DE663479C - Spherical rotary valve for internal combustion engines - Google Patents

Description

Spherical rotary valve for internal combustion engines The invention relates to a spherical rotary valve for internal combustion engines, its rotatable in the cylinder head spherical part connected to a hollow cylindrical drive and bearing journal and is sealed by a sealing ring located in the cylinder opening.

According to the invention, the sealing ring is from the slide drive pin by means of a gear in intermittent revolutions always in the same sense offset to ensure regular wear of the spherical surface of the ring and the slide bring about and ensure their correct renewal.

In known arrangements that have an alternating reciprocating motion . of the sealing ring around its axis by means of the intake and exhaust the flow generated by the gases is supposed to produce a certain leveling the load-bearing surfaces and the mechanical efficiency and the seal improved, but due to the lack of permanent forced rotation of the ring is a precise maintenance of the spherical surfaces, as well as the Acceleration of the radial heat equilibrium and the reduction in the change in shape cannot be done in the manner of the present invention.

In the case of a control with a rotary slide valve, in which the slide valve is located directly is kept in its warehouse, the cooling can probably be done by dissipating heat to the head part of the machine. However, the cooling is necessarily thereby limits that they require a heat flow across the mass of the slide makes and in this way brings about a change in shape. In contrast, diminished in the case of a slide that is carried by lateral bearings, the effective separation of the slide from its support the strength of the heat flow in the walls of the Slide and the associated changes in shape, but it allows not the flow of heat through direct conduction to the machine head. One must consequently take care of the cooling of the slide in a different way.

To this end, and to the, effect of the ring acting on an acceleration the heat balance aims to increase is according to the present Invention of the spherical part of the slide through a flexible, multi-part housing or enclosed in an envelope.

A rotary valve according to the present invention as it is for use is suitable for a single-cylinder four-stroke engine is illustrated in FIGS. It shows Fig. I a side view of the slide cooperating with the sealing ring, 2 shows a cross section of the slide attachment in the area adjacent to the spherical part Zone and the external view of the sealing ring.

Fig. 3 and q. are two cuts through the cylinder, the first in the plane through the longitudinal axis of the slide, the second in a plane perpendicular to the Slide axis.

The slide of Fig. I and 2 is a rotating body and is by a spherical part i formed; facing the combustion chamber and with a hollow, cylindrical pin 2 is connected.

The slide is held by bearings 3 on the cylindrical part sit so that the spherical part protrudes and the slot in the combustion chamber 6 covers (Fig. 3). The slide rotates around its axis of symmetry in a certain Relation to the revolution of the crankshaft.

The passages for the supply of the cargo or for the incineration necessary air in the case of a diesel engine to the combustion chamber and for discharge the combustion products are housed in the valve body, either cast in or subsequently milled in or the like.

The inlet channel q. (Fig. 3 and q.) Lies in the axis of the cylindrical Part. This channel goes over the entire length of the cylindrical part, and at When it reaches the spherical part, it bends at right angles to the axis of rotation.

The exhaust duct 5 is much shorter and essentially elbow-shaped. Its first part has a radial direction (Fig. 1, 2 and 4), the end part has an axial direction and ends in a round opening with the center point on the axis of rotation of the slide and on the opposite side of the drive axle. This opening is ongoing Connection with the exhaust pipe (Fig. 3).

As the slide rotates, the inlet duct and the exhaust duct come temporarily to cover an opening in the cylinder base through which the Inlet and exhaust.

To create a gas seal between the combustion chamber opening and the To create slide, the former is provided with a bore into which a sealing ring is inserted. The upper part of the sealing ring is turned and ground accordingly the spherical shape of the slider, and on the outer cylindrical surface are two or milled several grooves in order to insert ordinary spring washers 9 (Fig. 4.).

The gases compressed in the combustion chamber press the ring against it the slide, whereby the seal is secured.

