Intake system for multiple intake valve type engines

Several embodiments of induction systems for internal combustion engines that improve maximum power and also provide good running at low and medium speeds with a good torque curve throughout the engine speed range. Each embodiment includes a pair of intake passages that serve each chamber of the engine through a respective pair of intake valves. The intake passages are each tuned to serve a different running condition of the engine.

BACKGROUND OF THE INVENTION 
This invention relates to an intake system for multiple intake valve type 
engines, and more particularly to an induction system for an engine that 
improves performance throughout the entire speed and load range. 
The techniques of tuning an induction system for an engine are generally 
well known. It is also well known that induction system tuning may 
optimize running at a certain speed and load range; however, performance 
outside of this speed running condition may be deteriorated. For example, 
if the length of the runners of the induction system are tuned to achieve 
maximum power output, performance at low and mid-range may suffer. 
It is, therefore, a principal object of this invention to provide an 
induction system for an internal combustion engine that offers good 
performance over a wide speed and load range. 
It is known that the maximum power output of an engine may be increased by 
providing pairs of intake valves for each chamber of the engine, each of 
which is served by a separate intake passage. Although such arrangements 
improve maximum power output, this may be accompanied by a sacrifice in 
low and medium speed performance, particularly with a reduction of torque 
under these other running conditions. To offset these disadvantages, it 
has been proposed to incorporate a control valve in one of the induction 
passages that is operated so that the low speed requirements of the engine 
are supplied primarily through a single one of the induction passages. 
It is a further object of this invention to provide an improved induction 
system of this type wherein the individual intake passages are tuned so as 
to improve performance throughout the engine speed and load range. 
In engine embodying pairs of intake passages serving each chamber and a 
fuel injection system, it is important to insure that the amount of fuel 
delivered by the injection system is responsive to the total charge 
delivered to each chamber. This is particularly important where a control 
valve is employed as aforedescribed so that the charge at one speed range 
is delivered primarily through only one of the intake passages, and the 
charge at maximum output is delivered through both intake passages. 
It is, therefore, a still further feature of this invention to provide an 
improved fuel feed control for an injection type engine having multiple 
intake passages. 
In conjunction with the provision of a plurality of intake passages for 
each chamber of the engine and the independent tuning of these passages, 
it is important that this be achieved with as uncomplicated a construction 
as possible. It is, therefore, a still further object of this invention to 
provide an improved intake device for an engine embodying multiple intake 
passages. 
SUMMARY OF THE INVENTION 
A first feature of this invention is adapted to be embodied in an induction 
system for an internal combustion engine of the type that has a pair of 
intake ports serving the same chamber of the engine and separate intake 
passages each independently serving a respective one of the intake ports. 
In conjunction with this feature of the invention, the intake passages are 
each tuned differently from the other. 
Another feature of this invention is adapted to be embodied in an induction 
system of the type having a pair of intake ports serving the same chamber 
of the engine, a pair of intake valves for controlling the flow through 
the intake ports, separate intake passages each independently serving a 
responsive one of the intake ports, and fuel injection nozzle means 
disposed to discharge at a point where the flow therefrom may flow through 
either of the intake passages. In accordance with this invention air flow 
detection means for controlling the fuel discharge of the fuel injection 
nozzle means is positioned to sense the total air flow through both of the 
intake passages. 
Yet another feature of the invention is adapted to be embodied in an intake 
device for the induction system of an internal combustion engine. The 
intake device comprises a housing having an air inlet, a first plurality 
of individual air outlets each communicating with a first area within the 
housing that is in communication with the air inlet, and a second 
plurality of individual air outlets each communicating with a second area 
within the housing which second area is also in communication with the air 
inlet. The first area is spaced from the second area for establishing 
different flow conditions through the first air outlets than through the 
second air outlets.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Embodiment of FIGS. 1 and 2 
A multiple cylinder internal combustion engine constructed in accordance 
with a first embodiment of this invention is identified generally by the 
reference numeral 11. Although the invention is described in conjunction 
with a multiple cylinder engine, it is to be understood that certain 
facets may be employed in conjunction with single cylinder engines or 
engines of other than the reciprocating type. 
