wake cycle, respectively. Predictions of the model were obtained in an in silico study and confirmed by simulations of oscillations of spectral electroencephalographic indexes of sleep regulation obtained from night sleep and multiple napping attempts. Only simple-inverse exponential and exponential-functions from the thermostatic model were used for predictions and simulations of rather complex and varying shapes of sleep cycles during an all-night sleep episode. To further test the proposed model, experiments on mammal species with monophasic sleep are required. If supported, this model can provide a valuable framework for understanding the involvement of sleep-wake regulatory processes in the mechanism of thermostatic brain cooling/warming.

Performance Evaluation of Single Stage Flash Evaporation Desalination Unit Integrated with a Parabolic Trough Solar Collector for Basrah City Climate, Iraq

Solar energy is the most suitable among all renewable energy options for competing with fossil fuels in desalination due to its ability to utilize both heat and power for the process. In this study, the Parabolic Trough Solar Collector (PTSC) for powering a Single Stage Flash (SSF) desalination unit was proposed for Basrah city climate, Iraq. The desalination system comprises two directly coupled sub-systems: the PTSC and the SSF desalination unit. The preheated feed brine water coming from condenser was used as a Heat Transfer Fluid (HTF) for PTSC, which gets heated to a desired temperature referred to as the Top Brine Temperature (TBT). The numerical simulations were performed via EBSILON professional 16.02 (2022) software. The effects of TBT, mass flowrate of feed brine water to get the desired TBT, solar collector area, and vacuum pressure inside flash chamber on the performance of the desalination system was studied. A major finding of the current study can be summarized as follows: The collector efficiency is enhanced eventually as TBT increases. The maximum values of distillate water in June are around 5.5, 4.56, 3.69, 2.75 and 1.85 kg/h for 12.408, 10.434, 8.3472, 6.26, and 4.1736 m² collector area respectively, when TBT 107 °C and vacuum pressure 40 kPa. For 1.598 m² collector area, the total distillate in the 1st of June amounted to 7.9 kg, with an average production rate of around 0.7 kg/h. The solar SSF system's productivity per solar collector unit area at 20 kPa, 15 kPa, and 10 kPa vacuum pressures was 4.7 kg/day/m², 5.3 kg/day/m², and 6.25 kg/day/m², respectively. The average Performance Ratio (PR) values are determined to be 0.694, 0.577, and 0.491 for 10 kPa, 15 kPa, and 20 kPa, respectively. These results are very acceptable when compared with an existing literature.

Effect of Calcination Atmosphere on the Acid Leaching Recovery of Rare Earth Elements in Coal-Byproducts

ABSTRACT Thermal treatment of coal byproducts has been shown to improve leaching characteristics of rare earth elements (REEs) in bituminous coal sources due to its influence on the associated minerals. This study investigated the impact of the calcination atmosphere on REE leaching behavior in different density fractions of Baker and Fire Clay seam coarse refuse sources using a thermogravimetric analyzer to create an oxidizing or reducing atmosphere at a desired temperature for 2 h. The effect on leaching characteristics was evaluated using 1.2 M sulfuric acid at 75°C for 5 h at 1% w/v solid concentration. Rare earth element (REE) recovery for the 2.2 specific gravity (SG) sink fraction improved by approximately 15 absolute percentage points at 1000°C relative to the 600°C calcined sample in an inert atmosphere and equilibrated within 10 min from the start of the test. Contrarily, thermal treatment at 1000°C under oxidizing atmosphere significantly reduced the REE recovery due to sintering of the clays, which limited access to the RE minerals for leaching. In general, thermal treatment of heavier fractions in both atmospheres significantly improved the light REE (LREE) recovery while the increase in heavy REE (HREE) recovery was relatively less. As common clay minerals in the coal sources, kaolinite and illite samples were tested under the same conditions and using a digital scanning calorimeter. The findings confirmed that the improvement observed in REE leaching through thermal treatment at 600°C was due to decarbonization for the lighter density fractions and dehydroxylation of clays.

