Fuel Preporator® Is Patent Protected

Canada
2,108,391

United States
5,355,860 - 5,746,184
5,529314 - 6,729,310

Australia
2005101054

Additional U.S. & Foreign Patents Pending

Engineers Have Long Known About Entrained Air In Diesel Fuel

Cummins® Engine Co., Service Topic 5-135 states:

"Like water, fuel contains a certain amount of dissolved air depending upon the fuel temperature, pressure on the fuel, specific gravity and the amount of aeration to which the fuel has been subjected."

Caterpillar®, Special Instruction 651-1250 points out:

"Normally No. 2 Diesel Fuel contains about 10% air in solution, although the air is not visible."

Milwaukee School of Engineering, Handbook of Hydraulics agrees:

"Hydraulic oils also contain varying degrees of entrained air."

Parker - Racor Technical Support confirms:

"Fact ##1; There is Air entrained in diesel fuel."

Caterpillar®, PEHP7046:

"Damage can be caused by anything in your fuel system that should not be there, including particles, heat, water and air bubbles."

"Air becomes entrained in diesel fuel through agitation from pumping and sloshing in the tank. Additionally, the engine's transfer pump, operating under a vacuum, as with the conventional filter system, has a limited pressure flow available. This limited flow, which is insufficient to fully fill the pump mechanism at higher operating RPM's, results in pump cavitation and vapor. At higher altitudes, atmospheric pressure, the force that drives fuel from the tank, through the lines and filter, and into the transfer pump, decreases. This increases cavitation even more. Conventional fuel filter systems do nothing to relieve these conditions. In fact, as the filter becomes more restrictive to the fuel flow as it plugs with use, these conditions become much worse!"

University of Illinois Department of Mechanical & Industrial Engineering, College of Engineering's study of diesel fuel concludes:

"Diesel fuel is vaporized in a conventional filtering system and is allowed to pass on to the injector system."

"Air is also allowed to pass on to the injector system."

"These phenomena are undesirable because the two-phase flow from the conventional filtering system not only reduces the mass flow rate from the fuel pump but also leads to a lag in injector timing. This lag in the injection of the fuel can have a considerable negative effect on the performance of a diesel engine."

"Unlike the conventional filtering system, the Fuel Preporator® does not allow vaporized diesel fuel to be created, nor does the Fuel Preporator® allow entrained air to be passed on to the engine. The Fuel Preporator® eliminates the inconsistency that is found in a conventional fuel filtering system."

Entrained Air and Vapor in Diesel Fuel Causes Retarded Injection Timing!

Air and vapor are compressible. Their presence in the injector delays the pressure buildup and the injection. The delay of the injection results in retarded injection timing. Moreover, air in the fuel, no matter how small, remains a bubble. As a consequence, the amount of air entering the injector will vary from injection to injection. The more air/vapor present in the fuel the more retarded the injection timing, the less air/vapor present the less retarded the injection timing.

University of Illinois Engineering Department states:

"…it has been concluded that entrained air and fuel vapor present in the fuel injection system produces a timing delay for roughly one out of every three sprays…"

Retarded Injection Timing Negatively Affects Diesel Engine Performance!

Retarded injection timing caused by the presence of air/vapor in the fuel results in: low torque or power output, increased fuel consumption, increased exhaust emissions, rough idle/wet cylinder, and poor throttle response.

Low Torque and Low Power Output: Low torque due to a delayed injection results from the fuel arriving in the combustion chamber too late for a full burn.

Retarded Injection Timing

Specifically, a delay of the injection from an uncontrolled event, such as the presence of air/vapor in the fuel, allows the piston to move further into the power stroke before the injection takes place. The piston is now beyond the optimum position to fully utilize the pressure boost of the expanding gasses and for a complete burn of the fuel.

Corrected Injection Timing

The injection of fuel is intended, by preset parameters, to take place as the piston nears the top of the compression stroke. This allows the fuel to ignite as the crank journal approaches top dead center. Now, the timely injection followed by a full length power stroke, allows the fuel to burn completely and the expanding gasses to forcefully drive the piston downward. The full burn of the fuel maximizes power output and fuel efficiency with minimal exhaust emissions.

