ライフサイエンスコーパス: flow rate

1 with the membrane by varying the volumetric flow rate.

2 ive the frequency-dependent electron/current flow rate.

3 oiodine treatment on stimulated whole saliva flow rate.

4 uency increases linearly with the volumetric flow rate.

5 meter, drill pipe internal diameter, and mud flow rate.

6 ed through the nebulizer and the diluent air flow rate.

7 itions of 1V, 50 kHz and 0.02 mul/min sample flow rate.

8 is usually more than 50% of the 6-week blood flow rate.

9 ory resistance increases with the increasing flow rate.

10 ithin 5 min of deposition and 4.0 mL min(-1) flow rate.

11 t behaviour and is robust to fluctuations in flow rate.

12 ncreased water intake and decreased salivary flow rate.

13 lation (=suction pressure/flow rate) at each flow rate.

14 rostatic pressure (FIHP) following increased flow rate.

15 eflex, that was proportional to the urethral flow rate.

16 sponge shunt into LFA to decrease the fluid flow rate.

17 strating the benefits of the impinger's high flow rate.

18 made in each of five livers perfused at each flow rate.

19 reliably and quantitatively measures the CSF flow rate.

20 ology is being kept constant for a number of flow rates.

21 the droplet size is sensitive to changes in flow rates.

22 a spiral microfluidic channel under various flow rates.

23 es and venules and their respective relative flow rates.

24 citation voltages at different water and oil flow rates.

25 d-silica capillary geometries, and operating flow rates.

26 les were consistent with 50-150 mL/min vapor flow rates.

27 ntification of lymph velocity and volumetric flow rates.

28 porous and loosely attached biofilms at low flow rates.

29 performed equally well for typical nano-HPLC flow rates.

30 cytometry that are inherently limited to low flow rates.

31 ecreased along the fluidic channel at higher flow rates.

32 itation front was influenced by the relative flow rates.

33 ties, limited pressure monitoring, and fixed flow rates.

34 rfused directly through each scaffold at low flow rates ( 0.15mL/min).

35 The influence of biogas flow rate (0, 0.3, 0.6, and 1.2 m(3) m(-2) h(-1)) on the

36 ser scanning microscopy under variable cross-flow rate (0.5-2.0 L/min) and flushing time (10 to 30 mi

37 lize a wide range of periods (0.4 s-2 h) and flow rates (0.10-63 mul min(-1)) with completely indepen

38 rfused directly through each scaffold at low flow rates (~0.15mL/min).

39 nsist of acetonitrile: water (90:10, v/v) at flow rate 1.0mL/min and the eluent was monitored at 219n

40 d to optimize temperature (40-55 degrees C), flow rate (1.0-2.5 mL min(-1)), mobile phase composition

41 ure (100, 120 and 140 degrees C) and solvent flow rates (1, 3 and 5mL/min) were investigated at 0.5mm

42 ndomized to home oxygen alone (median oxygen flow rate, 1.0 L/min [interquartile range {IQR}, 0.5-2.0

43 to home oxygen plus home NIV (median oxygen flow rate, 1.0 L/min [IQR, 0.5-1.5 L/min]).

44 With 1.2 mL/min AF4 cross-flow rate, 1.5 mL/min AF4 channel flow rate, and 5 ms sp

45 olute 10% difference in FMD: change in blood flow rate =11.6%; 95% CI, 0.6% to 23.9%; P=0.04; change

46 olute 10% difference in NMD: change in blood flow rate =14.0%; 95% confidence interval [95% CI], 3.7%

47 were randomized to receive one of two blood flow rates: 150 or 250 mL/min.

48 At 24 months, measured maximum urine flow rate (16.3 mL/s from a volume voided of 109 mL) and

49 h high column temperature (55 degrees C) and flow rate (2.5 mL min(-1)).

50 In vitro, a single equation, flow rate = 3.75 x 10(-6) x DeltaV((-9.568+1.088 Vi)) pr

51 time of strong anion-exchange (2 mm column, flow rate 380 muL min(-1), injection volume 5 muL) could

52 The system features high flow rates, 5-30 muL/min plasma collection, with minimal

53 utologous blood via the portal vein at three flow rates (60, 80, 100 mL/min per 100 g of liver) was u

54 : a potential for long sampling time, a high flow rate, a high sampling and retention efficiency, low

55 ome investigated patterns of lead release by flow rate-all water samples contained lead above 15 mug/

56 ary glands on diagnostic scans correlates to flow rate alterations.