Reservoir Modeling Predicts Effect of Cold-Water Injection on Geothermal PTA

_ This article, written by JPT Technology Editor Chris Carpenter, contains highlights of paper SPE 212615, “Reservoir Modeling To Predict the Effect of Cold-Water Injection in Geothermal Pressure Transient Analysis,” by Purnayan Mitra, SPE, University of Petroleum and Energy Studies, and Nihal Mounir Darraj, SPE, Imperial College London. The paper has not been peer reviewed. _ Geothermal reservoirs are one of the cleanest renewable sources of energy poised to address the global energy challenge. A major issue in the exploitation of geothermal reservoirs, however, is to find best-fit analytical methods for pressure transient analysis (PTA). This is because the assumptions made to predict PTA in hydrocarbon reservoirs are not satisfied by geothermal reservoirs. In the complete paper, the effect of cold-water injection on PTA of geothermal reservoirs is studied by varying the temperature of the injected cold water from room temperature to reservoir temperature. Introduction A major method of extracting heat energy from the Earth is the injection of water. Cold water is injected deep into geothermal reservoirs at a depth of 2–4.5 km. In this environment, cold water is essentially heated by the hot granite rock. Hydraulic fracturing is used to produce a large crack within the geothermal reservoir. Two boreholes intercept the crack. These boreholes are used for passing the cold fluid stream and the hot stream, respectively. In many scenarios, the gradient within the geothermal reservoir is so strong that a dry stream is produced. The greater the temperature difference between the injected fluid and the interior of the Earth, the greater the heat transfer. Therefore, it is always desirable to inject cold water inside geothermal reservoirs to maximize heat transfer and extract more heat. The steam coming out from the reservoir after heat transfer is used to run turbines to generate electricity. The steam also is used for a variety of other purposes. However, instances exist in which the temperature gradient is not as high, and it is difficult to produce a sufficiently heated dry stream. In such cases, an organic Rankine cycle is used for heating the steam on the surface. In such a case, the hot water or steam mixture is passed through a heat exchanger for heating the fluid to a desired temperature. When cold water is injected into the reservoir, a need exists to analyze the pressure transience throughout the reservoir. Different formations affect PTA in different ways. PTA across the geothermal reservoir currently is performed using the empirical correlations available for hydrocarbon reservoirs. Although the method is not 100% effective because of differences in reservoir parameters, PTA provides an idea about reservoir conditions. To reduce imperfection, it is often preferred to use reservoir parameters rather than injectate properties. In the complete paper, the authors study the effect of injected water on geothermal reservoirs while varying temperature from 14 to 312°C.

The suitability of eggshell for improving the performance of water-based drilling mud in a high-temperature well

The selection of water-based mud for drilling a high-temperature and high-pressure (HTHP) well is the choice of many drilling mud engineers. This choice of mud is more attractive because it is cost-effective, eco-friendly, and easy to prepare but its reliability for drilling shale formations and geothermal resources optimally depends on the design and inclusion of the necessary additives to the drilling fluid. An HPHT-resistant deficiency of the drilling mud has been an age-long jeopardy of the development of a harsh elevated temperature reservoirs such as geothermal formation. Consequently, it has become imperative to innovate a thermal resistance material that is capable of serving as an additive and ensuring thermal stability for drilling mud through the drilling operation at the desired temperature ranges. Studies reported in the literature have revealed that, eggshell nanoparticles (ESN) withstand a lot of heat and at the same time retain their properties under extreme conditions. This study examines the viability of employing eggshells to enhance the efficiency of water-based drilling fluid in elevated-temperature wells. ESN was added at various weighted amounts to the petroleum industry's approved mud composition for an elevated temperature well to design eggshell-boosted water-based mud samples. In accordance with the American Petroleum Institute (API) mud test technique, evaluation of the prepared mud samples was done by performing filtration, and rheological tests under HPHT conditions. The outcomes of the study show how ESN helps water-based drilling mud to withstand drilling operations in elevated temperature formations by delaying thermal degradation up to 270 °C. Specifically, the Fluid sample with 5 lb./bbl of ESN exhibited an 8 % reduction in HPHT filtrate vol when compared with an equal volume of commercial calcium carbonate (CCC), while a larger quantity of ESN (6 lb./bbl) yielded a 17 % reduction. Additionally, the inclusion of 5 lb./bbl of ESN was observed to be more effective than an equal quantity of CCC at 250 °C as it yielded a 28 % increase in 10 min gel strength. However, the rheological properties of 5 lb./bbl of ESN were not as effective as CCC at low-pressure low-temperature (LPLT) conditions which may be due to the presence of organic matter as a constituent of ESN at any temperatures below 200 °C.

