RU128921U1 - MULTIFUNCTIONAL VORTEX HEAT GENERATOR (OPTIONS) - Google Patents

Abstract

1. A multifunctional vortex heat generator, comprising a closed housing with nozzles for supplying a heated fluid and removing heated fluid, rotors mounted inside the housing, made in the form of two disks mounted on independent shafts having independent drives and having the ability to rotate towards each other, characterized in which contains suction turbines that are rigidly fixed to independent shafts together with rotor disks, and in the rotor disks, opposite the installed turbines, squo conical-cylindrical openings directed into the cavity between the disks, the rows of fingers are rigidly mounted radially circumferentially radially around the circumference of the fingers, the fingers being made so that the rows of fingers of one disc freely enter with a gap between the rows of fingers of the second disc, and the conical-cylindrical openings one disk is located opposite the conical-cylindrical openings of another disk, and each disk with a turbine is equipped with a separate pipe, which is a pipe for supplying a heated fluid. 2. A multifunctional vortex heat generator comprising a closed housing with nozzles for supplying a heated fluid and removing heated fluid, rotors installed inside the housing, made in the form of two disks mounted on independent shafts having independent drives and having the ability to rotate towards each other, characterized in that it contains suction turbines that are rigidly fixed on independent shafts together with rotor disks, and in rotor disks, opposite installed turbines, are made through conical cylindrical

Description

The utility model relates to the field of power engineering for heating liquids in heating systems, hot water supply and can be used in the chemical, food, construction industries, etc., where fine grinding, mixing, activation, destruction of liquid and bulk materials is required.

Currently, heat pumps are widely used, using changes in physicochemical parameters to produce thermal energy. Known heat generator and a device for heating liquids, RF patent No. 2045715, IPC 6 F25B 29/00 (published 10.10.1995,), comprising a housing with a cylindrical part, a fluid accelerator made in the form of a cyclone, the end side of which is connected to the cylindrical part corps. At the base of the cylindrical part opposite the cyclone, a brake device is mounted.

A cavitation driving heat generator is also known - RF patent No. 2201562, IPC 7 F24J 3/00 dated 05/19/1999, including a housing in which relatively movable working bodies are located, the input and output of which are hydraulically communicated through a circulation channel with a throttling element. The working bodies, at least one of which is connected with the drive motor, are made in the form of opposed disks installed with a guaranteed gap between their ends, provided with adjacent grooves located on the interacting working ends of the disks obliquely to each other. The disadvantages of the above technical solutions include the technologically complex manufacture of their elements. In particular, the use of the labyrinth seal is justified at high temperature, its use to create high tightness is problematic.

Known RF patent No. 2201561 C2, IPC 7 F24J 3/00 (published March 27, 2003) for a cavitation-type heat generator in communication with a stimulating pump, the output of which is connected to the output channel of the vortex nozzle equipped with an axial output nozzle, and at the nozzle exit located made in the form of an asymmetric chamber at least one resonator of self-oscillations. This invention has the property of the occurrence of resonant oscillations inside the resonant cavities, which requires a certain elasticity of the medium before the cavitation phase. It is known that when resonance phenomena occur in confined spaces, the effect of water hammer and shock waves is observed. In technology, hydraulic shocks lead to destruction and periodic stresses on connecting and other mechanical parts in the field of resonance effects. Together with the processes of cavitation, this effect can lead to rapid aging, wear of elements and devices of the heat generator.

Known RF patent No. 2362947 C2, IPC 7 F24J 3/00 (published July 27, 2009) for a cavitation heat generator containing a working body consisting of a housing, covers, working disks of the heat generator of the first and second impellers, dividing walls, two check valves, a third thermal valve, an expansion unit for forming a steam-water mixture and a jet turbine, and the heat generator disks are made with recesses in the form of spherical segments and guide channels deposited on the ends of the disks, forming three spiral vortex channels with each second side of the disc, and along the cylindrical surface of the discs at an angle of 15 ° to their generatrix applied guide channels for guiding the heat-generator-steam mixture along the axis towards the impeller.

The disadvantage of this design is that during the operation of the heat generator, a phase transition to a vapor state or an boundary state is allowed when the energy release range moves to the optical or sound range, i.e. when the process of near-surface cavitation in the optical and low-frequency ranges becomes prevailing, which destroys the surface of the working bodies on which cavitation bubbles form. Together with cavitation processes, this effect leads to rapid aging and wear of elements and devices of the heat generator.

