Axial Flow Pump

Axial flow pumps are of the propeller type, in which the rotation of the impeller forces the water forward axially, and do not strictly qualify as centrifugal pumps.

From: Twort's Water Supply (Seventh Edition), 2017

Pump Types and Applications

Dennis P. Nolan, in Fire Pump Arrangements at Industrial Facilities, 2017

Axial flow pumps

Axial flow pumps have a motor-driven rotor that directs flow along a path parallel to the axis of the pump. The fluid thus travels in a relatively straight direction, from the inlet pipe through the pump to the outlet pipe. Axial flow pumps are most often used as compressors in turbo-jet engines. Centrifugal pumps are also used for this purpose but axial flow pumps are more efficient. Axial flow compressors consist of alternating rows of rotors and stationary blades. The blades and rotors produce pressure rise in the air as it moves through the axial flow compressor. Air then leaves the compressor under high pressure.

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Pump types and applications

Dennis P. Nolan P.E., PhD., in Fire Fighting Pumping Systems at Industrial Facilities (Second Edition), 2011

6.2.5 Axial flow pumps

Axial flow pumps have a motor-driven rotor that directs flow along a path parallel to the axis of the pump. The fluid thus travels in a relatively straight direction, from the inlet pipe through the pump to the outlet pipe. Axial flow pumps are most often used as compressors in turbo-jet engines. Centrifugal pumps are also used for this purpose, but axial flow pumps are more efficient. Axial flow compressors consist of alternating rows of rotors and stationary blades. The blades and rotors produce an increase in the air pressure as it moves through the axial flow compressor. Air then leaves the compressor under high pressure.

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Pumping; Electrical Plant; Control and Instrumentation

Don D. Ratnayaka, ... K. Michael Johnson, in Water Supply (Sixth Edition), 2009

17.5 Axial Flow and Mixed Flow Pumps

Axial flow pumps are of the propeller type, in which the rotation of the impeller forces the water forward axially, and do not strictly qualify as centrifugal pumps. Mixed flow pumps act partly by centrifugal action and partly by propeller action, the blades of the impeller being given some degree of ‘twist’. However, in practical terms there are no precise dividing lines between radial flow (centrifugal), mixed flow and axial flow pumps. In general, axial and mixed flow pumps are primarily suited for pumping large quantities of water against low heads, while centrifugal pumps are best for pumping moderate outputs against high heads. Axial flow pumps have poor suction capability and must be submerged for starting. They are most often used for land drainage or irrigation or for transferring large quantities of water from a river to some nearby ground-level storage. mixed flow pumps are shown in Plates 32(b) and (c).

Characteristic curves for typical mixed flow and axial flow pumps are given in Figure 17.4. The starting power required by the mixed flow pump shown is about the same as the duty power, but for the axial flow pump the starting power is substantially greater than the duty power. Axial flow pumps are therefore not started against a closed valve, which would overload a motor correctly sized for the expected duty. They are either started against an open valve to minimize the starting power and current required, or installed in systems specially designed to ensure no delivery valve is needed, for example with a siphonic delivery.

FIGURE 17.4. Characteristic curves for (a) a mixed flow pump and (b) for an axial flow pump.

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Pumping, Electrical Plant, Control and Instrumentation

Malcolm J. Brandt BSc, FICE, FCIWEM, MIWater, ... Don D. Ratnayaka BSc, DIC, MSc, FIChemE, FCIWEM, in Twort's Water Supply (Seventh Edition), 2017

19.5 Axial Flow and Mixed Flow Pumps

Axial flow pumps are of the propeller type, in which the rotation of the impeller forces the water forward axially, and do not strictly qualify as centrifugal pumps. Mixed flow pumps act partly by centrifugal action and partly by propeller action, the blades of the impeller being given some degree of ‘twist’. However, in practical terms there are no precise dividing lines between radial flow (centrifugal), mixed flow and axial flow pumps. In general, axial and mixed flow pumps are primarily suited for pumping large quantities of water against low heads, while centrifugal pumps are best for pumping moderate outputs against high heads. Axial flow pumps have poor suction capability and must be submerged for starting. They are most often used for land drainage or irrigation or for transferring large quantities of water from a river to some nearby ground-level storage. The pumps shown in Plates 32(b) and (c) are mixed flow.

Characteristic curves for typical mixed flow and axial flow pumps are given in Figure 19.4. The starting power required by the mixed flow pump shown is about the same as the duty power, but for the axial flow pump the starting power is substantially greater than the duty power. Axial flow pumps are therefore not started against a closed valve, which would overload a motor correctly sized for the expected duty. They are either started against an open valve to minimize the starting power and current required, or installed in systems specially designed to ensure no delivery valve is needed, for example with a siphonic delivery.

Figure 19.4. Characteristic curves for (a) a mixed flow pump and (b) for an axial flow pump.

