EP1489262A1 - Improved turbine - Google Patents

Abstract

A method for obtaining mechanical energy in a turbine is implemented as follows. The working medium is introduced into the channels of a rotor. The working fluid is accelerated when flowing out of the channels in the direction of the circumference, which is perpendicular to the radius of the rotor. The working medium is introduced from the channels of the rotor into the space around the rotor which is surrounded by a sleeve and interacts by means of friction with the sleeve which forms a closed space and which is arranged in the vicinity of the radius of the periphery and the outlet openings of the rotor channels. The working fluid flows out through openings in the casing, wherein it is accelerated in the direction of the circumference, which is perpendicular to the radius of the casing and is opposite to the direction of the rotor. The turbine contains a Scottish turnstile, which is designed as a rotatable tube. At least one pair of nozzles (3) with open ends bent in opposite directions are fastened to the tube radially opposite. A cylindrical drum (5) is coaxially connected to a rotatable shaft that includes the Scottish turnstile. A cylindrical belt of the drum (5) connects to the bent ends (4) with a gap. Two opposite nozzles (8) with open ends (9) are attached to the drum and are bent in opposite directions. The sockets (3, 8) of the Scottish turnstile and the drum (5) can be in a streamlined form, e.g. as an aerodynamic wing profile. <IMAGE>

Description

The invention relates to the field of mechanical engineering, to be precise hydraulic or pneumatic turbine or a steam turbine for the drive of electrical generators, compressors of cooling systems, of heat pumps etc.

U.S. Patent 3,282,560 discloses a process for the recovery of mechanical energy in a turbine according to the preamble of claim 1 known, the flowing out of the working fluid from the channels of the rotor and the envelope is in one direction. The rotor and the shell leave a wave turn to which they are rigidly attached.

A disadvantage of this method is that it is not possible to use the to gain mechanical energy from the rotor of the turbine because the moment that on the rotor when the working fluid flows out of the rotor channels arises (according to the law of conservation of kinetic energy), with a Counter torque is compensated for when braking the processed Working fluid is generated in the rotor on the inner surface of the shell; the useful moment only when the working fluid flows out of the openings in the casing generated under the pressure after the expansion of the working fluid in the Rotor channels has remained, causing significant energy losses (about 50%) arise.

Through the CH patent 6 694 428 is a method for the extraction of mechanical Known energy in a turbine according to the preamble of claim 1, in which the shell is designed as a radial blade turbine and against the Rotor turns.

A disadvantage of this known method is that it is not sufficient Size of the mechanical energy obtained, because the work equipment at Flow out through four channels of the rotor and when it is inserted into the the shell in the form of the blade turbine space around the rotor as well as when flowing out through the openings in the envelope between the Blades of the turbine at the point of contact with the currents from the Rotor channels is ejected, taking it up to the speed of the one Accelerated current coming from the rotor channels; for that part of the Energy of the electricity used up.

When flowing out through the openings in the shell, which act as a radial blade turbine is trained, there is in the acceleration of the work equipment in the radial blades due to centrifugal losses. There are also losses ventilation due to the circulation of the working fluid between the blades when flowing out through the openings in the envelope.

From the rotating shell, which is designed as a radial blade tube, flows the work equipment at a speed that differs significantly from the Speed of rotation of the shell differs, causing energy loss arise.

• ein Arbeitsrad, das als drehbares Rohr mit einem geschlossenen Ende ausgeführt ist; das Rohr ist koaxial mit der Turbinenwelle gekoppelt, und am Rohr ist mindestens ein Paar gegenüberliegender Stutzen mit offenen Enden befestigt,
• eine drehbare Hülle, die ein Arbeitsrad umfasst,
• ein das Arbeitsrad und die Hülle umfassendes Gehäuse mit Öffnungen für die Unterbringung der Welle sowie mit Stutzen für die Zuleitung und den Auslauf des Arbeitsmittels, wobei an der Hülle mindestens ein Paar gegenüberliegender Stutzen mit offenen Enden befestigt ist und die Hülle und das Arbeitsrad an einer Welle angebracht sind.

