Test Facility Research Articles

Progress on development of diagnostic system for negative ion source of CRAFT NNBI test facility

Progress on development of diagnostic system for negative ion source of CRAFT NNBI test facility

Steam Condensation Scaled Experiment in the Presence of Non-Condensable Gases for Small Modular Reactor Containment Passive Safety

This study presents scaled experiments using steam condensation with non-condensable gas (NCG)—helium (He), simulating hydrogen, and nitrogen (N2)—as these experiments are pivotal for water-cooled reactor passive containment cooling system (PCCS) design and analysis. Research into PCCSs for small modular reactors (SMRs) is especially important in light of SMR system design; however, studies in the literature reflect limitations due to test geometry and operational condition variations, without considering SMR prototypic design. To address these challenges, a scaled test facility was developed to accurately replicate SMR PCCSs. This facility includes vertical down-flow condensing test sections with 1-, 2-, and 4-in.-diameter condensing tubes, accompanied by annular water cooling. Experiments were conducted using both superheated and saturated steam, with steam mass flow rates in the presence of NCG varying from: (a) 55 to 66 kg/hr. of steam, and 1.8 to 22 kg/hr. of He (as the NCG); (b) 58 to 63 kg/hr. of steam, and 4.4 to 13.3 kg/hr. of N2 (as the NCG). Test data were collected on (a) the axial temperatures of the annular cooling water; (b) the outer wall temperature of the condensers; and (c) the mass flow rate, temperature, and pressure at the test section inlets and outlets. These primary test data were used in conjunction with a standard data reduction methodology to estimate essential thermal parameters such as heat fluxes, heat transfer coefficients, and condensation rates. The effects of NCGs on steam condensation within the geometry of the scaled test sections were then presented in regard to various testing conditions.

Design and Validation Strategy for an X-Ray Target Subject to Ultra High Heat Flux Loading

Abstract Microbeam X-ray therapy is a promising cancer therapy that uses a high-power electron beam hitting a metallic target. For a clinical microbeam therapy X-ray source, an electron beam of a power of 1 MW onto a focal spot of 0.05 mm × 20 mm size is needed, with a penetration depth of 0.1 mm. This means a heat flux input of 1 TW/m2, an order of magnitude higher than nuclear and medical applications. Numerical simulations based on surface and volumetric heat loading for such an electron beam are presented in this work. The local temperature around the focal spot is modeled in a lower-scale model with an element size of 10 µm and volumetric heat loading. This differs from the state-of-the-art simulations, in which electron beam loading is modeled as surface heat flux loads. The simulated temperature agrees with the mathematical estimates within an error of 10% while proving feasibility. A novel validation strategy is proposed to address the lack of available test facilities to replicate this extreme heat flux. The critical parameters describing the high-heat-flux-loading are identified as temperature, thermal strain, thermal stress, and strain rate. Scaled-down test specifications are determined to use a test facility of power less than 100 kW. With the verified simulation using the scaled-down test, it is proposed to establish the material's capability to withstand the concentrated 1 MW heat load without a 1 MW test facility.

Blue abyss to enable gravity-related research and training

The new step in space exploration coupled with an exponential increase in the number of astronauts flying in space and preparing future Moon and Mars missions in the coming years will be possible if research and training at different gravity levels is actively pursued. Blue Abyss proposes a versatile approach for astronaut training and research at various gravity levels and in different environments. Blue Abyss is establishing its first research, test and training center in Cleveland, Ohio, USA, with plans to expand to other locations in the USA, Middle-East and the Far-East. The Blue Abyss center will be built around three main axes: (1) A versatile multi-use dive pool with several platforms from 3 to 20 m, a space research area, the Astrolab platform at 12 m, and a 50 m deep shaft; (2) A centrifuge to train astronauts and to study hypergravity physiological effects; and (3) A parabolic flight capability to offer zero, Lunar, Mars, other reduced and hyper gravity accelerations for gravity-related research and training. The ground infrastructure will include classrooms, hypobaric and hyperbaric chambers, and a human performance research center including specialized test and evaluation facilities, microgravity and hypergravity simulators that will be used for physiological studies, rehabilitation and training. A pedagogical and outreach program will offer an interactive, dynamic approach to STEM-related education for students, tomorrow's scientists.

