CZ2008825A3 - Machine characterized by a piston within a cylinder - Google Patents

Abstract

The machine with the piston (2) in the cylinder (1) is designed to change the volume of the working space due to the reciprocal reciprocating motion of the piston (2) in the cylinder (1), in particular in an internal combustion engine, compressor or pump. The machine is provided with a sinusoidal guiding system for rotational movement of the piston (2) about its axis in the cylinder (1). The body of the piston (2) is provided with a vent (6) and the walls of the cylinder (1) are provided with channels (4, 5) for opening and closing the working space in the cylinder (1) relative to the surroundings.

Description

Machine with piston in cylinder

Technical field

BACKGROUND OF THE INVENTION The invention relates to a machine with a piston in a cylinder for providing a change in the volume of the working space due to a linear reciprocating movement of the piston in a cylinder, in particular in an internal combustion engine, compressor or pump.

BACKGROUND OF THE INVENTION

Solutions are known in which the piston in the cylinder moves only in a linear motion, and where a system of gears, camshafts, rocker arms and valves is used to convert the rotary rod and crankshaft to close and open the working space in the cylinder.

The machines constructed in this way contain many complex parts that perform different kinds of movements, thereby increasing the noise level and increasing the lubrication and sealing requirements.

Further, there are known solutions with a piston of a non-circular shape, where the piston moves only by rotary movement and does not stroke.

• ·· ·

The disadvantage of these machines is the low compression ratio and the large area of the working space due to its volume. Due to faster wear of the sealing elements, lubricant penetrates into the working space of the cylinder.

SUMMARY OF THE INVENTION

Disadvantages of the prior art are eliminated by a piston-in-cylinder machine according to the present invention whose piston performs a translational movement and a rotary movement.

Thus, it combines the advantages of a reciprocating piston such as a compact working space and a rotary piston machine that does not require additional moving parts to convert linear motion to rotary motion and to close and open the working space.

Accordingly, in accordance with the present invention, a cylinder piston machine has been developed to provide a change in the volume of the working space due to the linear reciprocating movement of the piston within the cylinder, particularly in an internal combustion engine, compressor or pump.

The machine is provided with a sinusoidal guide system for rotational movement of the piston about its axis in the cylinder, the piston body being provided with a vent and the walls of the cylinder being provided with channels for opening and closing the working space in the cylinder with respect to the surroundings.

• * ·

According to a preferred embodiment, the sinusoidal guide system comprises guide elements on the piston and a guide recess on the cylinder, the guide recess being defined by curves derived from a sinusoid.

According to an alternative preferred embodiment, the sinusoidal guide system comprises a guide recess on the piston and guide elements on the cylinder, the guide recess being defined by curves derived from a sinusoid.

According to one preferred embodiment of the present invention, the sinusoidal guide system is defined in the range of 0 to 4π.

According to an alternative preferred embodiment, the sinusoidal guide system is defined in the interval of 0 to 2π.

The piston is preferably provided with a rod passing through an opening in the transformer member.

The opening in the transformer member preferably has the same cross-sectional shape as the cross-section of the rod on the piston.

Advantageously, the transformer may comprise a gear wheel, a gear, a belt pulley, a sprocket, a pulley, an articulated clutch, an electrical, electromagnetic or hydraulic transmission member and the like.

The guide elements are preferably slidable or pivotable.

In a preferred embodiment, the guide elements and the guide recess can be toothed.

· · · · · · · · · · · · · · · · · · · · · · · · · · · · ·

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be explained in more detail below with reference to the accompanying drawings, in which:

Fig. 1a shows the roll unfold for curve 4π;

Fig. 1b shows the roll unfolding for curve 2π;

Fig. 2a shows a front view of a piston of a machine according to one embodiment with guide elements on the piston and guide recesses on the cylinder;

Fig. 2b shows a side view of the piston of the machine of Fig. 2a;

Fig. 2c shows a front view of the piston of the machine according to an alternative embodiment with guide recesses on the piston and guide elements on the cylinder;

Fig. 2d shows a side view of the piston of the machine of Fig. 2c;

Figure 3a shows the assembly of the machine of Figures 2a and 2b in an isometric view;

Fig. 3b shows the assembly of the machine of Figs. 2c and 2d in an isometric view;

Fig. 4a shows a cross-section of a machine cylinder with a guide system 4π;

5 • · · • · · · • * • · • «· • · giant. 4b shows cut cylinder machine s guiding system 4π; giant. 4c shows cut cylinder machine s guiding system 2π; giant. 5 shows floor plan possible variants solution a transforming member; giant. 6a shows cut machine according to 2a and FIG. 2b; giant. 6b shows cut machine according to FIG. 2c and FIG. 2d.

DETAILED DESCRIPTION OF THE INVENTION

The solution according to the invention relates to a machine with a circular piston 2 moving in a cylinder φ where the volume of the working space is changed, for example in an internal combustion engine, in a compressor or in a pump, by the piston 2 performing a translational movement top and bottom dead center, while rotating around its axis.

The piston 2 and the cylinder are provided with a guiding system which guarantees the rotary movement of the piston 2 about its axis, so that during the movement of the piston 2 from one dead center to the other, the piston 2 rotates about 90 ° or 180 ° about its axis.

The guide system can be constructed in various ways.

It is assumed that if the piston 2 is to perform a translational movement and a rotational movement at the same time, any point on the housing of the piston 2 describes the sinusoid cylinder 7 on the inner wall.

If two guide elements 12 are positioned symmetrically on the piston housing 2, then a sinusoid is defined at a given stroke. It is then given as _r j guiding recess formed for example by a groove or guiding offset, as an equidistant curve to the given sinusoid.