Furthermore, a reactive jet turbine is known from US Pat. No. 3,282,560, which has the following:

• a work wheel, which is designed as a rotatable tube with a closed end; the tube is coaxially coupled to the turbine shaft, and at least one pair of opposed open-ended stubs are attached to the tube,
• a rotatable shell that includes a work wheel,
• a housing comprising the work wheel and the casing with openings for accommodating the shaft and with sockets for the supply line and the outlet of the working medium, at least one pair of opposite sockets with open ends being fastened to the casing and the casing and the work wheel on a shaft are attached.

A disadvantage of this known turbine is the fixed connection of the shell and the Work wheel installed on a shaft and the rotation of the work wheel and the shell in one direction, thereby creating mechanical Energy is only ensured on a shell. The sockets of the work wheel are only elements of the turbine that only the pressure of the supply line of the working fluid throttle, whereby these elements lead to useless energy losses and thus lead to low efficiency. In addition, the low strength limits the long cylindrical shell with many openings on its surface Circulation speed of the shell and still sets the efficiency of the turbine more down.

• ein schottisches Drehkreuz, das als drehbares Rohr mit geschlossenen Enden ausgebildet ist, wobei das Rohr koaxial mit einer Welle gekoppelt ist und am Rohr mindestens ein Paar radial gegenüberliegender Stutzen mit von deren Achse in entgegengesetzten Richtungen abgebogenen, offenen Enden aufweist,

wobei die Achsen der abgebogenen, offenen Enden der Stutzen zu derjenigen Fläche senkrecht stehen, die über die Achsen des Stutzenpaars und die Achse des Rohrs verläuft, und wobei an der Rohrwand Öffnungen entsprechend den Stutzen ausgebildet sind,

• eine drehbare Hülle, die koaxial mit der Welle gekoppelt ist und das schottische Drehkreuz umfasst;
• ein das Arbeitsrad und die Hülle umfassendes Gehäuse mit Öffnungen für die Unterbringung des Rohrs und der Wellen des schottischen Drehkreuzes und der Hülle mit dem Stutzen für den Auslauf des Arbeitsmittels, wobei die Hülle als Schaufelturbine ausgebildet ist.

CH patent 6 694 428 discloses a radial two-shaft turbine which has the following:

• a Scottish turnstile, which is designed as a rotatable tube with closed ends, the tube being coaxially coupled to a shaft and having at least one pair of radially opposite connecting pieces on the tube with open ends bent from their axis in opposite directions,

the axes of the bent, open ends of the nozzles being perpendicular to the surface which extends over the axes of the pair of nozzles and the axis of the tube, and wherein openings corresponding to the nozzles are formed on the tube wall,

• a rotatable sleeve coaxially coupled to the shaft and comprising the Scottish turnstile;
• a housing comprising the working wheel and the casing with openings for accommodating the tube and the shafts of the Scottish turnstile and the casing with the connecting piece for the outlet of the working medium, the casing being designed as a blade turbine.

A disadvantage of this known turbine is that the blades in the Shell, which is designed as a blade turbine, attached to the edge of a disc is, whereby the centrifugal load on the blade by an additional Moment is increased because the node is the attachment of the blades unable to bear a high burden, so a reduction in the Circulation speed of the blade turbine is necessary and thus the efficiency the blade turbine is reduced. For the passage between the blades the flow of working fluid from the rotor nozzles to the blades under one certain angle can be directed by the shape of the blades and by the shape of the stream is determined from the nozzles. In this known turbine the flow of working fluid passes from the nozzles to the blades under different Angles, which in cross-section enlarged angles that in the Turbines with a separate nozzle apparatus are common, and a reduction of efficiency can be achieved.

The use of the hollow rotor (the Scottish turnstile) leads to Losses in the friction caused by the circulation of the work equipment in the cavity of the rotor, caused by the viscosity on the walls and by the Backflow in the middle part of the rotor cavity (the Scottish turnstile) is carried away, i.e. through the formation of a manifold vortex. The result is lost the capacity which is taken up by the rotor with cavity.

