Experimental evaluation of the flow field inside an open faced impeller

Berchane, Nader Samir

17 February 2005

The pressure distributions and forces presented in a thesis by Hossain [1] for a centrifugal pump illustrated a somewhat complex inter-relationship between various geometric and operating parameters of the pump studied. The pump had an open faced impeller of 33.65 cm diameter with 5 blades of backswept design. It was felt that the best way to resolve some of the questions related to Hossain’s results was to determine the fluid velocity field inside the pump. Thus the flow field through the impeller passages was measured using a 1-D Laser Doppler Velocimetry (LDV) system. The LDV was used to measure the radial and tangential velocity components as well as the turbulence intensities over the region accessible through the two optical windows in the front of the pump housing. Five axial planes were investigated by recording measurements along two radial lines at azimuthal angles of 45° and 315° (with respect to the horizontal axis of the pump) for design operating conditions. A once per revolution signal was used to supply the LDV system with a reference for the rotor position. It was found out that a leakage flow existed near the front wall of the impeller at z/h = 0.11, which was generated by the pressure difference between the impeller exit and inlet. It was also concluded that the velocity field was not fully two-dimensional in nature. This was believed to be a result of the 90° turn that the fluid endures as it enters the impeller inlet from the suction pipe.

Centrifugal pump

Experimental evaluation of the flow field inside an open faced impeller

Berchane, Nader Samir

17 February 2005

The pressure distributions and forces presented in a thesis by Hossain [1] for a centrifugal pump illustrated a somewhat complex inter-relationship between various geometric and operating parameters of the pump studied. The pump had an open faced impeller of 33.65 cm diameter with 5 blades of backswept design. It was felt that the best way to resolve some of the questions related to Hossain’s results was to determine the fluid velocity field inside the pump. Thus the flow field through the impeller passages was measured using a 1-D Laser Doppler Velocimetry (LDV) system. The LDV was used to measure the radial and tangential velocity components as well as the turbulence intensities over the region accessible through the two optical windows in the front of the pump housing. Five axial planes were investigated by recording measurements along two radial lines at azimuthal angles of 45° and 315° (with respect to the horizontal axis of the pump) for design operating conditions. A once per revolution signal was used to supply the LDV system with a reference for the rotor position. It was found out that a leakage flow existed near the front wall of the impeller at z/h = 0.11, which was generated by the pressure difference between the impeller exit and inlet. It was also concluded that the velocity field was not fully two-dimensional in nature. This was believed to be a result of the 90° turn that the fluid endures as it enters the impeller inlet from the suction pipe.

Centrifugal pump

Development of an endoscopic irrigation pump experience with Byrne Medical, Inc.

Cheng, Lui

17 September 2007

As an intern with Byrne Medical Inc., I took part in several development and validation projects for medical products. A design project for a medical irrigation pump for endoscopic procedure is the focus for my Doctor of Engineering degree. This project represents the scope and depth of a typical design project for a medical device. In this dissertation, a summary of motors used in current medical irrigation pumps available in the market, as well as their flow rates, is presented. A procedure of typical product design process is followed and a working prototype of endoscopic irrigation pump is designed and fabricated. The objective of the project was to design and fabricate a working prototype of a medical irrigation pump to be used for endoscopic procedures with standard videoscopes in the medical field. Currently there are no irrigation pumps that satisfy physicians’ needs. By manufacturing their own pump, Byrne Medical would be able to select a host of the positive features noted on other pumps and combine those features into a single pump that fits both the technical and user needs. The author made improvements in the areas of appearance, size, usability, functionality, product life, and ability to vary motor speed, and therefore the flow rate. Flow rate of the prototype was tested by measuring the amount of water it was able to pump per minute (milliliter per minute). Each tubing set was attached and secured onto the prototype unit and adjust the speed control to the maximum flow. The power switch was turned on and the pump was running continuously for twenty seconds. Water was collected and weighted with a digital scale. The amount of water (in pounds) per twenty seconds was then converted to milliliter per minute. Physicians in the GI (Gastroenterology) suites prefer an irrigation pump that rotates backward when they turn the power off to prevent the sterile water from dripping. A Multi-function Timer (model H3DE-M2) manufactured by Omron was selected for future improvement. A working prototype (previously fabricated) was tested with this DPDT timer and the result proved the improvement was achievable.