The complexity of the design and low maintainability are also among the disadvantages of this heat generator.

Known RF patent No. 2235950 C2, IPC 7 F24J 3/00 dated 09/10/2004 on a cavitation-vortex heat generator, comprising a housing having nozzles for supplying a heated fluid and removing heated fluid, a perforated stator and rotor located inside the housing, a pressure pump, the rotor drive, and the stator and rotor are made in the form of disks, perforated through holes, the stator is made in the form of one or more annular disks, and the rotor is made in the form of two disks mounted with a gap relative to each other, while ki rotor installed on independent shafts having independent drives independent and rotate toward each other.

The disadvantage of this design is the insufficient heating rate of the liquid, and the design of the device has great technical complexity in the manufacture, repair and unreliability in operation. This technical solution is taken as the closest analogue (prototype) for the three options of the proposed technical solutions.

The technical problem of the claimed utility models is the creation of devices that provide a higher rate of heating of the liquid (water, solutions, mixtures, etc.) by high-speed processing, obtaining the maximum friction surface of the liquid, simplifying the design, and as a result, improving the reliability and expansion Areas of use.

The technical problem to be solved in a multifunctional vortex heat generator according to its first embodiment, comprising a closed housing with nozzles for supplying a heated fluid and removing heated fluid, rotors installed inside the housing, made in the form of two disks mounted on independent shafts, having independent drives and having the ability to rotate towards to each other, is achieved by introducing suction turbines that are rigidly fixed to independent shafts together with rotor disks, and in rotor disks, on the contrary installed turbines around the circumference made through conical-cylindrical holes directed into the cavity between the disks, higher in the radius of which radially around the circumference are rigidly mounted rows of fingers, while the fingers are made so that the rows of fingers of one disk freely enter with a gap between the rows of fingers of the second disk, and the conical-cylindrical holes of one disk are located opposite the conical-cylindrical holes of the other disk and each disk with a turbine is equipped with a separate nozzle, which are nozzles for rootstock yes heated fluid.

The technical problem to be solved in a multifunctional vortex heat generator according to its second embodiment, comprising a closed housing with nozzles for supplying a heated fluid and removing heated fluid, rotors installed inside the housing, made in the form of two disks mounted on independent shafts having independent drives and having the ability to rotate towards to each other, is achieved by introducing suction turbines that are rigidly fixed to independent shafts together with rotor disks, and in rotor disks, on the contrary installed turbines around the circumference made through conical-cylindrical holes directed into the cavity between the disks, higher in the radius of which radially around the circumference are rigidly mounted rows of fingers made in the form of ellipsoidal fingers - blades perforated through the conical-cylindrical holes and mounted on the disks so that the holes in the fingers - the blades are directed along the rotation of the rotor discs and the rows of fingers - the blades of one disk freely enter with a gap between the rows of fingers - the blades of the second disk, and each electric motor is equipped with a device for controlling the speed.

The technical problem to be solved in a multifunctional vortex heat generator according to its third embodiment, comprising a closed casing with nozzles for supplying a heated fluid and draining a heated fluid, a collection of heated fluid, rotors installed inside the casing, made in the form of two disks mounted on independent shafts having independent drives and having the ability to rotate towards each other, is achieved by introducing suction turbines that are rigidly fixed to independent shafts together with rotor disks, and in the rotor disks, opposite the installed turbines, circumferential through-conical holes are made, directed into the cavity between the disks, the rows of fingers are rigidly mounted radially around the circumference radially around the circumference of the fingers, while the fingers are made so that the rows of fingers of one disk freely enter with a gap between the rows of fingers of the second disk, and the conical-cylindrical holes of one disk are located opposite the conical-cylindrical holes of another disk and each disk with a turbine is equipped with a separate nozzle, yuschiesya nozzles for supplying fluid to be heated, the entire inner surface of the housing and the outer surface of the turbine discs with the fingers, and drive shafts positioned within the housing, the wear are covered with ceramics, and outputs motor drives the rotor and collection of the heated liquid temperature sensor are connected to respective inputs of the control unit.

Figure 1 shows schematically a multifunctional vortex heat generator according to the first embodiment.

Figure (2) shows a schematic illustration of a multifunctional vortex heat generator according to the second embodiment.

Figure 3 shows schematically a multifunctional vortex heat generator according to the third embodiment.

On (Figure 4) shows the first disk of the heat generator attached to the shaft (end view).

On (Figure 5) shows a section of the first disk AA.

