DE2942033A1 - IC engine with oval cylinders - has multiple inlet and exhaust valves arranged in rows parallel to major axis of cylinder - Google Patents

Abstract

The engine has four cylinders (12) with pistons (13) reciprocating in them. The cylinders and pistons are oval with straight sides parallel to the axis of the engine joined by circular sections at the axial ends. Each piston has two connecting rods (17) spaced axially along it and linking it to cranks (18) on the crankshaft (14). Each cylinder has several inlet valves (24) arranged in a line axially along it. They are all operated together by a single cam having the necessary axial length. There is a similar linear arrangement of exhaust valves on the other side of the cylinder. There are two sparking plugs (28) in each cylinder.

Description

Patent attorneys Dipl.-Injs. Ji. Weickwann 'D-ipl.-Phys. Dr. K. Finckk

Dipl.-Ing. FAWeickmann, Dipl.-Chem.
Dr. Ing.H. Liska

^SBem ; ■>., - "· ■

8000 MUNICH 86, DEN '' ■ '■' ■ * ' ' ν

PO Box 860 820

MÖHLSTRASSE 22, CALL NUMBER 98 39 21/22

HONDA GIKEN KOGYO KABUSHIKI KAISHA
27-8, 6-chome, Jingumae, Shibuya-ku
Tokyo 150 / Japan

Internal combustion engine

Addendum to patent (patent application Γ 29 11 889.6-13)

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ORIGINAL INSPECTED

29420 ^ 3

The invention relates to an internal combustion engine that is suitable for high power output at high speed. In order to improve the power output per cubic capacity unit, was already proposed to increase the maximum speed. However, there are certain disadvantages here. First In the high speed range, the volumetric efficiency drops with increasing speed. To keep the speed below Maintaining a predetermined value to increase the volumetric efficiency, the cylinder must be supplied with an amount of fresh air which is proportional to the engine speed. However, it is known that the air speed no longer increases when it has reached about 0.5 Mach, which is why the volumetric efficiency then drops. Around To achieve higher volumetric efficiencies, the effective opening cross-section of the intake valves must therefore be increased will. The effective cross-section is limited by factors such as the size, number of intake valves and stroke of the intake valves.

Another difficulty that occurs as the speed increases, consists in unreliability of the valve control mechanism. When the engine speed is a predetermined If this exceeds the range, jumping movements and oscillating movements of the valves as well as other extraordinary effects can occur appear. The critical speed at which such phenomena occur is generally proportional to the square root the valve spring force and inversely proportional to the square root of the lowest valve acceleration. the maximum speed is therefore limited by these factors.

Furthermore, the upper limit of the engine speed is reached relatively early because of the inertia of the piston and others

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parts moving with it, for example the piston rod, is proportional to the square of the speed. The mechanical Losses increase abruptly in the high speed range.

Short-stroke machines have already been developed to avoid these problems in the area of high machine speeds. It however, there is a critical range of shorter strokes for which an effective compression ratio and a combustion chamber shape must be maintained for a given cubic capacity. Another suggestion to improve the Power output was an increase in combustion efficiency achieved by increasing the compression ratio. However, too high a compression ratio will cause pre-ignition or knocking. Acquaintance However, the properties of the fuel, the shape of the combustion chamber and the ignition point allow only minor ones Increases in performance, so that a significant improvement is not to be expected here. Developments too with the short-stroke principle and higher compression ratio did not lead to any significant improvement in performance.

The object of the invention is to provide another approach to increasing the power output, in which the disadvantages described above do not occur.

For this purpose, an internal combustion engine according to the features of the main claim. Advantageous further developments are the subject of the subclaims.

As will be described, the invention provides an improvement in volumetric efficiency to provide a to achieve a substantial increase in the service to be delivered.

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■ ·· ■ - 6'-

The performance of conventional four-stroke gasoline engines is particularly important here be improved. Since the maximum volumetric efficiency is determined by the effective opening cross-section of the Intake valves is determined, the ratio of the effective opening cross-section to the cross-sectional unit of the cylinder bore increase. As is well known, two intake valves per cylinder can increase the volumetrlsohen efficiency. Two Intake valves and two outlet valves per cylinder increase the volumetric efficiency, but inadequate Dimensions. Heretofore, having more than two intake valves per cylinder required a complicated and expensive valve control mechanism.

