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A Replacement Engine Brings Back That New Car Feeling..

May 31st, 2009

Many times I have seen a customer agonize over whether to just go buy another car or have a replacement engine installed in their current car while upgrading the cooling system and various other related components such as the catalytic converter at the same time.

Assuming your car or truck is in good operating condition other wise, why would you spend multiple thousands of dollars on another car when you can spend two to three thousand dollars on a replacement engine with a great warranty?

The greatest money saver you will run across when your car has a major issue such as an engine failure is to replace or repair the engine in your car, instead of replacing the whole car.

For a car or truck that is in good overall condition you can accomplish two things, one is that your car will move again after you put a rebuilt or good used engine in your vehicle. The other thing that happens is that now that your car runs like new again, you probably forgot how nice your vehicle ran before. Often we don’t notice the slow decline in performance and gas mileage loss during the period an engine deteriorates and then fails because we are so used to our cars “feel”.

People often call GotEngines.com back to thank them and let the experts know how much they appreciate the good advise they were given in terms of what the best choice was in  used replacement engines. Surprising as it may sound, when an individual has a serious engine problem and ultimately a failure, they suddenly realize how bad the car was running. The first thing that comes to mind upon driving the vehicle with a fresh engine is how much different the car feels and that it would have been a waste of money to buy a new car as a knee-jerk reaction.

This is the most important thing I will ever say about replacing an engine. Call GotEngines.com first, you will find out why they out perform every other engine supplier around.

Many of the suppliers of used, rebuilt and new replacement engines include some related critical parts to engine life with the package. They don’t want any problems or excuses either.

When I owned my repair shop from 1981 to 2006 (I sold it), we built excellent relationships and confidence in our customers. Customers were required to return in two weeks for a free warranty recheck of the work we performed on their car, almost always the first two things that came out of their mouths’ were “how wonderful their cars drive now that it was performing like it used too, and they were very pleased with their decision and happy to have kept the car and saved literally multi-thousands of dollars by not trading their car in”.

The point of this article is that is that sometimes when you understand a situation well enough to make an informed decision, not a knee-jerk decision it builds confidence in your ability to make good decisions. That almost always makes you feel good about yourself and better about your car. FYI, I still drive my 1988 GMC 1 ton pickup truck. I bought it new and have maintained it just like I recommend in the GotEngines.com Blog articles presented here for free. Enjoy.

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New Mercedes Benz diesel engine…OM 651: completely new design

May 31st, 2009

The four-cylinder OM 651 diesel engine is a completely new design. It only shares its overall displacement of 2.15 liters with its predecessor (to be precise: 2143 cc, predecessor 2149 cc). It has a completely different geometry, however. While the bore and stroke were previously roughly square, the new engine is a long-stroke unit with a smaller bore of 83 mm and a stroke of 99 mm. We call this undersquare in design terminology.

The compression ratio has been reduced from 17.5:1 to 16.2:1. The advan­tages include smooth idling even when cold, despite the undersquare confi­guration.

The pistons are of aluminum. Owing to the long-stroke design, an omega shape was chosen for the piston crown. This wide, flat crown works well with the long injection spray lengths of an undersquare engine. An optimized combustion process significantly reduces the carbon footprint.
Owing to the long stroke, the forged, weight-optimized connecting rods are short, which is an advantage in terms of strength. The forged crankshaft with eight counterweights rotates in five bearings. It is very low in vibrations, thereby contributing to the smoothness of the engine.

Camshafts are driven by gear-wheels and chain setup. The DOHC camshafts operate a total of 16 intake and exhaust valves using roller-type tappets with hydraulic valve adjustment. The camshafts are driven by a combination of gears and a short duplex chain. Great attention to detail has reduced the louder noise normally associated with gear-driven camshafts.
As before, a common-rail system is used to inject the fuel. This design ensures highly precise and therefore economical fuel metering for each cylinder, as well as smooth running. The maximum injection pressure has been increased 1800 bar in the new engine generation.

The new injectors are free of leaks, therefore no additional line is necessary to return fuel. This improves thermal management of the injection system and makes it unnecessary to cool the fuel. A compact dual-plunger injection pump generates the necessary pressure in the rail, while a throttle valve regulates the charge level.

The developers put great attention to the turbocharging. This is not only of decisive importance for the rated output and torque, but also for power delivery and responsiveness. In the basic 70 kW (95 hp) version, the engine is aspirated by a single-stage turbocharger with variable turbine geometry. This ensures a high level of efficiency and rapid response.