In order to let the sealing ring 8 (Fig: i and 2) rotate slowly about its axis, this is provided on its circumference with a toothed piece io which is in engagement with a similar toothing ioa provided on a resilient ring ii. The ring ii -is carried by an eccentric attachment i2 firmly connected to the neck 2 of the rotary valve. The rotation of the ring ii is inhibited by a fixed pin i9, diametrically opposite the toothing ioa, which engages in a radial slot 13 of the ring ii.

As a result of this arrangement, during the rotational movement of the pin: 2 and of the eccentric extension z2 fixedly connected to it, the ring ii is caused to oscillate about the fixed pin i9. During this oscillation, the gears io and iod slide in relation to one another. So that the sealing ring 8 always rotates intermittently in the same direction, the toothing of the bolt ii is designed like a locking wheel. In addition, the ring ii is double-walled, ie: it consists of two rings united at 13 , and is thus resilient or compressible. This compression has the effect that the sliding movement of the toothing of the ring on the toothing io of the sealing ring 8 remains ineffective when the ring vibrates in one direction, but is effective when the ring vibrates in the opposite direction.

The rotary movement of the slide axis 2 therefore causes the eccentric Ring i r to swing back and forth and the sealing ring intermittently always in the same Direction to turn.

The movement of the eccentric ring i i (Fig. I and 2) is temporal dimensioned so that they during the suction and the beginning of the compression stroke takes place, @d. H. when the forces acting on the sealing ring 8 are small. The backward stroke of the eccentric does not allow the sealing ring to rotate backward because the friction between the ring and the housing, which occurs as a result of the high pressures during the occurs following compression and combustion strokes, hold the ring in place. To that eccentric ring to enable i to reverse gear, it is in slotted in the manner described, so that: ß he sufficient elasticity possesses to bend and re-engage the teeth.

The rotation of the sealing ring 8 fulfills various tasks. Through this, that the contact surfaces change constantly, that the inequalities, either through foreign bodies or a slight, inevitable change in shape can be generated, are compensated.

Furthermore, each surface element of the slide tends to have the curvature the smallest ball produced by the sealing ring, and vice versa the concave seat of the ring has the tendency to become the largest, through the relative Adjust movement of the slide generated ball.

Has the sanding been sufficiently carried out in this way? then the two balls collapse, and this circumstance, which one is maintained permanently ultimately results in a minimum strength and a Minimum wear and tear.

Even a considerable amount of wear is therefore for the gas tightness in no way detrimental as the wings are perfectly spherical on a wear the same curvature.

The rotation of the sealing ring further causes each element the surface of one part periodically on each element of the surface of the other Part presses, and this is beneficial for the even distribution of the lubricant.

Finally, under the milled out gear rim = o (Fig. I and a) a resilient washer 14 is inserted (Fig.3), which is a little upwards exerts a directed force on the sealing ring in order to counteract any inclination of the ring, to stand out from the surface of the slide, this slide drive described is fundamentally different from other devices of this type, and therefore special requirements must also be met for this, which are dealt with below should be.

The mean temperature that the valve reaches in the company depends on the conditions for heat balance and mainly on the changes in heat by conduction between the slide surface and the gases in contact with it come. So you can influence these temperatures and keep them within appropriate To keep the whole surface of the exhaust pipe covered by a layer of boundaries smooth, polished, heat-resistant and heat-insulating building material.

An important point is that the mean temperatures of the slide so reduced that the heat transfer from the exhaust gases to the hotter ones Dividing the slide is reduced, reducing the temperature differences downwards be balanced out and a change in shape is made impossible.

Similarly, the inlet channel can be covered with a building material which has a higher or lower coefficient of thermal conductivity and which either rests tightly on the slide surface or is thermally insulated against it depends on whether you lower the temperature of the slide or a better one wants to achieve volumetric efficiency.

In the larger space between the inlet and outlet channels within the spherical part of the slide, a cavity 15 (Fig. Q,) can be let in the valve casting to counteract the forces which disturb the rotational equilibrium of the slide, due to the asymmetrically arranged channels .

