Archive for January, 2010

FOUR STROKE ENGINE LUBRICATION

Thursday, January 28th, 2010

What types of four stroke lubrication systems are there?

 There are four main types that are used on four stroke motorcycle engines:

  1. The  splash or spray system
  2. The total loss system
  3. The dry sump system
  4. The wet sump system

1. The splash or spray system of lubrication: This was employed in the earliest days of engine development. The system comprised a sump or crankcase with a set amount of oil enclosed within it. As the rotating crankshaft and connecting rod dipped into the oil at the bottom of the stroke it picked up and lubricated all of the lower parts of the engine. This type of lubrication under went small design modifications. These included a rod which extended down vertically from the big end bearings, dipping into the oil in the sump and therefore picking up a little more oil. There  were several designs of these. There are also accounts of con-rod and flywheel modifications. These were done for the sole purpose of getting the oil higher up the crankcase. The inherent side effect of this system of lubrication is that the crankshaft was subjected to oil drag as it splashed through the oil in the bottom of the engine.

These early engines employed mainly white metal and plain bronze bearings with crude seals. They were slow revving, being low in performance as well as in crankshaft and gearbox speed. As engines developed, the customer and therefore the manufacturer required more speed and with this came higher revs. The stroke of the latter day engines had to be shortened to attain these revs. With the increase in revolutions came increased performance and higher piston speeds. Basically all the internal workings of the engine were subjected to higher rotating and reciprocating speeds.

Oil development and improvement had crept a long with improved engine designs. The ball type bearing had replaced many of the plain bearings and seals were becoming more effective. A more modern lubrication system was required the keep up with the performance changes.

2. The total loss system: was employed for these more advanced engines. They used a simple oil pump that was hand operated. A typical vintage motorcycle users manual of the day stated that at normal riding speeds (20mph) one pump of oil was needed for every eight to ten miles and at higher speeds (30mph) a pump was required every six miles. The oil for the pump was fed from an oil tank. Before starting one of these engines you had to give it a pump of fresh oil. This topped up the splash lubrication system in the sump, which was still being used, and took care of the bottom half of the engine. Drip feed lubricators were often used in conjunction with hand pumps and were normally set to eight drops of oil per minute.

When using just the manually operated pump, the early motorcyclists sometimes it was found that the engine would run faster if less pumps were given, but only for a short while. This was due to there being less oil drag on the piston and other moving parts. If you were lucky you could flood the engine with a couple of extra pumps to make up for the lost ones that had given you the extra performance that all the early motorcyclists craved for. Oil had to be be more accurately governed and manufacturers decided if this could be done their engines would be more reliable, therefore not leaving a bad reputation for reliability in the hands of  their customers.

3. The dry sump system: was one of the first to be mechanically governed. This system uses two pumps. One feeds oil from an oil reservoir under pressure to lubricate the engine before dropping into the sump. The second pump or scavenge pump then picks up the oil to return it to the reservoir, sometime via the transmission or other parts of the engine that require lubrication. you will find on dry sump engines the scavenge pump is double the size of the feed pump. You should be able top see the scavenge pump working by removing the oil tank filler cap and observing oil being fed back into the tank.

When dry sump engines are laid up for a while there is a tendency for them to back flow on the scavenge side (wet sumping). When you start the engine with a dry sump that has sat for a while and you cannot see any return flow coming into the tank, pour a pint of oil in and wait until you see return flow activity. Then adjust the oil level with a siphon or draining.

4. Wet sump lubrication: was the next development and removed the necessity for an oil tank. It seems to be the most popular system for Japanese motorcycle manufactures. The oil is contained in the crankcase sump, however it is separated or masked from the crankshaft, so as to prevent oil drag and any frictional losses from the oil splash. A pump oils the engines vital components and returns the oil via a filter back to the sump for recirculation.

What types of oil pump are there?

There are four types of oil pumps commonly found on motorcycles. These are:

  1. Gear oil pumps
  2. Piston oil pumps
  3. Centrifugal pumps
  4. Trochoidal pumps
1. Gear oil pumps operate by circulating oil through a set of gears, with the gears being closely meshed within a housing of bronze or aluminium.
1. Gear Pump components

1. Gear Pump components

 
2. Piston oil pumps work of an eccentric drive pin or shaft. The pin can be commonly found on the end of the camshaft nut. This in turn drives two pistons, set within a bronze or aluminium body. The body employs spring loaded balls that sit on accurately formed seats. The balls operate in such a way as to create non- return valves through suction and pressure.
2. Piston pump fitted to a Triumph Tiger 100.