In the other output versions of the Mercedes four-cylinder engine, a further development of the two-stage turbocharging installed in a van for the first time in the preceding model is used. In this case a small high-pressure turbocharger works together with a large low-pressure turbocharger. The two turbines are connected in series. At low engine speeds only the compact high-pressure unit is active, which means that a high charge pressure can already be built up at very low engine speeds.

Thanks to specific improvements to all these units, this combination achieves both very good responsiveness from low engine speeds and excellent operating characteristics at high engine speeds, as well as top performance across the whole engine speed range. The driver does not notice the switchover from one to two-stage operation and back, and the engine characteristics correspond to those of a large-displacement diesel engine.
This so-called downsizing – high output and torque from a comparatively small displacement – is a precondition for low fuel consumption, the resulting, low level of emissions and low weight.

Lets hope the downsized Mercedes diesel engine with additional horsepower does not have the problem Ford has had with downsizing the 7.3 L diesel to 6 Liters.

It is important for you our readers to know what the future will bring us in engine technology. Even though we don’t expect to sell many of these new design Mercedes engines, GotEngines.com blog continues to bring the latest in new technology to you.

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Nissan Cube, cute, economical and affordable…

May 31st, 2009

It is easy to tune out the marketing sensationalism spewed out to the press about new-car introductions. But in the case of the new Nissan 2009 Cube, GotEngines.com likes  Nissan’s marketing strategy for its boxy creation.

In explaining the Cube , Nissan uses the nickname “mobile device,” and the company clearly hopes that this car will gain the social status of an Apple product.

The problem with this comparison is that Apple products tend to be trendy and expensive,  they’re status symbols that perform— whereas the Cube is unusual and affordable. If you’re looking for the automotive iPhone, it’s not the Cube. It’s the Shelby Mustang GT-500KR.

If you like fast Nissan cars, get one with the RB26EET engine in it..

The Cube is the trendy new breed, from brick like shape to its shag-carpet dashboard pad to the bungee cords on the doors.

The fact that Nissan sees the Cube as a design statement first, and a car second, comes through in the driving experience. Unlike a Toyata Scion xB, which maintains some pretense of performance, the Cube’s hardware is a mellow vibe. You get 15- or 16-inch wheels, a 1.8-liter 122-horsepower 4-cylinder engine and either a continuously variable automatic transmission (C.V.T.) or a 6-speed manual. Excellent braking system updates,

The 1.8 S model, at $15,410, is the lowest-price Cube available with the automatic transmission. Normally, Either the manual transmission or the variable automatic are available, but the C.V.T. seems well-suited to the Cube. If you’re driving in a relaxed manner, the C.V.T.  keeps the engine speed low and constant, imparting the feeling that the car is propelled by some kind of distant unseen force. The C.V.T.’s ability to make the most of the 1.8-liter motor is reflected in its impressive city fuel economy rating of 28 miles a gallon (30 m.p.g. on the highway). The manual Cube manages 24/29.

Among the subset of weird little boxy Asian runabouts (including the Scion xB, Honda Element and Kia Soul, the Cube is the most outrageous. It’s easy to poke fun at some of the Cube’s glaring silliness, but I admire a car that takes chances the way the Cube does.

Affordable, for sure because the Cube is available as a $15,000 car.

Keeping you posted on some of the new fuel efficient cars is part of our job at GotEngines.com Blog. Keep an eye on the future, but don’t arbitrarily replace your car if the engine fails. Talk to our experts at 1-888-344-8044, before you decide..

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Advantages of single overhead camshaft engines (SOHC)…..

May 31st, 2009

Finishing up the What is a Single Overhead Cam Engine post:

The main advantages of SOHC Engines Compared to DOHC Engines

A single overhead camshaft set up basically represents a simpler version of the more complex dual overhead cam engine. As indicated in its name, a dual overhead cam uses two camshafts per bank of cylinders to regulate valve control causing greater weight to be added to the engine.

Due to lighter valve-train weight, a single overhead cam engine also features a performance advantage over dual overhead cam setups with lower end torque values.

The single overhead valve configuration is quite mechanically friendly and allows modern engine builders a great deal of performance-seeking freedom.

Both single and dual overhead cam engines can easily facilitate variable valve timing. First developed for the dual overhead cam engine, Honda’s VTEC system was modified for use with single overhead cam engines. However, due to size constants within the cylinder head in this configuration, the VTEC valve timing can only be exercised on the intake valve.