With the partial supply of the working fluid to the casing (blade turbine) the four nozzles of the rotor (the Scottish turnstile), which in itself Rotates in the opposite direction, the working fluid that is between the blades is under low pressure at the time of contact with the currents ejected the rotor channels, up to the speed of the Accelerated current coming from the rotor channels; for that part of the Energy of the electricity used up.

In the casing (blade turbine) there are losses when accelerating the Working fluid in the radial blades due to the centrifugal force. Besides there there are losses in ventilation due to the circulation of the working fluid between the Scoop when flowing out through the openings in the shell.

The working fluid flows out of the rotating casing designed as a blade turbine out at a speed that is significantly different from the speed the envelope rotation, which causes energy losses.

This known turbine has a complicated construction and a complicated one Manufacturing technology because a blade turbine is used as the casing.

With the proposed method according to the invention for the extraction of Mechanical energy in a turbine is the job of increasing the mechanical energy released in the turbine due to the increase in Efficiency through maximum use of kinetic energy of the Current of the processed working fluid that comes from the rotor channels of the turbine flows out, and by ensuring a minimal, absolute speed the current is obtained as it flows out of the channels of the sheath.

The task of a process for the increased extraction of mechanical energy in to develop a turbine is solved as follows:

The process for extracting mechanical energy in the turbine closes the supply of the working fluid into the rotor channels and the acceleration of the Working fluid when flowing out of the channels in one direction Perimeter, which is perpendicular to the rotor radius, while guaranteeing the Rotor rotation on; According to this procedure, the work equipment is made from Rotor channels in the closed space formed by the shell around the rotor inserted around, interacting with the shell by friction; the Working fluid flows out through openings in the shell, being in a Direction is accelerated while ensuring the envelope rotation. According to the Invention, the space formed by the shell is closed and runs close to the radius, the radius of which is determined by the distance between the Output opening of a rotor channel is formed by the rotor axis; furthermore the working fluid flowing out through the openings in the casing along the Accelerated circumference perpendicular to the envelope radius in a direction that the Outflow of the working fluid from the rotor is opposite.

The closed version of the space formed by the shell and the the circumferential exit openings of the rotor channels and the Acceleration of the working fluid flowing out through the openings in the casing along the circumference perpendicular to the envelope radius in a direction that opposed to flowing out of the rotor, allow the fuse the rotation of the turbine shell using the superfluous energy of the Working fluid flow that flows out of the rotor channels. This leads to a Increase in the mechanical energy that is generated in the turbine.

In addition, the working fluid flows out through the openings in the Envelope at a speed equal to the rotational speed of the envelope in the The opposite direction is close, so that the absolute speed of the working fluid flow is close to zero, reducing the loss of mechanical energy become.

The load for the rotor and the casing can be chosen so that the same circulation speeds on the circles with the outer diameter of the rotor and the inner diameter of the casing.

The choice of the load for the rotor and the sheath to be the same Rotational speeds when the rotor rotates on its outer diameter and to fix the envelope to its inside diameter allows that Achieving maximum efficiency in the action of the turbine.

With the proposed turbine the task of increasing the mechanical energy released in the turbine by increasing the Benefit effect due to the minimal energy losses when the Work equipment out of the case and by simplifying the construction is won.

• ein schottisches Drehkreuz, das als drehbares Rohr mit geschlossenen Enden ausgebildet ist, wobei das Rohr koaxial mit einer Welle gekoppelt ist und am Rohr mindestens ein Paar radial gegenüberliegender Stutzen mit von deren Achse in entgegengesetzte Richtungen abgebogenen, offenen Enden befestigt ist, wobei ferner die Achsen der abgebogenen, offenen Enden der Stutzen senkrecht zu derjenigen Fläche stehen, die über die Achsen des Stutzenpaars und die Achse des Rohrs verläuft; und wobei an der Rohrwand Öffnungen entsprechend den Stutzen vorgesehen sind,
• eine drehbare Hülle, die koaxial mit der Welle gekoppelt ist und das schottische Drehkreuz umfasst,
• ein das Arbeitsrad und die Hülle umfassendes Gehäuse mit Öffnungen für die Unterbringung des Rohrs des schottischen Drehkreuzes und der Wellen des schottischen Drehkreuzes und der Hülle mit dem Stutzen für den Auslauf des Arbeitsmittels.