2. Piston pump fitted to a Triumph Tiger 100 being restored here at the workshop.

 

2a. Exploded view of a piston pump.

2a. Exploded view of a piston pump.

 
3. Centrifugal oil pumps operate in such a way that they need a round shaft or quill that rotates within a body made of bronze or aluminium. The shaft or quill has a spiral groove cut into its diameter. When it turns it therefore pulls oil along its length, like an Archimedes’ Screw.

 4. Trochoidal  pumps work with a star shaped gear attached to the end of a shaft. The gear is rotated within a metal body which has the same star shape cut into it, but bigger. The body of the pump, usually steel, also rotates within another housing, which is usually aluminium and machined into the engine cases. Oil enters the body and is pressurised in between the finely machined faces on the star and is forced around the engine via outlet ports.

4. Trochoidal pump components. This is the most common now for modern motorcycles.

4. Trochoidal pump components. This is the most common now for modern motorcycles.

 Oil pump restoration and repair

When repairing oil pumps, whether it be for cars or motorcycles, the first thing that has to be done is t o remove it from where it is fitted. The next thing to do with the pump while it is a complete unit is to look at its overall condition. Are the any knocks or dents that might have occurred while removing it. These dents may cause distortions or bad running clearances on shafts or gears within the their housings. When you look at a pump dents or knocks are not always clearly evident, as the may be black oily residue covering the pump body. These oily residues can usually be scrubbed off with petrol or paraffin. Here at Stotfold engineering we aqua-blast them clean. This helps identify any marks on the pump casings. The pump internals are washed in paraffin and blasted with high pressure air.

A gear pump stripped for restoration.

A gear pump stripped for restoration.

Prior to aqua-blasting the pump should be stripped down completely. Take notes on how it come to pieces and lay the parts out, so that you recognise them for reassembly. Use a digital camera if you think you will forget. Once all the parts are laid out it is time to clean and inspect them, taking note of wear and running clearances. When we rebuild pumps we always set running clearances to 0.001″. This leaves enough gap for hot oil to get between all of the running and pumping parts. It is worth taking into consideration that if any parts such as spindles or pinions are worn, they can be precision ground to just clean them up. The holes they run in can be then bored out and bushed to suit the new spindle diameter. I have not yet found a pump that could not be restored.

Fully restored oil pump completed by us.

Fully restored oil pump completed by us.

It is now time for reassembly. Each part has been meticulously cleaned and checked. Once reassembled, with any nuts replaced or wired up if necessary, it is time to oil it and run it to see if there are any tight spots. This can be done using a drill on low speed. Then check the it operates freely using  just your hand. It should run freely. You can now reinstall the pump.

 

By Terry Ives

 

 

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HONDA CB750 FOUR PART 7 – construction continues with the first part of the wiring.

Monday, January 25th, 2010
1. Work on the Honda CB750 cafe racer project continues

1. Work on the Honda CB750 cafe racer project continues

From day one of this cafe racer project I have always had it in my mind that all wiring should be well and truly hidden. To many really good creative bikes are made with little or no thought for the wiring. I like my wiring tidy and when ever possible hidden. When you decide to build the bike you have always wanted, or a bike you think that manufactures should have made, some elements of the build will always be compromised by budget, the shear practically of the idea or the simple fact it would take to long to make.

Too many people are fearful of wiring and hence it is usually one of those areas of a bike that gets neglected. If you are prepared to spend a little time and effort a neat and tidy custom loom can be made. The basic equipment for making your own loom is an assortment of different coloured wires, a soldering iron, solder, heat shrink, electrical tape, and a few connectors.

‘Vehicle Wiring Products’ have a good range of various electrical supplies and can be found on the web. To save money, if you can find a scrap car, you can remove its wiring harness and recycle it. Ideally new cars that have been written off, so their harnesses are quite new. This will give you a variety of colours and the harness will be longer than a bikes, so giving you plenty for adjustment. Wire where the copper core has gone black and tarnished should not be used. It will be hard to solder and will be more prone to failure.