Failure analysis of LCF cracked medium-voltage switch bellows

Abstract Three cracked spring bellows used for medium voltage switches were subjected to materialographic examinations. They were installed in switches that were tested in the test facility performing simulated switching cycles and failed prematurely. The number of load cycles until crack initiation is not known. However, it was well under 10,000. The cause of the crack was low-cycle fatigue (LCF) induced by wall thinning wear resulting from a relative movement between the bellow and the inner polytetrafluoroethylene (PTFE) sleeve. Hot cracking characteristics or evidence of other fracture mechanisms were not found.

Temperature Prediction for the Sirius-2c Nuclear Propulsion Fuel Experiment Conducted at the TREAT Facility

This study presents a predictive transient model developed for simulating experiments at the Transient Reactor Test (TREAT) Facility and its application to the Sirius-2c experiments. We introduce an innovative approach to predict control rod motion, reactor power, and specimen temperature during transient experiments using Griffin, BISON, and the stochastic tool packages of the Multiphysics Object-Oriented Simulation Environment. The model provides a blind prediction of the specimen temperature evolution during transient tests given a desired power signal. Initially, our model accurately predicts the transient motion of the control rods to achieve the desired reactor power profile. Subsequently, it predicts the specimen temperature based on the power deposited within the specimen. The simulation results show strong agreement with the measured reactor power and control rod positions; however, the specimen temperature is slightly overpredicted, primarily because of assumptions about surface emissivities. When considering a more accurate set of specimen emissivities, the predicted temperature aligns exceptionally well with the measured values according to post-analysis results. The simulation results will support the design and analysis of the National Aeronautics and Space Administration sponsored Sirius series of experiments for nuclear thermal propulsion applications, and the model can be utilized to assist in the design and optimization of new experiments to be conducted at the TREAT Facility.

Frequency-scanning burst-mode filtered Rayleigh scattering for kHz-rate, multi-parameter, gas-phase measurements.

Molecular Rayleigh scattering (RS) is sensitive to the pressure, temperature, velocity, and number density of the gaseous flow. Filtered Rayleigh scattering (FRS) utilizes a narrowband molecular filter to remove stray scattering and deconvolve the effect of flow conditions on the signal intensity. As single-frequency, intensity-based FRS techniques can typically only deconvolve a single parameter per detector angle, frequency-scanning (FS) FRS has been used to semi-spectrally resolve the signal and quantify multiple parameters using a single detector. In this work, the FS-FRS data rate was increased by a factor of 105 using a rapid wavelength-tunable burst-mode laser operated at 20 kHz. The technique is demonstrated for simultaneous, spatially resolved temperature, pressure, and radial velocity measurements time-averaged across 1 ms in an underexpanded jet, yielding a measurement rate of 1 kHz for potential use in high-speed flow test facilities.

Long Term Performance of Phase 1 Jointed Concrete Pavement Test Sections at the MnROAD Facility

Since 1994, the MnROAD pavement test facility has conducted comprehensive measurements of the performance and response of a variety of jointed concrete pavement designs. The primary objective of each MnROAD test section is to provide data toward validation or improvement of pavement performance prediction models. This paper examines the long-term trends of several critical performance parameters, for each of the fourteen original jointed concrete pavement sections constructed during Phase 1 (1994-2007) of MnROAD. These parameters include slab cracking, transverse joint deflection and load transfer efficiency, and ride quality. Through continual monitoring of the long-term performance of MnROAD jointed concrete pavement sections, there now exists a useful database of information related to concrete pavement behavior, particularly in colder climates. Analysis of MnROAD Phase 1 data reaffirms that AASHTO-based design methods are conservative in their prediction of performance.