The task of creating a turbine with higher efficiency is accomplished with a turbine that includes:

• a Scottish turnstile, which is designed as a rotatable tube with closed ends, the tube is coaxially coupled to a shaft and is attached to the tube at least one pair of radially opposite nozzles with open ends bent from their axis in opposite directions, wherein the axes the bent, open ends of the nozzles are perpendicular to the surface which runs over the axes of the pair of nozzles and the axis of the tube; and openings are provided on the pipe wall corresponding to the nozzles,
• a rotatable sleeve that is coaxially coupled to the shaft and includes the Scottish hub,
• a housing comprising the working wheel and the casing with openings for accommodating the tube of the Scottish turnstile and the shafts of the Scottish turnstile and the casing with the socket for the outlet of the working medium.

According to the invention, the shell is designed as a cylindrical drum with is provided with a cylindrical belt attached to the bent ends of the Connects the Scottish turnstile with a gap and on the at least one pair of opposite nozzles is attached with open ends, which are bent in opposite directions with respect to their axes. These directions are the directions of the sockets of the Scottish turnstile arranged opposite, with the axes of the bent, open ends the drum socket is perpendicular to the surface that is above the axes of the pair of nozzles and the axis of the tube; are on the wall of the belt Openings are provided according to the nozzle.

• dem abgearbeiteten Arbeitsmittel, das aus dem schottische Drehkreuz strömt, mit dem zylindrischen Gurt der Trommel zusammenzuwirken, der sehr nahe, und zwar im Abstand eines Spalts, an den abgebogenen Enden der Stutzen des schottischen Drehkreuzes angebracht ist, wobei das Arbeitsmittel das Drehkreuz drehen lässt;
• die Drehung der Trommel beim Herausfließen des Arbeitsmittels aus den offenen Enden der Trommelstutzen zu verstärken;
• die Konstruktion und die Herstellungstechnologie durch den Ersatz der Schaufelturbine zu vereinfachen.

The design of the sleeve as a cylindrical drum, the connection of the cylindrical drum belt to the bent ends of the sockets of the Scottish turnstile with a gap, the attachment of at least one pair of sockets with the open ends, which are bent in directions different from their axis, which correspond to the directions of the on the cylindrical drum belt are radially opposite nozzles of the Scottish turnstile, the axes of the bent, open ends of the drum nozzles being perpendicular to the surface which runs over the axes of the pair of nozzles and the axis of the tube, and the provision of openings on the wall of the belt according to the connector allow:

• the processed equipment flowing out of the Scottish turnstile to cooperate with the cylindrical belt of the drum, which is attached very close to and at a distance from the bent ends of the sockets of the Scottish turnstile, the work equipment causing the turnstile to rotate;
• to increase the rotation of the drum when the working fluid flows out of the open ends of the drum socket;
• Simplify design and manufacturing technology by replacing the blade turbine.

In addition, the working fluid flows out of the open ends the cylindrical drum at a speed equal to the orbital speed is close to the cylindrical drum in the opposite direction, so that the absolute velocity of the working fluid flow is close to zero, which makes the Turbine efficiency is increased.

The use of one or more pairs of nozzles allows the drum to turn and thereby gain additional mechanical energy. To this This creates additional mechanical energy due to the rotation of the Drum, so that the efficiency of the turbine is increased.