Connectors are really not that important, as you can solder all wiring without using them. The advantage of no connections is that there are no breaks in the wire and the potential for corroding connectors is avoided. The disadvantage is that if you have to remove a part it will need to be cut off and re-soldered back on. I have built bikes in the past with no connectors and aimed to keep all wires as intact as possible. There is good sound reasoning for this. Any break or connection in a wire creates resistance and the accumulative effect of this is voltage drop. For example, if you have a poor headlight output; you change the lens, the bulb and think the application of a fully charged new battery would cure it.  You failed take into account the half a dozen old connections between the battery and the bulb. It might have been more cost effective to replace the wire between the two with new wire with less breaks.

Manufactures of motorcycles tend to have plenty of connections and redundant wires. The reason being is that they have to sell their bike in many different countries and so need to add extra or different parts to the same model of bike. If you construct your own loom you can eliminate these unnecessary wires and simplify others. The routing of the cable can be improved too as they are often placed for ease of manufacture. There is nothing worse that seeing a load of cable ties on a frame tube. It smacks of poor design and lack of thought, hence wiring should be of equal importance to that flash end can you got for your exhaust system. In the planning stage of custom bike building it is one of those thing often overlooked.

Front exit for the wiring loom near the ignition box.

2. Front exit for the wiring loom near the ignition box.

For my bike the wiring will be as simple as possible and run where ever practical in the frame tubes. I planned the route of the wiring in advance when I was modifying the frame. The main harness will run up the main tube under the tank and exit near the ‘Boyer’ ignition box.

 

3. The finished wiring for the 'Boyer' and coils. Tidiness is next to Godliness

3. The finished wiring for the 'Boyer' and coils. Tidiness is next to Godliness

I decided not to use the con-volute tubing for the harness in the end as shown in photo 2. I heat shrank the whole lot and used the plastic braided harness cover for the length from the head stock to the headlight. One of our stainless steel clips was then used to hold the harness in position. The whole resulting wiring is neat and tidy with the minimum of connections ( photo 3. )

The alternator wires are run in a length of braided hose

4. The alternator wires are run in a length of braided hose

The wiring from the alternator was a bit of a problem but was solved by the use of some braided hose to make a feature of it. A piece of aluminium tube and a stainless ‘P’ clip were used to secure the bottom of the hose covering the wires.

Rear Brembo master cylinder

5. Rear Brembo master cylinder - the stop light wires run in the frame tube.

The rear brake light switch is fed by a wire running down the rear diagonal down tube and exits near the ‘Goodridge’ brake light switch. It is one of the bits of visible wiring, so I covered it with a rubber boot.

Switch gear is keep to a minimum, with the lights wired on permanently, so only a high/low beam switch is required. The other switch required is the engine cut switch and horn button. In the next part I will show you how the rear is wired, the switch gear wire is fitted and how the headlight is arranged.

By Colin Jones

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HYDRAULIC BRAKES – problems and solutions to common faults

Tuesday, January 19th, 2010
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1. Norton Commando double disc conversion.

 From time to time we get the same inquiries about various aspects of motorcycle building. Brakes is one of those subjects. People come into the workshop, phone or email saying ‘my brakes are spongy and how can I fix them’ or ‘my brakes work, but what can I do to improve them’.

Photos no.1 shows my Commando double disc conversion. It features twin “RGM” 12 inch discs with “AP Racing” calipers mounted on “Norvil” sliders. The master cylinder is “AP Racing”. Believe me the bike stops.

 

Pretech six pot caliper mounted on a Honda CB750 four.

2. Pretech six pot caliper mounted on a Honda CB750 four.

 

 

 

Photo 2. shows my Honda CB 750 four featuring a single “Pretech” six pot slim back caliper operating off the original disc and master cylinder.

Both of the above are vast improvements on the original brakes. However some people are very reluctant to even touch the brakes as they think it will cause them to fail and crash as soon as they ride the bike. It really is not that complicated, but if you are at all unsure of you own knowledge or abilities it would be best to speak to us or bring it in for us to work on.

 

 

The most common faults which lead to poor brake performance are the following:

  • Air in the system is the most common of them all. This is caused by the brake not being bled properly after a rebuild, or a loose connection on the hose lines, banjo bolt or bleed nipple  allowing air into the system.
  • Sticking pistons in the brake caliper allowing the pad to constantly run on the disc, causing friction and heating the fluid. The fluid boils and generates air bubbles so leading to spongy brakes.
  • Leaking fluid from the master cylinder seals or piston seals allows air into the system.
  • Worn out or tired brake hose. These degrade over a period of time so leading to greater expansion of the hydraulic fluid and loss of performance.

