Dual Loop Line-Focusing Solar Power Plants with Supercritical Brayton Power cycles

Most of the deployed commercial line-focusing solar power plants with Parabolic Troughs (PTC) or Linear Fresnel (LF) solar collectors and Rankine power cycles use a Single Loop Solar Field (SF), Configuration 1 illustrated in Fig. 2, with synthetic oil as Heat Transfer Fluid (HTF) [1, 2]. However, thermal oils maximum operating temperature should be below ~400ºC for assuring no oil degradation, hence limiting the power cycle gross efficiency up to ~38%. For overcoming this limitation Molten Salts (MS) as HTF in linear solar collectors (PTC and LF) were recently experimented in pilot facilities [3, 4]. Direct MS main drawbacks are the equipments and components material corrosion and the salts freezing temperature, requiring heat tracing to avoid any sald solidification, hence increasing the Solar Field (SF) capital investment cost and parasitic energy looses. Concentrated Solar Power plants (CSP) with Dual Loop SF are being studied since 2012 [5] for gaining the synergies between thermal oils and MS properties. In the Dual Loop SF the HTF in the primary loop is thermal oil (Dowtherm A) [6] for heating the Balance Of Plant (BOP) working fluid from ~300ºC up to ~400ºC, and a secondary loop with Solar Salt (60% NaNO3, 40% KNO3) as HTF, for boosting the working fluid temperature from ~400ºC up to 550ºC [7, 8, 9]. The CSP Dual Loop state of the art technology includes Rankine power cycles, the main innovation of this paper is the integration between Dual Loop SF and the supercritical Carbon Dioxide (s-CO2) Brayton power cycles [10], see Configurations 2 and 3 illustrated in Fig. 3a, Fig 3b. A secondary innovation studied in this paper is the integration between thermal oil HTF (Dowtherm A) in linear solar collectors, a widely validated and mature technology, with the s-CO2 Brayton power cycles. This technical solution is very cost competitive with carbon steel receiver pipes, low SF operating pressure, and no requiring any heat tracing. Two main conclusions are deducted from this researching study. Firstly we demonstrated the higher gross plant efficiency ~44.4%, with 550ºC Turbine Inlet Temperature (TIT), provided by the Dual Loop with the Simple recuperated s-CO2 Brayton cycle with reheating, in comparison with 41.8% obtained from the Dual Loop SF and subcritical water Rankine power cycle. And finally the second conclusion obtained is the selection of the most cost competitive plant configuration with a Single loop SF with Dowtherma A and a s-CO2 Brayton power cycle due to the receiver material low cost and no heat tracing for the thermal oil

Well being of obstetric patients on minimal blood transfusions (WOMB trial)

Background: Primary postpartum haemorrhage is an obstetrical emergency often causing acute anaemia that may require immediate red blood cell (RBC) transfusion. This anaemia results in symptoms such as fatigue, whic

Low-risk transfusion-related acute lung injury donor strategies and the impact on the onset of transfusion-related acute lung injury: a meta-analysis

Transfusion-related acute lung injury (TRALI) is the leading cause of transfusion-related mortality. In the past decade blood banks have implemented low-risk TRALI donor strategies, including a male-only donor policy for plasma-containing blood products to prevent onset of TRALI. We performed a meta-analysis to determine whether use of low-risk TRALI donor strategies for plasma indeed reduces onset of TRALI. We searched MEDLINE and Cochrane Central Register of Controlled Trials from January 1995 up to January 2013. Two reviewers independently extracted data on study characteristics, methods, and outcomes. Primary endpoint was onset of TRALI. Subgroup analyses were performed for patient populations prone to develop TRALI and general patient populations. Ten articles were included. Meta-analysis using a random-effects model taking into account all transfused products showed a significant reduction for the risk of TRALI after implementation of low-risk TRALI donor strategies (odds ratio [OR], 0.61; 95% confidence interval [CI], 0.42-0.88). Data from patient populations prone to develop TRALI showed a significant reduction of TRALI risk (OR, 0.51; 95% CI, 0.29-0.90), while data from general patient populations showed a similar nonsignificant trend (OR, 0.66; 95% CI, 0.40-1.09). Results were similar when taking only plasma products into account (OR, 0.62; 95% CI, 0.42-0.92). The introduction of low-risk TRALI donor strategies for plasma-containing products results in a reduction of TRAL

Flow cytometric lymphocyte subset enumeration: 10 Years of external quality assessment in the benelux countries