The engine 11 includes a cylinder block 12 to which a cylinder head 13 is 
affixed in known manner. The cylinder block 12 is formed by cylinder bores 
14 in which pistons 15 are supported for reciprocation. The pistons 15 
drive a crankshaft (not shown) in a known manner. The cylinder head 13 is 
provided with a plurality of cavities 16 that cooperate with the pistons 
15 and cylinder bores 14 to form the combustion chambers. The numeral 16 
will at times be referred to as identifying the combustion chamber. 
The cylinder head 13 is provided with a first intake passage 17 and a 
second intake passage 18 for each combustion chamber 16. The first and 
second cylinder head intake passages 17 and 18 terminate in ports that 
communicate with the respective combustion chamber 16. Intake valves 19 
control the flow through these ports into the respective combustion 
chamber 16. 
Pairs of exhaust passages 21 extend through the opposite side of the 
cylinder head 13. Exhaust valves 22 control the flow from each combustion 
chamber 16 into the respective exhaust passages 21. The exhaust passages 
21 merge and discharge into an exhaust manifold 23. 
Any suitable mechanism is employed for operating the intake valves 19 and 
exhaust valves 22. The valve operating mechanism may take the form of a 
pair of overhead mounted cam shafts, as indicated generally by the 
reference numeral 24. 
An intake manifold, indicated generally by the reference numeral 25, is 
affixed to the intake side of the cylinder head 13 in a known manner. The 
intake manifold 25 is provided with pairs of first and second intake 
passages 26, 27 for each combustion chamber 16. The first manifold 
passages 26 supply the first cylinder head passages 17 while the second 
manifold passages 27 serve the second cylinder head intake passages 18. 
The cylinder head passages 17 and 18 are divided by a wall 28 which 
terminates at an opening 29 that is spaced closely adjacent the intake 
ports and intake valves 19. The passage 29 interconnects the cylinder head 
intake passages 17 and 18 for a reason to be described and extends into 
the manifold 25. Preferably the effective cross-sectional area of the 
passage 29 is at least equal to the effective cross-sectional area of the 
cylinder head intake passage 17. 
A plurality of fuel injection nozzles are positioned with each nozzle 31 
being supported by the manifold 25 in a location so that its discharge 
spray flows into the interconnecting passage 29 and at least a portion of 
it will impinge upon the wall 28. As will be described, this disposition 
of the nozzles 31 insures that fuel will be delivered to the chamber 16 in 
uniform quantities through the engine and load ranges. 
An air intake device, indicated generally by the reference numeral 32, is 
provided for delivering an air charge to the manifold 25. The intake 
device 32 comprises an elongated housing having an air inlet 33 formed at 
one of its ends. The inlet 33 is in communication with an air flow 
detector (not shown) of any known type and which is adapted to sense the 
total air flow into the intake device 32. The interior of the intake 
device 32 is divided into an upper chamber 34 and a lower chamber 35 by 
means of a generally horizontally extending wall 36. The wall 36 extends 
at least in part through the inlet 33 so as to divide it also into an 
upper portion and a lower portion. 
A plurality of first runners 37 are formed by the intake device 32. The 
first runners 37 each extend from the lower end of the chamber 34 to a 
first manifold passage 26. Thus, a first series of intake conduits are 
formed for each combustion chamber 16 extending from the intake device 
chamber 34 and consisting of runners 37, manifold passages 26 and cylinder 
head passages 17. 
A second series of runners 38 are formed in the intake device 32. The 
second runners 38 extend from the lower surface of the lower chamber 35 to 
the manifold passages 27 and cylinder head passagess 18 so as to form 
individual intake tracts for the combustion chamber 16 that have a 
different length than the tract which extends from the housing chamber 34 
to the combustion chamber 16. The reason for this will be as described 
subsequently. 
A main, manually operated throttle valve 39 is positioned in the portion of 
the inlet 33 above the wall 36 and which cooperates with the runners 37. 
