Monday, December 19, 2011

DESPAIN ADDS THREE WINS WITH SCE GASKETS


Although the 2011 racing season didn’t end the way he wanted it to, Elliott Despain was still excited about the year in which he went to victory lane on three occasions. In seven years of Open Wheel Modified competition, Despain now has a total of ten wins.

“Our main goal going into the 2011 season was to get back into the win column”, said Despain. “We didn’t get to wave the checkered flag last year, so these three wins definitely gave us a huge boost of confidence.” 

Of the three wins, two of them came at Ponderosa Speedway in Junction City, KY. Elliott would visit victory lane for the first time ever at “Kentucky’s Baddest Bullring” on June 24. After a second place finish here on July 22, he returned to take his second win of the year at the central Kentucky D-shaped oval on October 30.  

“We love racing at ‘The Pond’”, stated Despain. “We’ve been really close to getting a win there in the past and to finally get one felt great. And then to go back and get another one felt even better.” The other win occurred on July 2 at Lake Cumberland Speedway in Burnside, KY.    

Besides the three wins, Elliott also accomplished another goal by finishing fifth in series points while competing in the American Modified Series. The AMS is a regional series sanctioned by the United Midwestern Promoters Open Wheel Modified division that competes at dirt track racing venues in Indiana, Kentucky, Ohio and Tennessee.

Of the eight races on the 2011 AMS tour, Despain Motorsports would score three top ten finishes which included a sixth place finish at Moler Raceway Park in Williamsburg, OH, a seventh place finish at Bluegrass Speedway in Bardstown, KY and an eighth place finish at Bloomington Speedway in Bloomington, IN.  

“After finishing fourth last year in the AMS, we knew that to get into the top five again would be a huge task for us,” replied Despain. “We raced against the best Open Wheel Modified drivers in the four-state area this year, and to finish fifth in the series is a huge accomplishment for our team.” Elliott will be honored for his series accomplishment next month at the UMP national awards banquet in Springfield, IL.

FINAL 2011 American Modified Series Championship Point Standings
1. Bryan Barber (Greensburg, KY) - 1,880
2. Joey Kramer (Hanover, IN) - 1,835
3. John Demoss (Bloomington, IN) - 1,815
4. Michael England (Glasgow, KY) - 1,795
5. Elliott Despain (Campbellsville, KY) - 1,465
6. Kelly Warren (Columbia, KY) - 1,300
7. Rocky Wilson (Hodgenville, KY) - 1,185 ®
8. Trent Young (Hopkinsville, KY) - 895
9. J.T. Ayers (New Haven, KY) - 875
10. Matt Hamilton (Aurora, IN) - 755


Another highlight of the 2011 racing season for Team Despain was competing in the “35th Annual Winternationals” at East Bay Raceway in Gibsonton, FL. Although he scored a sixteenth place finish on the first night of the series and a DNS on the second night, Despain left the sunshine state with a bit of pride.


“To not only race against some of the best Modified drivers in the country, including NASCAR stars Ken Schrader and Kenny Wallace, but to make the race was one of my career highlights”, said Despain. “I can’t wait to go back down there next year and see if we can’t improve a bit and at least get a top ten finish.”

As Despain reflected back on the 2011 racing season, he knows that none of it would have been possible without the help and support of his sponsors. “We are very fortunate to have the best of the best sponsors that any Modified driver can have”, said Elliott. “We can’t thank them enough for what they do for our team and we look forward to another successful season of racing with them again in 2012”.

Wednesday, December 7, 2011

Given the choices.. why would one use a copper head gasket?

Let’s dig into it because there are applications (perhaps more than you think) for which copper head gaskets are the best choice. To be sure, copper has been around for a while and with good reason. Let’s walk through some of the attributes and benefits unique to copper, then we’ll get ready to put them on.

Malleable: Copper is stronger than any composite head gasket yet still malleable so it conforms to the sealing surfaces. This strength-malleability combination is, more than any other attribute, the ‘selling point’ of copper as a head gasket material over other materials. While the advantages of strength are self evident, the benefits of a malleable gasket body are somewhat more nuanced. Simply put; conformity makes a tighter seal which will show up in lower leak down percentages.

