PL242539B1 - Bladeless turbine - Google Patents

Abstract

The bladeless turbine is designed to work in a closed circuit, which works with a heat pump. The turbine has a housing (1) with two inlet nozzles and a shaft (4) with an axially running outlet channel (5), on which discs (3, 3', 3") are butt jointed. Discs (3, 3', 3" ) are divided into sections (6, 6', 6") separated by partitions (7). depth.

Description

Description of the invention

The subject of the invention is a bladeless turbine driven by a medium with a low boiling point, especially carbon dioxide, for use in particular in the energy industry, in the automotive industry or for ship propulsion.

Known from the Polish description of the invention No. PL 233 053, a Tesla turbine working with low-boiling and medium-temperature media, is made of a package of discs, which is mounted on the shaft by means of retaining rods; retaining rods are threaded on both sides, fixed in flanges located on the shaft; there are spacers between the discs, the entire set of discs is positioned along the axis of rotation by means of spacer sleeves put on the retaining rods; the whole is bolted at the stop flange and secured with washers and nuts. The working medium is supplied on the outer periphery of the discs and directed through the nozzles to the spaces between the discs; the feed nozzles are formed by internal segments suitably spaced around the circumference; the entire feeding ring is closed by the outer segment and the outer ring forming part of the turbine body to which the feeding connector is attached.

It is known from the US patent US2014252772 a spiral gas turbine for converting the pressure and temperature energy of the gas into kinetic energy of the turbine to perform work. The gas travels outward through at least one helical channel cut into the flat discs so that its pressure gradually decreases along the length of the helix. A spiral has many turns, and the radius of the spiral is a given increasing function of the turns of the radius. The length of the spiral is about 1 meter, the width is about 1 cm, and the depth is a fraction of a millimeter.

GB2477101 discloses a friction disk turbine comprising a plurality of concentric circular disks with raised involute helical ridges formed on their surface and central openings. The discs are stacked and fastened together with through-bolts or rivets. The helical ridges form helical passages for the moss of the compressed working medium from the periphery to the inner part of the stack. The movement is transmitted by the friction of the working fluids to the discs. Each disc can provide one outlet. One or both faces of the disc stack may have a flanged disc connected to the axle shaft. If both surfaces have a flanged disc, one of the axial shafts may be hollow to allow the working medium to be blown off. Spiral ridges have the effect of increasing the surface area of the discs. The spiral ridges can be widened to create a taper effect at the entrance to each spiral passage.

The construction of a bladeless turbine is known from the American patent description US 1061206, which presents the idea of the energy conversion process from the working medium to the turbine wheel. The rotor consists of a package of many disks mounted on a shaft. Rotating discs have one large hole located in the axis of rotation. The discs are mounted on three-arm pads, the mounting points are located at the edge of the inner hole. Washers, which are also spacers between the discs, are directly mounted on the shaft. The entire system is supported on two bearings embedded in two halves of the body with a vertical division, perpendicular to the axis of rotation. Between the two halves of the body there is a half-ring element connecting the left and right parts. This element has a width adapted to the disk package. The power supply is carried out through two nozzles arranged tangentially to the circumference of the discs, located on opposite sides of the body, which is to enable the change of the direction of rotation of the impeller. At one point during operation, the rotor is fed from one nozzle.

It is known from the publication of the international application W O2012004127 a Tesla turbine for converting flow energy into shaft mechanical energy and a method for doing so. Within the housing is a turbine wheel that rotates around an axis and has a stack of parallel discs that are spaced apart and each has surfaces on both sides. Between the discs, fluid flowing tangentially into the housing through the inlet impinges on the surfaces of the discs and exits the housing through the outlet. The liquid flows through the interspace between suitably spaced discs to an outlet substantially centrally along the axis of the stack of spaced discs. As a result of the fluid impinging on the stack of discs, it begins to rotate in the direction of the fluid outlet.