Obviously these are the four most common problems. Physical damage, like an accident can also lead to problems or just bad positioning of a brake hose leading to it rubbing on another part of the machine.

SERVICING YOUR BRAKES: Once you have stripped your brakes, clean them thoughly and blow small oil ways through. Cleanliness is important as any dirt will cause damage to seals and reduce performance. Once reassembled with new seals, ensure firstly that all connections are tight. Use new copper washers on banjo bolts and make sure the bleed nipple is clean and not blocked with road crap. It is common for them to get blocked, especially if the caliper is mounted under the swinging arm, where it is punished by road dirt. This position on the bike will also be rough on the pistons and this is often the cause of seizure. Some bikes will have gaiters on the pistons to help protect them, but nowadays this is not often the case.

Rear brake stipped and cleaned for re-assembley

3. Rear brake stripped and cleaned for re-assembly

4. Finished rear brake assembled on the CB750 cafe racer project. Modified from an early Suzuki RGV250.

4. Finished rear brake assembled on the CB750 cafe racer project. Modified from an early Suzuki RGV250.

 BLEEDING THE BRAKES: The main  problem people often encounter is that they struggle to bleed the brakes. They assemble the brake back on the bike and try to bleed it with no success. Sometimes this works and the brakes are fine. However you should look at the position of the bleed nipple. Air is often trapped in the calipers nooks and crannies and no matter how much bleeding you do it will not come out. Simply take the caliper off and bleed with the nipple at the highest point. Rotate the caliper if necessary until air bubbles pop out of the bleed tube. Remember to place a tyre lever or some other flat piece of metal between the pads to stop piston coming out.

Speaking of equipment for bleeding, I have always used a length of clear plastic tube only, no non-return valve or fancy pressurised kits are really needed. Just ensure the tube is tight on the nipple head and long enough for the end to sit in the brake fluid bottle. However it is easier to bleed with two people.

The procedure: No.1 presses  the lever down. No.2 opens the nipple, allows fluid and air out, then shuts the nipple. No.1 then lets the lever out. The cycle continues until all the air is  removed and the brakes are firm. Every so often stop and just pump the lever to see how firm it is getting. Obviously the fluid is topped up as you go. A problem you may encounter is that the fluid may become air rated and fully of tiny air bubbles. In this case just leave it to settle for few hours before going again. It amazing what an overnight break can do for an air lock. Some calipers have two bleed nipples for each side of the caliper and this can be useful for easy removal of the air.

If you are still having problems getting the air out, stop a while, check the system for oil tightness, if all is OK then sometimes hanging the brake caliper with the bleed nipple at its highest point and tying the lever back under load over night can help.

Brake fittings

5. Various brake fittings

BRAKE FITTINGS : Most people nowadays upgrade their old rubber hose with new higher strength braided hose. I use “Goodridge” build-a-line hose now as it much easlier to fit and is easily obtained off the shelve from most motorcyle shops now. You can see the new build-a-line hose on the left in photo 5. The older hose, on the right in the same photo, was harder to fit as the banjo had to be postioned exactly in the right position for it to prevent the hose being twisted when fitted. With this new hose you simply bolt your banjos in position and then screw the hose on. Motorcycle shops sell it in all the common lenghts and it comes in 25mm increments. Banjos are also sold in various angles.

By Colin Jones

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HONDA CB750 FOUR PART 6 – the start of the final build

Monday, January 11th, 2010
Things starting to come together. Engine in, front end on, oil tank in, battery in, shocks mounted, and swinging arm in.

Things starting to come together. Engine in, front end on, oil tank in, battery in, shocks mounted, and swinging arm in.Forward view of the construction. Wiring and exhausts are left for later.

Forward view of the construction. Wiring and exhausts are left for later.

Forward view of the construction. Wiring and exhausts are left for later.

Finally I have reached the stage of reconstruction. The frame has returned from the painters (‘Full Range Finishes’ – Letchworth) and the swinging arm freshly chrome plated (‘Doug Heath’ – Baldock). Firstly the frame was prepared with new head races and all the threads cleaned. The engine was placed on the bench on its side. The frame was then lifted over the engine. This is the easiest method of putting the engine in the frame without giving yourself a hernia. Items like the alternator, oil pump, clutch, oil filter and sump pan can be put on later. Anything to keep the weight down for insertion into the frame. Once in the frame, all the above parts were fitted.