57 The experimental parameters (pH, flow rates, amounts of the modified silica gel, concentr

58 ial infarct size was increased, and coronary flow rate and +/- dP/dt were decreased during reperfusio

59 ned to be 100 degrees C temperature,15mL/min flow rate and 120min extraction time.

60 rs, 40 degrees C, 25% (w/w) ethanol, 1mL/min flow rate and 30min extraction time, with an extraction

61 rs, 60 degrees C, 25% (w/w) ethanol, 3mL/min flow rate and 30min for xanthophylls (all-trans-lutein,

62 NMD associated with greater 6-week AVF blood flow rate and AVF diameter (per absolute 10% difference

63 d with greater increases in 6-week AVF blood flow rate and AVF diameter (per absolute 10% difference

64 anges result in significantly reduced saliva flow rate and buffering capacity and increased mucus aci

65 decreased infarct size and improved coronary flow rate and cardiac function in both C57BLKS/J and db/

66 ressure, temperatures, particle size, SC-CO2 flow rate and co-solvent, on SC-CO2 extraction are inves

67 lar (i.e., parotid and submandibular) saliva flow rate and composition alterations, development of xe

68 Parallel on-site measurements of flare gas flow rate and composition were successfully performed at

69 files for PBUTs and the effects of dialysate flow rate and dialyzer size on PBUT removal.

70 associated with changes in 6-week AVF blood flow rate and diameter, suggesting that native functiona

71 ationships with both postoperative AVF blood flow rate and diameter.

72 Due to the high flow rate and different inlets, TAPI data were systemati

73 sequences applied to the MSPD cartridge, the flow rate and dilution of extract used for SPE loading.

74 ys operate in several modes depending on the flow rate and electric potential.

75 ility and process variability including mass flow rate and feed frame paddle speed.

76 es for seeking the fine balance between high flow rate and low electroporation voltage were steered c

77 selectivity is to carefully control the feed-flow rate and maintain one to two monolayers of water (a

78 uring LV developed pressure (LVDP), coronary flow rate and oxygen consumption in LANG and LWHs.

79 ctional information from scans such as blood flow rate and oxygen consumption provides new perspectiv

80 e error in Rh depends solely on the detector flow rate and particle size but not on the type of the s

81 Flow rate and perfusion pressure were reproducible withi

82 hat controls hydrogeological sustainability, flow rate and preferred flow direction in these systems.

83 thout consideration of flow conditions) and; flow rate and pressure drop.

84 ip between allowable range of drilling fluid flow rate and rated flow rate of drilling pump (Q r ).

85 , concentration and volume of eluent, sample flow rate and sample volume was examined using batch pro

86 Depending on the flow rate and the frequency of contractions, the bacteri

87 nd after the heat pulse, depends both on the flow rate and the surrounding temperature.

88 work provides a physical basis by which the flow rate and the voltage can be chosen for any nanosusp

89 VFT to ultrasound measurements of AVF blood flow rate and venous diameter at 1 day, 2 weeks, and 6 w

90 One-day and 2-week AVF flow rates and diameters were used to predict 6-week lev

91 ylene blue and methyl orange under different flow rates and different pH values by detecting the inte

92 is is due to the complementary nature of cLC flow rates and electrospray or nanospray ionization mass

93 The new system was operated at varied biogas flow rates and external applied voltages.

94 dchips were subjected to a range of measured flow rates and influent nitrate concentrations with an a

95 pressure increased with increasing irrigant flow rates and insertion depths of a 30-gauge side-venti

96 periapical fluid pressure at different fluid flow rates and insertion depths.

97 t ions was observed with relatively high gas flow rates and low discharge currents.

98 stream, revealing complex relations between flow rates and phosphate concentration that suggest chan

99 used in all mobile phase modes and with high flow rates and pressures to separate over 60 pairs of en

100 le setups where lead release under different flow rates and water chemistry scenarios was reported.

101 short time frames because they require slow flow rates and/or they are unable to handle milliliter-s

102 hanges were needed to adapt the incompatible flow-rates and a reverse-engineering approach that led t

103 ess (mobile phase pH, column temperature and flow rate) and stability (high temperatures and storage;

104 AF4 cross-flow rate, 1.5 mL/min AF4 channel flow rate, and 5 ms spICPMS dwell time, the AF4-spICPMS

105 However, proper choice of column, flow rate, and buffers enabled robust and automated puri

106 ulation was found to increase with decreased flow rate, and can be completely suppressed by the appli

107 desolvation-gas temperature, sample infusion flow rate, and cone voltage.