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Mechanical circulatory support: an overview

Paul Callan, Ioannis Dimarakis, in Advances in Medical and Surgical Engineering, 2020

2.7 Second generation devices

The second-generation devices incorporate an axial flow pump. This provides continuous blood flow, in contrast to the pulsatile flow of the first generation devices. The pump consists of a single moving rotor that spins as blood flows through the blades, imparting kinetic energy to move blood in a parallel direction to the impeller. The first device to receive approval as a bridge to transplantation was the Heartmate II (Abbott, Chicago, Illinois, USA; formerly Thoratec) (Fig. 7.4). The pump still requires a separate abdominal pocket, but as the device was far more compact than the first generation devices, it reduced the risk of complications such as bleeding and infection, and enabled implantation in patients with a smaller body habitus. They can provide flows of up to 10 L/min. The external driveline does not require a separate venting line, thus reducing its size, and the risk of complications. The Heartmate II trial compared the first generation Heartmate XVE to the Heartmate II in patients that were ineligible for heart transplantation (destination therapy) [32]. This showed a significantly higher survival free from disabling stroke or pump failure at 2 years in the Heartmate II arm (46% vs. 11%). The rates of right heart failure, infection, and arrhythmias were all significantly lower with the second-generation device. A study of the Heartmate II as a bridge to transplantation demonstrated 72% actuarial survival at 18 months with improved functional status and quality of life [33].

Figure 7.4. The HeartMate 2 LVAD.

Image provided courtesy of St. Jude Medical, Inc.

The Jarvik 2000 Flowmaker (Jarvik Heart, Manhattan, New York, USA) device incorporates a titanium impeller device that weighs just 85 g, compared to a Heartmate II device that weighs 350 g. It is small enough to fit in the left ventricular cavity and secured to the apex by means of a sewing cuff. Therefore, it does not require an inflow cannula. The external driveline is tunneled through the back, shoulder, and neck, with an exit site located behind the ear. The driveline is connected to a single lithium ion battery. As there is no need for a separate pump pocket, infective complications are reduced.

The HeartAssist5 (ReliantHeart, Houston, Texas, USA) is a second-generation device version of the Micromed DeBakey Noon VAD. It weighs 92 g, has an angled inflow cannula, and is implanted above the diaphragm. The outflow cannula contains an ultrasonic flow probe that measures real time flow. This is in contrast to the other commercially available devices, which estimate flows based on rotor speed, power consumption, and blood viscosity. Performance data from the device can be viewed remotely, potentially facilitating earlier intervention if a problem is detected. The device is approved as a bridge to transplantation and destination therapy in Europe, and is limited to investigational use in the United States.

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Classification: electric motors, pumps, fans

Jianfeng Yu, ... Jianming Qian, in Electrical Motor Products, 2011

2.6.2 Axial flow/propeller pump

In 1785, John Skeys patented a pump of novel construction, which was the prototype of the axial flow pump. The English physicist and engineer, James Thomson, initiated the idea of using guide vanes to enhance the performance of pumps. The English scientist Osborne Reynolds designed the first pump with adjustable inlet guide vanes in 1875 (Kaya, 2003). The first systematic investigations of rotodynamic pumps on a scientific basis were commenced in the 1890 s at the works of Sulzer Brothers in Switzerland. This lead was followed by other factories that endeavoured to become leading manufacturers of centrifugal pump design and, after this, the design of helicoidal, diagonal and axial flow pumps was developed rapidly.

As a general rule, axial flow pumps are usually selected for pumping large volumes of water against relatively low heads (1–15 m). The total head increase for axial flow pumps is small compared with that of centrifugal pumps.

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Second-generation ventricular assist devices

Roland Graefe, Sascha Groß-Hardt, in Mechanical Circulatory and Respiratory Support, 2018

Jarvik 2000

The Jarvik 2000 FlowMaker LVAD (Jarvik Heart, Inc., New York, NY) is a compact axial flow pump shown in Fig. 4.8 that provides continuous blood flow from the left ventricle to the descending or ascending aorta.

Fig. 4.8. The Jarvik 2000 and its placement.

Reprinted with permission from Texas heart institute homepage—research; October 2016. http://www.texasheart.org/Research/Devices/j2000.cfm.

The first human implantation of the Jarvik 2000 occurred in the year 2000. About the size of a common C-cell battery, it measures only 2.6 cm in diameter by 7.8 cm in length, with a pump body weight of 85 g. Because of its small size, most of the pump is located within the apex of the left ventricle. To the authors’ knowledge, it is still the smallest clinically available, long-term LVAD. The longest period of left-ventricular support has been achieved with the Jarvik 2000 with 9.5 years of uninterrupted support [7].

Two unique features have to be mentioned. First, there is a possible alternative powerline connection method available using a postauricular connector behind the ear. This connection method offers the advantage of limited relative motion of the driveline in comparison to the surrounding tissue. Second, patients have the opportunity to adapt the rotational speed themselves manually within limited safe boundaries. Further characteristics of the Jarvik 2000 are listed in Table 4.2.