The valve 33 is adapted to be operated by a suitable linkage system (not 
shown) under control of the operator. An automatically controlled valve 41 
is positioned in the portion of the inlet 33 below the wall 36 for 
controlling the flow to the intake device cavity 35. The valve 41 is 
operated so that it does not begin to open until the main throttle valve 
39 has a predetermined degree of opening. The point of opening of the 
secondary throttle valve 41 is chosen so that it will occur at a point 
when the engine 11 is operating above a predetermined engine speed and 
engine load. Normally this point will be above or near the upper end of 
the mid range speed and load of the engine. 
In operation, when the engine is running at idle or at low speeds, the 
control valve 41 will be closed and only the manually operated throttle 
valve 39 will be opened. Thus, the air charge for the engine will be 
supplied from the chamber 34 through the runners 37, manifold passage 26 
and cylinder head passages 17. The length of these individual inlet tracts 
is tuned so as to achieve maximum torque at this speed range. Because the 
charge is delivered to the chamber 16 primarily only through one of the 
intake tracts, even though both of the intake valves 19 are opened, the 
charge will enter the chambers 16 at a relatively high velocity and good 
running characteristics will be achieved. 
As the manually operating throttle valve 39 is progressively opened, a 
point will occur wherein the constriction of the intake valve 19 in the 
passages 17 will not permit sufficient charge to enter the chamber so as 
to achieve maximum torque. When this condition occurs, a portion of the 
charge will enter the chambers through the passage 29 and second cylinder 
head intake passage 18. The provision of the interconnecting passageway 29 
permits the charge to be delivered through both intake valves 19 during 
this running condition and torque and mid range performance are 
significantly improved through the use of the passage 29. Because of the 
disposition of the injection nozzles 31 so that they discharge onto the 
wall 28, there will be good fuel distribution to the chamber 16 regardless 
of whether the intake charge is delivered only through the passages 17 or 
through both passages 17 and 18. 
As the load and speed of the engine continues to increase due to continued 
opening of the throttle valve 39, the control valves 41 will be 
progressively opened. Thus, a portion of the intake charge will be 
delivered through the runners 38, manifold passages 27 and cylinder head 
intake passages 18. The length of this inlet tract is tuned so as to 
provide good charging efficiency at maximum engine speeds. Thus, the 
described arrangement promotes good charging efficiency throughout the 
engine speed and load ranges and, furthermore, provides a good torque 
curve, maximum power output, while at the same time maintaining good 
efficiency. By tuning the separate intake tracts serving each chamber, 
these results may be achieved and good charging efficiency insured at all 
engine speeds. Furthermore, since the separate intake tracts are generally 
independent of each other, the pulsations set up in each tract will not 
interfere with those of the other. 
Embodiment of FIGS. 3 and 4 
An engine constructed in accordance with a second embodiment of the 
invention is identified generally by the reference numeral 51. The valving 
and construction of the engine 51, except for the intake manifold and air 
intake device, are the same as the previously described embodiment. For 
this reason, the components which are the same have been identified by the 
same reference numerals and their description will not be repeated. 
In this embodiment, an intake manifold, indicated generally by the 
reference numeral 52, is provided. The intake manifold 52, as in the 
previously described embodiment, has first intake passages 53 that 
cooperate with the individual cylinder head intake passages 17 and second 
passages 54 that cooperate with the cylinder head intake passages 18. In 
this embodiment the control of the air flow through the second manifold 
passages 54 and the corresponding cylinder head second intake passages 18 
is provided by individual control valves 55 which are positioned in the 
manifold 52 in each of the passages 54. Each control valve 55 is supported 
for rotation on a control valve shaft 56 which has an actuating arm 57 
affixed thereto. The actuating arms 57 of all of the control valves 55 are 
pivotally connected to a common actuating link 58 so that they will be 
operated in unison. 
