Thread: mark IV 454 1983
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03-23-2008 10:30 PM #31
do you trim the edges of the chambers to prvent shrouding from the bigger valves
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03-23-2008 10:34 PM #32
some time s i do the ex there is other things to i feel are worth moreIrish Diplomacy ..the ability to tell someone to go to Hell ,,So that they will look forward to to the trip
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03-23-2008 10:41 PM #33
is there enough meat in that hump in the ex. side to grind most of it off to make a little v off the valve guide
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03-23-2008 10:55 PM #34
Originally Posted by craig akiyamaIrish Diplomacy ..the ability to tell someone to go to Hell ,,So that they will look forward to to the trip
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03-23-2008 10:59 PM #35
Thanks For Your Time
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03-23-2008 11:07 PM #36
yep ok you should look at your rpm and were you will use this engine at .if less then 600 lift cam a 781 049 head should work very good with out to much work just get a good valve job get some s steel valves and grind out any cast junk out of the ports and a bowl job and back cut the ex valves and call it goodIrish Diplomacy ..the ability to tell someone to go to Hell ,,So that they will look forward to to the trip
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03-23-2008 11:27 PM #37
Originally Posted by pat mccarthyIrish Diplomacy ..the ability to tell someone to go to Hell ,,So that they will look forward to to the trip
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03-24-2008 01:56 PM #38
Will cutting duel water ports in my block (duel water flow) make it run cooler
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03-24-2008 03:12 PM #39
Originally Posted by craig akiyamaIrish Diplomacy ..the ability to tell someone to go to Hell ,,So that they will look forward to to the trip
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03-24-2008 06:59 PM #40
I Can't Remember I Read Some Blocks Were Oem Like That(surfing The Web)
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03-24-2008 07:03 PM #41
Originally Posted by craig akiyamaLast edited by pat mccarthy; 03-24-2008 at 07:08 PM.
Irish Diplomacy ..the ability to tell someone to go to Hell ,,So that they will look forward to to the trip
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03-24-2008 08:15 PM #42
Coolant Routing Mk IV/Gen 5/Gen 6
There are two different ways that coolant can be routed through the engine: series flow and parallel flow. Both ways work just fine. There may be a slight preference for parallel flow, but it is not a big deal. Series flow has the water exiting the water pump, flowing through the block to the rear, it then transfers through the head gasket and into the cylinder head through two large passages on each cylinder bank at the rear of the block. The coolant then travels from the rear of the head, forward to the front of the head, into the intake manifold water passage and out past the thermostat and thermostat housing. The water cools the block first, then it cools the head. The coldest water (coming out of the water pump) is directly below the hottest water (having already picked up the heat of the block and the head) as the hot water transfers into the intake manifold. By contrast, parallel flow has the water exiting from the water pump into the block, where a portion "geysers" up into the head between the first and second cylinder, another portion "geysers" up to the head between the second and third cylinders, another portion geysers up to the head between the third and fourth cylinder, and the remainder transfers to the head at the rear of the block. The coolant temperature inside the engine is more even that way. The differences in coolant routing is having (or not having) the three additional coolant transfer holes in each block deck, and three matching holes in the head gasket. The heads have passages for either system, and are not different based on coolant flow.
Be aware that gaskets that DO have the three extra holes between the cylinders often have restricted coolant flow at the rear--instead of having two large coolant transfer holes at the rear, there is only one, and it's the smaller of the two holes that remains. This is important because if you use a parallel flow head gasket on a series flow block, you can have massive overheating and there's NOTHING that will cure the problem except to replace the head gaskets with ones that don't restrict flow at the rear of the block, or to drill the block decks to allow the coolant to flow into the head between the cylinders. Here's why they can overheat: A series-flow block doesn't have the openings between the cylinders, no coolant can flow up to the head there. The gasket may only have the single, smaller opening at the rear, so the amount of water that gets through that opening is greatly reduced from what the block designers intended. The result is that the coolant flow through the engine is only a fraction of what is needed.