The sockets of the Scottish turnstile can be drop-shaped become. The formation of the nozzle in streamlined form, i.e. with the Outer contours, which have a minimal resistance of the Ensure counter flow of the working fluid, for example one with a cross section teardrop shape, allows the reduction of aerodynamic friction losses when turning the Scottish turnstile in the with the Working equipment filled drum, which reduces the mechanical energy in the Drum is won, can be increased.

The streamlined shape of the stub of the Scottish turnstile can be found in the Cross-section form a wing-like profile in the ratio L / b≥5, where L is the chord of the wing and b is the maximum thickness of the wing.

The formation of the sockets of the Scottish turnstile in streamlined form, in Cross-section as a wing-like profile in the ratio L / b≥5, allows the creation of maximum optimal conditions with a reduction in aerodynamic Loss of friction when turning the Scottish turnstile in the with the Work equipment filled drum.

The drum sockets can be drop-shaped.

The formation of the drum socket in streamlined form, i.e. with the outer contours, which have a minimal resistance to the counter current of the Ensure work equipment and, for example, in cross-section as a drop-shaped one Profile are formed, allows a reduction in aerodynamic friction losses when rotating the drum filled with the working fluid in the Casing.

The streamlined shape of the drum socket can be cross-sectioned as wing-like Profile in the ratio L / b≥5, where L is the chord of the wing and b is the maximum thickness of the wing.

The formation of the streamlined shape of the drum neck in cross section as wing-like profile in the ratio L / b≥5 allows the creation of maximum optimal conditions while reducing aerodynamic friction losses when rotating the drum filled with the working fluid in the housing.

Fig. 1

eine allgemeine Darstellung der Turbine im Querschnitt,

Fig. 2

eine Frontansicht der in Fig. 1 dargestellten Turbine,

Fig 3

einen Längsschnitt durch einen Stutzen eines schottischen Drehkreuzes oder der Trommel, der im Querschnitt als flügelartiges Profil ausgebildet ist,

Fig. 4

einen Querschnitt längs der Linie A-A in Fig. 3 und

Fig. 5

einen Querschnitt längs der Linie B-B in Fig. 3.

The invention will now be described in more detail using exemplary embodiments. Show it:

Fig. 1

a general representation of the turbine in cross section,

Fig. 2

2 shows a front view of the turbine shown in FIG. 1,

Fig. 3

a longitudinal section through a socket of a Scottish turnstile or the drum, which is designed in cross section as a wing-like profile,

Fig. 4

a cross section along the line AA in Fig. 3 and

Fig. 5

3 shows a cross section along the line BB in FIG. 3.

The turbine contains a Scottish turnstile, the tube 1 with a closed end is formed. The tube 1 is coaxial with a shaft 2 coupled and can rotate together with this. At least on tube 1 a pair of radially opposite nozzle 3 with in opposite directions bent, open ends 4 attached. The axes of the bent, open Ends 4 of the nozzle 3 are perpendicular to that surface that over the Axes of the nozzle pair 3 and the axis of the tube 1 runs. On the pipe wall 1 openings 13 are provided corresponding to the nozzle 3. The open ends 4 can be designed as nozzles.

A rotatable, cylindrical drum 5 is coupled coaxially to a shaft 6 mounted coaxially to tube 1 and includes the Scottish turnstile. On cylindrical belt 7 of the cylindrical drum 5 connects to the bent Ends 4 of the nozzle 3 of the Scottish turnstile with a gap. On the cylindrical belt 7 of the cylindrical drum 5 is at least a pair of connecting pieces 8 attached with open ends 9, which are different in relation to their axis Directions are turned. Radial from the opposite directions of these directions the directions of the stubs 3 of the Scottish turnstile are opposite arranged. The axes of the bent, open ends 9 of the nozzle 8 cylindrical drum 5 are perpendicular to the surface that over the Axes of the connector pair 8 of the cylindrical drum 5 and the axis of the tube 1 runs. On the wall of the cylindrical belt 7 of the cylindrical drum 5 openings 10 are provided corresponding to the nozzle 8. A housing 11 includes the Scottish turnstile and the cylindrical drum 5 with the Openings for housing the tube 1 of the Scottish turnstile and the shafts 6 and 2 of the cylindrical drum 5 and the Scottish Turnstile and with nozzle 12 for the outlet of the work equipment. The housing 11 is connected to an inlet connection 14 of the supply line for the working medium. The tube 1 of the Scottish turnstile has numerous at its exit part Bores 15 on, it together with the inlet connector 14th Labyrinth seals form a minimal drain of the working fluid secure that is inserted into the turbine.