The aim of the invention is to develop a construction of a turbine intended for operation in a closed circuit, cooperating with a heat pump, with relatively small overall dimensions, which enables limiting the rotational speed of the rotor while increasing the torque.

The essence of the bladeless turbine according to the invention, which has a housing with at least one inlet nozzle for diagonal directing of the medium stream onto the ridges of the discs and the impeller fixed in it in the form of a shaft with longitudinal inlet holes and an axially running outlet channel on which the discs are mounted, located parallel to each other, and on the side surfaces of the discs there are identical grooves in the shape of an Archimedean spiral, consists in the fact that the turbine consists of at least one section of rotor discs in contact with each other with rectangular cross-sectional grooves of cyclically changing depth. There are partitions between the sections, tightly attached to the housing from the back side of the discs, where a turbine with one section or the first section of a multi-section turbine has two end discs with grooves located on one side of them, forming a pair with each other, on the principle of mirror image, or has two discs outer discs and at least one inner disc with grooves on both sides forming a mirror-image pair, where their number increases in successive sections, so that the concavities of the groove of one extreme disc correspond to the convexities of the groove of the other end disc, and the concavities of the groove on on one side of the inner disk correspond to the protuberances of the groove on the other side, creating channels of constant cross-section between the disks. Inside the outlet channel of the turbine rotor shaft with at least two sections, there are guiding baffles to direct the medium stream from one turbine section to the next.

The channels formed between the contacting discs have bottoms with an alternating aerodynamic profile.

The construction of the turbine according to the invention is especially intended for cooperation with a heat pump, with which it forms a common thermodynamic cycle, where the medium with a pressure of several dozen bars, from the pressure tank of the heat pump, is directed to the heat pump's boiler, and from there to the turbine and the compressor motor.

Through the use of grooves in the shape of an Archimedes spiral with a dozen or so turns in the rotor discs in contact with each other, with a rectangular cross-section and cyclically changing depth, channels for the flow of the medium were obtained, the bottoms of which are shaped in accordance with the aerodynamic profile in an alternating manner, it is possible to significantly reduction of the turbine dimensions, as a large number of working aerodynamic elements were obtained, acting as turbine blades.

The factor flowing around the aerodynamic profiles shaped at the bottom of the groove in both contacting rotor discs has a direction consistent with the movement of the discs. This is contrary to the commonly accepted opinion that the movement of the medium is diagonal but opposite to the direction of the aerodynamic profile.

The effect of the air stream on the profile of the aircraft wing is known, where the direction of the forces that push and pull from the bottom of the aircraft wing depends on the shape of this profile.

In the turbine according to the invention, the stream of the medium must have the opposite direction to the commonly used one and this does not affect the influence of the medium on the profile due to the high pressure of the medium, which does not affect the speed of the medium moving from the outer part of the rotor to its center, because the size of the difference pressure is maintained. The prevailing considerable pressure in the channel in which it flows causes the stream to adhere to the walls of the channel and does not allow it to detach from the flow around aerodynamic profile.

In this turbine, which works in a closed circuit, there is a significant overpressure, because it results from the pressure in the pressure tank of the heat pump and the condensation pressure of the refrigerant in the condensing exchanger.

- in zone I of the rotor, the pressure at the inlet is approx. 45-50 bar, and at the outlet approx. 33 bar.

- in zone II - 33 to 22 bar.

- in zone III - 22 to 10 bar.

The minimum pressure is 10 times greater than atmospheric pressure, so there is no risk of stream detachment and turbulent flow.

The turbine is characterized by a limited rotational speed, the size of which can be influenced by changing the number of sections - which changes the path of the medium in the rotor and the speed of the medium, as well as by appropriately shaping the bottoms of the grooves in the adjacent discs forming the aerodynamic channel. This turbine has a significant torque with relatively small overall dimensions. It is also characterized by high efficiency, where in connection with the heat pump almost all of the supplied heat energy is converted into work.