Assessment of temperature and time on the survivability of porcine reproductive and respiratory syndrome virus (PRRSV) and porcine epidemic diarrhea virus (PEDV) on experimentally contaminated surfaces.

Fomites might be responsible for virus introduction in swine farms, highlighting the importance of implementing practices to minimize the probability of virus introduction. The study's objective was to assess the efficacy of different combinations of temperatures and holding-times on detecting live PRRSV and PEDV on surfaces commonly found in supply entry rooms in swine farms. Two PRRSV isolates (MN 184 and 1-4-4 L1C variant) and one PEDV isolate (NC 49469/2013) were inoculated on cardboard and aluminum. An experimental study tested combinations of four temperatures (20°C, 30°C, 40°C, and 50°C) and six holding-times (15 minutes, 60 minutes, 6 hours, 12 hours, 24 hours, and 36 hours) for the presence of the viruses on each surface type. After virus titration, virus presence was assessed by assessing the cytopathic effects and immunofluorescence staining. The titers were expressed as log10 TCID50/ml, and regression models; half-lives equations were calculated to assess differences between treatments and time to not detect the live virus. The results suggest that the minimum time that surfaces should be held to not detect the virus at 30°C was 24 hours, 40°C required 12 hours, and 50°C required 6 hours; aluminum surfaces took longer to reach the desired temperature compared to cardboard. The results suggest that PRRSV 1-4-4 L1C variant had higher half-lives at higher temperatures than PRRSV MN 184. In conclusion, time and temperature combinations effectively decrease the concentration of PRRSV and PEDV on different surfaces found in supply entry rooms in swine farms.

Simple fabrication of superhydrophobic carbon felt with outstanding Joule heating and photothermal effects for all-weather recovery of viscous crude oil

The development of materials with simple preparation methods and exhibiting excellent photothermal and Joule heating effects, especially at low safety voltage inputs for reaching desired temperatures, is of great significance for realizing all-weather rapid recovery of high viscosity crude oil, but some challenges currently exist. Herein, carbon felt (CF), known for its excellent electrical properties, was used as a substrate and coated with molybdenum disulfide (MoS2) with excellent electrical properties and light absorption ability through a one-step hydrothermal method. Subsequently, the surface energy of the felt was reduced by further surface modification using polydimethylsiloxane (PDMS) to prepare superhydrophobic and superoleophilic CF (PDMS@MoS2@CF). It exhibited significant photothermal effects and exceptional Joule heating capabilities at safe low voltages, benefiting from the excellent electrical properties of CF and the exceptional photothermal and electrical properties of MoS2. Under 1 sun irradiation or a 2 V voltage, the surface temperature of PDMS@MoS2@CF could reach up to ∼78.5 °C or 93.0 °C, respectively. In addition to achieving low viscosity oil recovery, this material rapidly generated heat due to photothermal and Joule heating effects, significantly reducing the viscosity of crude oil and effectively achieving crude oil recovery. Further, the continuous recovery of crude oil from water surface could be realized using a peristaltic pump. Furthermore, the two effects complemented each other, enabling the all-weather rapid recovery of high viscosity crude oil while maximizing resource conservation and thus showing practicability. This material shows application prospects in addressing oil spills, particularly in scenarios involving high viscosity crude oil.

Neural correlates of thermal stimulation during active touch.