Peak Torque Falls Off as RPM Increases!

The following torque curves bare witness to the typical points where torque rise peaks and then begins to fall off. These diesel engines are all equipped with the conventional 'vacuum feed' filter system. Notice the point of torque rise, the peak torque range, and the similarity of rpm where torque begins to drop. This would imply the point at which atmospheric pressure fails to provide the Net Positive Suction Head necessary to support adequate fuel flow to the transfer pump, and cavitation becomes apparent.

Note: It is standard within the industry to perform test cell tests with clean fuel filters to allow the engine optimum performance. However, a diesel engine in day to day operation equipped with the conventional 'vacuum feed system' will suffer a decrease in power output, a decrease in fuel economy, and an increase in exhaust emissions as the fuel filter plugs with use.

Fuel Preporator® Increases Torque and Power Output!

With the entrained air eliminated from the fuel and the necessary NPSH, Net Positive Suction Head, supplied to the transfer pump, the Fuel Preporator equipped diesel engine will have a consistently timely injection and perform at peak power output and efficiency regardless of fuel filter condition. Torque rise off idle is seen to double, peak torque increases about 6% and does not fall off at the higher RPM's as it does with the conventional 'vacuum feed system.'

The torque curve graph on the right was performed by the University of West Virginia, Morgantown, Engine Lab. The top curve was the Fuel Preporator/No Air. The next to top curve was the Fuel Preporator/0.5 slpm Air Injection into the fuel tank.

The bottom two curves without the Fuel Preporator start dropping at the 15/1600 rpm range. The slight recovery at 1600/2200 rpm is not typical of an in-use engine.

The torque curve of a Caterpillar 3306 diesel engine under controlled testing at the University of West Virginia shows the performance improvement obtained through the use of the Fuel Preporator.

Increased Fuel Consumption

Retarded injection timing causes not only low power, but also an incomplete burn. This simply means that some fuel has not burned and is going out the exhaust. An incomplete burn in itself results in poor fuel economy. More than that, low power forces the driver to drop gears increasing the number of injections over the same distance and wasting even more fuel.

Fuel Preporator® Increases Fuel Efficiency!

An engine equipped with the Fuel Preporator, having a timely injection and complete burn of the fuel, develops more power from the same volume of fuel than it would when equipped with the vacuum feed filter system. Consequently, the Fuel Preporator equipped engine is the more efficient engine! Fuel savings of 6% and more are consistently produced through the use of the Fuel Preporator.

Increased emissions, Unburned HC's and NOx: Air/Vapor in the fuel causes retarded injection timing. As pointed out by the University of Illinois College of Engineering study, one out of every three injections is retarded. This triggers the chain of events that create major emission problems for the diesel engine. The retarded injections result in partially burned fuel or unburned hydrocarbons. The unburned hydrocarbons create deposits which reduce the volume of the combustion chamber, in turn, increasing the compression ratio. The retarded injection results in unburned hydrocarbons and deposits, The two out of three injections that are timely, result in higher temperatures and increased NOx gasses.

Fuel Preporator® Reduces Exhaust Emissions!

Tests show that after installing the Fuel Preporator®, and all injections become timely, the carbon deposits burn out after 100 to 120 hours of run time and the NOx decreases by 46%. Other tests have documented reductions in unburned HC's in Series 60 Detroits by 29% and 3406B Cat's by 76%.

EPA & CARB Certified Olsen Ecologic Lab, ISO 8178 8 Mode Testing of the Fuel Preporator®

"The ISO 8178 is an international standard designed for a number of non-road engine applications. It is used for emission certification and/or type approval in many countries worldwide, including the U.S.A., European Union and Japan. Depending on the legislation, the cycle can be defined by reference to the ISO 8178 standard, or else by specifying a test cycle equivalent to ISO 8178 in the national legislation (as it is the case with the U.S. EPA regulations). The ISO 8178 is actually a collection of many steady-state test cycles (type C1, C2, D1, etc.) designed for different classes of engines and equipment. Each of these cycles represents a sequence of several steady-state modes with different weighting factors." The following 6 charts and the brief summary are from the Analysis of the Olsen Ecologic ISO 8178 Test by Vineyard Technology. Both the test report and the analysis are available for study and verification.

