Low Differential Pressure Research Articles

2C21 Development of secondary suspension for improvement of wheel load variation (Part1)(Safety-Vehicle)

When railway vehicles run at exit transition curve, track twist produce wheel load variation. Especially if vehicle has air suspension, behavior of leveling valve increases diagonal differential pressure (Twist component of unbalance of air suspension pressure). Increase of wheel load variation makes margin of tight curve passing safety small. In order to improve running safety, reducing wheel load variation is very important. In this paper, authors have developed newly secondary suspension "connecting of front and rear air springs" for reducing wheel load variation in transition curve. This valve system can flow small amount of air at low differential pressure and flow large amount of air at high differential pressure. The developed air suspension system has evaluated with trial running in the test line. The test data show diagonal differential pressure is improved proximately 40%.

Pulsation effect on thrombus in a bifurcation pipe by the lattice Boltzmann method

Thrombosis caused by all kinds of cardiovascular diseases, has been influencing people's health. In a blocked blood vessel, pulsation flows have a positive effect on thrombus. Because of the blood viscosity and the inertias of red blood cells and the fluid, the frequency of pulsation flow influences the effect of dredge blood clots. Under the condition of low differential pressure, conduction of the another flow pipe reducing the pressure variation causes the effect of dredging blood clots not to be ideal in the bifurcated pipe model. So we will increase the differential pressure and improve the amplitude of pulsation flow, reduce the influence of the conduction effect of expedite tube, then study the effect of dredge blood clots which is caused by the pulsation flow in the bifurcated pipe. We find that low frequency pulsation flow has a good effect on dredge blood clots for a long time. Relatively, high frequency pulsation flow needs less time, but the effect of dredge blood clots is not obvious if the frequency is higher than a certain value. The friction between cells and the walls of the tube also has an effect on dredge blood clots.

Enhanced Sand-Control System Successfully Treats Six Zones in Offshore Indonesia Well

This article, written by JPT Technology Editor Chris Carpenter, contains highlights of paper OTC 24879, ’Enhanced Multizone Single-Trip Sand-Control System Successfully Treats Six Zones in Offshore Indonesia Well,’ by Leon Zhou and Indra Gunawan, ConocoPhillips, and Ricki Jannise, Casey Suire, and Tyson Eiman, Halliburton, prepared for the 2014 Offshore Technology Conference Asia, Kuala Lumpur, 25-28 March. The paper has not been peer reviewed. Although multiple-zone, downhole sand-control-tool systems have been in use since the early 1990s, these systems have been designed for jobs that require only low pump rates with low pressure differentials. Multiple-zone systems capable of high fracturing pump rates and the associated differentials only recently have been introduced to the oil field, but most of these completions have been limited to four or five treated zones. This paper presents a case history from Indonesia in which six discrete zones in an offshore deployment were treated successfully in a single trip. Field History The Bawal field is located in Block B, 1000 km north of Jakarta, in the South China Sea. The average water depth across the field is 280 ft. The Bawal field was discovered in 1979; the field is approximately 5 km long and 2 km wide. The Bawal reservoirs consist of subangular-to- rounded, well-sorted silt to extremely fine quartz sand. The initial development concept was to drill and complete two to three subsea wells and tie them back to a nearby production facility, Hangtuah, 43 km away. The first-gas-production target was 2012. The reservoirs all require sand control, varying degrees of stimulation, high-rate water packing at rates of 8 to 20 bbl/min, and fracture treatments at rates of 22 to 35 bbl/min. The operator has completed multiple fields with two dominant completion methods: openhole standalone screen (OHSAS) and cased-hole frac pack (CHFP). The OHSAS completions typically are installed in horizontal wells or very-high-angle wells. The OHSAS requires special reservoir-drill-in fluid with calcium carbonate to drill the reservoir section, run the premium screen, wash the pipe, and conduct mudcake cleanout. Typically, a CHFP is conducted with tubing- conveyed perforation and alternative- flow-path sand screen being run in one trip; then, a frac pack is pumped with viscoelastic fracturing fluid. Historically, the operator has completed subsea wells with downhole sand control using the OHSAS method for single- zone completions and singletrip frac-pack/high-rate water packs for multizone commingled production. For frac-pack completions, the completion system used previously was capable of treating only up to three zones; therefore, the treatment rate per zone became lower, and there was always an issue with slurry distribution. If more than two to three zones were required per well, a stacked frac-pack completion was implemented. Completing these wells with conventional stacked sand-control methods meant spending many rig days tripping pipe in and out of each well. The single-trip multizone methods previously used in the area typically would provide only a limited pump rate of up to 10 bbl/min per zone and pressure ratings of 6,000 psi. For the new wells, the fracture treatments would require a more-robust system that would include a pressure rating of 10,000 psi because of sandout conditions. Another challenge was that commingling these zones into one well has historically resulted in 50% less recovery compared with single-zone completions. Early water breakthrough coming in from one of the zones would cause the well to load up and die. Therefore, the operator also wanted to include installation of an intelligent-completion system that would allow zonal isolation without intervention, to optimize reserves recovery. The multizone frac-pack completion not only would have to be capable of completing up to six zones in one run but also would have to be compatible with the planned intelligent-system equipment.

