1,647 research outputs found
Fault Detection and Diagnosis in Air Conditioners and Refrigerators
A fault detection and diagnosis (FDD) method was used to detect and diagnose
faults on both a refrigerator and an air conditioner during normal cycling operation. The
objective of the method is to identify a set of sensors that can detect faults reliably before
they severely hinder system performance. Unlike other methods, this one depends on the
accuracy of a number of small, on-line linear models, each of which is valid over a
limited range of operating conditions.
To detect N faults, N sensors are needed. Using M>N sensors can further reduce
the risk of false positives. For both the refrigerator and air conditioner systems, about
1000 combinations of candidate sensor locations were examined. Through inspection of
matrix condition numbers and each sensor's contribution to fault detection calculation, the
highest quality sets of sensors were identified. The issue of detecting simultaneous
multiple faults was also addressed, with varying success.
Fault detection was verified using both model simulations and experimental data.
The results were similar, although in practice only one of the two would probably be
used. Both load-type faults (such as door gasket leaks) and system faults were simulated
on the refrigerator. It was found that system faults were generally more easily detectable
than load faults.
Refrigerator experiments were performed on a typical household refrigerator
because it was readily available in a laboratory, but the results of this project may be
more immediately useful on larger commercial, industrial or transport refrigeration
systems. Air conditioner experiments were performed on a 3-ton split system. Again, the
economic benefits of this type of fault detection scheme may also be more feasible for
larger field-assembled systems.Air Conditioning and Refrigeration Project 8
Letter from Charles W. Miller to James B. Finley
Rev. Charles W. Miller (North Indiana Conference), informs Finley that the second quarterly conference for Richmond Circuit will be held in two weeks -- December 15 & 16. Miller invites Finley to attend. He would be happy to host Finley at his home, offering Methodist Preachers fare for meals and a Prophets room which contains a fireplace. Abstract Number - 454https://digitalcommons.owu.edu/finley-letters/1652/thumbnail.jp
MARKETING OF COTTON FIBER IN THE PRESENCE OF YIELD AND PRICE RISK
An expected utility model and a chance constrained linear programming model were used to analyze four marketing strategies and seven crop insurance alternatives in cotton marketing in Georgia. The results obtained suggest that the existing marketing tools and insurance alternatives can be used successfully as a substitute for government support.Demand and Price Analysis, Marketing, Risk and Uncertainty,
Elastic constants of 3-, 4- and 6-connected chiral and anti-chiral honeycombs subject to uniaxial in-plane loading
Finite Element models are developed for the in-plane linear elastic constants of a family of honeycombs comprising arrays of cylinders connected by ligaments. Honeycombs having cylinders with 3, 4 and 6 ligaments attached to them are considered, with two possible configurations explored for each of the 3- (trichiral and anti-trichiral) and 4- (tetrachiral and anti-tetrachiral) connected systems. Honeycombs for each configuration have been manufactured using rapid prototyping and subsequently characterised for mechanical properties through in-plane uniaxial loading to verify the models. An interesting consequence of the family of 'chiral' honeycombs presented here is the ability to produce negative Poisson's ratio (auxetic) response. The deformation mechanisms responsible for auxetic functionality in such honeycombs are discussed
LOMA: A fast method to generate efficient tagged-random primers despite amplification bias of random PCR on pathogens
10.1186/1471-2105-9-368BMC Bioinformatics9BBMI
Imaging atlas for eligibility and on-study safety of potential knee adverse events in anti-NGF studies (Part 1)
SummaryMonoclonal antibodies that bind and inhibit nerve growth factor (NGF) have demonstrated both, good analgesic efficacy and improvement in function in patients with osteoarthritis (OA). Despite initial promising data, trials in OA had been suspended by the Federal Food and Drug Administration (FDA) due to concerns over accelerated rates of OA progression. Imaging will play a crucial role in future clinical trials to define eligibility of potential participants and to monitor safety during the course of these studies. This will require baseline and frequent follow-up radiographs of both, the index joints and other large weight bearing joints to identify subjects at risk prior inclusion and on study so treatment can be discontinued.This imaging overview in the form of an atlas describes and illustrates potential exclusionary joint imaging findings at eligibility and potential adverse joint events on radiography and magnetic resonance imaging (MRI) in studies investigating a-NGF compounds. The overarching goal of this atlas is to facilitate trial design and to promote a common language and understanding between potential expert readers. This first section of the atlas will focus on knee joint specific findings that are relevant to a-NGF studies