Irrigation Pump

MIXED PHASE COMPRESSION HIGH EFFICIENCY HEAT PUMP

Chan, WenYen

13 March 2015

The objective of this thesis is the design and realization of a higher efficiency air source heat pump. The improved pump???s operating cost must rival the cost of heating with natural gas, while incurring a minimal increase in the capital cost of the pump. A COP greater than 4 at ???15C ambient is needed to achieve this goal. During winter season testing a COP of 4.25 +/- 0.11 was observed. This tracks well with a predicted COP of 4.4 and also against a commercial system with a claimed COP between 2.1 and 3.0.

heat pump

Reduction of oil pump losses in automatic transmissions

Larsson, Camilla

January 2014

In the vehicle industry it is of great interest to reduce the emissions and lower the fuel consumption.Up to now a lot of effort has been put into increasing the efficiency of the engine,but it starts to get expensive to keep improving the engine. In this master thesis the transmissionand especially the oil supply to the transmission is investigated. An example of how the requirements of an oil pump can be decided is described. Knowingthe requirements different pumps may be adapted to meet the demands. The gear pumpused today is compared with a variable displacement pump and an electric pump. The gearpump is not possible to control, but the other two are. A few simple control strategies areintroduced. The strategies are implemented and the three pumps are used in the same drivecycle. It is shown that it is possible to reduce the energy that the pump requires if it isreplaced by a variable vane pump or an electric pump.

oil pump

vane pump

gear pump

electric pump

variable displacement

automatic transmission

pump

oil

control

Design Evaluation of a Duplex Circular Wet Well Pumping Station Under Steady State and Dynamic Operating Conditions

Mailloux, James Thomas

29 April 2010

Duplex Circular Wet Well (DCWW) lifting pump stations are utilized for pumping clear and solid-bearing liquid. Understanding the effect of design criteria on pump performance is important to minimize maintenance costs and maximize efficiency. There are currently no known full-scale laboratory studies that have been performed to investigate the overall design of DCWWs. The objective of the research was to evaluate the impact of various design criteria, such as internal geometry and operating conditions on the performance of DCWW pump stations and provide documentation and recommendations which will be used to augment the current Hydraulic Institute/American National Standard for Pump Intake Design (ANSI/HI 9.8-1998), (HI) guidelines. The research was conducted in two phases; Phase 1 consisted of performing a comparative analysis of the basic flow patterns within the wet well by means of Computational Fluid Dynamics (CFD), Phase 2 consisted of performing detailed evaluations of various design aspects on pump performance using a full-scale Physical Model constructed for the research. The CFD research provided indications regarding potential performance problems that may occur due to poor flow patterns and potential pump suction swirl, while the physical research provided a basis for determining the relative advantages of different designs. The physical research included the evaluation of general flow patterns, free-surface and subsurface vortices, air entrainment and pump suction swirl. Measurement of the steady state swirl within the pump showed unacceptable performance in accordance with the HI acceptance criteria. Swirl data collected under real-world dynamic operating conditions showed that the pump typically did not experience the adverse conditions indicated at steady state. Normal (symmetrical) pump orientation resulted in more favorable operation in terms of pump swirl and ingestion of entrained air than a coplanar (inline) condition. A minimum water elevation was established to minimize air-entrainment and swirl entering the pumps, reducing possible effects such as cavitation and vibration of the pump impeller. Air-core subsurface vortices were present under the pumps, requiring pump-cones to be installed. The collection of real-time dynamic data will allow design engineers to better understand actual pump performance under normal cycling and clean-out modes, reducing the operating time under unfavorable conditions and overall maintenance requirements.

Dynamic pump operation

Circular pump station design

Fluid Dynamic and Performance Behavior of Multiphase Progressive Cavity Pumps

Narayanan, Shankar Bhaskaran

2011 August 1900

It is common for an oil well to produce a mixture of hydrocarbons that flash when exposed to atmospheric pressure. The separation of oil and gas mixtures on site may prove expensive and lead to higher infrastructure and maintenance costs as well. A multiphase pump offers a good alternative with a lower capital cost and increased overall production. A Progressive Cavity Pump (PCP) is a positive displacement pump type that can be used to pump a wide range of multiphase mixtures, including high viscosity fluids with entrained gas and solid particles in suspension. Despite its advantages, a PCP has a reduced ability to handle high gas-liquid ratios due to limitations of its elastomeric stator material required to overcome thermo and mechanical effects. Also the efficiency decreases significantly with increases in gas volume fractions and reduced differential pressures. The current study focuses on studying the behavior of this unique pump in a wide range of GVFs and studying the effect of this ratio on overall efficiency, temperature and pressure distribution on the stator. The pump exhibits vibration issues at specific differential pressures and they have been studied in this work. This can be of critical value as severe vibration issues can damage the pump components such as couplings and bearings leading to high maintenance costs. Another important issue addressed by this research is the behavior of this pump in transient conditions. Oil well production is highly unpredictable with unexpected rises and drops in GVFs. These transient conditions have been simulated by varying the GVF over wide ranges and studying the pump's behavior in terms of load, temperature rises and instantaneous pressure profiles on the pump stator. This thesis provides a comprehensive study of this pump, its operating ranges and behavior in off-design conditions to assist oil and gas exploration ventures in making an informed choice in pump selection for their applications based on field conditions.

Fluid dynamics

Multiphase pump

Progressive Cavity pump

Flow in centrifugal water pump impellers

Rose, Martin George

January 1987

No description available.

621.69

Water pump development

Numerical modelling of a nanosecond optical parametric oscillator

Lyons, Sean Christopher

January 2000

No description available.

621.381045

Pump absorption

Self-induced flow circulation by enclosed rotors

Daneshmandi, Mohsen

January 1995

No description available.

621.69

Pump seal cooling