RU2421633C1 - Belashov's rotary piston vacuum pump - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: pump base accommodates rotary locking device made up of flaps the channels of which accommodate fluid flow distribution system with check mechanism. Said base incorporates also locking device for said rotary locking device made up of recess to interact with retainer core provided with spring-loaded rod and electromagnetic coil. Rotary mechanism is arranged in said rotary locking device made up of gear wheel interacting with shaft gear, shaft being coupled with reduction gear and motor. Rotary locking device is provided with insert interacting via rolling or sliding elements with housing base and cover. Top working zone of check mechanism is communicated via channels with bottom working zone. Rotary mechanism shaft interacts via transfer device or directly with rotor.

EFFECT: expanded performances, higher reliability of seal, reduced weight and higher efficiency.

Description

The invention relates to mechanical devices for pumping or pumping liquids or gases, in particular to combined rotary piston vacuum pumps of a modular type, which can be used as a low vacuum pump or high pressure pump for oil and gas production, pumping a fluid medium consisting of from gas, liquid and petroleum products, as well as their mixtures in any proportions, to create pressure in the Belashov hydrophysical cavitation heat heater, to power the working mixture in a reactive Belashov’s engine, for compressing air and gases, in energy, in mechanical engineering, in shipbuilding, in military equipment, in particular for cavitation-reactive torpedoes with separable warheads, in underwater vehicles, in industrial enterprises, in transport, and in mining , in utilities, etc.

A multi-stage centrifugal pump is known, including a housing, guide vanes, exhaust caps, sealing elements, a mechanical seal assembly and an unloading device (see patent of the Russian Federation No. 2136968, class F04D 1/6, 29/42, 29/62 - analogue).

Known liquid piston rotary vacuum pump containing a cylindrical housing with inlet and outlet nozzles, a rotor with hydrocameras for moving liquid pistons, a rotor drive and a device for supplying fluid to hydraulic chambers for moving liquid pistons (see the patent of the Russian Federation No. 20144501 , CL F04C 7/00, 19/00 - analogue).

Known rotary piston vacuum compressor containing a housing with a profiled inner surface of variable radius, a circular cylindrical rotor with retractable blades swinging on the axes. Inside the rotor there is a blade supercharger having a suction hole, and the outlet is made between the rolling axis and the blades and looks like an interscapular channel connected to the suction hole and is equipped with blades (see patent of the Russian Federation No. 2202714, class F04C 18/44, 23 / 00 - analogue).

A known rotary vacuum pump containing a collapsible housing made in the form of a housing base and a housing cover, which are fastened together by fasteners, a fluid injection system connected to the discharge chamber, a fluid removal system connected to the high pressure chamber and the rotor shaft associated with the drive, while on the rotor there is a piston continuously rotating inside the surface of the cylinder and a rotary locking device (see patent of the Russian Federation No. 2030638, class F04C 2/00, 2/24 - prototype).

The objective of the invention is the expansion of the functionality of a modular rotary piston vacuum pump, increasing the reliability of the sealing assembly of the rotor and the cylindrical piston, reducing the weight and maintenance of components, unification and manufacturability, simplifying the design and improving efficiency.

Figure 1 shows a General view of a rotary piston vacuum pump.

Figure 2 shows a rotary piston vacuum pump without a housing cover.

Figure 3 shows a section aa rotary-locking device of a rotary piston vacuum pump.

Figure 4 shows a section bB rotary piston vacuum pump.

Figure 5 shows the operation of the shut-off mechanism of the shutters of the rotary shut-off device of a universal rotary piston vacuum pump.

The essence of the technical solution lies in the fact that in a rotary piston vacuum pump, made in the form of a module, which contains a collapsible housing made in the form of a housing base and housing cover, which are fastened together by fastening elements, a fluid input system connected with a vacuum chamber, a fluid removal system connected to the high-pressure chamber and a rotor shaft connected to the drive, with a piston located on the rotor continuously rotating inside the cylinder surface and a rotary locking device the trinity, according to the invention, the housing base and the housing cover are made interacting with the rotor by means of sealing and oil scraper rings, a rotary locking device is placed inside the base, which is made in the form of dampers, in the channels of which there is a fluid distribution system with a shut-off mechanism made in the form of a valve and a rod located between the stiffnesses, while the limiter of movement and supporting platforms are installed on the rod, the fixing device of the rotary a pivot device, which is made in the form of a recess interacting with a retainer rod having a spring-loaded rod and an electromagnetic coil, the rotary mechanism is located in a rotary locking device, which is made in the form of a gear interacting with a gear of a shaft connected to a gearbox and an electric motor, where a locking device having an insert, through rolling or sliding elements, interacts with the base of the housing and the housing cover, and the upper working area of the shutter-and-gate valves the mechanism through channels is connected with the lower working area, and the shaft of the rotary mechanism through the transmission device or directly interacts with the rotor, and the electric motor contains a software and control device.

In addition, to facilitate the design of the rotor contains technological windows.

