Cadillac engine knowledge
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− | == | + | ==Cam degreeing== |
Cam degreeing benefits from advancing the cam timing 2 degrees, as these engines had a retarded cam in stock form for emissions. Attach the degree wheel to the crank with a 9/16 fine thread bolt. | Cam degreeing benefits from advancing the cam timing 2 degrees, as these engines had a retarded cam in stock form for emissions. Attach the degree wheel to the crank with a 9/16 fine thread bolt. | ||
+ | ==Transmissions== | ||
The basic 472 and the later 500 engines both use a standardized Buick/Pontiac/Olds/Cadillac bellhousing pattern, so a Turbo 400 automatic will bolt right up to the back of the block as long as the proper Cadillac flexplate and torque converter are used. The Turbo 425 front-drive automatic transaxle also fits these engines as used in the Eldorado, although a special dual-sump oil pan and pickup are used with these transmissions due to the required halfshaft clearance. Any rear-wheel drive engine can be converted to front-drive and vice versa if the proper oil pan and pickup are used, although 2 of the main cap bolts must be removed and swapped to mount the pickup's bracket. Another good thing about these engines using a Turbo 400 transmission is that a B/P/O/C patterned case can be stuffed with the Chevy 4x4 tailshaft and associated hardware for use in an off-road truck. The engine weight is approximately 600 pounds fully dressed and splits the difference between small and big block Chevy, so suspension modifications are not usually necessary. Transfer case choice for a 4x4 should be a 205, as fitted to some mid/late '70's Chevy 1 ton trucks. The 205 is a strong gear-driven transfer case and holds up nicely to the big Caddy's torque output. | The basic 472 and the later 500 engines both use a standardized Buick/Pontiac/Olds/Cadillac bellhousing pattern, so a Turbo 400 automatic will bolt right up to the back of the block as long as the proper Cadillac flexplate and torque converter are used. The Turbo 425 front-drive automatic transaxle also fits these engines as used in the Eldorado, although a special dual-sump oil pan and pickup are used with these transmissions due to the required halfshaft clearance. Any rear-wheel drive engine can be converted to front-drive and vice versa if the proper oil pan and pickup are used, although 2 of the main cap bolts must be removed and swapped to mount the pickup's bracket. Another good thing about these engines using a Turbo 400 transmission is that a B/P/O/C patterned case can be stuffed with the Chevy 4x4 tailshaft and associated hardware for use in an off-road truck. The engine weight is approximately 600 pounds fully dressed and splits the difference between small and big block Chevy, so suspension modifications are not usually necessary. Transfer case choice for a 4x4 should be a 205, as fitted to some mid/late '70's Chevy 1 ton trucks. The 205 is a strong gear-driven transfer case and holds up nicely to the big Caddy's torque output. | ||
+ | ==Engine mounting== | ||
When bolting these engines into most any application, use the stock-type Cadillac Eldorado engine mounts, oil pan and associated pickup tube. Fabricate a set of 3/8 inch thick plates to be bolted between the crossmember. The big Cad has the mount bolts 3-1/2 inches ahead of where the Chevy mounts are when measuring from the stock Chevy engine to transmission bellhousing mating surface. For a 4x4 truck, the engine usually fits well with crossmember and framerail notches to clear the oil pump. If the truck originally ran a Turbo 350 transmission, the crossmember goes back about 3 inches and custom driveshafts will need to be made up to fit. These should run the large 1 ton U-joints for longest life. | When bolting these engines into most any application, use the stock-type Cadillac Eldorado engine mounts, oil pan and associated pickup tube. Fabricate a set of 3/8 inch thick plates to be bolted between the crossmember. The big Cad has the mount bolts 3-1/2 inches ahead of where the Chevy mounts are when measuring from the stock Chevy engine to transmission bellhousing mating surface. For a 4x4 truck, the engine usually fits well with crossmember and framerail notches to clear the oil pump. If the truck originally ran a Turbo 350 transmission, the crossmember goes back about 3 inches and custom driveshafts will need to be made up to fit. These should run the large 1 ton U-joints for longest life. | ||
+ | ==Oil pumps== | ||
There are different oil pumps for the big Cadillac engines. One faces forward from the block at a 45 degree angle downward. The next faces downward 45 degrees and points right toward the bottom of the crankshaft pulley. There is another that I have not seen that has been described as pointing more outward than the first one I described. These can all be interchanged, but make very sure to properly clean the oilpump and block mating surfaces and always use a new oil pump gasket. The correct gaskets will be from major gasket manufacturers, and should be only something like 0.005" thick if I remember correctly. An oil pump gasket that is too thick will cause more oil to bypass the pump gears and allow more end play of those gears too, something you do not want. | There are different oil pumps for the big Cadillac engines. One faces forward from the block at a 45 degree angle downward. The next faces downward 45 degrees and points right toward the bottom of the crankshaft pulley. There is another that I have not seen that has been described as pointing more outward than the first one I described. These can all be interchanged, but make very sure to properly clean the oilpump and block mating surfaces and always use a new oil pump gasket. The correct gaskets will be from major gasket manufacturers, and should be only something like 0.005" thick if I remember correctly. An oil pump gasket that is too thick will cause more oil to bypass the pump gears and allow more end play of those gears too, something you do not want. | ||
