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1. A Variable Rate Drip Irrigation Prototype for Precision Irrigation

   https://doi.org/10.3390/agronomy11122493  

   AL-agele, Hadi A.; Jashami, Hisham; Nackley, Lloyd; Higgins, Chad (December 2021, Agronomy)

   A new Variable Rate Drip Irrigation (VRDI) emitter that monitors individual water drops was designed, built, and tested. This new emitter controllers water application directly by monitoring the volume applied in contrast to uniform drip irrigation systems that control water application indirectly by pressure compensation and operational times. Prior approaches assumed irrigation volumes based on flow rates and time and typically did not verify the applied amount of water applied at each water outlet. The new VRDI emitter self-monitors the total volume of water applied and halts the flow once the desired total water application has been achieved. This study performed a test for a new VRDI emitter design with two inner diameters of 0.11 cm and 0.12 cm and two outer diameters 0.3 cm and 0.35 cm compared to a commercial drip emitter. Laboratory tests verify that the integrated volume measurements of the VRDI system are independent of pressure. Conversely, the flow rates of the commercial pressure-compensated drip lines were not independent of pressure. These results demonstrate that this form of VRDI is technically feasible and is shown to be energy efficient, requiring lower system operating pressures than pressure-compensated lines. The VRDI system can reduce water consumption and related water costs. 

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2. Design and Thermal Analysis of a 3D Printed Impingement Pin Fin Cold Plate for Heterogeneous Integration Application

   https://doi.org/10.1109/TCPMT.2022.3185401  

   Hoang, Cong Hiep; Azizi, Arad; Fallahtafti, Najmeh; Rangarajan, Srikanth; Radmard, Vahideh; Arvin, Charles; Sikka, Kamal; Schiffres, Scott; Sammakia, Bahgat (June 2022, IEEE Transactions on Components, Packaging and Manufacturing Technology)

   Miniaturization and high heat flux of power electronic devices have posed a colossal challenge for adequate thermal management. Conventional air-cooling solutions are inadequate for high-performance electronics. Liquid cooling is an alternative solution thanks to the higher specific heat and latent heat associated with the coolants. Liquid-cooled cold plates are typically manufactured by different approaches such as: skived, forged, extrusion, electrical discharge machining. When researchers are facing challenges at creating complex geometries in small spaces, 3D-printing can be a solution. In this paper, a 3D-printed cold plate was designed and characterized with water coolant. The printed metal fin structures were strong enough to undergo pressure from the fluid flow even at high flow rates and small fin structures. A copper block with top surface area of 1 inch by 1 inch was used to mimic a computer chip. Experimental data has good match with a simulation model which was built using commercial software 6SigmaET. Effects of geometry parameters and operating parameters were investigated. Fin diameter was varied from 0.3 mm to 0.5 mm and fin height was maintained at 2 mm. A special manifold was designed to maximize the surface contact area between coolant and metal surface and therefore minimize thermal resistance. The flow rate was varied from 0.75 L/min to 2 L/min and coolant inlet temperature was varied from 25 to 48 oC. It was observed that for the coolant inlet temperature 25 oC and aluminum cold plate, the junction temperature was kept below 63.2 oC at input power 350 W and pressure drop did not exceed 23 Kpa. Effects of metal materials used in 3D-printing on the thermal performance of the cold plate were also studied in detail. 

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3. Two-phase Impingement Cooling using a Trapezoidal Groove Microchannel Heat Sink and Dielectric Coolant HFE 7000

   https://doi.org/10.1109/ITherm51669.2021.9503283  

   Hoang, Cong Hiep; Rangarajan, Srikanth; Radmard, Vahideh; Fallahtafti, Najmeh; Tradat, Mohammad; Arvin, Charles; Schiffres, Scott; Sammakia, Bahgat (June 2021, 2021 20th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (iTherm))

   This paper focuses on two-phase flow boiling of dielectric coolant HFE 7000 inside a copper multi-microchannel heat sink for high heat flux chip applications. The heat sink is composed of parallel microchannels, 200 μm wide, 2500 μm high, and 20 mm long, with 200-μm-thick fins separating the channels. The copper heat sink consists of almost 100 channels connected by a longitude groove with a nearly trapezoidal cross section. Coolant impinges down to the base at the groove and then goes along the microchannels. A copper block heater arrangement was used to mimic a computer chip with a footprint of 1”x1” (6.45 cm2). The base heat flux was varied from 7.75 W/cm2 to 96.1 W/cm2 and the mass flux from 547.6 to 958.4 kg/m2s, at a nominal saturation temperature of 54 °C. Heat transfer coefficients as high as 57.5 kW/m2K were reached, keeping the base temperature under 66 °C with a maximum of 21.9 kPa of pressure drop, for inlet subcooling of 5 degree and a coolant flow rate of 958.4 kg/m2. Effects of inner diameter of tubing on thermal performance and pressure drop are also discussed. It was observed that an increase of tubing inner diameter by 60 % can result in increase of heat transfer coefficient by 47.8 % and reduction in pressure drop by 63 %. 