A biannual external quality assessment (EQA) scheme for flow cytometric lymphocyte immunophenotyping is operational in the Benelux countries since 1996. We studied the effects of the methods used on assay outcome, and whether or not this EQA exercise was effective in reducing between-laboratory variation. Eighty test samples were distributed in 20 biannual send-outs. Per send-out, 50-71 participants were requested to enumerate CD3+, CD4+, and CD8+ T cells, B cells, and NK cells, and to provide methodological details. Participants received written debriefings with personalized recommendations after each send-out. For this report, data were analyzed using robust multivariate regression. Five variables were associated with significant positive or negative bias of absolute lymphocyte subset counts: (i) platform methodology (i.e., single-platform assays yielded lower CD4 + and CD8+ T-cell counts than did dual-platform assays); (ii) sample preparation technique (i.e., assays based on mononuclear cells isolation yielded lower T-cell counts than those based on red cell lysis); (iii) gating strategies based on CD45 and sideward scatter gating of lymphocytes yielded higher CD4+ T-cell counts than those based on "backgating" of lymphocytes guided by CD45 and CD14); (iv) stabilized samples were generally associated with higher lymphocyte subset counts than nonstabilized samples; and (v) laboratory. Platform methodology, sample stabilization, and laboratory also affected assay variability. With time, assay variability tended to decline; this trend was significant for B-cell counts only. In addition, significant bias and variability of results, independent of the variables tested for in this analysis, were also associated with individual laboratories. In spite of our recommendations, participants tended to standardize their techniques mainly with respect to sample preparation and gating strategies, but less with absolute counting techniques. Failure to fully standardize protocols may have led to only modest reductions in variability of results between laboratories

RHC and RHc genotyping in different ethnic groups

BACKGROUND: RH genotyping assays are mainly based on research in whites. These assays may not be reliable in a multiracial society because of the genetic variation in RH among ethnic groups. STUDY DESIGN AND METHODS: Five groups from different ethnic backgrounds were serologically typed for C and c and were genotyped on nucleotide C48 and intron 2 for RHC and RHc on nucleotides C178 and C307. RESULTS: RHc genotyping with both methods proved to be reliable. RHC genotyping on C48 is not reliable because of a 48G>C mutation in the RHce allele (false-positive prediction of C). This mutation was found in every ethnic group and does not affect c or e expression. RHC genotyping on intron 2 is unreliable because of r's (Cdes) alleles (a false-negative prediction of C). This allele was found in whites and blacks from Curaçao and South Africa. Reactions of r's cells with anti-C are weaker, but no negative reactions with various MoAbs were found. A new method (RHC/c/hex3-intron 4/exon 7 multiplex PCRs) was developed based on intron 2 and r's hybrid exon 3 characteristics (RHC) and C307 (RHc). CONCLUSIONS: Reliable RHC and RHc genotyping is possible in different ethnic groups with the RHC/c/hex3-intron 4/exon 7 multiplex PCR approac

RHD(T201R, F223V) cluster analysis in five different ethnic groups and serologic characterization of a new Ethiopian variant DARE, the DIII type 6, and the RHD(F223V)

BACKGROUND: The RHD phylogeny in humans shows four main clusters of which three are predominantly observed in (African) black persons. Each of the African clusters is characterized by specific amino acid substitutions relative to the Eurasian RHD allele. RH phylogeny defines the framework for identification of clinically relevant aberrant alleles. This study focuses on the weak D type 4 cluster (characterized by RHD(T201R, F223V) (602C>G 667T>G)) in five ethnic groups. STUDY DESIGN AND METHODS: A total of 1702 samples were screened for the presence of 602C>G and 667T>G by sequence-specific polymerase chain reaction (PCR-SSP). Eighty samples were assigned to the weak D type 4 cluster and were molecularly characterized by PCR-SSP and RHD sequencing. Antigens of aberrant alleles were characterized with monoclonal anti-D according to the 37-epitope model when possible. RESULTS: Five new aberrant alleles, DIII type 6, DIII type 7, DARE, RHD(T201R, F223V) (without 819G>A), and RHD(F223V), were identified and DIII type 6, DARE, and RHD(F223V) were serologically characterized with monoclonal anti-D. Both the DARE and RHD(F223V) showed epitope loss. It is postulated that the 1136C>T nucleotide substitution (characteristic for the DAU allele cluster) is present on the DVa(KOU) allele. CONCLUSION: Identification of the new variant alleles refines the phylogeny of RHD in humans. The proposed DVa(KOU) allele with 1136C>T (DVa(KOU)T379M) is probably caused by conversion of the DAU0 allele and the DVa(KOU) allele, forming a phylogenetic link between the DV allele and the DAU cluster. By describing the RHD(F223V) (602C>G) and RHD(T201R, F223V) (602C>G and 667T>G) alleles formal proof is given for the origin of the non-Eurasian cluste