Thermal feedback technologies have been explored in human-computer interaction to provide secondary information and enhance the overall user experience. Unlike fast-response haptic modalities such as vibration and force feedback, the human brain's processes associated with thermal feedback are not fully understood. In this study, we utilize electroencephalography (EEG) brain imaging to systematically examine the neural correlates associated with a wide range of thermal stimuli, including 9, 15, 32, and 42°C, during active touch at the fingertip. A custom experimental setup is developed to provide thermal stimulation at the desirable temperature levels. A total of 30 participants are recruited to experience the four levels of thermal stimulation by actively touching a thermal stimulation unit with the index finger while recording brain activities via EEG. Time-frequency analysis and power spectral density (PSD) of the EEG data are utilized to analyze the delta, theta, alpha, beta, and gamma frequency bands. The results show that the delta, theta, and alpha PSDs of 9 and 15°C stimuli are significantly higher than the PSDs of 32 and 42°C in the right frontal area during the early stage of the stimulation, from 282 ms up to 1,108 ms (One-way ANOVA test, Holm-Bonferroni correction, p < 0.05). No significant differences in PSDs are found between 9 and 15°C thermal stimuli or between 32 and 42°C thermal stimuli. The findings of this study inform the development of thermal feedback system in human-computer interaction.

Magneto-photothermal synergy applied to gold-coated magnetic nanoparticles

In this work, we describe the synthesis of magnetic nanoparticles with a suitable size for easy cellular internalization, avoiding their rapid renal excretion (less than 5 nm) and accumulation in the liver (more than 100 nm). The nanoparticles are functionalized with a biocompatible polymer (low molecular weight, branched polyethylenimine, PEI), and this treatment allows their functionalization with a shell of gold particles in order to improve their ability to absorb electromagnetic radiation in the visible and near infrared wavelength regions. As a result, the magnetic nanostructures are potential agents of local heating (hyperthermia) by exposing them to alternating magnetic fields (magnetic hyperthermia) or to light of the suitable wavelength (photothermia). Magnetic hyperthermia experiments demonstrate that both types of particles can reach the desired temperature range for cell apoptosis, with the difference of a shorter time needed when gold is absent. The released thermal energy is measured by the SAR (specific absorption rate, in W/g), and the values found are promising, up to 600 W/g in the case of uncoated particles. Regarding the photothermia response under the IR radiation, it is comparable for gold-coated and uncoated magnetic particles, but it is enhanced by a factor of almost 10 when the incident light is visible (blue-green) and the particles are provided with their gold shell. Improvements related to the selection of gold particles with resonant absorbance in the infrared are under investigation.

EXPERIMENTAL AND COMPUTATIONAL STUDY ON THERMAL PERFORMANCE OF WOOD-PLASTIC COMPOSITES IN BUILDING ENVELOPE

Wood-plastic composites (WPCs) are attractive material for enhancing thermal performance of buildings by acting as an insulation surface. A fast and reliable experimental method was devised using a simple quasi-steady heating film (QSHF) method to measure the thermal conductivity of locally manufactured WPCs in Kuwait. QSHF used two blocks of standard materials compared with the classic methods, although it does not require a fixed constant heating source nor a cooling source. QSHF had a 10 cm &amp;times; 10 cm &amp;times; 0.5 mm silicon heating film controlled by a temperature controller and several transparent acrylic square blocks of the same size with 10 mm thickness as the standard materials. The top surface of the WPC samples was the cold side of the system, which is open to indoor temperatures of 22-23&amp;deg;C. The bottom layer can be maintained at any desirable temperature ranges from 25&amp;deg; to 55&amp;deg;C using the heating film to simulate the real outdoor environment. The thermal conductivities of locally manufactured WPCs type, namely FB16, FB18W, CD, and TD, were 0.0912, 0.1174, 0.3453, and 0.3078 W/m.K, respectively, obtained within 1 to 3 hours, which all fall below the standard value of 0.414 W/(m&lt;sup&gt;2&lt;/sup&gt;.K) for composite walls and 0.1-0.2 W/m.K for wood. Multiphysics CFD simulation for DP45 sample and TRNSYS simulation for FB18W WPC in the building envelop were conducted which showed strong 2D effects and 3.3&amp;#37: reduction in maximum cooling load in Kuwait, respectively.