On (Fig.6) shows the second disk of the heat generator attached to the shaft (end view).

On (Fig.7) shows a section of the second disk AA.

On (Fig. 8) a finger is shown — a blade of a heat generator according to the second embodiment (side view).

On (Fig.9) shows a section of the finger - shoulder blades AA (in the second embodiment)

The multifunctional vortex heat generator according to the first embodiment (Figs. 1, 4, 5, 6, 7) contains a closed housing 1 with nozzles 2 for supplying a heated fluid and removal of a heated fluid 3, a collection of heated fluid 4, rotors 5 mounted inside the housing 1, made in in the form of two disks 6 and two suction turbines 7, rigidly mounted on independent shafts 8 together with disks 6 of the rotor 5. The shafts 8 in the housing 1 are installed in the bearing units 9 and have independent drives 10 connected to the electric motors 11, and the shafts 8 can rotate on Stretch each other. In the disks 6 of the rotors 5 opposite the installed turbines 7, circumferential through conical-cylindrical openings 12 are made, directed into the cavity between the disks 6, the radii of the rows of fingers 13 are rigidly mounted radially around the circumference, while the fingers 13 are made so that the rows of fingers 13 one disk 6 freely enter with a gap between the rows of fingers 13 of the second disk 6, and the conical-cylindrical holes 12 of one disk 6 are located opposite the conical-cylindrical holes 12 of the other disk 6 and each disk 6 with a turbine 7 is equipped with a bkom 2 for feeding heated liquid. The rotor 5 of the heat generator is an easily removable design, consisting of a disk 6 with fingers 13, a turbine 7 and a shaft 8, which, before assembling the heat generator, undergoes statistical and dynamic balancing. Balancing allows you to reduce noise during the operation of the heat generator and increase its service life. The collection of heated liquid 4 through the circulation pump 14 is connected to the heating system and is equipped with temperature sensors EVCO NTC TMF and level Aries of the remote control, which are not shown in the drawing. Housing 1 and rotor 5 of the heat generator are made of corrosion resistant (stainless) steel GOST 5632-72 group 1. A general view and section of the disks 6 is shown in (Figs. 4, 5, 6, 7).

The multifunctional vortex heat generator according to the second embodiment (Figs. 2, 8, 9) contains a closed housing 1 with nozzles 2 for supplying a heated fluid and removing heated fluid 3, a collection of heated fluid 4, rotors 5 mounted inside the housing 1, made in the form of two disks 6 and two suction turbines 7 mounted on independent shafts 8 together with disks 6 of the rotors 5. The shafts 8 in the housing 1 are installed in the bearing units 9 and have independent drives 10 connected to the electric motors 11, and the shafts 8 can rotate towards others yn friend. In the disks 6 of the rotors 5 opposite the installed turbines 7, circular conical-cylindrical holes 12 are made around the circumference, directed into the cavity between the disks, higher in the radius of which are rows of fingers 13 rigidly mounted radially around the circumference, made in the form of ellipsoid fingers - blades perforated through the conical cylindrical holes 15 and mounted on the disks 6 so that the holes in the fingers - blades 13 are directed along the rotation of the disks 6 and the rows of fingers - blades 13 of one disk 6 freely enter the gap between the rows and fingers - blades 13 of the second disk 6 and each electric motor 11 is equipped with a device 16 for regulating the rotational speed of the electric motors 11 using a pump drive frequency converter (KSB concentrators). The collection of heated liquid 4 through the circulation pump 14 is connected to the heating system and is equipped with temperature sensors EVCO NTC TMF and level Aries of the remote control, which are not shown in the drawing. General view and incision of the finger - the blades 13 are presented in (Fig.8.9). The external contour of the cross section along AA of the finger - blade 13 is an ellipsoid, the height of which, for example, is 12 mm, and its width, for example, is 8 mm. The heat generator rotor 5 is an easy-to-assemble design consisting of a disk 6 with fingers 13, a turbine 7 and a shaft 8, which undergoes statistical and dynamic balancing before assembling the heat generator. Balancing allows you to reduce noise during the operation of the heat generator and increase its service life. Case 1 and rotors 5 of the heat generator are made of corrosion-resistant (stainless) steel GOST 5632 group 1.