The connector 3 of the Scottish turnstile can be designed in a streamlined shape be, e.g. in cross-section as a drop-shaped profile.

The streamlined shape of the nozzle 3 of the Scottish turnstile can be in Cross section are formed as a wing-like profile in the ratio L / b≥5, where L the chord of the wing and b is the maximum strength of the wing.

The nozzle 8 of the cylindrical drum 5 can be formed in a streamlined shape be, e.g. in cross-section as a drop-shaped profile.

The streamlined shape of the nozzle 8 of the cylindrical drum can be in cross section are formed as a wing-like profile in the ratio L / b≥5, where L is the chord of the Wing and b is the maximum thickness of the wing.

The selection of the minimum, aerodynamic, integral losses at the Rotation of the nozzle 3 of the Scottish turnstile and the nozzle 8 of the cylindrical drum 5, which in cross section as a wing-like profile, for example symmetrical Zhukovksy profile, were formed according to the value of the Profile resistance Cx = 0.02 carried out according to the method described in the book by G.I. Abramovich "The Applied Gas Dynamics", publisher "Nauka"; Editor of the Literature for physics and mathematics, M, 1969, p. 545, picture 10.12 is set out. The symmetrical Zhukovsky profile is shown in Figures 3, 4 and 5.

The turbine works as follows: The work equipment is in the Inlet 14 and the tube 1 of the Scottish turnstile. Then it is passed into the channels of each pair of nozzles. The working tool flows from the opposite, open ends at high speed 4 of the nozzle 3, it being perpendicular to the direction of the circumference Radius of the Scottish turnstile while ensuring that Rotation is accelerated by the generation of a recoil moment.

The back flow of the working fluid from the open ends 4 of the nozzle 3 with the high speed gets into the cavity of the enclosed space around the Scottish turnstile around which is formed by the cylindrical drum 5 and cooperates with the wall of the cylindrical drum 5 by friction, causing the drum to spin. The work equipment then gets into the Spigot pair 8 of the cylindrical drum 5 and flows with the open ends 9 high speed, accelerating and rotating the cylindrical Drum 5 caused due to the generation of the recoil moment.

In the course of the rotation of the cylindrical drum 5, the open Ends 4 flowing out working fluid flow within the cylindrical drum 5 braked by the frictional forces up to the rotational speed, with a Frictional torque is generated that the rotation of the cylindrical drum 5th causes.

At the same time, the working medium acts on the rotation of the cylindrical drum 5 (inside the drum) a centrifugal force, a centrifugal pressure is generated, under the influence of which the working fluid from the open ends 9 the cylindrical drum 5 flows out, generating an additional moment, that can be added to the frictional moment.

From the rotating Scottish turnstile and the cylindrical drum 5 the rotations to shafts 2 and 6 and then to consumers transfer.

In this way the useful use of the energy is done in the Scottish Turnstile processed work equipment and the acquisition of additional Power.

The working fluid continues to get into the housing 11 and flows over the nozzle 12 for the outlet of the work equipment.

The use of sockets 3 and 8 of the Scottish turnstile and the cylindrical drum 5 in a streamlined shape allows the reduction of aerodynamic losses in the rotation of the nozzle and the increase in obtained mechanical energy in the turbine.

The process of obtaining mechanical energy in the turbine is implemented as follows:

The working fluid is introduced into the rotor channels of the turbine and accelerated, d. H. its speed will be towards as it flows out of the channels the circumference with the rotor radius while guaranteeing the rotor rotation and the extraction of mechanical energy increases. It turns next to that Rotor also its shaft, from which the useful energy is taken.