Current SOHC Engines in Production

Besides Honda VTEC engines, a leading champion for single overhead cam technology is the 2 valve and 3 valve version Ford Modular engines powering the Mercury Grand Marquis as well as the Ford Mustang. With pushrod valve-trains commonly associated to American muscle engines, Ford had previously produced a limited number set single overhead cam of 427 V8 engines to compete with Chrysler’s HEMI engine on the NASCAR circuit.

One of the largest engines incorporating the single overhead cam setup is the Mercedes-Benz V12 engines available on the SL Class, as well as S65 and SL65 AMG. Attributed to saving weight, the single overhead cam V12 can also earn credit for 510 horsepower and 604 horsepower, respectably

The two articles on SOHC engines should provide enough info to understand them in simplicity. GotEngines.com at 1-888-344-8044 has immediate delivery on nearly every SOHC engine on the market today. We also provide information on many other aspects of your car on our GotTransmissions.com Blog. Subscribe for free and enjoy.

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What is a Single Overhead Cam Engine (SOHC)??

May 28th, 2009
SOHC engine

SOHC engine

Highly efficient in design, a single overhead cam(SOHC) engine potentially generates a higher engine speed permitting greater revolution per minute(RPM) than compared to older style pushrod-driven overhead valve (OHV) powerplants. Gaining attention like they were invented recently, today as advanced, single overhead cam engines were successfully used in racing back to the 1920s when the famous Bugatti used it on their Type 35 Grand Prix car. Find someone with an old ’60′s used Ford Fairlane that had the Ford SOHC side oiler engine for the fastest ride of your life..

While not seen in widespread production until the about 1980s, single overhead cam as well as double overhead cam (DOHC) engines have now pressed OHV engines into a declining minority.

Overhead cam relates to the presence of the camshaft located over the cylinders. The designation for single overhead cam relates to a bank of cylinders meaning only one camshaft is used on in-line engines. On V pattern engine blocks, two cylinder banks are present taking the total number of camshafts to two. Capable of directly actuating the valve’s rocker arms, this is a most efficient design over more traditional pushrod engines. Besides eliminating the weight for up to 16 pushrods in V8 engines, there is a lesser amount of energy lost allowing for faster camshaft and crankshaft RPMs.

Similar to other valvetrain arrangements, a chain or rubber belt runs from a gear at front of the crankshaft to the camshaft maintaining the engine timing. Where it differs is that the distance between the crankshaft and camshaft requires a timing chain to stretch longer. For V pattern engines, the need to control two camshafts requires an additional timing chain.

We have covered the basic function and theory of SOHC engines today. There are some really cool SOHC engines built in the past and currently being produced, check our GotEngines.com blog for the next installment on SOHC engine application and usage..

 

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Continuation article on catalytic converters…

May 28th, 2009

Part-2 continuation post from yesterdays ‘Cat’ post.

On 1996 and newer vehicles that have On Board Diagnostics II (OBD II), there is a “catalyst monitor” that monitors the operating efficiency of the converter. A second oxygen sensor is mounted behind the converter to compare oxygen levels in the exhaust before and after the converter.

Under normal operating conditions, the downstream O2 sensor should have little switching activity. But if the rate at which the downstream O2 sensor is switching starts to increase, it tells the OBD II system converter efficiency is dropping and there’s a potential emissions problem. If the problem may cause emissions to exceed 1.5 times the federal limit, the Malfunction Indicator Lamp (MIL) will come on and the PCM will log a diagnostic trouble code for “catalyst is below threshold efficiency” (P0420, P0421, P0422, P0430, P0431 or P0432). The bottom line here is you have a bad converter — unless the problem is something else like a bad oxygen sensor or open fuel feedback control loop.

Contamination causes failures:

When other reactive substances find their way into the exhaust, they can cause problems with the catalyst inside the converter.

Prior to 1975, tetraethyl lead was used to boost the octane rating of gasoline and to lubricate the exhaust valves. When catalytic converters were added in 1975, leaded gasoline was gradually phased out. Fuel restrictors were incorporated into the fuel filler inlet pipe so motorists couldn’t fill up with the leaded gasoline — but many managed to defeat these devices because leaded fuel was cheaper than unleaded. Eventually, leaded fuel disappeared in the U.S. so this should not be a concern unless somebody fills up a car with racing fuel or is traveling south of the border.