108 optimize sample dilution, rinsing protocol, flow rate, and pore size, leading to >80% for the recove

109 ls are symmetric in terms of radius, length, flow rate, and pressure.

110 imes are obtained by decreasing the solution flow rate, and reaction times between 1.0 and 22 mus are

111 age, auxiliary helium flow rate, carrier gas flow rate, and temperature was also systematically inves

112 riables such as loading mass, concentration, flow rate, and up-scaling on the extraction selectivity

113 tion, standardizing or adjusting for urinary flow rate, and using covariate-adjusted standardization

114 ation by urinary creatinine, osmolality, and flow rates, and inclusion of these metrics as independen

115 rticles and by varying the applied voltages, flow rates, and the width ratios of the droplet splittin

116 evice flexibility in terms of sampling time, flow-rate, and iHWG design facilitates tailoring the dev

117 (e.g., discharge/carrier gas composition and flow rate, applied voltage) on the analysis of model aro

118 ion cell ( approximately 20 muL) at moderate flow rates ( approximately 0.5 mL min(-1)), where a shor

119 IA system capable of operating at a range of flow rates ( approximately 50 nL/min to 500 muL/min) to

120 ew as approximately 10 molecules of DNA with flow rates as high as 1 mL/min, handling samples as larg

121 Use of the 3D serpentine column at a higher flow rate, as compared to the 3D spiral column, provided

122 he effects of diminished kinesin velocity on flow rates, as well as prior observations on f-actin per

123 d with 10-fold slower local actin retrograde flow rates, as well as spatial homogenization of actin-b

124 network counteracts the decrease in solution flow rate associated with increasing viscosity within th

125 AVF blood flow rate at 1 day is usually more than 50% of the 6-wee

126 (Rh) only at the lowest investigated passage flow rate at the detector (0.2 mL/min).

127 A mismatch in the electroosmotic flow rate at this junction led to the generation of pres

128 128) maintained at least 85% of their week 2 flow rate at week 6.

129 or Erectile Function [IIEF] score) and urine flow rates at 24 months post transplant.

130 Using Flow/Volume Simulator, when setting flow rates at 6, 30, 60, 90, and 120L/min, we read off s

131 a novel proof-of-concept approach to measure flow rates at the tip of electrospray emitters when the

132 riability approach were applied to the daily flow rates at the two representative hydrological statio

133 esistances by calculation (=suction pressure/flow rate) at each flow rate.

134 stream temperature, nutrient load, gradient, flow rate) at regional and global scales before reliable

135 ate is sensitive only to changes in vascular flow rate; based on this technique, blood flow was not s

136 ty in the selection of column dimensions and flow rates because the two dimensions constrain each oth

137 from individual microbubbles in vessels with flow rates below 2 mm/s.

138 At very low flow rates below 50 nL.min(-1) very sharp, pulled nanosp

139 The sensor behavior is reported for flow rates between 0-52.5 mL/h at 32-39 degrees C, adequ

140 es between 1.0 and 22 mus are obtained using flow rates between 48 and 2880 pL/s, respectively.

141 ronchopulmonary dysplasia, the difference in flow rates between groups diminished.

142 ean aggregate size was apparent in the lower flow rate branches.

143 migration, morphology and F-actin retrograde flow rate can be shifted to lower stiffness by simultane

144 the cells and the ridges ensure that a high flow rate can be used without lift forces quenching adhe

145 erformance on bias voltage, auxiliary helium flow rate, carrier gas flow rate, and temperature was al

146 meters, including blockage ratio, volumetric flow rate, cell concentration, and polymer chain length.

147 diagnostic scans was correlated with saliva flow rate changes after radioiodine treatment.

148 the resulting analytes at a slightly higher flow rate compared to the feeding capillary.

149 Alterations in salivary flow rate, composition, and xerostomia inventory score w

150 Stimulated whole saliva flow rate decreased after ablation therapy (from 0.92 [i

151 n injections, the injectivity was decreased (flow rate decreased from 1.9 to 0.47 L/min) and a reduct

152 The same flow-rate dependence of ADAMTS13 activity we also observ

153 tionship is comparable to other systems, the flow rate dependency has not been previously demonstrate

154 ic, non-Fickian transport is saturation- and flow-rate-dependent.