The working fluid flows from the rotor channels into the enclosed space the rotor around and interacts with the shell by friction, the one forms closed space and that according to the circumference of the exit openings of the rotor channels. The formation of the envelope according to the radius of the The envelope allows the circumference along the exit openings of the rotor channels to turn the rotor; the interaction of the friction of the work equipment with the shell causes rotation of the shell, with centrifugal pressure is generated within the shell. The shell can be used, for example, as a drum be carried out. Then the working fluid flows through the action of the Centrifugal pressure through the openings in the shell (this can for example the openings 10 in the cylindrical drum 5 and the openings be in the socket 8); the work equipment is in the direction of the Perimeter, which is perpendicular to the radius of the envelope, and in the opposite Direction of flowing out of the rotor while ensuring the Accelerated rotation of the shell and the extraction of mechanical energy. The flow out of the with acceleration (increase in speed) Openings of the envelope in the direction of the circumference that correspond to the radius of the envelope standing vertically allows the sleeve to be turned. Braking the work equipment, that flows from the rotor channels into the shell allows the rotational effect to be strengthened by the forces of friction of the working medium with the casing and by the Recoil forces. In doing so, the shell also rotates its shaft, of which the additional useful energy is removed.

The load on the rotor and the casing can be chosen to be the same Orbital speeds of rotation of the outer diameter of the rotor and of the inner diameter of the shell can be reached. This is due to the connection realized by energy consumers, for example from generators to the Shafts of the rotor and the shaft, as well as by the setting of such Operating modes are realized in which the rotational speeds of rotation the outer diameter of the rotor and the inner diameter of the shell are. In this case, the maximum efficiency of the turbine can be achieved.

According to the conservation law of moment of kinetic energy, the torque is that acts on the rotor M1, equal to the total torque M2 that on the envelope acts (M1-M2).

If the flow rate of 1kg / s of the working fluid from the rotor channels with the radius R is W1, then M1 = M2 = (W1-V1) · R, where V1 is the rotational speed of the rotor.

The power achieved by the rotor at the angular velocity ω1 = V1 / R is N1 = (W1-V1) · R · V1 / R = (W1-V1).

At the same moment M1 = M2, the power that is achieved by the casing is at ω2 = V2 / R, where V2 is the rotational speed of the envelope, N2 = (W1-V1) · R · V2 / R = (W1-V1) · V2.

Thus, the presence of the rotating shell allows the same Orbital speeds V1 = V2 and in the absence of aerodynamic and other losses, in addition to receiving the same performance as the performance of the Rotors, i.e. the overall performance of the rotor-shell system doubles, and it the theoretical maximum efficiency of the turbine is achieved.

With V1 = V2 = V, the efficiency is: η = (N1 + N2) / W1 2 / 2 = 4 (V / W1 - V2 / W1 2 ) and with a ratio V / W1 = 0.25 η = 4 (0.25 - (0.25) 2 ) = 0.75.

A liquid, gas or steam can be used as the working medium in the turbine be used.

Example of using the procedure

The turbine works with water vapor. A Scottish type rotor Turnstile with two channels is used. The water vapor gets into the two Rotor channels embedded. The water vapor flow will flow out the channels accelerated in the direction of the perimeter, leading to the rotor radius is vertical, up to a speed of 790 m / s. A rotor with one Radius of r = 0.48m and a speed of n = 5000rpm is used. The Circulation speed of the rotor is 251 m / s. The rotor turns, and from The mechanical energy is taken from its shaft.

The water vapor flows from the rotor channels into the closed room the rotor around and interacts with the shell by friction, the one forms closed space and with exit openings according to the radius the circumference of the rotor channels is provided. Over the openings in the cover the water vapor flows out, up to a speed of 251 m / s in the direction of the circumference, which is perpendicular to the radius of the envelope, and in the Direction, which is the direction of the working fluid flowing out of the rotor opposite is accelerated while ensuring the rotation of the shell becomes. The radius of the shell insignificantly exceeds the radius of the rotor and is 0.4805m. The speed of the casing is n = 4990rpm. The shell turns itself, and the additional mechanical energy is taken from its shaft.