The multifunctional vortex heat generator according to the third embodiment (FIG. 3) comprises a closed housing 1 with nozzles 2 for supplying a heated fluid and removing heated fluid 3, a collection of heated fluid 4, rotors 5 mounted inside the housing 1, made in the form of two disks 6 and two suction turbines 7 mounted on independent shafts 8 together with disks 6 of rotors 5. Shafts 8 in housing 1 are mounted in bearing units 9 and have independent drives 10 connected to electric motors 11, with shafts 8 being able to rotate towards each other other. In the disks 6 of the rotors 5 opposite the installed turbines 7, through the conical-cylindrical openings 12 are made, directed into the cavity between the disks, the rows of fingers 13 are rigidly mounted radially around the circumference of the circumference of the fingers 13, while the fingers 13 are made so that the rows of fingers 13 of one disk 6 freely with a gap between the rows of fingers 13 of the second disk 6, and the conical-cylindrical holes 12 of one disk 6 are located opposite the conical-cylindrical holes 12 of the other disk 6. Each disk 6 with a turbine 7 is equipped with a pipe ohm 2 for supplying a heated fluid, and the entire inner surface of the casing 1 and the outer surface of the turbines 7, disks 6 with fingers 13 and shafts 8 of the drive 10 located inside the casing 1, are coated with wear-resistant ceramics - zirconium oxide, and the outputs of the electric motors 11 of the drives 10 of the rotors 5 , the temperature sensor of the heated liquid in the collector 4 is connected to the corresponding inputs of the control unit 17, which is a soft-start device for electric motors 11 (EnergySaver - ESTS1, Efficient Systems LLC) with the energy function saving. The device allows, in addition to the on / off function of electric motors 11, to eliminate “gaps” in the supply network when starting up the equipment, to reduce the heating of power cables, to increase the service life of the equipment and save electricity up to 30%. The rotor 5 of the heat generator is an easily collapsible design consisting of a disk 6 with fingers 13, a turbine 7 and a shaft 8, which undergoes statistical and dynamic balancing before assembling the heat generator. Balancing allows you to reduce noise during the operation of the heat generator and increase its service life. The collection of heated liquid 4 through the circulation pump 14 is connected to the heating system and is equipped with temperature sensors EVCO NTC TMF and level Aries of the remote control, which are not shown in the drawing. The housing 1 and the rotors 5 of the heat generator are made of ordinary steel and coated by spraying with zirconium oxide.

Consider the operation of a multifunctional vortex heat generator according to its first embodiment (Figure 1). The heat generator operates as follows. After filling the heating network and the closed housing 1 of the heat generator through the inlet pipes 2 with a working fluid (water), the motors 11 of the actuators 10 are turned on, driving the turbine 7 together with the disks 6 and the liquid. After passing through the turbines 7 from two sides and the conical-cylindrical openings 12 of the disks 6, the fluid flows are divided into many powerful jets on each disk 6 and are directed towards each other, and then after the collision of these flows are discarded due to centrifugal force in the perpendicular direction between those rotating in opposite directions disks 6 with fingers 13. After processing between the rows of fingers 13 of disks 6, the liquid due to centrifugal force is thrown onto the wall of the housing 1, and then flows through the pipe 3 into the fluid collector and 4, included in the heating main, through the circulation pump 14.

In the cavity between the disks 6 with the fingers 13, powerful vortex fluid flows form from the center to the periphery of the disks 6, which enhances the cavitation process. As a result, a vacuum region is formed inside the vortex, in which cavitation bubbles appear, and in the areas of high pressure in the opposing flows, the micro bubbles “burst” not at the walls of the disks 6 but inside the liquid flow with fast energy release in the thermal infrared range, without destroying the disks 6 with fingers 13. The temperature control of the heated liquid in the collector 4 is controlled by turning on and off the electric motors 11 according to the signals of the temperature sensor installed in the collector 4 etoy liquid. When the coolant reaches the maximum temperature set by the consumer (not> 95 ° C), the motors 11 are turned off, when the coolant (water) is cooled to the minimum set temperature (not <65 ° C), the motors 11 are turned on. Upon reaching the upper or lower level in the collection 4, the signal from the level sensor is supplied to the heating main operator. During the heating season, the average heat generator runs 25-30% of the time.

Compared with the prototype, the proposed design of the multifunctional vortex heat generator provides faster heating of the liquid, is easy to manufacture, reliable in operation and can be used for grinding, mixing, activation, destruction of liquid and bulk components.

Consider the work of a multifunctional vortex heat generator in its second embodiment (Figure 2).