+ | ==Clearance issues== | ||
In cars, the clearance problems are usually at the front crossmember, the exhaust manifold at the driver's side and possibly the airbox on the firewall. This can be dimpled with fibreglass or sheetmetal if necessary. Streetrods usually have sufficient room to drop the big Cad in. The fit is tight like with a big block Chevy, but the only change required will be in motor mount placement. Most all vehicles requiring a rear-sump oil pan and pickup can use the Eldorado pan and pickup tube, or a mid-sump pan and pickup as found on the smaller 368-425 Cadillac engines of '77-'79 vintage. Stock exhaust manifolds may be used, or aftermarket block-hugger style headers can be sourced from Sanderson. In most cases where a big block Chevy header can be used, the Chevy flanges can be removed and Cad flanges can be made up quite easily. The primary tubes may need a bit of tweaking to line up with the ports with this method. Remember that the front and rear drive exhaust manifolds are different for the driver's side. This may help in routing the exhaust if it looks like a tight fit on that side. | In cars, the clearance problems are usually at the front crossmember, the exhaust manifold at the driver's side and possibly the airbox on the firewall. This can be dimpled with fibreglass or sheetmetal if necessary. Streetrods usually have sufficient room to drop the big Cad in. The fit is tight like with a big block Chevy, but the only change required will be in motor mount placement. Most all vehicles requiring a rear-sump oil pan and pickup can use the Eldorado pan and pickup tube, or a mid-sump pan and pickup as found on the smaller 368-425 Cadillac engines of '77-'79 vintage. Stock exhaust manifolds may be used, or aftermarket block-hugger style headers can be sourced from Sanderson. In most cases where a big block Chevy header can be used, the Chevy flanges can be removed and Cad flanges can be made up quite easily. The primary tubes may need a bit of tweaking to line up with the ports with this method. Remember that the front and rear drive exhaust manifolds are different for the driver's side. This may help in routing the exhaust if it looks like a tight fit on that side. | ||
+ | ==Intake manifold== | ||
Stock carbureted intake manifolds benefit from a 1 inch spacer under the carburetor, adding around 15 horses. Because of the bathtub-type steel intake gasket, plate stock and exhaust tubing can be fabricated into a tunnel-ram style dual carb manifold. I built one of these to use the Quadrajets from 4.1 liter Buick V-6 engines, as two of these with straight linkage feed the big motor quite well. The bathtub gasket can be reused by using a bit of Permatex to seal the block and head surfaces by encircling the ports to prevent an internal vacuum leak on both sides of the gasket. | Stock carbureted intake manifolds benefit from a 1 inch spacer under the carburetor, adding around 15 horses. Because of the bathtub-type steel intake gasket, plate stock and exhaust tubing can be fabricated into a tunnel-ram style dual carb manifold. I built one of these to use the Quadrajets from 4.1 liter Buick V-6 engines, as two of these with straight linkage feed the big motor quite well. The bathtub gasket can be reused by using a bit of Permatex to seal the block and head surfaces by encircling the ports to prevent an internal vacuum leak on both sides of the gasket. | ||
+ | ==EFI== | ||
The factory EFI system used from '75-'76 on 500 cubic inch engines is a ported injection system which operates similarly to the familiar Chevy tuned port injection. It appears like a large throttle body on an intake with separate fuel injectors. Each cylinder has its own injector mounted in the intake runner near the intake gasket area with a common fuel rail feeding all 8. This system was also used through 1979 on Sevilles as standard equipment and as an option on full size cars. It consists of four main systems; the ECU, the fuel delivery system, the air distribution system, and the sensors which supply information to the ECU. The ECU is a pre-programmed computer that analyzes the sensor information and computes the exact fuel requirements based on that information. It supplies the proper amount of fuel by opening the injectors for a specific amount of time, which varies as the engine operating conditions change. The fuel system consists of 2 fuel pumps (1 in tank, 1 on chassis), the fuel filter, the fuel presure regulator, the fuel rails and lines, and the injectors. The fuel system runs with a pressure reading of 39 to 55-95 PSI. A relief valve protects the system from excessive fuel pressure. The fuel regulator maintains the pressure in the fuel rails at 39 PSI for proper injector operation. The injectors are divided into 2 main groups, one for cylinders 1, 2, 7, and 8 and the other group for injectors 3, 4, 5, and 6. All four injectors in each group open simultaneously, with the 2 groups alternating in operation. The air distribution system consists of the throttle body assembly and the intake manifold. The throttle body houses the fast idle valve and the idle bypass air passage. The fast idle valve allows extra air to bypass the throttle blades when the engine is cold and closes as it warms up. The warm idle is adjusted at the idle bypass air passage. The sensors are as follows...MAP(intake pressure), TPS(throttle position), MAT(air temp), CTS(coolant temp), and RPM (engine speed measured at distributor). The MAP sensor is housed in the ECU and a plastic vacuum line connects it to the throttle body. The TPS sensor is mounted on the throttle body and is controlled by throttle blade movement. The MAT and CTS sensors are completely interchangeable. The MAT is located