To the volumetric efficiency T ^ in a four-stroke machine To increase, the draining effect of the exhaust system must be used positively. This emptying effect results from the effect of the inertia of the exhaust gases when flowing out and causes an increase in the flow velocity of the mixture sucked in through the suction valves. It is therefore important to have multiple intake valves as To arrange a group on one side of the combustion chamber and several outlet valves as a group on the other side thereof to provide both groups as close together as possible. Furthermore, the intake valves must for a higher engine speed and the outlet valves can also be arranged in a row. This enables the suction valves to be controlled directly a common camshaft. Another camshaft actuates all outlet valves directly. If rocker arms are used, it is thus possible to provide a simple valve control for the simultaneous actuation of several valves.

The performance coefficient <x (performance related to the ■ cubic capacity) can be expressed by the following equation:

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/ Number of suction valves \ fcircumferential length per] ν per cylinder / (suction valve /

Diameter of the circle equivalent to the cross section of each cylinder

Here, the maximum valve lift is generally not dependent on the number of valves and therefore does not determine that Coefficient ° (, because it represents a constant. In order to obtain the coefficient <x To make dimensionless, the denominator of the preceding fraction is given as the diameter of a circle whose Area is equal to the cross-sectional area of each cylinder.

Given the above assumption, it is assumed that η suction and discharge valves are arranged parallel to the longer dimension of the elongated cross-section of a cylinder. Their axes have an angle of 0 degrees with respect to the longitudinal axis of the cylinder. First, it is assumed that for a dv circular cylinder, the diameter of the intake valve and the diameter of the discharge valve dv _Ä "is 0.9 dv _e. This is known to be a very cheap value. (1)

The diameter d "of the cylinder bore results from the following Equation:

d _n = dv / (n-1) ² + 0.9 cos ² 9 + l (2)

a S

Therefore, the above two equations (1) and (2) result in the coefficient ** - for the circular bore as follows:

O)

J (nl) ² + 0.9 cos ² 0 + l

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For a cylinder with an elongated (elliptical) cross-section, the diameter of an equivalent circle results from the following equation:

a) η β 1

d _n β 1.49 cos © dv "(4)

Ij S

b) η ^ 2

^d B ^β _{cosQ + 284 cos} 2 _{Q dV} (5)

From the above equations (1), (4) and (5) the coefficient oc can be calculated as follows:

a) Number of valves η «1

^ T7h9 cosG

b) η ^ 2

". _. η τγ

In Fig. 6 the coefficient is for various valve arrangements shown. It can be seen that for η ^ 2 compared to the optimal state for circular cylinder bores a significantly higher value is achieved with elliptical bores.

In this way, an extensive improvement in the power output per displacement unit or the coefficient can be achieved.

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The following are exemplary embodiments of the invention described with reference to the figures. Show it:

Fig. 1 is a partially sectioned plan view of the most important parts of a four-cylinder internal combustion engine according to the invention,

Fig. 2 shows a longitudinal section of the internal combustion engine Fig. 1,

Fig. 3 shows a cross section of the internal combustion engine Fig. 1,

FIG. 4 the view 4-4 according to FIG. 3,

Fig. 5 is a graphical representation of the flushing efficiency as a function of the speed for Internal combustion engines with different numbers of intake valves per cylinder,

6 shows three graphical representations of the relationship between the coefficient <*. with the number of suction valves per cylinder, with an elongated cylinder cross-section with a circular cylinder cross-section is compared. Here the angle O is half that enclosed by two planes Angle. One level contains the axes of the suction valves, the other the axes of the outlet valves,

FIG. 7 shows a representation similar to FIG. 4 for an exemplary embodiment with three suction valves and three outlet valves,

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FIG. 8 shows a representation similar to FIG. 4 for an exemplary embodiment with five suction valves and five outlet valves and

FIG. 9 shows a representation similar to FIG. 4 for an exemplary embodiment with six suction valves and six outlet valves.

The internal combustion engine 10 shown in the figures has a machine body 11 with four mutually parallel, upright cylinders 12. A piston 13 is guided in each cylinder 12 / however, they are sliding against one another Surfaces not cylindrical. Each piston and each cylinder, however, has a direction parallel to the longitudinal axis X-X of the crankshaft 14 has an elongated shape, as shown in FIG.

As can be seen from Fig. 4, each cylinder 12 has an elongated cross-section, by which it is to be understood that the larger dimension is perpendicular to a smaller dimension. The cylinder 12 is preferably curved Pages 15, which form a partial circle in cross section. These curved sides 15 merge into one another via side surfaces 16 about, which are preferably designed as mutually parallel planes. However, these side surfaces 16 can also be curved be to increase the side dimension of the cylinder so that the cross section of the cylinder is also elliptical can be. The term "elongated" should be understood to mean any shape that is not circular in the above sense. Each cylinder 12 is symmetrical about a plane which passes through the longest dimension of the cylinder cross section is.