Anharmonic parametric excitation in optical lattices
We study both experimentally and theoretically the losses induced by
parametric excitation in far-off-resonance optical lattices. The atoms confined
in a 1D sinusoidal lattice present an excitation spectrum and dynamics
substantially different from those expected for a harmonic potential. We
develop a model based on the actual atomic Hamiltonian in the lattice and we
introduce semiempirically a broadening of the width of lattice energy bands
which can physically arise from inhomogeneities and fluctuations of the
lattice, and also from atomic collisions. The position and strength of the
parametric resonances and the evolution of the number of trapped atoms are
satisfactorily described by our model.Comment: 7 pages, 5 figure
Evaluation of the Removal of Organic Sulfur from Coal
As the removal of sulfur from coal prior to combustion acquires more importance in order to meet evermore stringent antipollution regulations, research on the development of methods for the cleaning of coal continues to expand. Reviews are available which describe the various methods for desulfurizing coal (1, 2, 3). The sulfur content in coal is usually a few per cent, but it can range from less than 0.5 per cent to as much as 8 per cent or more. Much of the sulfur is inorganic in nature, occurring in discrete mineral phases; the inorganic sulfur is mostly pyrite with small amounts of sulfates such as gypsum. Part of the sulfur in coal is termed organic sulfur, being intimately bound to the organic coal matrix. The chemical nature of this organic sulfur is not well established. During the desulfurization of coal, some of the coarse inorganic sulfur components can be removed
Enhancing energy absorption in quantum dot solar cells via periodic light-trapping microstructures
Colloidal quantum dot (CQD) solar cells prove to be promising devices for optoelectronic applications due to their tunable absorption range, deep infrared absorption capabilities, and straightforward processability. However, there remains a need to further enhance their device performance - particularly when one has to adhere to strict physical limitations on their physical structure. Here we present a three-dimensional numerical model of CQD solar cells in COMSOL Multiphysics based on the finite element method. With this model we have simulated the optical characteristics of several CQD solar cells across varying photonic structures and physical parameters to investigate how distinct photonic structures may enhance the light absorption and current output of CQD solar cells using identical physical parameters. Of the many cells simulated, one notable model increased the predicted current in the active layer PbS by 69.33% as compared to a flat solar cell with identical physical parameters, and produced a current of 24.18 mA cm-2 by implementing a cross-shaped photonic structure built on top of a flat substrate of glass and ITO. This cross-shaped model serves as a key example of how unique photonic structures can be implemented to further enhance light absorption
Detecting a stochastic background of gravitational radiation: Signal processing strategies and sensitivities
We analyze the signal processing required for the optimal detection of a
stochastic background of gravitational radiation using laser interferometric
detectors. Starting with basic assumptions about the statistical properties of
a stochastic gravity-wave background, we derive expressions for the optimal
filter function and signal-to-noise ratio for the cross-correlation of the
outputs of two gravity-wave detectors. Sensitivity levels required for
detection are then calculated. Issues related to: (i) calculating the
signal-to-noise ratio for arbitrarily large stochastic backgrounds, (ii)
performing the data analysis in the presence of nonstationary detector noise,
(iii) combining data from multiple detector pairs to increase the sensitivity
of a stochastic background search, (iv) correlating the outputs of 4 or more
detectors, and (v) allowing for the possibility of correlated noise in the
outputs of two detectors are discussed. We briefly describe a computer
simulation which mimics the generation and detection of a simulated stochastic
gravity-wave signal in the presence of simulated detector noise. Numerous
graphs and tables of numerical data for the five major interferometers
(LIGO-WA, LIGO-LA, VIRGO, GEO-600, and TAMA-300) are also given. The treatment
given in this paper should be accessible to both theorists involved in data
analysis and experimentalists involved in detector design and data acquisition.Comment: 81 pages, 30 postscript figures, REVTE
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