The heat generator works in the same way as the heat generator according to the first embodiment (Figure 1), but with the following fundamental difference. The fundamental difference is that the fingers 13 (Figure 2) of the disks 6 of the rotors 5 are made in the form of ellipsoidal fingers - blades, perforated through through conical-cylindrical holes 15 and mounted on the disks 6 so that the holes 15 of the fingers of the blades 13 are directed along during the rotation of the disks 6 and during the rotation of the disks 6 create super-powerful zones of compression and discharge inside the fluid flow, which dramatically reduces the heating time of the fluid, and the presence of a device 16 for controlling the speed of the motors 11 using a frequency converter Vatel allows you to create optimum fluid heating.

Consider the work of a multifunctional vortex heat generator according to the third embodiment (Figure 3).

The heat generator works in a similar way as a heat generator according to the first embodiment (Figure 1), but with the following difference. The difference is that the heat generator is equipped with a control unit 17 (Fig. 3), with which the motors 11 are smoothly started. Before starting the heat generator to work, the upper (not> 95 ° C) and lower (not <65) are installed on the control unit 17 ° C) the temperature limits of the liquid. When the temperature of the liquid in the collector 4 of the upper limit is reached, the electric motors 11 are turned off, and when the lower limit is reached, they smoothly turn on. Coating the inner surface of the housing 1 and the working elements of the rotors 5, shafts 8, turbines 7, disks 6, fingers 11 with wear-resistant ceramics (zirconium oxide) significantly increases the life of the heat generator.

Compared with the prototype, the proposed options for a multifunctional vortex heat generator provide a higher fluid heating rate, simplification of the design (the prototype has a complex nozzle system, a belt drive gearbox and low maintainability) with a simultaneous increase in operational reliability and expansion of the field of application in other industries.

Claims (3)

1. A multifunctional vortex heat generator, comprising a closed housing with nozzles for supplying a heated fluid and removing heated fluid, rotors mounted inside the housing, made in the form of two disks mounted on independent shafts having independent drives and having the ability to rotate towards each other, characterized in which contains suction turbines that are rigidly fixed to independent shafts together with rotor disks, and in the rotor disks, opposite the installed turbines, squo conical-cylindrical holes directed into the cavity between the disks, the rows of fingers are rigidly mounted radially circumferentially above the radius of the fingers, while the fingers are made so that the rows of fingers of one disk freely enter with a gap between the rows of fingers of the second disk, and the conical-cylindrical holes one disk is located opposite the conical-cylindrical holes of another disk, and each disk with a turbine is equipped with a separate pipe, which is a pipe for supplying a heated fluid. 2. A multifunctional vortex heat generator comprising a closed housing with nozzles for supplying a heated fluid and removing heated fluid, rotors installed inside the housing, made in the form of two disks mounted on independent shafts having independent drives and having the ability to rotate towards each other, characterized in that which contains suction turbines, which are rigidly fixed on independent shafts together with rotor disks, and in the rotor disks, opposite the installed turbines, squashes are made around the circumference conical-cylindrical holes directed into the cavity between the disks, rows of fingers made in the form of ellipsoid fingers — blades perforated through the conical-cylindrical holes — are mounted radially higher on the radius of the radius and are mounted on the disks so that the holes in the fingers the blades are directed along the rotation of the rotor disks, and the rows of fingers - the blades of one disk freely enter with a gap between the rows of fingers - the blades of the second disk, and each electric motor is equipped with a device for speed control. 3. A multifunctional vortex heat generator comprising a closed housing with nozzles for supplying heated fluid and removing heated fluid, a collection of heated fluid, rotors installed inside the housing, made in the form of two disks mounted on independent shafts having independent drives and having the ability to rotate towards each other , characterized in that it contains suction turbines that are rigidly mounted on independent shafts together with rotor disks, and in rotor disks, opposite the installed turbines, the circles are made through conical-cylindrical holes directed into the cavity between the disks, the rows of fingers are rigidly mounted radially around the circumference of the radial circumference of the fingers, the fingers being made so that the rows of fingers of one disk freely enter with a gap between the rows of fingers of the second disk, and the conical cylindrical holes of one disk are located opposite the conical-cylindrical holes of another disk, and each disk with a turbine is equipped with a separate pipe, which is a pipe for supplying a heated fluid, the entire inner surface of the casing and the outer surface of the turbines, discs with fingers and drive shafts located inside the casing are coated with wear-resistant ceramics, and the outputs of the electric motors of the rotor drives, the temperature sensor of the heated fluid reservoir are connected to the corresponding inputs of the control unit.

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