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4. Mapping the performance of a versatile water-based condensation particle counter (vWCPC) with numerical simulation and experimental study

   https://doi.org/10.5194/amt-16-3973-2023  

   Hao, Weixing; Mei, Fan; Hering, Susanne; Spielman, Steven; Schmid, Beat; Tomlinson, Jason; Wang, Yang (January 2023, Atmospheric Measurement Techniques)

   Abstract. Accurate airborne aerosol instrumentation is required to determine thespatial distribution of ambient aerosol particles, particularly when dealingwith the complex vertical profiles and horizontal variations of atmosphericaerosols. A versatile water-based condensation particle counter (vWCPC) hasbeen developed to provide aerosol concentration measurements under variousenvironments with the advantage of reducing the health and safety concernsassociated with using butanol or other chemicals as the working fluid.However, the airborne deployment of vWCPCs is relatively limited due to thelack of characterization of vWCPC performance at reduced pressures. Giventhe complex combinations of operating parameters in vWCPCs, modeling studieshave advantages in mapping vWCPC performance. In this work, we thoroughly investigated the performance of a laminar-flowvWCPC using COMSOL Multiphysics® simulation coupled withMATLAB™. We compared it against a modified vWCPC (vWCPC model 3789, TSI,Shoreview, MN, USA). Our simulation determined the performance of particleactivation and droplet growth in the vWCPC growth tube, including thesupersaturation, Dp,kel,0 (smallest size of particle that canbe activated), Dp,kel,50 (particle size activated with 50 %efficiency) profile, and final growth particle size Dd underwide operating temperatures, inlet pressures P (30–101 kPa), and growthtube geometry (diameter D and initiator length Lini). Theeffect of inlet pressure and conditioner temperature on vWCPC 3789performance was also examined and compared with laboratory experiments. TheCOMSOL simulation result showed that increasing the temperature difference(ΔT) between conditioner temperature Tcon andinitiator Tini will reduce Dp,kel,0 and thecut-off size Dp,kel,50 of the vWCPC. In addition, loweringthe temperature midpoint(Tmid=Tcon+Tini2) increasesthe supersaturation and slightly decreases the Dp,kel. Thedroplet size at the end of the growth tube is not significantly dependent onraising or lowering the temperature midpoint but significantly decreases atreduced inlet pressure, which indirectly alters the vWCPC empirical cut-offsize. Our study shows that the current simulated growth tube geometry (D=6.3 mm and Lini=30 mm) is an optimized choice forcurrent vWCPC flow and temperature settings. The current simulation can morerealistically represent the Dp,kel for 7 nm vWCPC and alsoachieved good agreement with the 2 nm setting. Using the new simulationapproach, we provide an optimized operation setting for the 7 nm setting.This study will guide further vWCPC performance optimization forapplications requiring precise particle detection and atmospheric aerosolmonitoring. 

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5. KARST HYDROLOGICAL CONTROL ON OXYGEN ISOTOPE VARIABILITY OF CAVE DRIP WATER: A REGIONAL CAVE MONITORING STUDY FROM THE PERUVIAN ANDES

   https://doi.org/10.1130/abs/2023AM-391666  

   Forsyth, Alexander; Litchfield, Kirsten; Olson, Elizabeth; Stoltenberg, Hailey; Clavel, Avery; Ramjohn, Maryam; Nazir, Saliha; Piccirillo, Laura; Parmenter, Dylan; Verheyden, Anouk; et al (January 2023, Geologic Society of America)

   Recent studies have improved our understanding of how karst hydrology impacts variability in modern cave drip water δ18O values and the resultant calcite δ18O values of speleothem paleoclimate records. Monitoring of cave drip water isotope values reveals that flow path controls the differences in drip site values in many caves worldwide. We present a case study of three caves from the central Peruvian Andes where isotopic differences between sites are informed by monitoring data. Relative humidity at Huagapo and Pacupahuain caves is 100% year-round with no fluctuations, so any isotopic fractionation of waters must occur in the vadose zone or epikarst. Precipitation isotope data from the 2022-2023 year show differences with elevation, where annual mean precipitation at 3600 masl (meters above sea level) is, on average, 2‰ greater than precipitation at 4100 masl. Cave drip water was sampled four times (April, June, and November 2022, and June 2023). Average drip water δ18O values were lowest at the high elevation (4004 masl) cave of Antipayargunan -14.7 ± 2.5‰; similar values were found at the lowest elevation (3600 masl) cave of Huagapo -14.5 ± 1.2‰. Pacupahuain cave had the highest values with an average of -13.9 ± 1.7‰. The higher values at Pacupahuain Cave (3800 masl) may be attributed to higher evaporation due to vadose zone residence time, a lower average recharge elevation for this catchment and/or potential contribution from a sinkhole lake (Lago Gallerina) above the cave. Huagapo Cave is large, and sampling sites over 1 km in distance show that the δ18O value of drip water increases by 0.5‰ with increasing distance from the cave entrance. Drip counting sensor data and a continuous SYP autosampler at Pacupahuain Cave provide a time series showing that drip rate peaks during the monsoon season. More specifically, the data show a maximum of 2 ‰ difference in drip water at the autosampler site between the end of the wet season in May and the middle of the dry season in August – at which point drips cease for six months. Seasonal recharge dominates most drip water sites, while drip counters show evidence for fracture and diffuse flow-dominated drip sites. These data suggest that, similar to other cave sites, flow path is important for intra-cave differences in drip water isotope values. However, we find that karst hydrology plays a more dominant role between caves. 

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