Characterization of a single emitter passively fed electrospray ion source: part I - luminescence imaging analysis

Abstract Luminescence at the face of ionic liquid ion sources and nearby facility surfaces is a commonly reported radiative phenomenon that requires thorough examination. In this study, we present magnified images of a single emitter porous-media ionic liquid electrospray in profile, which provides spatial information on the origin of the luminescence. To determine what role facility interactions play in luminescence at the electrospray face, we varied the distance and material of a downstream beam target on which the ion plume terminated. The effect of applied emitter voltage on luminescence was also examined. Analysis of luminescence images and corresponding telemetry data demonstrate that the formation of luminescence near the emitter tip is not only a function of the surrounding test facility, but also dependent on the electrospray device, itself. The data also indicate the majority of luminescence observed within our experimental system is formed primarily from high-energy collisions between emitted propellant ions and propellant accumulated on the orifice of the extractor electrode.

Shear Wave Method for Concrete Pavement Diagnostics

Field trials involving typical pavement constructability and rehabilitation issues at the Federal Aviation Administration’s National Airport Pavement Test Facility, the Minnesota Road Research Project, and various in service pavements using MIRA were verified. The trials indicate that, while the device is a useful portable pavement diagnostic alternative capable of consistent thickness measurement, reinforcement location, and distress evaluation, significant efforts and user expertise are required for measurement and data interpretation of large scale applications. Thus, a couple productive, objective signal interpretation methods are presented for automated analysis of reinforcement location in continuously reinforced concrete pavement as well as an initial distress indicator using two-dimensional ultrasonic signature analysis. This type of automation for multiple applications shows promise for the use of ultrasonic tomography to improve large scale pavement quality assurance, quality control, and rehabilitation projects in the future. Innovative imaging methods such as synthetic aperture focusing technique panoramic reconstructions and synthetic aperture focusing technique three-dimensional visualizations were also introduced to improve the ability to obtain relational information when dealing with larger scanned areas. Ultrasonic tomography is shown to be an accurate, reliable, and convenient alternative/supplement to traditional techniques or can be used to replace or reduce the need for forensic methods such as coring.

Concrete Overload Test at the FAA National Airport Pavement Test Facility

Concrete Overload Test at the FAA National Airport Pavement Test Facility

Development and Validation of Reliability Testing Methods for Insulation Systems in High-Voltage Rotating Electrical Machinery on Ships

Lloyd’s Register became the first classification society to mandate reliability testing for insulation degradation in rotating electrical machinery. As the maritime industry shifts toward eco-friendly practices, high-voltage rotating electrical machinery on ships increasingly features higher voltages and larger capacities. However, incidents involving insulation systems have also become more frequent. Additionally, testing facilities with the necessary equipment to perform such reliability tests are lacking, and standardized testing methods are yet to be established. This study proposes test items, methods, and evaluation criteria for the reliability testing of high-voltage rotating electrical machinery. The testing methods are broadly categorized into four types: thermal, electrical, multifactor, and thermomechanical degradation reliability testing. The proposed methods were validated by conducting long-term testing over approximately one year. Key results showed a breakdown time of 7056 h in thermal evaluation, 5040 h in electrical evaluation, and 258.5 d in multifactor evaluation, as well as a 63rd percentile value of 245.7 h in thermomechanical evaluation, all of which fulfill the required criteria. The study offers practical guidelines for ensuring the durability and safety of high-voltage electrical machinery, aligning with the sustainability and safety goals of the maritime industry.

Evaluating the accuracy of multiple rapid diagnostic tests for HIV detection in serum samples analysed during point-of-care proficiency testing assessments.

HIV rapid diagnostic tests are crucial for timely diagnosis, especially in resource-limited settings. The World Health Organization recommends sensitivity ≥99 % and specificity ≥98 %. This study assessed RDT performance across South Africa's provinces using a proficiency testing program. From April to June 2023, 25,458 blinded serum samples were sent to testing facilities for screening and confirmatory testing. Sensitivity, specificity, predictive values, and concordance (Cohen's Kappa) were evaluated. The response rate was 98.25 %. Sensitivity and specificity were both 98.7 %, with agreement at 98.7 % (kappa 0.97, p < 0.001). Northern Cape showed the lowest sensitivity (91.8 %) and specificity (92.0 %), while Gauteng, KwaZulu-Natal, and Mpumalanga exceeded 99 %. Although national RDT performance met WHO standards, Northern Cape's results reveal the need for improved training, quality assurance, and proficiency testing to strengthen diagnostic accuracy.