The subject of the invention is shown in the example of the embodiment in the drawing, in which Fig. 1 shows a schematic view of a bladeless turbine in a longitudinal section, Fig. 2 - the turbine wheel in an axonometric view from above, in the arrangement, Fig. 3 - a turbine wheel in an axonometric view from below, in spacing, Fig. 4 - schematic of the rotor disc in cross-section, Fig. 5 - schematic of the turbine rotor in longitudinal section through 10 windings of the aerodynamic channel, in the second section A-A, Fig. 6 - schematic section of the channels between the rotor discs in longitudinal section B-B.

The bladeless turbine according to the exemplary embodiment has a housing 1 with two inlet nozzles 2 for diagonal directing of the medium stream onto the backs of the discs 3, 3', 3, which are mounted on the shaft 4 with an axially running outlet channel 5, the discs touching each other with their side surfaces creating a rotor. The discs 3, 3', 3 are divided into three sections 6, 6', 6, increasing in number in subsequent sections, and the sections are separated by partitions 7, which are tightly attached to the housing 1 from the back side of the discs 3, 3', 3 On the side surfaces of the discs 3, 3', 3 there are identical grooves 8, 8', 8 in the shape of an Archimedean spiral.

Each section 6, 6', 6 consists of two end discs 3, 3' with grooves 8, 8' on one side and at least one inner disc 3 with grooves 8 on both sides. The grooves 8, 8', 8 have a rectangular profile with a cyclically changing depth, so that the grooves 8, 8' of the outer disks 3, 3' and the grooves 8 on both sides of the inner disks 3 form pairs with each other on the principle of mirror reflection. The concavities of the groove 8 of one end disc 3 correspond to the convexities of the groove 8' of the other end disc 3', while the concavities of the groove 8 on one side of the inner disc 3 correspond to the convexities of groove 8 on its other side. All the rotor discs 3, 3', 3 touching each other with the crests of the grooves 8, 8', 8 form between them channels 9 of a constant cross-section, whose bottoms 10, 10' are shaped in accordance with the aerodynamic profile and run in an alternating manner. Inside the outlet channel 5 of the shaft 4 of the turbine rotor with three sections 6, 6', 6, there are two guiding baffles 11 for directing the medium stream from one section of the turbine to the next section.

Claims (2)

Fig. 1. A bladeless turbine consisting of a casing with at least one inlet nozzle for diagonal directing of the medium stream onto the ridges of the discs and a rotor mounted in it in the form of a shaft with longitudinal inlet holes and an axially running outlet channel on which the discs are mounted, located parallel to each other , and on the side surfaces of the discs there are identical grooves in the shape of an Archimedean spiral, characterized in that the turbine consists of at least one section (6, 6', 6) of discs (3, 3', 3) in contact with each other with grooves ( 8, 8', 8) with a rectangular cross-section with cyclical changes of depth, and between the sections (6, 6', 6) there are partitions (7) tightly attached to the housing (1) from the back side of the discs (3, 3', 3), wherein the turbine with one section or the first section of a multi-section turbine has two end discs (3, 3') with grooves (8, 8') located on one side of them, forming a pair with each other, on the principle of mirror image, or has two shields (3, 3') and at least one inner disk (3) with grooves (8) located on both sides forming a mirror-image pair with each other, their number increasing in successive sections so that the concavities of the groove (8) of one outer disc (3) correspond to the convexities of the groove (8') of the other extreme disc (3'), while the concavities of the groove (8) on one side of the inner disc (3) correspond to the convexities of the groove (8) on the other side, which creates between discs (3, 3', 3) channels (9) with a constant cross-section, while inside the outlet channel (5) of the shaft (4) of the turbine rotor with at least two sections (6, 6'), there are baffles (11) directing to directing the medium stream from one section of the turbine to the next. 2. A turbine according to claim 1, characterized in that the channels (9) formed between the contacting discs (3, 3', 3) have bottoms (10, 10') with an alternating aerodynamic profile.