on the intake manifold and the CTS is located on the passenger cylinder head water outlet. The RPM sensor is on the distributor shaft under the cap assembly and sends engine speed and fuel triggering information to the ECU. This system runs in open loop configuration without an oxygen sensor and is quite easy to transplant into any vehicle, as long as all the components are used. The ECU has a separate computer/engine wiring harness that is easily swapped from donor vehicle to the new vehicle with only 4 wires and one vacuum line needing to be hooked up to work properly. All of the servicing information can be found in Chilton's #8587 manual, which deals exclusively with Cadillacs from 1967 to 1989. | The factory EFI system used from '75-'76 on 500 cubic inch engines is a ported injection system which operates similarly to the familiar Chevy tuned port injection. It appears like a large throttle body on an intake with separate fuel injectors. Each cylinder has its own injector mounted in the intake runner near the intake gasket area with a common fuel rail feeding all 8. This system was also used through 1979 on Sevilles as standard equipment and as an option on full size cars. It consists of four main systems; the ECU, the fuel delivery system, the air distribution system, and the sensors which supply information to the ECU. The ECU is a pre-programmed computer that analyzes the sensor information and computes the exact fuel requirements based on that information. It supplies the proper amount of fuel by opening the injectors for a specific amount of time, which varies as the engine operating conditions change. The fuel system consists of 2 fuel pumps (1 in tank, 1 on chassis), the fuel filter, the fuel presure regulator, the fuel rails and lines, and the injectors. The fuel system runs with a pressure reading of 39 to 55-95 PSI. A relief valve protects the system from excessive fuel pressure. The fuel regulator maintains the pressure in the fuel rails at 39 PSI for proper injector operation. The injectors are divided into 2 main groups, one for cylinders 1, 2, 7, and 8 and the other group for injectors 3, 4, 5, and 6. All four injectors in each group open simultaneously, with the 2 groups alternating in operation. The air distribution system consists of the throttle body assembly and the intake manifold. The throttle body houses the fast idle valve and the idle bypass air passage. The fast idle valve allows extra air to bypass the throttle blades when the engine is cold and closes as it warms up. The warm idle is adjusted at the idle bypass air passage. The sensors are as follows...MAP(intake pressure), TPS(throttle position), MAT(air temp), CTS(coolant temp), and RPM (engine speed measured at distributor). The MAP sensor is housed in the ECU and a plastic vacuum line connects it to the throttle body. The TPS sensor is mounted on the throttle body and is controlled by throttle blade movement. The MAT and CTS sensors are completely interchangeable. The MAT is located on the intake manifold and the CTS is located on the passenger cylinder head water outlet. The RPM sensor is on the distributor shaft under the cap assembly and sends engine speed and fuel triggering information to the ECU. This system runs in open loop configuration without an oxygen sensor and is quite easy to transplant into any vehicle, as long as all the components are used. The ECU has a separate computer/engine wiring harness that is easily swapped from donor vehicle to the new vehicle with only 4 wires and one vacuum line needing to be hooked up to work properly. All of the servicing information can be found in Chilton's #8587 manual, which deals exclusively with Cadillacs from 1967 to 1989. | ||
+ | ==Distributors== | ||
Point-type distributors are similar to the familiar Chevy and use the same internal parts, however the internal shaft and the housing are Cadillac only. Ignition parts for the HEI-style distributors are also the same as the Chevy engine uses, with a few exceptions. First, like the points distributor, the shaft and housing are Cadillac only. Also, the distributor will differ between carbureted and fuel injected engines. The fuel injected distributor has a position sensor under the main body that tells the computer the engine speed and when to trigger the proper injectors. If you're not sure what distributor you have, the carbureted version looks the same as the Chevy, and the fuel injected has a square portion with a round 3 pin plug directly above the clamp area. Finally, the hold-down clamp used will depend on the distributor. They don't interchange, so get the clamp when you get the distributor. Best choice for ignition wires would be a cut-to-fit set, as even the stockers do not fit quite the way they should due to the front-mounted distributor location. | Point-type distributors are similar to the familiar Chevy and use the same internal parts, however the internal shaft and the housing are Cadillac only. Ignition parts for the HEI-style distributors are also the same as the Chevy engine uses, with a few exceptions. First, like the points distributor, the shaft and housing are Cadillac only. Also, the distributor will differ between carbureted and fuel injected engines. The fuel injected distributor has a position sensor under the main body that tells the computer the engine speed and when to trigger the proper injectors. If you're not sure what distributor you have, the carbureted version looks the same as the Chevy, and the fuel injected has a square portion with a round 3 pin plug directly above the clamp area. Finally, the hold-down clamp used will depend on the distributor. They don't interchange, so get the clamp when you get the distributor. Best choice for ignition wires would be a cut-to-fit set, as even the stockers do not fit quite the way they should due to the front-mounted distributor location. | ||