Laboratory measurements of low- and high-frequency elastic moduli in Fontainebleau sandstone

The presence of pores and cracks in rocks causes the fluid-saturated wave velocities in rocks to be dependent on frequency. New measurements of the bulk modulus at low frequencies (0.02–0.1 Hz) were obtained in the laboratory using oscillation tests carried out on two hydrostatically stressed Fontainebleau sandstone samples, in conjunction with ultrasonic velocities and static measurements, under a range of differential pressures (10–95 MPa), and with three different pore fluids (argon, glycerin, and water). For the 13% and 4% porosity samples, under glycerin- and water-saturated conditions, the low-frequency bulk modulus at 0.02 Hz matched well the low-frequency and ultrasonic dry bulk modulus. The glycerin- and water-saturated samples were much more compliant at low frequencies than at high frequencies. The measured bulk moduli of the tested rocks at low frequencies (0.02–0.1 Hz) were much lower than the values predicted by the Gassmann equation. The frequency dispersion of the P and S velocities was much higher at low differential pressures than at high pressures, due to the presence of open cracks at low differential pressures.

High-Reliability Gas Lift Flow-Control-Device Technology and Erosion/Endurance Tests

This article, written by JPT Technology Editor Chris Carpenter, contains highlights of paper SPE 159848, ’High-Reliability Gas Lift Flow-Control-Device Technology and Erosion/Endurance Tests,’ by Jun Xu, Stuart L. Scott, SPE, and Wayne Mabry, SPE, Shell E&P, and Jose Gamboa, SPE, The University of Tulsa, prepared for the 2012 SPE Annual Technical Conference and Exhibition, San Antonio, Texas, USA, 8-10 October. The paper has not been peer reviewed. High-reliability gas lift flow-control devices (GLFCDs) enable gas lift for wells with the potential for H2S in the produced gas and where casing is not qualified for H2S service. Valve specifications are such that no leakage is allowed at both high (8,000-psi) and low (1-psi) differential pressures across the valve. A series of tests was designed using the environmental-stress-screen (ESS) concept and a harsh test standard that greatly exceeds API specifications for GLFCDs. Introduction GLFCDs are usually incorporated into the production conduit and used to inject high-pressure natural gas from the injection conduit to the interior of the production conduit. Commercially available GLFCDs typically contain one-way check systems comprising a ball, hemisphere, or cone, which is pressed against a valve-seating ring by a spring. Unfortunately, many GLFCDs are prone to wear and damage because of fluid cut during the operation. Some of Shell’s Gulf of Mexico deepwater wells commonly produce sour fluids, which the casing program was not designed to tolerate. When sour production enters casing that is not qualified to National Association of Corrosion Engineers standards, the wells cannot be produced. Therefore, a family of high-reliability GLFCDs has been developed for use in deepwater/subsea associations. This technology is viable for any gas lift well because of significant cost savings in change-out of GLFCDs and the ability to maintain well integrity. Fig. 1 presents schematics of the GLFCD through which liquids are unloaded from the casing annulus into the tubing, while Fig. 2 details several types of high-reliability GLFCDs. High-Reliability-GLFCD Design Validation and Qualification Procedures A series of design validation and qualification tests has been established and executed to determine whether high-reliability GLFCDs meet the acceptance criteria of API or ISO standards and Shell specifications and qualifications. Shell’s test program for these GLFCDs comprises three parts: factory acceptance, qualification, and endurance. Every individual GLFCD that has passed all factory-acceptance tests would be deemed accepted for installation and service. If the prototype of a GLFCD has passed Shell tests, it is deemed qualified to be a high-reliability GLFCD. Currently, three gas lift manufacturers have developed GLFCDs and products that have been tested using Shell’s test program; these test results are described in the following sections.