Phosphorus is the main additive used nowadays that ruins a converter. Phosphorus is found in motor oil. So is zinc, which can also cause trouble. Normally these trace metals do not cause a problem. But in a high mileage engine with worn valve guides, rings and/or cylinders, oil burning can pump enough oil into the exhaust to foul the converter. Once this happens, there is no fix other than to replace the converter. Trouble is, the new converter will eventually suffer the same fate as the old one unless the cause of the oil burning is also repaired — which typically means a rebuilt or used replacment engine.

Sulfur is another contaminant. It is found in small amounts in gasoline. As long as the concentration is limited, it causes no problem. But too much sulfur in a tank of bad gasoline can create a rotten egg odor in the exhaust and cause the converter to ignite at a higher than normal temperature, which ncreases pollution and probably damaging the converter.

Silicone is an ingredient in traditional antifreeze. Silicone is used to provide corrosion protection for aluminum parts. As long as it stays inside the cooling system, it has no effect on the converter. But if the head gasket starts to bleed coolant into the combustion chamber, or the head develops a hairline crack that leaks coolant, silicone can get into the exhaust and ruin the converter. As with phosphorus contamination, it is essential to eliminate the source of the coolant leak before the converter is replaced, otherwise the new converter will have the same fate as the old one.

If the converter has failed because of contamination, the oxygen sensors should also be checked because they may be contaminated, too.

When a converter gets too hot:

The converter can handle quite a bit of heat. High levels of pollutants coming out of the engine cause the catalytic converter’s temperature to increase dramatically. This can damage the converter.

If the converter overheats (1800 degrees F-plus), it can actually melt the ceramic honeycomb inside the shell. The result may be a partial or complete blockage that causes a sharp increase in exhaust backpressure and a big drop in driveability and fuel economy. If the converter is completely plugged, it will cause the engine to stall or damage it. This is where a remanufactured or used engine comes into play.

Underlying causes here include things like fouled spark plugs, bad plug wires, leaky engine valves or a leaky head gasket. Any of these can allow large quantities of unburned fuel to pass into the exhaust. .

Checking for restrictions is easier and doesn’t require any special equipment. A restriction problem might be suspected if your engine has a power loss, uses a lot of gas, or stalls after it starts and won’t restart until cooldown. A good diagnosis will prove it.

Low intake vacuum readings are a classic symptom of to much backpressure which may be due to a plugged converter.

Note the reading at idle, then hold rpm at 2,500. The needle will drop when you first open the throttle, then stabilize. If the reading then starts to drop, backpressure is building up in the exhaust system.

You can also attempt to measure exhaust backpressure directly. If the car has air injection, disconnect the check valve from the distribution manifold, and insert a pressure gauge. Or, remove the oxygen sensor and take your reading at its hole in the manifold or headpipe. Refer to the backpressure specs for the application. Generally speaking, more than 1.25 PSI of backpressure at idle, or more than 3 PSI at 2,000 rpm tells you there’s a blockage.

A “bump it” test on the outside with a soft rubber mallet will tell you if the catalyst inside is loose. You should not hear any rattling inside a monolithic converter. If you do, it means the honeycomb inside is broken.

If you suspect a blockage, one can try disconnecting or removing the cat and starting the engine. If it perks up, have your converter swapped out for a new one.
 
As with any engine problems, it’s important to diagnose and repair the cause of the the problem first.

The EPA’s has strict rules for replacement: a competent repair shop cannot simply replace a converter until it is out of factory warranty and a qualified need for replacement has been established and documented. The repair shop must also obtain your authorization for repairs in writing, keep the paperwork for a period of time, as well as the old cat to prove it’s case.

The replacement converter must be the same type as the factory original and installed in the same location. .

The federal emission warranty on OEM converters is at least 8 years or 80,000 miles. If your OEM converter is still under warranty, you should be able to get a free replacement from your new car dealer. If it is out of warranty, you can take it to any on the level competent repair shop or change it yourself.

Replacement converters must be certified to meet the factory standards. We have covered catalytic converters in full now on the GotEngines.com blog……to add more info to our library for your benefit.

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Automotive engine catalytic converters or ‘cats’- part-1…

May 28th, 2009

What is the one of most important emissions control devices on a vehicle today? The catalytic converter, because it helps cleans many exhaust pollutants that exit the engine. It operates at temperatures of 600 to 1000 degrees F.

BTW: Parking over a pile of dry leaves or the like can start a fire..