The rotary piston vacuum pump, figure 1, is made in the form of module 1. Each module contains a collapsible housing made in the form of the base of the housing 2 and the cover of the housing 3, which are interconnected by fasteners 4. At the base of the housing 2 there is a system fluid inlet 5 with a shut-off device 6, a fluid removal system 7 with a shut-off device 8 and a locking device 9. The actuator 10 is connected to at least one module of the rotary piston vacuum pump 1 through a removable shaft 11, which with the help of keyway of compound 12, Figure 2, interacts with the rotor 13. The rotor 13 is disposed on the piston 14 which is continuously rotated within the cylinder 15, located in the collapsible enclosure. The piston contains o-rings 16 and oil scraper rings 17. The housing cover 3 interacts with the rotor 13 by means of o-rings 18 and oil scraper rings 19. Inside the base of the housing 2 there is a rotary locking device 20, which is made in the form of a shutter 21 and a shutter 22. In the shutters a distribution system for the current medium 23 with a shut-off mechanism 24 and a shut-off mechanism 25 is located. The shutter 21 has an upper working area 26 and the shutter 22 has an upper working area 27. The rotary shut-off device 20 is intended but for the free movement of the piston 14 inside the cylinder 15, as well as for separating the rarefaction chamber at low pressure 28 from the high-pressure chamber 29. The shaft 30, figure 3, of the rotary locking device 20 interacts with the housing cover 3 through the rolling or sliding elements 31 and through the rolling or sliding elements 32 interacts with the base of the housing 2. The upper working area 26 of the shutter 21 through the channel 33 is connected with the lower working area 34. The upper working area 27 of the shutter 22 through the channel 35 is connected with the lower working area 36. Between the upper and lower work whose zone the liner 37 is located. The locking device 9 contains a recess 38 for the latch rod 39. The latch rod is provided with a spring 40 and a rod 41 that interacts with the electromagnetic coil 42. The rotary mechanism 43 is made in the form of a gear 44 interacting with a gear 45 located on the shaft 46, which is connected with the gearbox 47 and the electric motor 48. Moreover, the shaft of the rotary mechanism through the transmission device or directly interacts with the rotor 13, and the electric motor 48 may contain software and control device. The base of the housing 2 interacts with the rotor 13 using the sealing rings 49 and the oil scraper rings 50. With increasing pressure or discharge in the rotary piston vacuum pump, figure 4, in its design it is necessary to repeatedly increase the number of sealing rings 18 and 49, as well as the oil scraper rings 19 and 50, and to reduce the weight of the rotor 13, it is necessary to make windows 51. The rotation of the rotor 13 should be carried out clockwise 52.

Along the perimeter of the rotor 13 there is a mechanical seal system 53 for the shutter 21 and the shutter 22, which reliably separates the rarefaction chamber 28 from the high-pressure chamber 29. The shut-off-through mechanism 24 is made in the form of a valve 54 having a stem 55, which is located between the stiffness 56 and the stiffness 57. A motion stop 58 and a support pad 59 for the spring 60 are mounted on the stem 55. The shut-off mechanism 25 is in the form of a valve 61 having a stem 62 that is located between stiffness 63 and stiffness 57. A motion stop 64 is installed on the stem 62 the support platform 65 for the spring 66. The distribution system of the current medium 23 contains a channel 67 for the valve 54 and a channel 68 for the valve 61, through which the current medium 69 enters.

The rotary piston vacuum pump operates as follows.

The first stage of operation of the rotary piston vacuum pump occurs when the actuator 10 is turned on, when the removable shaft 11, the rotor 13 and the piston 14 begin to rotate clockwise 52, while the shutter 21 of the rotary locking device 20, which is fixed by the latch pin 39, overlaps the circle inside the cylinder 15. The current medium 69 from the fluid input system 5, through the shut-off-through device 6, the distribution system of the current medium 23, channel 67, valve 54, shut-off-through mechanism 24 enters the discharge chamber 28. Moving along the closed circuit to the cylinder 15, the rear base of the piston 14, captures the current medium 69, passes all the space inside the cylinder 15 and fills the vacuum chamber 28. After approaching the front base of the piston 14 to the working area 26, the electromagnetic coil 42 is actuated, the latch pin 39 is released and the rotary lock is turned devices 20. Then, using the gear 44, which interacts with the gear 45 located on the shaft 46, the gearbox 47 and the electric motor 48, of the rotary mechanism 43, the rotary-locking device is rotated CTBA 20.

The second stage of operation of the rotary piston vacuum pump begins when the shutter 22 of the rotary locking device 20 overlaps the circle inside the cylinder 15, is fixed by the latch pin 39, and the rotor 13 with the piston 14 will continue to rotate clockwise 52. Next, the current medium 69 from the input system fluid 5, through the shut-off device 6, the distribution system of the current medium 23, channel 68, valve 61, shut-off-through mechanism 24 will enter the discharge chamber 28. Moving along the cylinder 15, the rear base of the piston 14 will be gripping fill the current medium 69 and fill the vacuum chamber 28. At the same time, the front base of the piston 14 in the chamber 29 creates high pressure, which rests on the upper working area 27, the shutter 22. The upper working area 27 is connected through the channel 35 to the lower working area 36 and the system the outlet of the fluid 7 with the shut-off device 8. The high pressure of the current medium 68 created in the chamber 29, using the shut-off device 8 and the front base of the piston 14 should be evenly distributed between the upper working area 27 and the lower working th zone 36 to securely hold the latch pin 39.