제연구역 출입문의 최적 설계를 위한 도어클로저의 기준 산정에 관한 연구

본 연구의 목적은 제연구역 출입문의 최적 설계를 위한 플로어힌지(floor-hinge) 및 도어클로저(door closer)의 기준을 제시하는데 있다. 차압에 대한 개방력은 60 Pa일 때 60.75 N, 40 Pa일 때 40.5 N, 32.5 Pa일 때 32.91 N, 12.5 Pa일 때 12.66 N 등이다. KS F 2806의 기준을 적용한 플로어힌지 및 도어클로저의 개방력은 No.1은 27.5 N, No. 2는 40 N, No. 3는 75 N, No. 4는 100 N, No. 5는 125 N 등이다. 차압과 플로어힌지 및 도어클로저의 개방력을 NFSC 501A의 개방력 제한값과 비교한 결과 기준을 초과하는 것으로 확인되었다. 따라서 NFSC 501A 차압과 방연 풍속을 설계에 반영하는 것뿐만 아니라 개방력도 설계에 반영할 필요가 있다. 제연댐퍼의 종류에 따라 출입문의 플로어힌지 및 도어클로저의 설치 조건은 호칭에 따라 다르다. 저차압용의 경우는 No. 1, No. 2, No. 3의 설치가 가능하며, 일반 차압용의 경우에는 No. 1, No. 2의 설치가 가능하였다. The purpose of this study is to assess the criteria on a floor hinge and door closer for the optimum design of the access door of a smoke control room. The door opening force due to differential pressure is 60.75 N, 40.5 N, 32.91 N and 12.66 N when the differential pressure is 60 Pa, 40 Pa, 32.5 Pa and 12.5 Pa, respectively. The door opening force of the floor hinge and door closer to which the criteria of KS F 2806 are applied is 27.5 N, 40 N, 75 N, 100 N and 125 N for the Nos. 1, 2, 3, 4 and 5 class floor hinges and door closers, respectively. This study compared the differential pressure and opening force limits of floor hinges and door closers with the values specified in NFSC 501A and found that they exceeded the criteria specified in NFSC 501A. Therefore, it is necessary to reflect the differential pressure and smoke control wind speeds as well as the opening forces specified in NFSC 501A on the design of floor hinges and door closers. The installation conditions of floor hinges and door closers of access doors differ depending on the type and name of a smoke control damper. This study found that Nos. 1, 2 and 3 floor hinges and door closers could be installed for access doors with low differential pressure and that Nos. 1 and 2 floor hinges and door closers could be installed for access doors with normal differential pressure.

Development and Application of Metering Instrument for Well-Head Metering in Block 75 of Sulige Gas Field

Along with large scale application of cluster wells in Sulige gas field, the common low pressure flow meter can not be used in metering single well production with connecting wells in series. For this reason, we have developed a flow metering instrument of natural gas, which has the features of high static pressure, low differential pressure and high precision. Installed at the high pressure end of gas production wellhead, the instrument can bear 40Mpa static high pressure and has the features such as low pressure loss, broad measuring range, small temperature drift, high precision, long service life, solid, low cost and so on. With required measurement accuracy and resistance to pressure, which have been verified by the wide application, the instrument gave a solution to metering single well production of cluster wells.

