WO2015160280A1 - Rotary-compression turbo-piston reversible converter - Google Patents

Abstract

An original design for the coupling of rotational bodies and the rotational and translational motion thereof, which design is capable of replacing crank mechanisms and rotary mechanisms for converting the pressure of a medium into rotational motion and vice versa. The present mechanical design can fully replace the mechanisms of compressors, pumps, manipulators, automobile engines and vacuum cleaners. The present invention is capable of changing transmission principles and a braking system, of replacing the mechanical transmission of torque to device actuators with hydrodynamic transmission, and of making possible the effective accumulation of energy.

Description

 Description of the invention.

Rotary-compression turbo piston reversible

converter.

This invention relates to the field of engineering. Applicable in all areas of industry where, by changing the pressure of a liquid or gas, it stands. the task of obtaining torque and vice versa the conversion of torque into energy of a liquid or gas. This mechanical circuit can completely replace the engines of cars and cars, drives of manipulators, robots,

compressors and pumps, change transmission principles, brake system

cars, replacing the mechanical transmission of torque with compression, removing the mechanical joints and gearboxes. Mechanical motion, by analogy with wildlife ^ will be controlled by changes in fluid pressure.

 Currently, compressor systems and engines use crank-piston piston systems and various devices with a rotating rotor, plunger devices.

 Known piston pump (Russian patent RU N ° 2328621, IPC

F04B9 / 02 (2006.01), 24.1.2006). Known plunger pump (Russian patent

RU Jvf2 2066399, IPC F04B9 / 103, 02.17.1994) For existing piston and plunger pumps transmitting reciprocating movements of pistons or plungers at the time of the working shaft, the main disadvantages are:

uneven moment in time, the presence of a complex distribution system of the working medium, consuming part of the mechanical energy, a constant change in pressure in the working chambers, a huge number of mating parts, large dimensions.

 Rotor blade systems are devoid of the above disadvantages, but have a low efficiency of the working fluid or gas and are not reversible in energy conversion.

 A simple, reversible converter of the kinetic energy of liquids and gases into the energy of the torque, which implements the principle of an infinite piston, is not currently used in industry.

 The problem to which this invention is directed, is the transmission of gas or liquid pressure at a torque with maximum efficiency and vice versa.

SUBSTITUTE SHEET (RULE 26) This device has a new set of structural elements that are interconnected with other elements of the device in contrast to existing devices. The essence of the invention consists in a special conjugation of mechanical bodies, in which the movement of a variable volume of space from the inlet to the outlet and vice versa is accompanied by an unambiguous translational - rotational movement of the pistons and rotation of the cylinder block transmitting torque.

Unlike existing prototypes for this purpose, it has the following root differences:

 1. Original design.

 2. A rotating bearing moment of the cylinder block.

 3. Fixed eccentric shaft.

 4. The grooved sliding connection of the pistons to the shaft, in contrast to existing ring joints.

 5. An unambiguous dependence of the volume of the passing fluid and the moment of rotation.

6. The reversibility of the inlet and outlet.

The mechanical circuit of the converter consists of four main parts:

The body, cylinder block, pistons (one or two), the shaft are conjugated in a special way.

 1. The stationary body of Fig. 1, Fig. 2, having a cylindrical inner surface 1 with slots 2 for inlet-outlet of a dynamic medium (gas or liquid) with covers 3, has an input 4 and an output chamber 5. The covers have openings for the shaft with an offset of H relative to the center .

2. The cylinder block FigZ is a cylindrical body

 corresponding to the profile of the housing, rotating in the housing with a minimum clearance of bearings 6 of Fig. 2, sealed with oil seals of 7 of Fig. 2. The cylinder block has transverse openings 8 of a rectangular-oval (either round or rectangular shape) and a longitudinal round hole 9. To remove and apply the torque of the device, gear 11 is dressed.

3. The pistons of FIG. 4 have a transverse profile similar to the holes in the cylinder block. They have a transverse groove 10 in the center of a special shape defined by two round holes and a sample between them. The ends of the pistons are rounded in accordance with the diameter of the cylinder block.

SUBSTITUTE SHEET (RULE 26) 4. The shaft of Fig. 5 is inserted into the housing covers, passes through the longitudinal hole of the cylinder block and the grooves of the cylinder.

 Dimensions of the parts are interconnected:

 1. The shaft offset H of FIG. 1 is half the size of FIG. 4. Size A of FIG. 4 is equal to the size of FIG. 4. The radius D of FIG. 4 of the piston groove is equal to half the diameter of the shaft E of FIG. 5. Radius F is equal to the diameter of the cylinder block. The diameter of the inner hole of the cylinder block 9 of FIG. 3 is equal to the sum of the double displacement of the shaft H of FIG. 1 and the diameter of the shaft E of FIG. 5.