One or more buttresses or ribs attached to the inner core of the Valve are provided, and the cavity supports, either left standing during casting or later to fill in the holes that the 'retaining bolts hold correspond to the core, can represent further means of distributing the heat, which is absorbed by the cavity, and regulate the thermal expansion of the latter.

To the heat flow from the sealing ring to the slide in an easy way to monitor and to avoid or at least regulate a change in shape, can have indentations on the inner or outer cylindrical surface of the sealing ring be screwed in. These depressions can also reduce the rigidity of the sealing ring Reduce.

In Figs. 3 and q. is the spherical part of the slide in one enclosed hollow spherical housing that is divided into two parts, the be connected to each other by means of springs and bolts.

So that the spherical housing is relieved of the bearing pressures, can it can move freely in the center axis of the sealing ring. It sits with little Play in the cavities of the cylinder head and extends to the sealing ring. the inner surface of the housing is designed in such a way that there is sufficient clearance (between and the slide) in relation to the mean temperatures achieved and the corresponding expansion coefficients of the building material used.

The housing is divided into two parts, namely the part plane runs either perpendicular to the axis of the sealing ring, as can be seen from FIG. 4, or down by 9o ° rotated the plane containing the two axes of the slider and the sealing ring. Light pressure is applied to both parts appropriate springs exercised, which within small limits regardless of the changing Sizes of wear and temperature conditions remains.

The slide valve can be lubricated in different ways. So z. B., as shown in FIGS. 3 and q. the lubricant can be seen to be guided by means of a pipe and a line to a hole 17 which is provided with a thread. This hole is shown in the middle position for the sake of convenience, but would suitably lie to the side of the center line that runs through the slide outlets.The so-called dry running lubrication could be used in water-cooled machines and wherever the temperature of the parts can be kept sufficiently low, to ensure only low losses of lubricating oil. In this case, the amount of oil supplied is much larger than it is needed for lubrication, and an appropriate line must be provided to discharge the excess amount.

The spherical housing 16 that surrounds the slide can be used for this purpose Have suitable means of preventing the loss of lubricant through the valve openings to prevent through. A design to prevent the loss of lubricant to prevent the exhaust pipe is shown in FIG.

The lubricant can be supplied to the slide in various ways thanks to the cover by the spherical housing and the even distribution effect of the rotating sealing ring. So it can be B. the slide through holes which are drilled into the housing or through lubrication grooves in the slide surface. But it can also be fed through openings, which are drilled in the radial direction through the sealing ring and into a groove the surface of the sealing ring. Another way would be in it consist of supplying the lubricant by means of a channel in the slide, the Feed could start from the end of the cylindrical shaft and lead to a groove, which, as mentioned, would have to be provided on the spherical surface of the slide.

Claims (3)

PATENT CLAIMS: i. Spherical rotary valve for internal combustion engines, its spherical part rotatable in the cylinder head with a hollow cylindrical one Drive and bearing journals are connected and through one in the cylinder bottom opening lying sealing ring is sealed, characterized in that the sealing ring (8) from the slide drive pin (2) by means of a gear (1 o, i i, i2) in intermittent, always in the same sense of rotation is offset, for the purpose, bring about regular wear of the spherical surfaces of the ring and the slide and to ensure their correct renewal. 2. Spherical rotary valve for Internal combustion engine according to claim i, characterized in that with the drive journal (2) an eccentric attachment (12) is connected, on which a ring (i i ', sits, inclined teeth (ioa) are cut into one side surface; those with a cooperate on the circumference of the sealing ring (8) provided ring gear (io), the ring (t i) being provided by a pin cooperating with a slot (13) (ig) is secured against a rotary movement and receives an oscillating movement, which takes the sealing ring (8) with it in one direction, while in the other Direction due to the oblique teeth and the resilient design of the ring (i i) there is no rotation of the sealing ring. 3. Spherical rotary valve according to Claim i and 2, characterized in that the slide by a spherical Housing is enclosed, with a small amount of play in the cavities of the cylinder head sits and consists of two halves (16), which with light resilient pressure against abut the rotary valve, the housing moving in the direction of the sealing ring axis can move freely and is secured against rotation. '