Metal-to-Metal: To an engine builder, the words “High Performance” pre-suppose high pressure, high pressure requires a more robust combustion seal and the best combustion seal is metal-to-metal. I’ll elaborate; many cylinder head gaskets are coated with sealants designed to eliminate fluid leaks. From experience, readers of this article will be familiar with the various types from slick to sticky and while these work well for fluid sealing they are not able to withstand combustion pressure and heat. No matter how good an elastomeric coating may be for coolant or oil, it will eventually scrub off, burn off, or blow off the fire ring area of the head gasket and in performance engines this can happen in a surprisingly short period of time. Once the sealant is gone from the fire ring combustion seal it’s a short trip to the nearest coolant passage. Silicone, or other rubber-like sealants or coatings should never be placed on the combustion seal in performance engines.

 Options: Copper comes in a wide range of thickness choices; (from .021” to .093” in roughly ten thousandths increments) providing the options necessary to optimize piston to valve, piston to head and in wedge combustion chambers, piston to quench area.

Conductivity: Copper is the standard for conductors, in head gaskets we don’t care about electricity but we do deal with heat. Superior conductivity benefits performance and racing engine builders in two primary ways: A. block & head temperatures are more even. B. Combustion chamber hot spots are dissipated quickly. Cylinder block/head temperature parity is an aid to tuning, though frankly, it’s a minimal factor until you reach the narrow end of the tuning window. The big advantage of conductivity is in the combustion chamber area. In and around the combustion chamber standard composite head gaskets and MLS head gaskets are somewhat insulated from the cylinder head and block by the facings and coatings respectively. Heat related failures occur more often with composite and MLS head gaskets than with copper because the heat is trapped within the gasket body allowing hot spots to intensify, whereas the copper being both a better conductor and having direct contact with the block and head (remember metal-to-metal) transfers the heat to the heat exchanger, aka the cooling system, through the head and block.

Elasticity: Another interesting feature of copper, this benefit comes into play when you’re out of the tuning window far enough to actually damage the head gasket. Un-alloyed or pure copper has a 25% coefficient of elasticity; cool term, here’s what it means. In a 4 inch section, the copper head gasket will stretch to 5 inches before it ruptures. This gives the user a ‘safety factor’ not available with other head gasket materials. Blown, nitrous or turbocharged engines can develop cylinder pressures high enough to lift the cylinder head or push the gasket. A typical bad-actor in this regard is the small block Ford; get some good cylinder heads, add some boost or nitrous, she’s goin’ fast but Daddy wants more and.. the head gasket is peekin’ out between the bolts. If this happens with copper the damage is apparent but the head gasket hasn’t yet failed. The safety factor of elasticity allowed the copper gasket to push but still remain intact so you can either back it down & make the next round or back it down & drive home. If you push a composite gasket, game over.

Do Copper Head Gaskets Require Different Torque Values?

Generally No. Fastener torque values are determined in relationship with the cylinder head and block structure. Arbitrarily increasing torque values will distort the block or head. However, there are good cases for fine tuning the torque values based upon how the head gaskets look after the first use. A nice thing about copper head gaskets is that you can ‘read’ them very easily once you know what to look for and, what to look for is evenly distributed clamp load. No gasket works in isolation, all gaskets require clamp load to do what they do and copper gaskets tell you where the clamp load is light by keeping their shine. Specifically, you want to see machining marks from the block & head surfaces transferred to the copper gasket body everywhere on the gasket. Places where the original finish of the gasket remains need some attention. Keep in mind there may be other factors in play such as, a ring dowel counterbore that has become too shallow from surfacing or a head nut bottoming on the threads of a head stud. Once you have eliminated any mechanical obstruction preventing the head from seating properly you can safely increase torque values in the light load areas by 5 to 10 ft lbs.

What about re-torquing? Solid copper (like a liquid) does not compress, it displaces. Since the copper gasket body does not compress no re-torque is technically necessary. However, since the engine build using a copper head gasket is almost always within the realm of performance or racing, I always recommend one re-torque of the head bolts after a complete heat cycle.