155 a liquid nebulization (LN) with online, high-flow-rate dilution (with dilution factors up to 10000) i

156 monopolar RF ablation, change in portal vein flow rates does not have a statistically significant eff

157 ch increased the ratio of the end-expiratory flow rate (EEFR) to the peak expiratory flow rate (PEFR;

158 We couple 163 well measurements of methane flow rates; ethane, propane, and n-butane concentrations

159 ng the effects of CO2 temperature, pressure, flow rate, ethanol percentage and extraction time was se

160 were the nebulization gas flow rate, liquid flow rate, extraction time, acid concentration, nebulize

161 The root-mean-square of flow rate fluctuations could be an order of magnitude hi

162 stration of increased efficiencies at higher flow rates for specific separations, and

163 SHM designs under a wide range of volumetric flow rates for two analytes: high diffusivity ssDNA and

164 In terms of flow rates, for a given particle size, the higher the fl

165 o (percent predicted), and forced expiratory flow rate from 25% to 75% of expired volume (percent pre

166 t chromatographic resolution at mobile phase flow rates from 1 to 55 muL min(-1).

167 to ESI for all drugs and peptides tested at flow rates from 15 to 55 muL min(-1).

168 Pumping flow rates from 5.3 to 40 microL min(-1) under different

169 l indices, unstimulated whole-mouth salivary flow rate, gingival crevicular fluid biomarkers).

170 ion of higher silicon temperature and oxygen flow rate gives rise to the formation of black silicon w

171 induces steady-state maximal hyperemia at a flow rate >/=15 mL/min.

172 proportion of aqueous/organic phase, pH and flow rates have been carefully evaluated.

173 vant frequencies and pressures and attains a flow rate higher than all previously reported soft pumps

174 s that derive from (i) abrupt changes in the flow rate, (ii) instability of signal acquisition and (i

175 We characterize a high-flow-rate impinger with respect to particle collection a

176 trace pollutant concentrations, and the high flow rates impose challenges for micropollutant biodegra

177 ations suggest that an increase in dialysate flow rate improves the reduction ratio (and removal) of

178 The average flow rate in July, the 30-day annual maximum flow rates,

179 e have previously been used to measure fluid flow rate in microfluidic channels.

180 ns resulting in reductions in hematocrit and flow rate in the daughter and mother vessels.

181 These adaptations resulted in hindlimb blood flow rates in IUGR that were similar to control fetuses

182 nt in the newborn period improves expiratory flow rates in midchildhood, which seems to be achieved b

183 nanoconfinement and the resulting minuscule flow rates in such systems.

184 and myosin localization drive actin network flow rates in the prospective cell rear above a critical

185 to continuously monitor xylem cavitation and flow rates in the stem of an intact vine during 10 d of

186 es were supported by a heated repeller using flow rates in the upper nL min(-1) range.

187 L h2 keeps decreasing as the drilling fluid flow rate increases.

188 Above this threshold, high actin flow rates induce a nonlinear switch in adhesion strengt

189 To determine whether blood flow rate influences circuit life in continuous renal re

190 This corresponds to a vertical flow rate into the aquifer of 19 m/year.

191 d p-cresyl glucuronide, an increase in blood flow rate is advantageous.

192 For retained compounds, the optimal flow rate is found to be on the order of 0.4 mL/min, ach

193 f particulate materials often weakens as the flow rate is increased, leading to potentially disastrou

194 ability, ultrasound imaging of microvascular flow rate is sensitive only to changes in vascular flow

195 eous pressure to be generated when the fluid flow rate is sufficiently high and when the needle tip i

196 e extraction yield were the nebulization gas flow rate, liquid flow rate, extraction time, acid conce

197 Effects of such parameters as flow rate, loading time, volume in the insert well, and

198 dissolved lead by 19%, while sampling at low flow rates (<5.2 LPM) was found to consistently suppress

199 ased in the daughter branches for a range of flow rates, mainly due to the lower shear conditions and

200 Melbourne at 11 years of age had expiratory flow rates measured according to the standards of the Am

201 6 weeks, at least 50% of their 6-week blood flow rate measurement was achieved at 1 day.

202 crochannel, enhances the sensitivity of this flow rate measurement.