Development of Kennel Cage Cooling System Using Thermoelectric Cooler

Animal welfare is one of society's top priorities nowadays; hence, pets have been considered part of every family's household. Pet safety and its condition are frequently monitored, and many innovative inventions are being created. A Peltier module, commonly known as a thermoelectric cooler, is widely used in cooling modules. A thermoelectric cooler is used to produce cold air to give comfort to their cages. Installing a cooling system with a control system creates cool air inside the cell with a fan. The temperature inside the cage can be manually controlled depending on the desired temperature, between 20 and 25 degrees Celsius. Using t-test analysis, the results show that the thermal reading of the developed device is accurate and the system is fully operational. However, outdoors may affect the task; the Peltier may produce less coldness and vary according to the kennel cage design and size.

A novel ultrahigh-sensitive optical thermometer based on inverse thermal responses of Nd3+ and Yb3+ emissions in BaGd2(MoO4)4 phosphor

Nowadays, lots of efforts have been vested on the exploitation of novel luminescent thermometric materials to achieve remote temperature readout with ultra-high sensitivity and sub-degree resolution. Herein, the BaGd2(MoO4)4: Yb3+, Nd3+ phosphors were successfully prepared via a solid-state reaction method, and their concentration/temperature-dependent luminescence behaviors were investigated systematically. Upon 980 nm excitation, the photoluminescence (PL) spectra consisted of three emission bands centered at 754 nm, 805 nm and 872 nm from Nd3+, together with an emission band peaked at 1008 nm from Yb3+. As the temperature elevated, the Yb3+: 2F5/2 → 2F7/2 emission weakened sharply, whereas the promoted phonon-assisted energy transfer process from Yb3+ to Nd3+ and excited-state absorption process of Nd3+ led to an intense thermal enhancement of the Nd3+: 4Fj → 4I9/2 (j = 7/2, 5/2, 3/2) transitions. Moreover, the thermally enhancing factor was found to depend on the Nd3+ concentration. By utilizing the luminescence intensity ratio (LIR) technique, the temperature sensing behaviors based on thermally coupled levels (Nd3+: 4Fj, j = 7/2, 5/2, 3/2) and non-thermally coupled levels (Nd3+: 4Fj and Yb3+: 2F5/2) were studied at the different doping concentrations. When the temperature sensing was based on LIR between Nd3+: 4F3/2 → 2I9/2 and Yb3+: 2F5/2 → 2F7/2 transitions, the BaGd2(MoO4)4: 3 mol%Nd3+, 15 mol%Yb3+ sample displayed excellent thermal sensitivity (2.28–8.42 %K−1) and temperature resolution (0.1–0.22 K) at temperatures ranging from 298 K to 573 K, which were superior to those of many other reported luminescence materials. The present work might give a new input for developing near-infrared (NIR) luminescence materials with desirable temperature sensing performances.

Numerical investigation of thermal management of lithium ion battery pack with nano-enhanced phase change material and heat pipe

LIBs are primary power sources for EVs and their performance and life depend on operating temperature and temperature uniformity. Phase change material (PCM) as well as heat pipes and hybrid cooling systems are adopted for thermal management of LIBs at lower and higher C rates, respectively. In this study, a numerical model of a novel LIB assisted with nano-enhanced PCM (NEPCM) and heat pipes is developed, and simulated at 1C, 3C and 5C conditions, air velocities of 0.5 m/s, 1 m/s and 1.5 m/s, different cell orientations, nanoparticle (NP) concentrations, and ambient conditions. The results revealed that the horizontal cell configuration exhibits superior performance of 1.52 K lower battery pack temperature compared to vertical configuration due to heat transfer and fluid flow. The average battery pack temperature remains in the desirable temperature range for a substantial duration (65 %) of discharge process with PCM assisted battery pack at 3C condition, while it is only 20 % for naturally cooled battery pack. NEPCMs with 14.78 % and 9.11 % concentrations of NP exhibit good thermal performance in vertical and horizontal arrangements, respectively. It is also observed that the PCM assisted battery system results in thermal stratification in the battery pack which can be weakened by the inclusion of NP in PCM.