Monitoring of Strength Development in Portland Cement Concrete With High Fly-Ash Content at the FAA’s National Airport Pavement Test Facility

Construction Cycle 2 (CC2) at the FAA’s National Airport Pavement Test Facility (NAPTF) included construction of three concrete test items MRC, MRG, and MRS on three different support conditions (crushed-stone subbase, slab on grade, and econocrete stabilized subbase). All three test items were constructed on a CBR 7-8 subgrade. The existing econocrete subbase (P-306) from CC1 test item MRS was used for CC2 MRS. Concrete was placed in the test items using a concrete pump into fully formed 15 ft. (4.57 m) by 15 ft. (4.57 m) slabs. Test results are presented and discussed in this paper. Test results include concrete placement details (slump, air content, concrete temperature), compressive strengths, flexural strengths, elastic modulus from free-free resonance tests on concrete beams and cylinders, portable seismic pavement analyzer (PSPA) tests, and strength results from sawed beams and cored cylinders taken from untrafficked test slabs. Concrete specimens included both laboratory cured and field cured specimens. PSPA tests were performed on the test item slabs at the age of one day and on regular intervals after that, coinciding with the laboratory testing of beams and cylinders. The test results showed good correlation between elastic modulus (from free-free resonance and PSPA tests) and strength values (compressive and flexural strengths) and demonstrated the application potential of a testing device such as PSPA for assessing the early-age strength of concrete.

Results of development and experimental studies of the storage complex with the energy storage unit SPENE-1

The RELEVANCE of the study is to develop a controlled storage complex (SC) of electrical energy for modern distributed energy based on advanced innovative technologies. OBJECTIVE. To conduct experimental studies, confirm the main technical solutions incorporated into the SC design and develop design and technological documentation (DTD). METHODS. When solving the tasks, experimental methods were used to confirm theoretical studies and calculations of SC units and elements, implemented by MatLab®. RESULTS. The article describes the relevance of the topic, the ways and stages of developing the SPENE-1 SC energy storage device. The work was carried out in three stages. At the first stage, the functional structure of the storage complex, a mathematical model of the storage complex operation as part of an electrical network, methods for calculating parameters and controlling energy flows in electrical networks of various topologies, as well as the ECD for an experimental sample of the storage complex and the control system were developed. At the second stage, an experimental sample of the storage complex control system was manufactured and the experimental sample of the storage complex control system was adjusted and tested. A program and methodology for testing an experimental sample of the storage complex, including the control system, have been developed; methodological materials for conducting comprehensive tests of experimental samples and working documentation for upgrading the test facility have been prepared. At the third stage of the work, the following was performed: a) assembly, adjustment and testing of the NC for conducting joint comprehensive tests of experimental samples; b) determination of the optimal parameters of the NC, the main characteristics and the range of their changes; c) experimental tests of the critical parameters of the superconducting suspension of the rotor-flywheel of the experimental sample of the storage complex and its control system; d) experimental comprehensive tests of experimental samples; e) adjustment of the KTD based on the results of the manufacturing technology and experimental comprehensive tests. CONCLUSION. The results obtained in the work are of great importance for the development of distributed energy in the Russian Federation. The ECD of the storage complex and the test base, as well as regulatory documents for the operation of the storage complex in various power supply systems have been developed. The NC can be used in traction electric systems of electric transport, distributed electric networks with alternative power sources. The application of the developed NC is especially effective in power supply systems operating in low temperature conditions, for example, in the Arctic and space.

A Multidisciplinary Approach to Diagnosing Blastic Plasmacytoid Dendritic Cell Neoplasm (BPDCN): Practical Recommendations and Insights from Countries of the Gulf Cooperation Council.