I then put the front end back in complete, as I had already finished and assembled it. The oil tank was then fitted and the hoses to the engine and the oil cooler were also put into place. The modified ‘Dresda’ swinging arm was fitted with the ‘Hagon Nitro’ shocks. The custom battery box and battery were mounted. The 31mm CR special carburettors are mounted and connected to the throttle linkages. I then placed all the electrical  components into place; the micro digital box, single phase regulator and micro coils. The rear sets were then fitted to the rear frame hangers.

Next time I will talk about the wiring and some of the teething problems I have encounted. Until next time, wishing you all a happy new years motorcycling.

By Colin Jones

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AQUA-BLASTING – information & guide to this type of suface cleaning

Sunday, January 10th, 2010
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Stotfold Engineering's Aqua Blasting machine. 'Comet' wet blasting unit made by Abrasive Developments Limited.

NAMES: Aqua-blasting, also known as vapour blasting and wet blasting.

WHAT IS AN AQUABLASTER?: Essentially it is a machine that operates using a medium compressed air supply and a high pressure pump. The sump of the cabinet type aqua-blaster contains water and a measured amount of media. The water and the media are mixed in the sump. The high pressure pump forces the mixture through a rubber hose to the gun, which is usually manually held via  two apertures in the cabinet that have rubber gloves fitted on flanges inside. The whole cabinet is rendered waterproof through the rubber seals to the side door. The door is for loading any work or article into the cabinet. Aqua-blasting cabinets normally have a rotating table within the center of the cabinet. This is used to rotate heavy items, such as engine casings or other difficult to maneuver parts. The table is normally rotated manually by the operator.

HOW DO AQUA-BLASTERS CLEAN?: Aqua-blasters clean materials as well as surface etch. The cleaning process takes place when water and the media are passed through a nozzle at high velocity. The velocity is important and can be made manually through air intake pressure adjustments. The nozzle, which is made of tungsten, guides the water and media in a controlled stream. When this stream of water and media is directed at the surface of the item to be cleaned. The surface of the item is subjected to an erosive affect.

The point of putting parts through this erosive or scrubbing cycle using aqua-blasting is to clean them down to the original base material. For example we were given a ‘Primus’ camping stove that had heat proof paint on it. The camping stove case was made from very thin metal and would not stand up to aggressive treatment, such as shot or sand blasting. The aqua-blaster was set to just strip the paint down to the base metal. This is done by controlling the air pressure or adjusting the distance the nozzle is from the work. The paint was stripped and only the bare metal was visible. Now the bare metal had to be subjected to the erosive effect of aqua-blasting. This was procured by playing the nozzle and fourth across the item until the desired satin finish was to ones liking and all the paint and rust had been removed.

The erosive or scrubbing affect on the surface of bare metal, when you get through the layers of paint or rust, is non-aggressive, in other words it does not have an adverse effect on the surface structure of the base metal, in fact a beneficial effect. 

WHAT EFFECT DOES AQUA-BLASTING HAVE ON MATERIALS?:Take a set of crank cases for example. When they are sand-cast, they were left to weather or age before they were fitted with all internal components, as were the cast iron parts such as the cylinder liners and cylinder heads. The natural aging of these parts was crucial to let them settle down and loose all of the inbuilt stresses created through the casting process. Later modern castings are pressure fed die castings for greater mass production. These have lots of stresses in them and they retain them.

I was given a set of die cast crankcases to experiment on. Firstly I cut through the fly wheel housing with a milling cutter. I then measured the amount of distortion caused by this machining. I then took the same cases and aqua-blasted them. I then replicated the previous milling machining on the flywheel casing. The amount of distortion on the aqua-blasted case was 75% less than on the non-blasted case. This bares out the advantages of aqua-blasting. We have however had not problems with distortion on sand-cast castings, whether aqua-blasted or not.

Triumph T140 crankcases aqua-blasted

Triumph T140 crankcases aqua-blasted

 Aqua-blasting not only cleans down to the base structure, but also normalises it. The scrubbing action of aqua-blasting on the base metal is found to have no adverse affects on material stability, whether it is in thick or thin sections.