The control valves 55 are operated in response to the engine speed and load 
and for this purpose an actuator, indicated generally by the reference 
numeral 59, is provided. The actuator 59 may be responsive to engine load 
as sensed either by a pressure or pressures in the intake system, by any 
of the well known devices used for this purpose, or may be responsive to 
the pressure in the exhaust system as in the illustrated embodiment. The 
actuator 59 includes an outer housing 61 that is divided into an 
atmospheric pressure chamber 62 and a sensing chamber 63 by means of a 
diaphragm 64. The diaphragm 64 is connected to an actuating rod 65 which 
is, in turn, pivotally connected to the actuating link 58. A coil 
compression spring 66 is positioned in the chamber 62 and normally urges 
the diaphragm 64 and rod 65 to a position wherein the control valves 55 
are either fully or substantially fully closed. 
The chamber 62 is continuously vented to atmospheric pressure by means of a 
clearance that exists between the housing 61 and the rod 65. The chamber 
63 is exposed to exhaust gas pressure by means of a conduit indicated 
schematically at 67 that extends to one of the exhaust passages of the 
exhaust manifold 23. A filter 68 is interposed in the conduit 67 so as to 
preclude the admission of foreign particles into the actuator 59. 
In order to periodically clean the filter 68, an atmospheric inlet 69 is 
interposed between the filter 68 and the actuator chamber 63. The 
atmospheric inlet 69 incorporates its own filter and a check valve 71 
which is normally closed when there is a greater than atmospheric pressure 
in the conduit 67. At such times as a less than atmospheric pressure is 
experienced in the manifold 23, as occurs due to the pulsations of the 
engine, a reverse flow will be induced through the filter 68 by opening of 
the check valve 71 and any particles accumulated by the filter 68 will be 
driven back into the exhaust system. 
The induction system also includes an intake device, indicated generally by 
the reference numeral 72. The intake device 72 includes an inlet portion 
73 in which a single, manually operated throttle valve 74 is provided. 
Unlike the embodiment of FIGS. 1 and 2, the interior of the intake device 
72 is not divided by means of a wall. Nevertheless, separate tuning is 
still accomplished by virtue of short runners 75 that extend from the 
lower wall of the intake device 72 and which connect with the second 
manifold passages 54 and, accordingly, the cylinder head intake passages 
18. As in the previous embodiment, the short runners 75 are tuned with the 
remainder of their cooperating intake passages for maximum performance at 
full power. 
Longer runners 76 are also provided by the intake device 72 and they 
terminate adjacent the upper end of the intake device 72. These longer 
runners 76 cooperate with the manifold passages 53 and cylinder head 
intake passages 17 and as in the previously described embodiment, are 
tuned for low and mid range running. 
The operation of this embodiment is similar to the operation of the 
previously described embodiment except that the control valves 55 are 
operated in response to exhaust pressure rather than the position of the 
throttle valve 74. That is, at low engine speeds the control valves 55 
will be maintained in a closed position by the atmospheric pressure acting 
in the secondary chamber 62 and the action of the spring 66. Thus the 
charge requirements will be primarily supplied through the runners 76, 
manifold passages 53 and cylinder head intake passages 17. As the speed 
and load of the engine increase due to opening of the throttle valve 74, a 
point will be reached when a portion of the intake charge passes through 
the passage 29 and enters the chamber through the intake passages 18 in 
addition to the intake passages 17. Eventually the speed and load will be 
such that the pressure in the conduit 67 and chamber 63 will overcome the 
atmospheric pressure and the pressure of the spring 66 to open the control 
valves 55. Then, maximum power may be achieved. Also, as with the 
previously described embodiment, the individual intake tracts are designed 
to maximize performance throughout the entire speed and load ranges 
without interference from each other. 
It should be readily apparent from the foregoing description that each 
embodiment is effective to provide extremely good running throughout the 
entire speed and load range of the engine and also permits maximum power 
to be achieved. By employing relatively independent intake tracts, the 
induction system may be tuned to a wide range of running conditions and a 
good power and torque curve can be obtained. Although two embodiments of 
the invention have been illustrated and described, various other changes 
and modfications may be made without departing from the spirit and scope 
of the invention, as defined by the appended claims.