The third stage of operation of the rotary piston vacuum pump occurs when the removable shaft 11, the rotor 13 and the piston 14 continue to rotate clockwise 52, while the shutter 21 of the rotary locking device 20, which is fixed by the latch pin 39, overlaps the circle inside the cylinder 15. The current medium 69 from the fluid input system 5, through the shut-off-through device 6, the distribution system of the current medium 23, channel 67, valve 54 of the shut-off-through mechanism 24 enters the discharge chamber 28. Moving around the circumference of the cylinder 15, the rear axle The piston 14 will capture the current medium 69 and fill the vacuum chamber 28. At the same time, the front base of the piston 14 in the chamber 29 creates high pressure, which rests on the upper working area 26, the shutter 21. The upper working area 26 is connected through the channel 33 to the lower working zone 34 and the system of fluid removal 7, with a shut-off device 8. The high pressure of the current medium 69 created in the chamber 29, using a shut-off device 8 and the front base of the piston 14 should be evenly distributed between the upper the working area 26 and the lower working area 34 to securely hold the retainer pin 39. After approaching the front base of the piston 14 to the working area 26, the electromagnetic coil 42 is actuated, the retainer rod 39 is released and the rotary locking device 20 is rotated. Next, use the gear 44 interacting with a gear 45 located on the shaft 46, the gearbox 47 and the electric motor 48, of the rotary mechanism 43, the rotary-locking device 20 is rotated. All other stages of the rotor-piston vacuum um-pump occur consecutively one after the other.

The rotary piston vacuum pump creates and freely maintains a vacuum (vacuum) in the inlet pipe, and in the outlet pipe high pressure of aggressive or non-aggressive liquids, oil products, gas, water, etc ..., in one stroke of the piston. All systems, parts, assemblies and mechanisms of each rotary piston vacuum pump module are identical and interchangeable, which facilitates the manufacturing and repair process, as well as reduces its cost.

With the invention of the rotary piston vacuum pump, which can simultaneously create a vacuum in the supply pipe (vacuum) and the discharge pipe in one cycle, the task of ensuring the smooth operation of the Belashov universal jet-rotary engine is very simple:

- simplified design,

- its mass decreases,

- the efficiency increases,

- the design is cheaper

- the list of components is reduced,

- the engine becomes easy to maintain and repair,

- simplifies the mode of preparation of the working mixture,

- constant high pressure is created,

- creates a constant vacuum (vacuum),

- injection of the working mixture and its ignition on the flywheel rotor can occur in a pulsed or continuous mode,

- in the engine there is no need to have an ignition system of the working mixture, since a simple filament can handle this, which can be switched on constantly.

A progressive technical solution, which is aimed at creating a rotary piston vacuum pump that can change the design of economical and environmentally friendly jet-rotary Belashov engines. Increase the efficiency of hydrophysical cavitation thermal heaters Belashova. To increase the maneuverability of underwater vehicles and cavitation-reactive torpedoes with separable warheads. To increase the productivity of gas and oil production from deep wells. Apply new technologies in high pressure and vacuum pumps in shipbuilding, mechanical engineering, mobile power modules, industrial enterprises, energy, transport, mining, underwater vehicles, utilities, etc.

Claims (2)

1. The rotary piston vacuum pump is made in the form of a module, which comprises a collapsible housing made in the form of a housing base and a housing cover, which are fastened together by fastening elements, a fluid injection system connected to the discharge chamber, and a fluid removal system connected to the high-pressure chamber and the rotor shaft associated with the drive, while on the rotor there is a piston continuously rotating inside the surface of the cylinder and a rotary locking device, characterized in that the base of the housing and The housing arm is made interacting with the rotor by means of sealing and oil scraper rings, a rotary locking device is located inside the base, which is made in the form of dampers, in the channels of which there is a fluid distribution system with a shut-off mechanism made in the form of a valve and a rod located between stiffnesses, while on the rod there is a movement limiter and supporting pads, at the base there is a locking device of a rotary locking device, which is made in the form of a recess The rotary mechanism is located in the rotary locking device, which is made in the form of a gear interacting with the gear of the shaft connected to the gearbox and the electric motor, where the rotary locking device having the liner, through the rolling or sliding elements interacts with the base of the housing and the housing cover, and the upper working area of the shutter-plate valves through channels is connected to the lower working area, moreover, the shaft of the rotary mechanism through the transmission device or directly interacts with the rotor, and the electric motor contains a software and control device. 2. The rotary piston vacuum pump according to claim 1, characterized in that to facilitate the design of the rotor contains technological windows.

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