Block & Head Preparation for Copper Head Gaskets:

Cleanliness is next to..You might be surprised at some of the samples we’ve received from customers asking “why did it fail?” Then again if you’ve been around for a while, you may not be surprised at all. I have seen head gaskets with sawdust, sand and actual small rocks embedded in them, as well as the remains of facing material from the previous head gasket. The aircraft industry has an acronym that’s suitable here; FOD, Foreign Object Damage. Like leaving a wrench in the lifter valley, rocks in the combustion seal are not ok, chaos will ensue. So, as Momma taught us: let’s be clean when we’re doin’ our duty. Use a residue-free solvent such as aerosol brake cleaner and a clean rag on the head and block sealing surfaces before assembly.

Flat: Of course the block & head should be flat within .002” across and .004” lengthwise, with surface finish of 60 to 80RA preferred, 60 to 100RA acceptable.

Combustion Sealing: Head gasket sealing is a matter of balance and more pressure is needed on the combustion seal than other areas of the gasket, this is due to the vast difference in pressures acting against the head gasket. Consider that an engine developing 1.5 to 2 horsepower per cubic inch will have between 1000 and 1200 psi in the combustion chamber while, less than 1/2” away, the cooling system is running at 22psi max. Since a standard copper gasket is flat, clamp load from the tightened head bolts will be distributed evenly unless some method is used to ‘tip the balance’ and concentrate the proper load on the combustion sealing area. When using flat copper head gaskets, the accepted method has been to install O-rings in the block or head sealing surface around the bore or chamber respectively, to accept an o-ring. What’s an o-ring you ask? Simpler than you think, it’s just a piece of wire tapped into a groove that sticks out enough to pinch the copper gasket. Well, maybe that’s an over simplification but all you have to know from there are the proper dimensions of the O-ring groove.

Sealants Required? Yes, some method of sealing is required if the engine will be running coolant or oil through the head gasket. I state it this way because many racing specific engines either A. do not run coolant or B. re-route the coolant and oil away from the head/block mating surfaces. Since most engines run coolant and oil through the head gaskets we’ll discuss head gasket sealants. Most importantly, you don’t need very much; second, don’t use silicone.. that about covers it. People get into trouble with leaking head gaskets when they use too much sealant, especially too much silicone. Since the block and head surfaces are flat, the potential leak paths are very small, even with a 100RA surface finish the peaks and valleys are only about .002”, which doesn’t require very much sealant to be fluid-tight. Head gasket dressings do not cure, therefore, as the head bolts are tightened the sealant ‘flows’ from the places it’s not needed (peaks) but remains in place to seal the leak paths (valleys). By contrast, silicone cures to form a layer that the cylinder head can sit on, never actually coming into contact with the head gasket (refer back to our discussion about metal-to-metal above). We recommend and use both KW Copper Coat and Hylomar in the aerosol cans, simply spray a light coat on both sides of the gasket, let it ‘tack up’ for a while (no less than 2 hours) and you’re ready to bolt the heads on.

We could go into much more detail about each of these items if this was a technical manual but my hope is that this information will be of help to you when the need arises, or you need some options that are not available from conventional head gaskets.

SCE Gaskets manufactures a complete line of racing and performance gaskets including standard flat copper head gaskets of the type discussed here.  As well, we offer our patented self sealing (no sealant required) copper head gaskets for use with O-rings and self sealing copper head gaskets with Integral Combustion Seal O-rings (no machining required). We also have a complete line of replacement gaskets for passenger cars, light trucks, vintage and tractor engines marketed under our Engine Master brand.

Wednesday, November 30, 2011

SCE Gaskets’ product line grows with major acquisition

SCE Gaskets is pleased to announce that SPM Gaskets, LLC of Spencer, Iowa is now a part of the family. The acquisition adds significantly to the product offering of SCE Gaskets in the form of embossed and composite head gaskets, vintage automotive and tractor engine gaskets, marine gaskets and engine rebuild gasket sets for all popular domestic and import applications.

SCE Gaskets’ California location will continue to handle new product design, tooling and production of copper head gaskets, copper exhaust gaskets, injection molded gaskets, and heavy duty truck gaskets. SPM Gaskets’ Iowa manufacturing plant produces engine rebuild gasket sets along with all other engine gaskets for automotive, marine, tractor and industrial applications.

Ryan Hunter, SCE Gaskets added, “We continue to expand the vision of SCE to meet the changing economy, automotive and mechanical industries. SPM was a natural fit for our expansion as they have built a stellar product reputation second only to our own. Combining our customer service, innovation and quality principles we believe our SPM and SCE customers will be incredibly excited about the merger and the added benefits this means for them.”