A feature of the kinematic scheme in contrast to similar devices are:

1. The cylinder block represents the body of revolution and is the source

occurring in the device torque.

 2. Double-sided pistons, special shape. When the cylinder block rotates, they translate along the cylinders, thanks to a groove of a special shape, sliding on an eccentric shaft.

 3. The cylinder block, pistons and an eccentric shaft, due to their geometric dimensions, are connected into a single kinematic scheme, which ensures the transfer of pressure of the medium to the pistons and to the torque of the cylinder block and vice versa.

 4. To equalize the moment in time, a second cylinder is used, offset from the first one by 90 degrees, while the input and output chambers by two cylinders are common. This allows the device, with a deviation of about 10%, with a quarter-turn harmonic, to provide a continuous torque in time.

The method of transferring the pressure of a liquid or gas to the torque of mechanical bodies and vice versa, different from the existing ones by removing the torque from the cylinder block, the shape of the parts, layout, simplicity of design, high efficiency.

 For use as a pump or torque generator, Fig6 shows the changes in the position of the piston depending on the rotation of the cylinder block. A liquid or gaseous medium supplying the inlet pipe under excessive pressure presses the piston, creating a moment of its rotation relative to the eccentric shaft and at the same time forcing it to move along the cylinder. The moment of rotation is transmitted to the cylinder block, forcing it to turn. The moment changes according to the trigonometric law. Its value reaches its maximum when the piston

SUBSTITUTE SHEET (RULE 26) located opposite the inlet, and the minimum when turning 90 degrees relative to the inlet.

Mr / - The moment created by the device

 Rg - Overpressure in the inlet relative to the outlet Sp - Area of the piston

 L - Shaft offset relative to the axis of the cylinder block

 The moment created by the device is equal to the pressure on the piston, multiplied by the area of the piston, multiplied by the offset of the eccentric shaft.

Mr. = Pr * Sp * L * sin (fi)

The moment from one side of the piston is interrupted and acts with a period of 2Pi. Row1 Fig 7..

The moment on the other side of the piston lags behind Pi Row2 Fig. 8. Moments created by the second piston Row2 Fig. 9.

The total moment of the device Row5 will represent the following time dependence: Mr = Pr * Sp * L * (sin (fi) + cos (fi)) will be described in the range from 0 to Pi / 2) The maximum value of the trigonometric coefficient will be equal to the root of 2, and minimum 1. The average value is 2 / (Pi / 2) = 4 / Pi = 1.27. Row5 Fig 10.

The final formula for calculating the average moment created by the pressure of the medium on the pistons:

 Mr = Pr * Sp * L * 4 / Pi

 Accordingly, to calculate the average pressure created by the moment applied to the cylinder block:

 Pr = Mr * Pi / (Sp * L * 4)

The piston stroke is determined by double bias L. The productivity of the device will be determined by the formula:

SUBSTITUTE SHEET (RULE 26) W = u * 4 * Sp * 2 * L

 Where

 W - productivity m3 / s

 U - cylinder speed r / s

Pistons can have a round, but better rectangular shape or with

beveled corners. The rectangular shape of the piston better distributes the pressure of the pistons on the shaft and prevents axial rotation.

 To reduce the line of contact of the surfaces and make the size of the inlet openings independent of the diameters of the cylinders, a cylinder with the necessary slots of Fig. 1 is tightly stretched onto the cylinder block.

 When using the circuit as an internal combustion engine, the places of mixture inlet to the housing change. To use the push-pull mode. On Fig carburetor 1 1 spark plug 12 shows the phase of the absorption of the combustible mixture. On Fig shows the ignition phase and the stroke of the piston.

SUBSTITUTE SHEET (RULE 26)

Claims

Claim.

1. Rotary-compression turbo-piston reversible transducer, consisting of a stationary body having a cylindrical inner

a surface with slots for the inlet and outlet of a dynamic medium (gas or liquid), a cylinder block of a cylindrical shape corresponding to the housing, while the cylinders are perpendicular to its axis of rotation, bilateral cylinders move in the cylinders having a transverse groove in the middle of a certain shape corresponding to the diameter of the shaft, the shaft is fixed in the housing, offset by a certain distance

relative to the center of the device, perpendicular to the axes of the inlet and outlet, rotating in the cylinder of the housing with a minimum clearance, separated by seals and sitting on bearings, having a longitudinal hole in the center, while rotating the cylinder block, in contact with the walls of the grooves of the pistons, the shaft provides free translational movement of the pistons and formation of torque; and two or more cylinders provide continuity in time of the torque, the removal of which occurs with the gear fixed to the cylinder block, and two bearings and oil seals provide rotation of the cylinder block and sealing.

SUBSTITUTE SHEET (RULE 26)