Scenario A is the diesel baseline testing. An average of three runs, using the cycle weighted data, provided an output power of 45.68 HP.

Scenario B, air entrainment, reduced this power by 25% to 34.37 HP. By adding the PureFlow® system, the power was fully restored to 45.69 HP. Fig. 1 shows this graphically.

Fuel economy testing provided similar results, shown in Fig. 2. The average Brake Thermal Efficiency (BTE) was 28.8%. This means that of all the energy supplied to the engine by the fuel, 28.8% of this returned in the form of useful work, the remaining 71.2% was wasted to the atmosphere via the radiator, exhaust, and direct radiation. Air entrainment reduced this to 23.9% BTE, a reduction of 17%. Again, the PureFlow® device fully restored performance to baseline conditions, raising thermal efficiency to 29.2%.

Air entrainment increased all components of gaseous emissions, including carbon monoxide (C), oxides of nitrogen (NOx), and unburned total hydrocarbons (THC). The increases ranged from 25-100% in terms of gm/bhp-hr, as seen in Fig. 3. Often, there is a tradeoff between these emission components. The fact that all three were significantly worsened indicates a serious disruption in the combustion event. Notably, the PureFlow® system restored all three components to essentially baseline conditions.

Fuel cavitation testing, simulated by a fuel line restriction, provided similar results to that of air entrainment. There was a 23% loss in power accompanied by a 6% loss in fuel efficiency, as is illustrated in Figs. 4-5. The PureFlow® system restored baseline values.

CO, NOx, and THC gaseous exhaust emissions were degraded by cavitation as seen in Fig. 6. The PureFlow® system restored these values to near baseline conditions.

What about exhaust particulate matter emissions (PM)? Lack of data for the baseline and wide variability in recorded results under otherwise similar conditions precludes any definitive analysis of PM.

Rough Idle and Wet Exhaust

Rough idle results from inconsistent injection timing due to the variation of air/vapor present in each injection. The delayed injections also cause the idle speed of the engine to drop below the set idle rpm. Consequently, the ECM or governor must then increase the amount of fuel injected to bring the engine back to the set idle speed. This adds more fuel than the engine can completely burn. After considerable idle time, if the idle is not brought up to 800-1,000 rpm, the excessive fuel washes oil from the rings and liners, contaminates the oil in the crankcase and causes excessive engine wear. More importantly, the wet cylinder effect causes excessive unburned fuel in the exhaust of the idling diesel and has lead to anti-idling laws for truckers across the nation.

Cummins Engine Company specifically points out in their trouble shooting manual for the following complaints: first, check for air in the fuel and then, fuel inlet restriction.

Cummins Bulleting No. 3666239, Section TT-Engine Performance Troubleshooting Tree:

• Engine Acceleration or Response Poor

• Cranking Fuel Pressure is Low

• Engine Operating Fuel Pressure is Low

• Engine Difficult to Start or Will Not Start (Exhaust Smoke)

• Engine Difficult to Start or Will Not Start (No Exhaust Smoke)

• Engine Power Output Low

• Engine Runs Rough at Idle

• Engine Run Rough or Misfires

• Engine Speed Surges at Low or High Idle

• Smoke, Black – Excessive

• Smoke, White – Excessive

• Engine Shuts Off or Dies Unexpectedly or Dies During Deceleration

• Engine Starts But Will Not Keep Running

• Engine Will Not Reach Rated Speed (RPM)

All of the Above Symptoms Require:

Troubleshooting Step 4:

• Step 4: Fuel System Checks

• Step 4A: Check for air in the fuel

• Step 4B: Check fuel inlet restriction