The shafts of the rotor and the sheath become the burden of individual Generators charged. Such operating modes of the generators are set that the orbital speeds of rotation of the outer diameter of the rotor and the inner diameter of the casing are equal to 251 m / s. In this The maximum mechanical energy at the theoretical is from the turbine Efficiency decreased from η = 0.86.

The method according to the invention for obtaining mechanical energy is have been confirmed by experiments, and the one realizing this method Turbine passed the test successfully.

Most successfully, the invention can be hydraulic, pneumatic or Steam turbine for driving electrical generators, compressors from Cooling systems and heat pumps, etc. are used.

Claims (7)

Process for the extraction of mechanical energy, in which the working medium is introduced into the channels of a rotor, when flowing out of the channels in the direction of the non-circle, which is perpendicular to the radius of the rotor, accelerated by rotating the rotor and out of the channels of the rotor into one of one Is formed, the enclosed space is introduced around the rotor, which cooperates with the sleeve by means of friction, and in which the working fluid flows out through openings in the sleeve, being accelerated in one direction with rotation of the sleeve,
characterized in that the space formed by the casing is closed and runs in the vicinity of the circumference, the radius of which is formed by the distance of the outlet opening of a rotor channel from the rotor axis, and in that the working medium flowing out through the openings in the casing along the circumference is accelerated perpendicular to the envelope radius in a direction opposite to the flow of the working fluid out of the rotor. Method according to claim 1,
characterized in that the rotor and casing are operated such that the same rotational speeds are achieved at the locations of the outer diameter of the rotor and the inner diameter of the casing. Turbine for performing the method according to claim 1 or 2, with a Scottish turnstile, which is designed as a rotatable tube (1) with a closed end, the tube being coaxially coupled to the turbine shaft (2) and on the tube (1) at least one pair of radially opposite nozzles (3) with opposite from their axis In the direction of the bent open ends (4), the axes of the bent open nozzle ends (4) are perpendicular to the surface which extends over the axes of the nozzle pair (3) and the axis of the tube (1), and wherein the tube wall has openings (13) corresponding to the connecting piece (3), a rotatable sleeve which is coaxially coupled to the shaft (2) and comprises the Scottish turnstile, a housing (11) comprising the work wheel and the casing with openings for accommodating the tube (1) of the Scottish turnstile and the shafts of the Scottish turnstile and the casing with a nozzle (12) for the outlet of the working medium, characterized in that the casing is designed as a cylindrical drum (5) in that a cylindrical belt (7) of the drum connects to the bent ends (4) of the connecting pieces (3) of the Scottish turnstile with a gap that on the cylindrical belt ( 7) the drum has at least one pair of radially opposite nozzles (8) with open ends (9) which are bent in different directions with respect to their axis, these directions being opposite to the directions of the nozzles (3) of the Scottish turnstile and the Axes of the bent, open ends (9) of the connecting piece (8) of the drum (5) are perpendicular to the surface which runs over the axes of the connecting piece pair (3) and the axis of the tube (1), and that on the wall of the Belt (7) openings (10) are formed according to the nozzle. Turbine according to claim 3,
characterized in that the connecting pieces (3) of the Scottish turnstile are drop-shaped. Turbine according to claim 4,
characterized in that the streamlined shape of the connecting piece (3) of the Scottish turnstile is formed in cross section as a wing-like profile in the ratio L / b≥5, where L is the chord of the wing and b is the maximum thickness of the wing. Turbine according to claim one of claims 3 to 5,
characterized in that the nozzles (8) of the drum (5) are drop-shaped. Turbine according to claim 6,
characterized in that the streamlined shape of the drum socket (8) is formed in cross section as a wing-like profile in the ratio L / b≥5, where L is the chord of the wing and b is the maximum thickness of the wing.

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