203 ile phase of H2SO4 0.005 mol L(-1) solution, flow rate of 0.3 mL min(-1) and column temperature of 35

204 water without salt, adjusted pH of 5.4 and a flow rate of 0.36mL/min.

205 nium formate in water and acetonitrile, at a flow rate of 0.5 mL/min.

206 consisted of water and acetonitrile, with a flow rate of 0.5mL/min in gradient elution mode.

207 mn (5.0 mum, 4.6 x 150 mm), at 30 degrees C, flow rate of 0.8 mL min(-1) and detection at 285 nm.

208 nitrile, a temperature of 35 degrees C and a flow rate of 0.8 mL min(-1).

209 the same test conditions (25 degrees C, air flow rate of 1 cm(3) min(-1)).

210 nalyte feeding rate (i.e., a sample solution flow rate of 1.0-75.0 muL min(-1)).

211 pid response (up to approximately 60 ms at a flow rate of 1.5 mL/min), quick warm-up time ( approxima

212 the two species examined and at a 2-propanol flow rate of 160 muL/h, MPA demonstrated the greatest sh

213 .2% at the external voltage of 1.2 V and gas flow rate of 19.6 mL/h.

214 A flow rate of 3.0mLmin(-1) was selected as optimum for al

215 Argon, at a flow rate of 60 mL min(-1), was the best DBD discharge g

216 To maintain flow rate of 60L/min, suction pressure of around 20-cmH2

217 affect previous estimates of the volumetric flow rate of dead oil from the emission source.

218 range of drilling fluid flow rate and rated flow rate of drilling pump (Q r ).

219 This contrasts with the constant flow rate of dry granular hoppers and the decreasing flo

220 The frequency of breathing and peak flow rate of exhaled air are necessary parameters to det

221 e of dry granular hoppers and the decreasing flow rate of pure liquids.

222 h could easily follow the frequency and peak flow rate of the human breathing.

223 -cut volume, head-cut volume, pH and cooling flow rate of the internal partial condenser during the h

224 ct of applied voltage, signal frequency, and flow rate of the sample on the cell capture efficiency.

225 ards, we obtain analysis rates of 100K/s and flow rates of 10 mL/min, while maintaining optical perfo

226 ored solutions under different angles and at flow rates of 25, 50, and 100 muL/min.

227 fference in circuit life whether using blood flow rates of 250 or 150 mL/min during continuous renal

228 nomically feasible bioprocess produced molar flow rates of 4550 mol per day from MES and AF independe

229 Repeat measurements over 2 years show that flow rates of high emitters are sustained through time.

230 ters such as pH, eluent type and its volume, flow rates of sample solution, ligand amount, sample vol

231 tunately, bigger frit pores result in larger flow rates of the reference solution through the pores,

232 solution, type and concentration of eluent, flow rates of the sample and eluent, volume of the sampl

233 ilm and a protein were elucidated at various flow rates of those molecules.

234 ges for the electrode channels even at harsh flow rates of up to 40.0 mL min(-1).

235 The effects of the flow rate on the extraction selectivity of the sorbent w

236 estigate the effect of change in portal vein flow rates on the size and shape of ablations created by

237 utcomes, alternative metrics such as urinary flow rate or analytic strategies such as covariate-adjus

238 ased by almost 90% irrespective of the fluid flow rate or needle insertion depth.

239 nerally increase with increasing carrier gas flow rates or lower gas temperature of the ICP.

240 et size and generation frequency rather than flow rates or pressures.

241 eated by the bipolar device at the different flow rates (P > .05 for all outcomes).

242 unstimulated whole- and stimulated glandular flow rates (P < 0.05).

243 tory flow rate (EEFR) to the peak expiratory flow rate (PEFR; from 10% to 25% to 50% to 75%).

244 cts of the allowable range of drilling fluid flow rate (Q min </= Q </= Q max ) were not considered.

245 yzed by histopathological assessment, saliva flow rate, quantitative PCR, Western blot analyses and i

246 measures more accurate than those of 1 day (flow rates, R(2) = 0.47 and 0.61, respectively; diameter

247 ranes), it is only obtained at a very narrow flow rate range due to the high pressure drops at small

248 high net power densities over a much broader flow rate range.

249 umes are approximately 150 and 250 nL, while flow rates ranging from 0.5 muL/min to 15 muL/min have b

250 t processing up to 120muL of DNA dilution at flow rates ranging from 1 to 5muL/min without compromisi

251 , nano-ESI is typically done at capillary LC flow rates ranging from 200 to 300 nL/min.