Blastic plasmacytoid dendritic cell neoplasm (BPDCN) is an aggressive orphan hematopoietic malignancy characterized by cutaneous and systemic hematologic involvement. BPDCN is frequently misidentified, but early, accurate diagnosis is critical to extending patient survival using tagraxofusp, a first-in-class CD123-targeted therapy, and increasing their chances of receiving a potentially curative stem cell transplantation. Cases of BPDCN in countries of the Gulf Cooperation Council are lower than the extrapolated incidence from other geographic locations due to lack of awareness of key diagnostic features, lack of consensus on the minimal phenotype for diagnosis, and lack of local immunohistochemistry testing facilities, contributing to underdiagnosis in this region. Practical recommendations, a streamlined diagnostic panel, and suggested multidisciplinary approaches based on expert experience regarding diagnostic and clinical challenges specific to this region, and a review of the literature are presented here to facilitate diagnosis of BPDCN in this region by primary care physicians, dermatologists, and hematologists.

Large errors in soil carbon measurements attributed to inconsistent sample processing

Abstract. To build confidence in the efficacy of soil carbon (C) crediting programs, precise quantification of soil organic carbon (SOC) is critical. Detecting a true change in SOC after a management shift has occurred, specifically in agricultural lands, is difficult as it requires robust soil sampling and soil processing procedures. Informative and meaningful comparisons across spatial and temporal timescales can only be made with reliable soil C measurements and estimates, which begin on the ground and in soil testing facilities. To gauge soil C measurement inter-variability, we conducted a blind external service laboratory comparison across eight laboratories selected based on status and involvement in SOC data curation used to inform C market exchanges, which could include demonstration projects, model validation, and project verification activities. Further, to better understand how soil processing procedures and quantification methods commonly used in soil testing laboratories affect soil C concentration measurements, we designed an internal experiment assessing the individual effect of several alternative procedures (i.e., sieving, fine grinding, and drying) and quantification methods on total (TC), inorganic (SIC), and organic (SOC) soil C concentration estimates. We analyzed 12 different agricultural soils using 11 procedures that varied in either the sieving, fine-grinding, drying, or quantification step. We found that a mechanical grinder, the most commonly used method for sieving in service laboratories, did not effectively remove coarse materials (i.e., roots and rocks) and thus resulted in higher variability and significantly different C concentration measurements from the other sieving procedures (i.e., 8 + 2, 4, and 2 mm with a rolling pin). A finer grind generally resulted in a lower coefficient of variance, where the finest grind to &lt; 125 µm had the lowest coefficient of variance, followed by the &lt; 250 µm grind and, lastly, the &lt; 2000 µm grind. Not drying soils in an oven prior to elemental analysis on average resulted in a 3.5 % lower TC and 5 % lower SOC relative to samples dried at 105 °C due to inadequate removal of moisture. Compared to the reference method used in our study where % TC was quantified by dry combustion on an elemental analyzer, % SIC was measured using a pressure transducer, and % SOC was calculated by the difference in % TC and % SIC, predictions of all three soil properties (% TC, % SIC, and % SOC) using Fourier-transformed infrared spectroscopy (FTIR) were in high agreement (R2 = 0.97, 0.99, and 0.90, respectively). For % SOC, quantification by loss on ignition had a relatively low coefficient of variance (5.42 ± 3.06 %) but the least agreement (R2 = 0.83) with the reference method. We conclude that sieving to &lt; 2 mm with a mortar and pestle or rolling pin to remove coarse materials, drying soils at 105 °C, and fine-grinding soils prior to elemental analysis are required to improve accuracy and precision of soil C measurements. Moreover, we show promising results using FTIR spectroscopy coupled with predictive modeling for estimating % TC, % SIC, and % SOC in regions where spectral libraries exist.

Current Status, Challenges, and Perspectives in the Conservation of Native Honeybees and Beekeeping in Cambodia.