If the converter does its job efficiently, the vehicle will meet emissions and pass both a tailpipe emissions check with an OBD II emission scanner, a plug-in emissions tester.

The causes of failure that can actually damage an engine to the point of engine replacement basic overheating of all internal engine components thus damaging seals, rings and all hardened parts leading to a failure.

TYPES OF CATS

Before we go any further, we need to take a quick look inside the converter to understand how it operates. Inside the outer shell, which is usually stainless steel, is a ceramic or metallic honeycomb sprayed with a very thin coating of special reactive metals. These metals have the properties needed to ignite the chemical process. They are not used up over time, but become full so to speak over time.

The first converters came out in about 1975 were “two-way” or “oxidizing” converters because the catalyst only reacted with hydrocarbons [HC] and carbon monoxide [CO] in the exhaust.

The power-train control module [PCM] adjusts the air/fuel mixture when the engine is warm by manipulating the rich/lean signal from the oxygen sensor in the header exhaust pipe. By rapidly changing the air/fuel mixture back and forth, the overall mixture averages out and keeps emissions at a minimum.

On some newer vehicles, a new type of oxygen sensor, also called an “air/fuel ratio” sensor) is used. Instead of producing a high or low voltage signal, the signal changes it’s attitude in direct proportion to the amount of oxygen in the exhaust.

This provides a more precise measurement for better fuel control and tells the PCM the exact air/fuel ratio.

I realize this is a complicated article to understand. The most important thing to know is that a clogged cat on any car or truck will inhibit the power and performance dramatically. Possibly cause an engine failure due to heat build up in the engine. I have seen several vehicles, such as a Ford engine needing the be replaced with a used engine due to forcing the vehicle to go when it clearly had a problem and lacked power. 

I have also installed a used Toyota engine in Tundra pickup that had severe cat problems. Read our next post on GotEngines.com Blog, completing your catalytic converter education.

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Modis: automotive engine diagnostic scan tool…

May 27th, 2009

The Modis is a professional diagnostic tool that lets you pinpoint and diagnose today’s sophisticated vehicles such as the Mercedes engines faster. This scan tool is the standard of the industry and rightfully so. We used one of the early Modis Scan tools in my shop. I do not recommend it for home use since it cost about ten thousand dollars..

Although not many engine suppliers use tools like this to insure every unit sold is 100% healthy, company’s like GotEngines.com use them to test every engine for defects before it gets shipped. One reason the rate of problems with used engines supplied by <strong>GotEngines.com</strong> is less than 5%. And that is low..

The highly technological system incorporates advanced  (on-board diagnostic) capabilities including Domestic and Asian Import Vehicle Communication Software, plus a cool feature for instant diagnosis, called Fast-Track Troubleshooter; it actually combines software that integrates experience-based information with scan tool instrumentation solutions. The MODIS system also features a powerful 4-channel lab scope with multiple secondary ignition capabilities and a powerful Digital Graphing Multimeter built into it.

Fast-Track Component Tests combine MODIS scope and DVOM (digital volt ohm meter) instrumentation with information direct from factory-trained and ASE-certified master technicians to quickly locate, connect, test, and troubleshoot components. It’s a hand-held with everything you need for today and tomorrow.

The particular scanner system gives you fast one stop access to  Domestic and Asian Import Vehicle Communication Software, supported by the Snap-On tools. Add to this a fast 4-channel lab scope, digital graphing multimeter, and Fast-Track itemized component tests and you are the fastest tech in the shop. (and the poorest)!

The rest of the information on this tool probably means nothing to most folks. But what I have just said about this tool and comparable ones is one reason a good diagnosis is worth the hour worth of labor that a qualified shop might charge you. FYI, at my shop, we diagnosed for free, no charge, no obligation. It was a courtesy to who ever stopped in for work.

I could go on and on ‘hipping’ you up to the really cool diagnostic tools available through many companies, but I think perhaps that is for future posts. Our point at GotEngines.com Blog is this:…it is much more cost effective with a  successful outcome  paying the diagnosis fee (which in some cases is absorbed by the shop upon repair) than to arbitrarily change parts. For instance, buying a 700.00 dollar computer, when you had a fourty dollar bad part.

Lets see…$80.00 dollars to diagnose and $40.00 dollars for a part and $75.00 dollars labor is $195.00, which beats a $700.00 on-board computer that did not fix the problem..I hope you lighten up on your mechanic now. He paid a lot of money for the tool and his years of experience are priceless.