252 e the hydrodynamic focusing as a function of flow rate ratio of the microfluidic chamber inlets.

253 flow rate, which is 2000-times less than the flow rate required to obtained the 8 mus reaction time u

254 In contrast, an increase in the fluid flow rate results in an increase in the microchannel cro

255 sence of a physiologically relevant shearing flow rate results in very different size and shape-depen

256 inuous renal replacement therapy using blood flow rate set at 250 mL/min was not more likely to cause

257 and 0.1 cell/mL were analyzed in 30 mL with flow rates set to 10 mL/min and frame rates of 4 fps (fr

258 ith a "wide" high throughput flow cell (e.g. flow rates set to 10 mL/min) in contrast to the conventi

259 Relatively large flow tube enables high flow rate, simple flow characterization and low shear fo

260 eration of the microfluidic device including flow rate, solution exchange rate in a microchamber, she

261 ere used to investigate the influence of air flow rates, stove geometry, fuel type, and operating mod

262 action conditions in terms of concentration, flow rate, temperature, and embedded particle amount as

263 configuration, precursor and dispersion gas flow rates, temperature and concentration fields) on the

264 times faster than SFE when using the highest flow rate tested, 3 mL/min.

265 of 80% and 100%, respectively, at all biogas flow rates tested.

266 s, for a given particle size, the higher the flow rate, the higher the M-value.

267 flow rate in July, the 30-day annual maximum flow rates, the date for the maximum rate, the rise rate

268 Here we show that the pressure-driven flow rate through individual nanotubes can be determined

269 with decreased DNA length and with increased flow rate through the ES capillary.

270 The resultant ion distributions lead to the flow rate to be directional-dependent, indicating that t

271 At these flow rates, trouble shooting and leak detection of LC sy

272 Effects of pH value, flow rates, type, concentration and volume of the eluent

273 fected both by exposure level and by urinary flow rate (UFR).

274 Using short efficient columns and high flow rates (up to 19 mL/min), separations on the order o

275 Moreover, the relatively high flow rates used for the second dimension make direct (sp

276 e collected, and unstimulated whole salivary flow rate (UWSFR) was determined.

277 iments that FCS can sensitively quantify the flow-rates, variability, and content of rapidly passing

278 ustments did not fully address the effect of flow rate variations.

279 parameters and the LS and the spray solution flow rates was tested in in-line LS DESI MS.

280 .6 au/sec +/- 0.6, and mean changes in renal flow rate were 2.1 mL/min/g +/- 0.2 versus 1.9 mL/min/g

281 AVF draining vein diameter and blood flow rate were assessed postoperatively after 1 day, 2 w

282 Sex and peak expiratory flow rate were associated with retinal thickness in the

283 solution composition, and modifier solution flow rate were carefully optimized.

284 Alterations in saliva flow rate were not associated with semiquantitatively as

285 mpling end of the probe, and carrier solvent flow rate were optimized for maximum signal.

286 uence, laser beam scan rate, and carrier gas flow rate were optimized in order to gain the highest Au

287 ient composition of the mobile phase and the flow rate were optimized with respect to the resolution

288 enal parenchymal perfusion, and renal artery flow rates were measured for MR-guided and x-ray-guided

289 parameters (radio frequency power and argon flow rates) were optimized.

290 ast reaction time is obtained with a 48 pL/s flow rate, which is 2000-times less than the flow rate r

291 t force comes into effect at relatively high flow rates, which appears to reduce the separation effic

292 eals the optimum ranges of applied power and flow rates, which ensure the proper position of ion clou

293 ecreases with the increase in drilling fluid flow rate, while L h2 keeps decreasing as the drilling f

294 ll phloem concentrations and weak scaling of flow rates with hydraulic resistance.

295 For flow rates with low Reynolds number, the mode changes to

296 hrough packed glass beads under two relative flow rates with Na2CO3 and CaCl2 in the inner and outer

297 +1.088 Vi)) provided good prediction for the flow rate, with 6.3% RMS relative error.

298 le with the traditional methods of measuring flow rates, with the potential advantages of being fully

299 een adopted involving sampling at different: flow rate (without consideration of flow conditions, e.g

300 nts (60-76%), inversely correlated to biogas flow rates, would allow the production of approximately