Table 4.2. Characteristics of the Jarvik 2000

Name Jarvik 2000 Ventricular Assist Device Support Duration Long-Term
Manufacturer Jarvik Heart, Inc. (USA) Position Implantable
First in man 2000 [6] Number of implants Unknown
First regulatory approval CE approval 2005 [6] Availability Selected countries in Europe and Japan
Unique features Alternative connector available (postauricular, behind-the-ear)
Manual speed adjustment by the patient possible

The pump layout is similar to the HeartMate II and can be observed in Fig. 4.9.

Fig. 4.9. The Jarvik 2000.

Reprinted with permission from Texas heart institute homepage—research; October 2016. http://www.texasheart.org/Research/Devices/j2000.cfm.

Instead of contact bearings, the Jarvik 2000 employs cone bearings to maintain a safe, failure-free impeller operation (not shown). One cone bearing is located upstream and one downstream of the impeller. Both axial and radial forces on the impeller are absorbed in this manner. It is claimed that a small hydrodynamic fluid film is formed and thus separates the rotating impeller from the stationary struts forming the second bearing partner. The pump can be operated at 8000–12,000 rpm and can generate an average flow rate of 3–7 L/min at 4–8 W of power consumption under optimal conditions [16].

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Use of ESP Equipment in Special Conditions

Gabor Takacs Ph.D, in Electrical Submersible Pumps Manual, 2009

4.3.4.3.5 Special Pumps

Special ESP pumps designed to produce well fluids with very high free gas content are also available. These are tapered pumps with an intake inducer (axial flow pump) at the bottom, specially developed, low NPSH (net positive suction head) pump stages in the middle, and standard stages at the top of the pump assembly. The intake inducer provides a positive pressure for the gas/liquid mixture to enter the upper stages, the low NPSH stages mix and compress the gassy fluid so that the standard stages at the top can increase the flowing pressure to the level required for lifting the liquid to the surface. Thanks to the special design of the low NPSH stages, surging and gas locking are eliminated, thus ensuring a long operational life of the ESP equipment even in gassy wells.

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Review of Research in Cardiovascular Devices

Zbigniew Nawrat, in Advances in Biomedical Engineering, 2009

9 Conclusions

Notable achievements in cardiovascular research and devices that are currently under investigation and expected in the near future are listed below:

1.

New pediatric devices, such as the axial-flow pumps and small-diameter valve prostheses, have been introduced, and some are under construction. As the devices become more and more reliable, mechanical circulatory support will play an increasingly important role, not only for rescue therapy but also for safe treatment of the most complex congenital heart diseases, not only with the aim of bridging to cardiac recovery or transplantation but, eventually, as a permanent solution.

2.

The effective miniature blood pumps have been commonly used in minimally invasive cardiology. Transported to the destination place through the arteries, the smart pump mainly for short-term heart support can play an important role in an emergency.

3.

New types of devices create possibilities of pump and blood oxygenation introduction into clinical practice. The idea is not new, but thanks to new materials (durable, semiconductive silicon membranes) that are being rapidly developed.

4.

New “biomechanical” valves and vessels completely synthetic/artificial, but flexible and durable, will be introduced. The development of small-caliber vascular grafts is very important for bypass and graft surgery.

5.

A significant improvement in technical support for preplanning and control surgical interventions, including telemedicine technology, will be observed.

6.

Bioartificial myocardial grafts will be introduced in which perfusion by a macroscopic core vessel will be applicable.

7.

Improved cell-culture techniques may render human aortic myofibroblasts a native tissue-like structure.

8.

Tissue-engineered bioprosthethic valves will be commonly used in clinics.

As the field of surgery robots controlled by surgeons expands, the economical cost is expected to reduce, which will allow surgeons to more commonly use teleoperation in situations that warrants professional staff assistance such as wars, epidemics, and space trips. The situation of “no contact” between the medical personnel and the patient will reduce the risk of loss of health because of the infection(s) from the side of the operating staff.

It is most probable that contemporary telemanipulators will be replaced by adaptive robots in the near future. Currently, the trials of shifting from passive to active systems can be seen. To be clear, let’s define the basic concepts: Teleoperators are remotely controlled by operator robot transferring on distance motoric and sensoric functions, whereas adaptive robots have more advanced control system with sensoric and learning abilities. However, creating the next-generation “intelligent” robots is a true challenge. These robots must be able to work unaidedly in various environments, gathering information from their senses. Optimization of their behavior and the effectiveness of given task realization will depend on “self-learning control algorithm”, which will more resemble systems based on “instincts” in relation to living creatures and contact with surroundings by means of “senses”, zoom, touch sensors (inductive, supersonic, optical, pneumatic, and microwave). I am convinced that they will not be similar to contemporary cardiosurgical robots, but they will be able to replace them considerably. Probably, they will be microrobots that are able to reach, e.g., a given human internal diseased organ (e.g., the heart).

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