A Numerical Study of the Flow and Pollutant Dispersion in Valley-River Urban

Air flow and pollutant dispersion characteristics in a real valley city are studied under the real boundary condition. The 3D computational fluid dynamics using Reynolds-averaged Navier-Stokes modeling was carried out in Lanzhou which is a typical valley city in Northwest, China. The standard κ­-ε turbulence model as a simplified computational fluid dynamics model is used to provide moderately fast simulations of turbulent airflow in an urban environment. The modeled flow field indicated that the geometry, wind direction and source location had a significant effects on the flow field. The flow shows the funnelling is rather obvious when the wind flow through the narrow area in the middle of the city. It is obvious that in the high-altitude region, due to the impact of high and low differential pressure and terrain, SO2 and NO2 formed two cyclic concentration field in the dispersion process.

Pioneering demineralized and desalinated water cost reduction with innovative brackish water RO membrane technology

Breakthrough reverse osmosis (RO) membrane chemistry and innovative materials of construction have been developed to achieve highest possible NaCl rejection while maintaining maximum element productivity. Novel brackish water reverse osmosis (BWRO) membrane element delivers to end users state-of-the-art salt rejection (99.7%) at 30% lower energy consumption compared to current high rejection BWRO membranes in addition to tailored salt passage reduction of critical solutes as nitrate, boron, silica, and ammonium. The novel module component, low differential pressure (LDP) feed spacers, provide end users with up to 15% savings in direct RO energy reductions via the lowest feed-side pressure drop available in the market. The LDP spacer outperforms other spacers by reducing pressure drop while maintaining high active area and a unique BWRO element with productivity up to 14,000 gallons per day has been achieved. A financial analysis was carried out with a refined cost model using different economic frame conditions. It shows RO plant energy costs can be reduced by up to 30% in industrial applications without compromising the product water quality. In SWRO application, the size of the BWRO pass can be reduced by 19%, resulting in an overall water cost reduction of 0.53 UScts/m3 produced water.

Hot-Wire Calibration at Low Velocities: Revisiting the Vortex Shedding Method

The necessity to calibrate hot-wire probes against a known velocity causes problems at low velocities, due to the inherent inaccuracy of pressure transducers at low differential pressures. The vortex shedding calibration method is in this respect a recommended technique to obtain calibration data at low velocities, due to its simplicity and accuracy. However, it has mainly been applied in a low and narrow Reynolds number range known as the laminar vortex shedding regime. Here, on the other hand, we propose to utilize the irregular vortex shedding regime and show where the probe needs to be placed with respect to the cylinder in order to obtain unambiguous calibration data.

Penetration of fine particles through rough cracks

Many building materials have random roughness protrusion scales of up to hundreds of micrometers. A scaled down experimental facility was designed to investigate fine particles' penetration through a straight, smooth and rough crack under four different pressures ranging from 2 to 8 Pa. Sandpapers with three different roughness scales were used to create 10 to 100 micron rough surfaces. Particle concentration for sizes ranging from 20 to 500 nm was measured to determine the penetration. Contrary to expectations, the results are not sensitive to roughness scales. Besides, it is also noticed that under low differential pressure scenario, deposition for rough cracks for small particles is higher than that of smooth crack which will offer better protection for indoor exposure. A simple mathematical model was also developed to predict particle deposition on rough surfaces by diffusion mechanism on extended surfaces. The experimental results match well with the model prediction.

SO2 crossover flux of Nafion® and sFS-PBI membranes using a chronocoulometric (CC) monitoring technique

Abstract A chronocoulometric electrochemical measuring technique was used to evaluate the gas flux and permeation properties of sulphuric acid dissolved SO2 across various polymeric membranes, using an in-house assembled permeation setup. This was done in the temperature and differential pressure range of 298–353 K and 0–2 bar respectively. The sulphuric acid concentration was varied between 30 and 90 wt%. The electrochemically measured current due to SO2 oxidation at the platinum electrode was converted to molar gas flux using Faraday's law. The flux was found to decrease as the temperature increased for all the evaluated membranes for example from 2.16×10−8±0.15 mol s−1 cm−2 at 298 K to 1.46×10−8±0.15 mol s−1 cm−2 at 353 K for Nafion® 112. The flux was found to increase with increasing Δp across the membrane and decrease with increasing acid concentration. From the flux data we were able to calculate the SO2 permeation, diffusion and solubility parameters for the various membranes.The measured and calculated values were compared to existing literature values. The lowest SO2 crossover was observed at high temperatures, low differential pressures and high H2SO4 concentrations.