The four honeybee species native to Cambodia-Apis dorsata, Apis cerana, Apis florea, and Apis andreniformis-play a vital role in ecosystem health and agricultural productivity through their pollination activities. Beekeeping in Cambodia has primarily developed around the introduced species Apis mellifera. However, it remains underdeveloped compared to neighboring countries, with wild honey collection continuing to play a significant role. Although native bees are not at immediate risk of extinction, their crucial ecological and socio-economic roles, coupled with the threats to their populations, necessitate the urgent implementation of conservation policies. The beekeeping sector in Cambodia faces numerous challenges that hinder its development. These include a lack of documentation and official data, limited access to productive apiaries, inappropriate pesticide practices, insufficient knowledge about bee health, diseases, and parasites, inadequate organization and representation of beekeepers, the high cost of Cambodian honey, and a lack of consumer awareness and trust in local bee products. This paper provides an overview of the status and distribution of honeybee species, along with the production, value chain, and trade of bee products in Cambodia. It examines the challenges of conserving native honeybees and developing the beekeeping sector while proposing strategies to strengthen bee conservation and support the growth of beekeeping in the country. Key recommendations focus on integrating bee conservation strategies with broader conservation goals, such as reducing deforestation, promoting sustainable agriculture, and regulating the consumption of wild bee brood. Key strategies for the development of beekeeping are documenting and conserving bee floral resources and habitats, reducing the use of bee-toxic pesticides, developing research and training capacities in beekeeping, regulating bee imports, and enhancing quality and authenticity testing facilities. Additionally, building capacity among honey value chain stakeholders in areas such as quality control, authenticity, processing, packaging, and marketing is essential.

Low-vibration cryogenic test facility for next generation of ground-based gravitational-wave observatories.

We present the design and commissioning of a cryogenic low-vibration test facility that measures displacement noise from a gram-scale silicon cantilever at the level of 10-16m/Hz at 1kHz. This sensitivity is necessary for future tests of thermal noise models on cross sections of silicon suspension samples proposed for future gravitational-wave detectors. A volume of ∼36 l is enclosed by radiation shields cooling an optical test cavity that is suspended from a multi-stage pendulum chain providing isolation from acoustic and environmental noise. This 3kg test cavity housing a crystalline silicon cantilever is radiatively cooled to 123K in 41h and held at that temperature over many months with a relative temperature stability of ±1 mK. The facility housing the test cavity is sensitive to cavity length changes, which can resolve thermal fluctuations at the desired sensitivity. It is capable of interferometrically measuring temperature-dependent broadband displacement noise directly between 50Hz and 10kHz, where current and future ground-based gravitational wave observatories are the most sensitive. With a suitable cantilever design, the cryogenic facility we describe here will allow for the measurement of broadband thermal noise in crystalline silicon at 123K. This will guide the design of suspensions in planned future cryogenic ground-based gravitational-wave detectors such as LIGO Voyager and may have implications for suspensions in the Einstein Telescope. This facility is also suitable for the testing of new mirror coatings at cryogenic temperatures.

Dynamics of residential indoor gas- and particle-phase water-soluble organic carbon: measurements during the CASA experiment.

Previous time-integrated (2 h to 4 h) measurements show that total gas-phase water-soluble organic carbon (WSOCg) is 10 to 20 times higher inside homes compared to outside. However, concentration dynamics of WSOCg and total particle phase WSOC (WSOCp)-are not well understood. During the Chemical Assessment of Surfaces and Air (CASA) experiment, we measured concentration dynamics of WSOCg and WSOCp inside a residential test facility in the house background and during scripted activities. A total organic carbon (TOC) analyzer pulled alternately from a particle-into-liquid sampler (PILS) or a mist chamber (MC). WSOCg concentrations (215 ± 29 μg-C m-3) were generally 36× higher than WSOCp (6 ± 3 μg-C m-3) and 20× higher than outdoor levels. A building-specific emission factor (Ef) of 31 mg-C h-1 maintained the relatively high house WSOCg background, which was dominated by ethanol (46 μg-C m-3 to 82 μg-C m-3). When we opened the windows, WSOCg decayed slower (2.8 h-1) than the air change rate (21.2 h-1) and Ef increased (243 mg-C h-1). The response (increased Ef) suggests WSOCg concentrations are regulated by large near surface reservoirs rather than diffusion through surface materials. Cooking and ozone addition had a small impact on WSOC, whereas surface cleaning, volatile organic compound (VOC) additions, or wood smoke injections had significant impacts on WSOC concentrations. WSOCg concentration decay rates from these activities (0.4 h-1 to 4.0 h-1) were greater than the normal operating 0.24 h-1 air change rate, which is consistent with an important role for surface removal.