High-Pressure Pump

3.2.1 Structure of high-pressure plunger pumps

The pump head hosts the water inlet and water outlet valve arrangements. It consists regularly of corrosive-resistant forged steel, partly also of coated spheriodal graphite cast iron. Typical plunger diameters for on-site high-pressure plunger pumps utilised for hydrodemolition applications are between 25 mm and 40 mm. The plungers are made from coated steel alloys, hard metals or ceramics (the latter material is limited to rather low operating pressures).

Safety and control devices include safety devices and pressure-measuring devices. Safety devices prevent the permissible pressure from being exceeded by more than 2.0 MPa, or 15%. These devices include pressure relief valves or burst disks, respectively. Automatic pressure regulating valves limit the pressure at which the pump operates by releasing a present proportion of the generated volumetric flow rate back to the pump suction chamber or to waste. It should be used to regulate the water pressure from the pump and is individually set for each operator. Pressure-measuring devices directly measure and display the actual operating pressure.

Auxiliary Nozzles for Wheel Cleaning

Heinzel and Antsupov (2012) reported recent findings in creep-feed grinding on the effectiveness of different nozzles at lower pressures. Wheel clogging tends to be a greater problem in creep-feed grinding due to the long arc of contact. It was reported that fan-shaped nozzles are better for preventing wheel clogging than round needle-shaped nozzles. Results were reported showing up to 30% reduction in grinding forces and up to 20% reduction in wheel wear. The nozzle was positioned at a stand-off distance slightly greater than the coherent length of the jet (coherent length is described later, see page 138). At this position, the jet had dispersed into fine droplets that then impinged on the wheel surface. Each droplet causes a shock wave that has a cleaning effect on the wheel surface. The jet was directed perpendicular to the wheel surface, and it was concluded that the jet impact was insufficient to erode the wheel bond. It was also found that the cleaning effect was reduced at higher wheel speeds as might be expected due to the effects of the air barrier.

8.3.2 Tubing Breaking

Under higher pump pressure, the tubing may crack or fall to the bottom. Judged on the basis of pump pressure, a tubing breaking incident is different to the nozzle falling off. When a crack appears in the tubing, the pump pressure will decrease step by step with the crack propagating. If the tubing breaks off completely, the pressure will also fall suddenly by a greater degree compared to the nozzle falling off. If the above accidents happens, the tubing should be tripped out, beginning fishing job if the tubing gets broken down.

2.1.1 Pump

The high pressure pump is driven up to 3000 rpm and has a capacity of 15 L/min with the 1500 bar system rating. Due to the fact that it has been developed to run on heavy fuel oil (HFO), the pumping element section runs with only fuel, and the camshaft drive section is engine oil lubricated. A dividing wall arrangement is made between pumping section and cam drive. The pumping output is metered by means of solenoid controlling the flow passage area on the pump filling suction side. The solenoid is isolated from the HFO. Because medium speed engines run on some HFO’s up to 1000cSt at 40 °C, the fuel system has to circulate through the pump and rail parts and back to tank until a suitable heating temperature is achieved. This means the pump has a warm up circulation valve placed within the output section of each pumping element, which is closed once the pump is operated at pressure over 10 bar. The pump has been developed to run with operating viscosities between 2cSt (typical for marine diesel oil) and 24cSt, with heated HFO.

11.5.13 Fluid (circulating) system

Fluid storage tanks, fluid pumps, high pressure hoses (or Chiksan®), and a circulating swivel make up the main components of the fluid system. If drilling operations are to be undertaken with the HWO unit, additional mud mixing and handling equipment would be added. In most respects, the fluid system is essentially the same as that used on a conventional drilling rig. Indeed, on rig-assist operations it is likely that the rig’s own fluid system would be used.

Pumps need to be rated for the maximum anticipated wellhead pressure plus a margin, to allow for frictional pressure drop when circulating. Most pumps used for HWO operations on live wells will have to handle high pressure, and therefore are of limited output.

High pressure paint spraying

This method relies on a high pressure pump to supply the paint to the gun. No air is employed to atomize the paint nor does any air issue from the gun, so the method is also known as “airless” spray painting. Air at 6 bar is supplied to the pump which generates a spray pressure up to 360 bar. The air consumption per litre of paint is lower than with low pressure painting.

The paint passes through a tungsten carbide nozzle with a small orifice and is atomized by the high pressure. Because no air is used at the nozzle, there is little or no mist created. Thick coats of high viscosity paint can be applied, so it is suitable for high capacity applications on large structures, ships and buildings. Up to 5 litres/min can be applied.

Ambient Noise and Vibration

Vibrosieves are the major vibration source in powder production. Their levels of common vibration by geometric mean frequencies are characterized by following data: 89.5, 82.5, and 75 dB along 16, 31.5, and 63 Hz, respectively, while the admissible limit is 92 dB.

Pumped vs. Static Feed

Many PEM electrolyzer cell designs require high-pressure or circulating pumps, but static water-feed electrolysis can generate high-pressure gases without pumps. Static feed electrolysis transports water (by osmosis and diffusion) between the water supply and the oxygen electrode, where electrolysis occurs. Static feed systems can eliminate all moving parts (except the poppets inside valves and water expulsion containers) by suitable modifications to the electrolysis cell itself. A URFC system that employs static feed electrolysis and stores oxygen can be completely closed to the environment and has the potential to be a “maintenance-free” system. Such a system has clear advantages in locations where maintenance is expensive or prohibitive. Thermal management of static feed systems (without pumps) is a challenge, so high-performance operation can be difficult to achieve.

Although the supply of reactant gases in a static mode during fuel cell operation is feasible, particularly using pure hydrogen and oxygen, removal of water requires special cell designs.

Pumped versus Static Feed

Static feed electrolyzers have been developed for use with propellant generators for small satellites since the mid-1970s. Up to 6.9 MPa hydrogen and oxygen gas generation pressures have been demonstrated using high-pressure water. Improvements have been made on this capability with proprietary cell designs that can produce high-pressure gas from low-pressure water. High-pressure gases can diffuse into lower pressure zones, so care must be taken to avoid masking the water source with diffused gases. Operation in the fuel cell mode poses a challenge in product water removal. Proton-exchange membrane type static feed URFCs were demonstrated (over 700 cycles, at pressures up to 2.1 MPa) for small satellite energy storage.

3 ULTRA HIGH INJECTION PRESSURE FOR HEAVY DUTY APPLICATIONS

As shown in Figure 7 increased injection pressure at constant NO_x emission contributes significantly to fuel consumption reduction and thus CO₂ emission reduction. The result confirms that also increasing the injection pressure from 2500 bar further to 3000 bar gives additional fuel consumption reduction potential. Even more relevant is the significant soot emission reduction, which will help to avoid or simplify the particulate after treatment. With 3000 bar injection pressures it is possible with almost no disadvantages in fuel consumption to reduce the hydraulic flow rate of the nozzle and by this in total reduce soot emissions by 70% compared to the conventional system.

Finally as already indicated in Figure 1 the path towards Tier4f with a simplified and more efficient system can be achieved by various systems which will require more or less intense improvements on the engine including the boosting system, the peak pressure capability and the heat rejection of the vehicle. However so far all results show the additional flexibility gained by injection pressures of up to 3000 bar can help in many ways.