Two connecting rods 17 connect each piston 13 to crankshaft bearings 18 on a crankshaft 14. Each connecting rod

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17 is attached to a piston pin 19 with piston 13, which runs parallel to the axis X-X of the crankshaft 14. The piston rings 21 seal the respective piston 13 from the respective cylinder 12. The crankshaft 14 is in Machine body 11 in several axially spaced apart Bearings 22 stored.

The cylinder head 23 is provided with stationary inserts 23a, each of which has a plurality of valve seats for intake valves and outlet valves 25. The suction valves 24 are arranged in a straight line so that they can through a camshaft 26 common to them can be controlled. Similarly, the outlet valves 25 are on one arranged straight line so that they can be controlled by a camshaft 27 common to them. One Toothed washer 30a on crankshaft 14 drives toothed washers 30 on each camshaft 26 and 27 via one or more toothed belt not shown. Two spark plugs 28 are provided for each cylinder and are symmetrical about the intake valves 24 and the outlet valves 25 are arranged.

Each suction valve 24 has a valve head 29 and a valve tappet, which is in a guide 31 of the stationary Cylinder head 23 is performed. Each outlet valve 25 has a valve disk 32 and a plunger in a Guide 33 of the stationary cylinder head 23 is guided. Each valve disk 29 and 32 is arranged in a combustion chamber 34 between the walls of the cylinder 12, the stationary insert 23a and the piston 13 is formed.

When the machine is in operation, air enters intake ducts 35 and flows through carburetors 36 and other intake ducts 37 past the intake valves 24 into the combustion chambers 34. After the compression stroke of each piston 13, the spark plugs 28 ignite the compressed mixture, see above that the pistons 13 are moved and the connecting rods 17 rotate the crankshaft 14. The outlet valves 25 are

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opened to combusted exhaust gases through the exhaust ducts 38 to dissipate. The connecting rods 17 are designed in the same way.

In the embodiment shown in Fig. 7, three suction valves 24 are on a straight line on one side and arranged parallel to a central plane which runs through the longer axis of the elongated cylinder 35. Three Exit valves 25 are arranged on a straight line on the other side and parallel to said plane. Two spark plugs 28 are symmetrical in the one indicated by the dash-dotted line r passing through the centers of the Suction valves 24 and the outlet valves 25 runs, arranged limited space.

In the embodiment shown in Fig. 8, five suction valves 24 are in a straight line on one side arranged parallel to a central plane which runs through the longer dimension of the elongated cylinder 37. Five exhaust valves 25 are arranged on a straight line on the other side and parallel to the plane. Four spark plugs 28 are symmetrically arranged in an area defined by the dot-dash line r which connects the centers of the intake valves 24 and the exhaust valves 25 to one another.

In the embodiment shown in Fig. 9, six suction valves 24 are in a straight line on one side and disposed parallel to a central plane passing through the longer axis of the elongated cylinder 38. Six outlet valves 25 are arranged on a straight line on the other side and parallel to said plane. Three spark plugs 28 are symmetrically provided in the area enclosed by the chain line r which connects the centers of the intake valves 24 and the exhaust valves 25 to one another.

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L e r s e i t e

Claims (5)

Claims 1./Brennkraftmaschine with at least one piston with \ * y oblong cross-section which is guided in a correspondingly shaped cylinder him, with a number of intake valves which are parallel to a straight line on one side to an in direction of the longer dimension of the piston or cylinder cross-section extending plane are arranged and with a number of outlet valves which are arranged on a straight line on the other side of said plane parallel to this according to patent ... (patent application P 29 11 889.6-13), characterized in that three or more than four suction valves (24) and three or more than four outlet valves (25) are provided. 2. Internal combustion engine according to claim 1, characterized in that with three intake valves (24) and three outlet valves (25) two spark plugs (28) are provided. 3. Internal combustion engine according to claim 1, characterized in that with five intake valves (24) and five outlet valves (25) four spark plugs (28) are provided. 4. Internal combustion engine according to claim 1, characterized in that with six intake valves (24) and six outlet valves (25) three spark plugs (28) are provided. 5. Internal combustion engine according to one of claims 2 to 4, characterized in that the spark plugs (28) within an area are arranged by a 130019/0065 -Z- Line (r) connecting the centers of the suction valves (24) and the outlet valves (25) are included is. 130019/0065