Stability of Lobed Superpressure Balloons During Ascent

It is known from large-scale experiments that the successful deployment of lobed superpressure balloons can depend on the used gas. Some balloons deployed properly during an inflation with air but failed to reach the desired equilibrium configuration for helium. Furthermore, depending on the desired flight altitude, a helium-filled balloon might or might not deploy properly. This paper investigates this phenomenon by studying the stability of lobed superpressure balloons during ascent. It is shown that wrinkles increasingly reduce the stiffness of balloons for a decreasing gas density and an increasing flight altitude such that clefts can develop at very low differential pressures in nearly fully inflated balloons.

Numerical Analysis of Flow through a Hole for Modeling of Wind Tunnel Porous Wall

To model porous walls used in transonic wind tunnels, flow through a hole is investigated using Computational Fluid Dynamics (CFD). First, we analyze the relation between flow rate and differential pressure across the hole. At low differential pressures, such as for wind tunnel porous walls, the flow rate is found to increase linearly with differential pressure. We therefore propose a new model based on a linear relationship between flow rate and differential pressure. The effects of hole shape and boundary layer conditions near the hole are then investigated. In the outflow case (i.e., wind tunnel to plenum chamber), the flow rate increases as the ratio of hole depth to diameter becomes large due to variation of the flow separation area at the hole exit. Boundary layer thickness also affects the flow field: when the ratio of boundary layer thickness to hole diameter becomes small, the flow rate decreases, because the flow along wind tunnel side wall interacts more strongly with the flow through the hole.

Complementary products and devices

The design of a contactless seal for use in collars of pump impellers of high-speed units is described. A cup with an unconventional scheme of loading and deforming (straining) of the cup body has been used in the design of the seal unit. At low differential pressures, the cup seal functions as a conventional cup seal, but at high differential pressures it turns into a slit seal. The maximum positive effect in terms of influence on the dynamic characteristics of the rotor is achieved at fixed ratios of the dimensions of the deformed cup and parts that form the seal unit. The data obtained by comparative experimental study of the cup-slit and conventional seal units are provided. Use of cup-slit seals having fluoroplastic (Teflon) cups in oxygen pumps will help reduce expenditures for finding a solution to the problem of safe operation of such pumps.

A study on the phenomenon of rate of loading in motor operated gate valves

This study analyzed the rate of loading (ROL) phenomenon, which is generated during the operation of a motor operated valve (MOV) under fluid pressure conditions. ROL is one of the most important parameters for an MOV performance evaluation. This paper includes the analysis results for the characteristics of ROL and the effect of fluid pressure on the ROL. Dynamic and static test were performed to analyze the ROL effect for flexible wedge gate valve. The result of this analysis confirmed that the ROL is generated under fluid pressure condition and that the ROL value under high differential pressure condition appeared to be higher than under low differential pressure condition. According to the test results of multiple valves, the ROL appeared to become higher, as the differential pressure increased, and under the high differential pressure condition, it accounted for approximately 17.6% of the thrust loss. In addition, the ROL effect was negligible in valves with a low differential pressure (below 1100 kPa).