GotEngines.com at 1-888-344-8044…

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OBD-1 and OBD-2

May 27th, 2009

Brian, the founder of GotEngines.com is a sponge when it comes to knowledge. He asked me what is a diagnostic link connector? And I was happy to oblige!!

The ALCL link (Assembly Line Communications Link). Or more commonly referred to as a DLC (Diagnostic Link Connector).

All OBD-1 and OBD-2 cars, although the OBD-2 connector has to be located in the passenger compartment next to the steering post, easily accessible from the driver’s seat. You will most likely find the connector right below the steering column!

Legally, the connector OBD-2 must be located within three feet of the driver and not require tools to be accessed. Check under dash and behind ashtrays.

On-Board Diagnostics, or OBD-1, in an automotive reference to a generic term referring to a vehicle’s self-diagnostic and reporting ability. OBD-1 systems give the vehicle owner or a qualified repair technician access to state how healthy various vehicle sub-systems are.

Using a scan tool, or scanner, the amount of diagnostic information available by OBD-1 has become more and more technologically advanced since the introduction in the early 1980s of on-board vehicle computers. Early instances of OBD-1 would simply illuminate a malfunction indicator light, or MIL, if a problem was detected—but would not provide any information as to the nature of the problem.

Modern OBD-11 systems use a standardized digital communications port to provide real time data in addition to diagnostic trouble codes, or DTCs, which allow one to rapidly identify and remedy malfunctions within the vehicle.

All cars built since January 1, 1996 have OBD-II systems. Variations actually were put in use in isolated cases in 1994. OBD-II signals are most often sought in response to a “Check Engine Light” appearing on the dashboard or drive ability problems experienced with the vehicle. The data provided by OBD-II can often pinpoint the specific component that has malfunctioned, saving substantial time and cost compared to guess-and-replace repairs. OBD-II signals can also provide valuable information on the condition of a used cars engine health before purchase.

With the advent of OBD-11, the actual DLC became standardized on autos manufactured world wide. The beauty of this is that all OBD-2 DLC’s have the same connector, meaning the scan tool does not need a prioritized DLC connector for each brand of car, as we did and still do on Pre-OBD-2 cars. OBD-1 requires a different connector for every make of car, which really adds up since there are more than 20 connectors available.

I have talked about hand held code readers and affordable scan tool for home use. A full blown professional scan tool that pinpoints problems and then helps run through series of tests to diagnose the problem can cost from $4000.00 bucks up to over $10000.00. Not a realistic tool for the homeowner. Without even mentioning the training and time and practice a mechanic needs in order to effectively use it.

The point we want to make in our GotEngines.com Blog post today is that if the engine light turns on, get it checked ASAP. You may actually have an engine problem, since this lite is also hooked to the transmission, in essence. Saving money is having your vehicle scanned before any repair work is done. The old days of replacing parts until the problem is solved is more expensive with the introduction of expensive electronic components, such as computers.

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What is an engine ‘camshaft’ and what does it do?

May 26th, 2009

A camshaft or ‘bumpstick’ as it has been known as in the automtive field is a shaft with eccentric lobes on it. The camshft is driven by a chain, gears or a timing belt and the eccentric lobes move the valves in the head up and down in the proper sequence.  

Some engines use pushrods to push the valves open and closed, some engines have a single overhead camshaft to move the valves and some engines use a double overhead camshaft to move the valves up and down..The only engines that use a different system are old lawnmowers and most of the pre-40′s car engines. These engines are called a ‘flat head’ design and are obsolete.

Regardless of the particular design of an engine, the camshaft is hooked to the crankshaft in the engine with a timing belt or gears or a chain and move in synchronization with the crankshaft. This is what we call timing. We want the valve to open at the proper time or they will hit the pistons and probably cause a engine failure.

I have mentioned that people who ignore their timing belts almost inevitably end up buying a rebuilt engine from GotEngines.com. Any model of rebuilt engine is on hand from Honda engines to Land Rover engines. Every rebuilt engine sold by GotEngines.com has a new camshaft installed. Camshaft lobes wear out and cause a very slow and unnoticable loss of power. Generally the power loss is not noticed until the camshaft or engine is replaced.

Regarding valves, lifters and pushrods, lets say for today these are directly related components to the camshaft and will be discussed more in the near future. We provide this sort of information on our GotEngines.com blog as a source of information top help make engine replacement decisions easier and safer.

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