When we propel a media alone, such as shot or sand-blasting without having water involved, the media hits the object at a force of its given velocity. When the impact of the media takes place on that object it will have an adverse or restructuring effect on the material it bears on. The application of water into the mixture gives a cushioning effect to the blasting process, allowing all impurities on the surface to be removed without damaging the structure of the material.

A Ducati Mach 1 engine being restored here at the workshop. All the main engine parts were aqua-blasted before assembly.

A Ducati Mach 1 engine being restored here at the workshop. All the main engine parts were aqua-blasted before assembly.

WHAT MEDIA PRODUCTS DOES AQUA-BLASTING USE?:Almost anything can be used in conjunction with water to produce a clean satin finish. Varying the media has only a slight affect on the final product finish. Media’s include; glass (150-200 micron), calcium carbonate, olivine, almandite, garnet, and aluminum oxide. All these produce a nice satin finish that is sought after by the classic motorcycle and car fraternity.

WHAT CAN AQUA-BLASTING CLEAN?:Aqua-blasting struggles on some paints, most of all powder coating and also some of the casing paints found on Japanese motorcycle engines. We usually use a stripper, such as ‘Nitromors’, to remove and soften the coating before finishing with aqua-blasting. Sometimes this require several re-applications to fully clean the object and it can be quite time consuming. Aqua-blasting  cleans the gummy lacquers from carborettors and most paints from steel and aluminium surfaces. Oil stains on engine cases and con-rods can also be removed.

WHAT SHOULD YOU NOT AQUA-BLAST?: There is no discernible change in diameter or bore on objects after aqua-blasting, however surfaces that require running fits and tight clearances should not be touched with any type of blasting equipment. They should be masked off with tape or covered. The following should not be aqua-blasted:

  • Big end bearings : although needle roller cages can be blasted.
  • Pistons : the reason being it upsets the diameter patterns of the circumferential grooves that pick up oil to lubricate the piston skirt.
  • Small end gudgeon pins
  • Any white metal or lead bronze materials that have a bearing surface
  • Valves: unless the stems have been masked of.

WHAT ARE THE MAIN USES OF AQUA-BLASTING?: Aqua-blasting is used mainly in the restoration, renovation, and preparation of metals and some other materials. Aqua-blasting has also become favourable for graffiti removal.

At Stotfold Engineering we cater for classic and vintage motorcycle and car clubs. Work includes engine & gearbox casings, crankcases, engine covers, barrels, carburettors, frames & swinging arms and many other vehicle components. Any stripped down basic component can aqua-blasted by us. We can aqua-blast steel, brass, titanium, aluminium and cast iron. If we repair aluminium or cast iron for you we can then finish the item off with aqua-blasting to hide any signs of repair.

WHY IS AQUA-BLASTING MORE ADVANTAGEOUS THAN SHOT-BLASTING?: Firstly shot-blasting is a destructive process. It erodes metal surfaces, leaving them open to further corrosion, unless immediately painted with a phosphate type paint. Shot-blasting produces dust, heat and releases toxic bi-products into the atmosphere. It also wears out hoses and nozzles at a greater rate and so this cost has to be passed on to the customer. Because aqua-blasting uses a aqueous media it does not produce dust or heat. Heat produces rust  on bare metal surfaces. With aqua-blasting there are not toxic or chemical compounds to attack the atmosphere or earth as the bi-products are filtered out by a special water trap. Aqua-blasters run for hours on a single fill of media; grit, bead or glass etc..The aqua-blasting nozzles and hoses last thousands of hours longer than the equivalent shot-blasting fittings.

WHY IS AQUA-BLASTING MORE COST EFFECTIVE?: As previously explained there is less waste, less wear on parts and no toxic wastes. All of these factors have a positive impact on the customers costs.

HOW SHOULD THE PARTS BE CLEANED AFTER BLASTING?: It is imperative that all parts are meticulously cleaned after using any grit based cleaning. After general rinsing and washing grit can still be lodged in small orifices like carburettor jets, oil ways and any other small cavities and voids. Stotfold Engineering, after aqua-blasting, completely removes every particle of grit from parts by washing in paraffin and then ultrasonically cleaning them. Sound expensive, but you should take into account that an engine can expire very quickly from a few particles of grit. Here we also recommend that any new build engine should be started and run, on any cheap mineral oil of the correct grade, brought up to working temperature and then have the oil and filter changed. This allows the engine to be fully flushed of any possible grit contamination.

By Terry Ives

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