Rotordynamic Force Coefficients of a Hybrid Brush Seal: Measurements and Predictions

Brush seals effectively control leakage in air breathing engines, albeit only applied for relatively low-pressure differentials. Hybrid brush seals (HBS) are an alternative to resolve poor reliability resulting from bristle tip wear while also allowing for reverse shaft rotation operations. A HBS incorporates pads contacting the shaft on assembly; and which under rotor spinning, lift off due to the generation of a hydrodynamic pressure. The ensuing gas film prevents intermittent contact, reducing wear, and thermal distortions. This paper presents rotordynamic measurements conducted on a test rig for evaluation of HBS technology. Single frequency shaker loads are exerted on a test rotor holding a hybrid brush seal, and measurements of rotor displacements follow for operating conditions with increasing gas supply pressures and two rotor speeds. A frequency domain identification method delivers the test system stiffness and damping coefficients. The HBS stiffness coefficients are not affected by rotor speed though the seal viscous damping shows a strong frequency dependency. The identified HBS direct stiffness decreases ∼15% as the supply/discharge pressure increases Pr=1.7–2.4. The HBS cross-coupled stiffnesses are insignificant, at least one order of magnitude smaller than the direct stiffnesses. A structural loss factor (γ) and dry-friction coefficient (μ) represent the energy dissipated in a HBS by the bristle-to-bristle and bristle-to-pad interactions. Predictions of HBS stiffness and damping coefficients correlate well with the test derived parameters. Both model predictions and test results show the dramatic reduction in the seal equivalent viscous damping coefficients as the excitation whirl frequency increases.

Effects of relative gas flow direction in the anode and cathode on the performance characteristics of a Molten Carbonate Fuel Cell

In this work, three-dimensional numerical simulation of conservation equations for mass, momentum, energy, species and electrochemical reaction has been carried out to compare the performance characteristics of a Molten Carbonate Fuel Cell (MCFC) with three different flow types, co-flow, counter-flow and cross-flow. Depending on the flow types, distributions of pressure difference, temperature and current density in the electrolyte matrix were examined and the fractions of various losses were scrutinized. The simulation results show that the co-flow type has the lowest pressure difference across the matrix and the distributions of temperature and current density are more uniform than other types. However, it was found that since irreversible losses due to ohmic resistance, anode activation and cathode activation are smallest in the counter-flow type, best performance can be expected by the MCFC with the counter-flow type.

Modeling of transient hydrogen permeation process across a palladium membrane

Transient mass transfer processes of hydrogen permeating through a Pd membrane are modeled to aid in predicting the hydrogen transport behavior. The model is established in terms of the quasi-steady time and the steady permeation rate. Meanwhile, four important parameters are considered; they are the permeation lag time, the initial permeation rate, the concave up period and the concave down period. A unit step function is embedded in the model to account for the effect of the hydrogen permeation lag at a lower pressure difference. Corresponding to the lower, the moderate and the higher pressure differences (i.e. 3, 5 and 8 atm), though the hydrogen permeation undergoes a three-stage, a two-stage and a one-stage processes, respectively, these processes can be predicted well by an arc tangential function. By introducing an adjusting parameter in the arc tangential function, there exists an optimal value of the adjusting parameter when the pressure difference is lower. In regard to the moderate and higher pressure differences, the predictions agree with experiments well if the adjusting parameter is sufficiently large. Physically, the unit step function is used to account for the controlling mechanisms of hydrogen diffusion toward the membrane and the spillover of the hydrogen across the membrane. The initial jump parameter represents the rapid response of the initial hydrogen permeation. The adjusting parameter can be used to describe the relative importance of the concave up and the concave down periods.

A study on a characteristic of stem friction coefficient for motor operated flexible wedge gate valve

Stem friction coefficient is a coefficient that represents friction between thread leads of the stem and stem nut. It is an important factor to determine output thrust delivered from the actuator to the valve stem in assessing performance of motor operated valves. This study analyzes the effects of changes in differential pressure on stem friction coefficient, and determines the bounding value of stem friction coefficient. A dynamic test was conducted on multiple flexible wedge gate valves in various differential pressure conditions, and the test data was statistically analyzed to determine the bounding value. The results show that stem friction coefficient in middle and high differential pressure is influenced by fluid pressure, while stem friction coefficient in low differential pressure is almost not affected by fluid pressure. In addition, it is found that the bounding value of stem friction coefficient is higher in a closing stroke than in an opening stroke.