Analogously, the guide elements 8 can be arranged in the cylinder 1 and the guide recess 7 in the housing of the piston 2.

By adjusting the steepness of the guide recesses Ί_, the translational movement is set to accelerate, thereby adjusting the dynamics of the individual machine operating cycles. The guide elements 8 may be constructed as sliding, rotating, toothed or the like.

Example of a guide system

The piston 2 is provided with two opposing sliding guide elements 8 and the cylinder 1 is provided with a guide recess 7 which is arranged to rotate the piston 2 about its axis so that the piston 2 is rotated around one axis to the other. its axis by 90 °. The guide recess 7 is delimited by two symmetrical equidistant curves to the cosine in the interval of 0 to 4π.

The body of the piston 2 is provided with a vent 6 which, together with the openings in the cylinder 2 ', ie the channels 4, ensures the closing and opening of the working space in the cylinder 1 with respect to the surroundings.

The design of the ducts 4 and 5 is analogous to the shape of the guide recess 7. The lengths of the ducts 4 and 5 can be used to adjust the intake and exhaust dynamics.

During suction, the vent 6 in the piston 2 overlaps the suction channel 4 in the cylinder 1. During the exhaust, the vent 6 in the piston 2 overlaps the exhaust channel 4 in the cylinder 6. During compression and during expansion, the vent 6 in the piston 2 is sealed against the inner wall of the cylinder 6.

The torque transmission is trivial because the piston 2 rotates about its axis during duty cycles. An example of a torque transmission is shown in Fig. 5, where the piston 2 is provided with a rod 9 which passes through an opening in a transformer member, such as a gear 3.

For example, the transformer may also be comprised of a transmission disc, pulley, sprocket, pulley, articulated clutch, electric, electromagnetic or hydraulic transmission member and the like.

Machine with piston in cylinder applied as internal combustion engine

In a four-stroke internal combustion engine, the piston 2 is provided with two opposing guide elements 8 and the guide recess 7 in the cylinder 8 is delimited by equidistant curves to the cosineoid at an interval of 0 to 4π.

During rotation of the piston 2 about its axis by 360 °, the piston 2 performs four translational movements between dead centers.

·· ·

Fig. 1a shows the unfolding of the cylinder 1, indicating the individual operating cycles:

• 0 ° - 90 °: During suction, piston 2 moves from top dead center to bottom while simultaneously rotating about 90 ° around its axis. The vent 6 in the piston 2 follows the suction passage 4 in the cylinder 1 and the fuel mixture is sucked from the intake manifold 11 into the working space in the cylinder 90 ° - 180 °: During compression the piston 2 moves from the bottom dead center to the rotates about its axis by 90 °. The working space in the cylinder 1 is closed from the surroundings.

• 180 ° - 270 °: During expansion, piston 2 moves from top dead center to bottom while simultaneously rotating about 90 ° around its axis. The working space in the cylinder 7 is closed from the surroundings.

• 270 ° - 360 °: During exhaust, piston 2 moves from the dead center to the top and at the same time rotates about its axis by 90 °. The vent 6 in the piston 2 follows the exhaust duct 5 in the cylinder 1 and the flue gas is forced out of the working space in the cylinder 1 into the exhaust pipe 10.

Machine with piston in cylinder applied as a compressor or pump

In the compressor or in the pump, the piston 2 is provided with two guide elements 8 and the guide recess 13 in the cylinder 1 is delimited by equidistant curves to the cosinusoid in an interval of 0 to 2π.

During rotation of the piston 2 about its axis by 360 °, the piston 2 performs two translational movements between dead centers.

Fig. 1b shows the development of the cylinder 1L, indicating the individual operating cycles:

• 0 ° - 180 °: During suction, the piston 7 moves from top dead center to bottom while simultaneously rotating about 180 ° about its axis.

The vent 6 in the piston 2 follows the suction channel 4 in the cylinder 1 and gas or liquid is sucked from the inlet system of the pipe 11 into the working space in the cylinder 1.

• 180 ° - 360 °: During displacement, piston 2 moves from the dead center to the top dead center and rotates 180 ° around its axis.

The piston vent 15 follows the discharge channel 12 in the cylinder 1, and gas or liquid is expelled from the working space in the cylinder. into the pipe outlet system 10.

Claims (8)

PATENT CLAIMS A machine with a piston in a cylinder for providing a change in the volume of the working space as a result of a linear reciprocating movement of the piston (2) in a cylinder (1), particularly in an internal combustion engine, compressor or pump. ) around its axis in the cylinder (1), characterized in that the piston body (2) is provided with a vent (6) and the walls of the cylinder (1) are provided with channels (4, 5) for opening and closing the working space in the cylinder (1) ) relative to the surroundings. Machine according to claim 1, characterized in that the sinusoidal guide system comprises guide elements (8) on the piston (2) and a guide recess (7) on the cylinder (1), the guide recess (7) being defined by curves derived from sinusoids. Machine according to claims 1 and 2, characterized in that the piston (2) is provided with a rod (9) passing through an opening in the transformer member. Machine according to claim 3, characterized in that the opening in the transformer member has the same cross-sectional shape as the cross-section of the rod (9) on the piston (2). Machine according to claim 1, characterized in that the transforming member is formed by a gear wheel, a gear (3), a pulley, a sprocket, a pulley, an articulated clutch, an electric, electromagnetic or hydraulic transmission member and the like. Machine according to any one of the preceding claims, characterized in that the guide elements (8) are slidable. Machine according to any one of the preceding claims, characterized in that the guide elements (8) are designed to be rotatable. Machine according to any one of the preceding claims, characterized in that the guide elements (8) and the guide recess (7) are provided with a toothing.