For more information about SCE and SPM please contact at SCE Gaskets, Inc. 1-800-427-5380.

About SCE Gaskets: Established in 1989, SCE Gaskets quickly became the biggest name in Copper Gaskets and now offers cutting edge engine gaskets of all types. SCE is the world leader in racing and hard core engine gaskets. Several gasket categories such as embossed copper exhaust gaskets, self sealing copper head gaskets, and Integral Combustion Seals are the result of SCE Gaskets' racetrack-to-roadway innovations. SCE Gaskets are made in the USA!

About SPM Gaskets: SPM was founded in 1975 by Ronald Van Pelt and incorporated in 1976. With significant growth and sales the small start up grew to a 30,000 square foot, Spencer, Iowa facility by 1987. SPM is a leader in gaskets and seals for the Automotive, Antique, Marine and Industrial industries. SPM is the manufacturers’ gasket maker.

Tuesday, October 11, 2011

Head gasket failure

·         What, including detonation, leads to head gasket failure?

Detonation; what you can’t hear will still hurt you.. Or, if it runs on gas but sounds like a diesel, have your camera ready..

We’re discussing internal combustion engines not dynamite so, in context, detonation is defined as: “a premature spontaneous burning of a fuel-air mixture inside an internal-combustion engine”. Detonation is the result of a second flame front that ignites as a result of; rapidly increasing pressure from the compression stroke and ignition of the spark induced flame front.  Detonation occurs after the spark plug fires (as opposed to pre-ignition which occurs.. well, prior to ignition) and the resultant spike in pressure delivers a blow to the ascending piston and combustion chamber so severe that you can hear it in the driver’s seat (open headers can make it tough to hear but the damage is still happening). The effect of detonation is very similar to whacking the piston with a sledgehammer as it approaches TDC, except that the impact is more widely distributed. If allowed to continue, detonation will eventually lead to component failure, how soon depends upon the engine output per cubic inch. High horsepower-per-cubic-inch engines develop higher combustion pressures and in turn, deliver a harder ‘hit’ under detonation. Therefore, most readers of this article won’t have much time to ‘detect and correct’ before something blows up, or out. Though it may seem odd for a head gasket manufacturer to say, the preferred component to fail is the head gasket. Why? Because it’s cheaper than pistons, rods, crankshafts, cylinder heads or blocks. In this case the head gasket acts as a fuse. Learn to read your head gaskets, it’s the closest you’ll ever get to having your engine talk to you, “Houston.. we have a problem..”

Cleanliness is next to..

You might be surprised at some of the samples we have received from customers asking “why did it fail?” Then again, if you’ve been around racing for a while, you may not be surprised at all. I have seen head gaskets with sawdust, sand and actual small rocks embedded in them, as well as the remains of facing material from the previous head gasket. The aircraft industry has an acronym that’s suitable here; FOD, Foreign Object Damage. Like leaving a wrench in the lifter valley, rocks in the combustion seal are not ok, chaos will ensue. So, as Momma taught us: let’s be clean when we’re doin’ our duty. Use a residue-free solvent such as aerosol brake cleaner and a clean rag on the head and block sealing surfaces before assembly.

Hot Stuff..

Aside from the obvious, (poor machine work, dirt & debris on the sealing surface, uneven surfaces) a composite performance head gasket will fail from excessive temperature. Sometimes it’s difficult to determine which happened first, the high temperature or the gasket failure, regardless, it is imperative to find the culprit. High temperature can be caused by: detonation, plugged coolant system, inadequate radiator or fan(s) incomplete coolant filling or low water pump volume. A few really sharp engine builders have recently been able to add some insight about heat related head gasket failures. In short; the coolant temperature gauge may not be telling the whole story. If coolant filling is incomplete or flow (velocity) is too low, localized hot spots may develop around the combustion chamber. These ‘hot spots’ can cause the coolant to boil locally which in turn damages the head gasket. The kicker is; this localized boiling event can take place while the overall system temperature is registering at or near normal. The way to combat this is to have a water pump that moves A LOT of water and some electric water pumps are not up to the task. 

Ryan Hunter

SCE Gaskets, Inc.