Most, but NOT all Mk IV engines are Series Flow. ALL Gen 5 and Gen 6 engines are Parallel Flow. A series flow block can be converted to parallel flow by drilling 3 holes in each deck surface, and then use parallel flow head gaskets. You can use the parallel flow gaskets as templates for locating the additional holes. It's really easy: Put the parallel flow gaskets on the block, mark the location and size of the three extra holes. Remove the gasket. Grab a 1/2" drill and a drill bit of the correct size, and pop the extra holes in the block. There is NO modification needed on the head castings. Some blocks have one of the holes already, but it needs to be ground oblong to properly match the gasket. Again, very easy with a hand held die grinder and rotary file.
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03-24-2008 08:19 PM #43
Coolant Routing Mk IV/Gen 5/Gen 6
There are two different ways that coolant can be routed through the engine: series flow and parallel flow. Both ways work just fine. There may be a slight preference for parallel flow, but it is not a big deal. Series flow has the water exiting the water pump, flowing through the block to the rear, it then transfers through the head gasket and into the cylinder head through two large passages on each cylinder bank at the rear of the block. The coolant then travels from the rear of the head, forward to the front of the head, into the intake manifold water passage and out past the thermostat and thermostat housing. The water cools the block first, then it cools the head. The coldest water (coming out of the water pump) is directly below the hottest water (having already picked up the heat of the block and the head) as the hot water transfers into the intake manifold. By contrast, parallel flow has the water exiting from the water pump into the block, where a portion "geysers" up into the head between the first and second cylinder, another portion "geysers" up to the head between the second and third cylinders, another portion geysers up to the head between the third and fourth cylinder, and the remainder transfers to the head at the rear of the block. The coolant temperature inside the engine is more even that way. The differences in coolant routing is having (or not having) the three additional coolant transfer holes in each block deck, and three matching holes in the head gasket. The heads have passages for either system, and are not different based on coolant flow.
Be aware that gaskets that DO have the three extra holes between the cylinders often have restricted coolant flow at the rear--instead of having two large coolant transfer holes at the rear, there is only one, and it's the smaller of the two holes that remains. This is important because if you use a parallel flow head gasket on a series flow block, you can have massive overheating and there's NOTHING that will cure the problem except to replace the head gaskets with ones that don't restrict flow at the rear of the block, or to drill the block decks to allow the coolant to flow into the head between the cylinders. Here's why they can overheat: A series-flow block doesn't have the openings between the cylinders, no coolant can flow up to the head there. The gasket may only have the single, smaller opening at the rear, so the amount of water that gets through that opening is greatly reduced from what the block designers intended. The result is that the coolant flow through the engine is only a fraction of what is needed.
Most, but NOT all Mk IV engines are Series Flow. ALL Gen 5 and Gen 6 engines are Parallel Flow. A series flow block can be converted to parallel flow by drilling 3 holes in each deck surface, and then use parallel flow head gaskets. You can use the parallel flow gaskets as templates for locating the additional holes. It's really easy: Put the parallel flow gaskets on the block, mark the location and size of the three extra holes. Remove the gasket. Grab a 1/2" drill and a drill bit of the correct size, and pop the extra holes in the block. There is NO modification needed on the head castings. Some blocks have one of the holes already, but it needs to be ground oblong to properly match the gasket. Again, very easy with a hand held die grinder and rotary file.
ebay guides and reveiew
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03-24-2008 09:29 PM #44
o.k. what do you think of this, for double roller timming chain i heard you could cut a small groove in the front half of the first crank bearring to supply oil to hit the back of the timming gear for good chain oiling
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03-24-2008 10:31 PM #45
Originally Posted by craig akiyamaIrish Diplomacy ..the ability to tell someone to go to Hell ,,So that they will look forward to to the trip
Merry Christmas ya'll
Merry Christmas