EA021678B1 - Device for receiving mechanical work from nonthermal energy source - Google Patents

Abstract

The object of the invention is a device for receiving mechanical work from nonthermal energy source. The invention relates to machine building, in particular to designing engines in which an outer power supply is used for generating mechanical work and can be used for designing autonomous power units for providing power supply. The device comprises a body, a working mechanism comprising a working chamber with varying volume and a kinematical pair with possibility of reciprocal motion with respect to the body, systems for filling and evacuation of working medium from the working chamber, an executive mechanism and a de-compensation vacuum chamber with a vacuum pump wherein the working mechanism is placed. The working mechanism can be arranged as two opposing silphons, or as a cylinder-piston group of 2 opposing cylinders, movable end surfaces of which are rigidly attached to the rods and are connected into the kinematical pair in such a way that that form a unitary power pair with possibility of their synchronous reciprocal motion. The working mechanism of the claimed device can also be arranged as two membranes rigidly connected to each other with one rod in such a way that they like two silphons (or cylinders) form a unitary power pair. The claimed design of the device provides possibility of its work under the conditions of higher complexity of the environment and simultaneous saving energy for maintaining engine operation with maximum efficiency.

Description

The device relates to the field of mechanical engineering, in particular to the development of engines that use an external energy supply to generate mechanical work, and can be used to create engines, as well as combined autonomous power units to provide power, in particular, in high-altitude conditions and for space devices operating in outer space.

Atmospheric engines are known whose operating principle is based on the use of atmospheric pressure as an external source of non-thermal energy, which is converted into mechanical work.

For example, a device in which atmospheric pressure is used to obtain mechanical work, containing a classic cylinder-piston group of two pistons connected by a common rod that move reciprocally in stationary cylinders, while the reciprocating movement of the rod is transmitted to the main shaft by means of a ratchet mechanism (patent AB 2023746 A, P01B 29/02, 1980).

The disadvantage of this device is the design complexity, in which the transmission of mechanical work with a ratchet mechanism to the main shaft through a closed vacuum shell does not allow to obtain an acceptable efficiency (hereinafter - efficiency) for the practical use of this device.

A device is known in which atmospheric pressure is used to obtain mechanical work as an external energy source (patent IE 4131627 A1, P01B 29/02, 25.03.93).

Such a device consists of a fixed cylinder, in which a piston is connected with the crank by means of a connecting rod. The atmosphere is let in and pumped out through the channels in the closed end of the cylinder.

The disadvantage of this device is that, as shown by bench tests of a similar device, conducted by the authors of the proposed technical solution, with increasing frequency of the reciprocating movement of the piston above 3 Hz (180 rpm) in the open part of the cylinder, where the piston is in contact with air , the atmospheric pressure on the outer side of the end surface of the piston begins to fall, which leads to a sharp decrease in the efficiency of the device. This is due to turbulent processes occurring with the air in the well of the open part of the cylinder. Those. This device cannot be used to generate electrical energy by generators at a standard frequency with an efficiency that is acceptable for practical use.

Closest to the proposed one is a device in which atmospheric pressure is used as an external energy source to obtain mechanical work (in particular, moving the load relative to the supporting and underlying surfaces) (patent IA No. 89112, B65O 7/00, 2009, and also EAPO patent No. 013312, 2010).

Such a device consists of a support mounted on the underlying surface, a supporting platform with a supporting surface, a loading platform rigidly connected to the load being moved, a working chamber with a working medium made in the form of a bellows with an elastic side surface, which is rigidly connected with its upper base to the supporting surface , and the lower base - with a loading platform. The working chamber is connected to the pumping means via an exhaust valve, and to the fluid inlet system through an inlet valve. The device also provides a closed cycle of movement of the working environment. In this case, either the moving load or the crank mechanism with a rotating shaft can be rigidly connected to the lower base of the working chamber.

Although this device consumes additional external energy for pumping and inlet systems, it has significant advantages compared to analogs, as it is technologically and structurally simpler than similar devices, which compares it favorably with practical applications.

However, its disadvantage is that this device cannot work effectively in high altitude and in outer space due to reduced pressure or complete absence of atmosphere, as well as at high altitudes due to low atmospheric pressure, at which the efficiency of the device is significantly reduced.

The aim of the invention is to improve the known device for obtaining mechanical work, in which by modifying its design it is possible to operate in conditions of increased environmental complexity while reducing energy costs for maintaining the operation of the device with maximum efficiency. Due to which the productivity of the device as a whole increases and the scope of its application expands.

This goal is achieved in that the device for obtaining mechanical work from a source of non-thermal energy comprises a housing with a working mechanism located inside it, an inlet and vacuum pumping system for the working medium, and an actuator containing a movable working element and converting the non-thermal energy of the working medium into useful work.

The working mechanism of the device includes a working chamber with a variable volume, connected through inlet and outlet valves to the systems of inlet and vacuum pumping of the working medium, a part of the surface of which is made movable with the possibility of its reciprocating movement under

- 1 021678 by the action of pressure of the working medium and is rigidly connected with the rod kinematically connected to the movable working element of the actuator of the device.

The claimed device is characterized in that it additionally contains a vacuum decompensation chamber (hereinafter - VCD) with a vacuum pump, and its working mechanism contains an additional similar working chamber with a variable volume, coaxial with the first working chamber.

In this case, the moving surface parts of both working chambers are opposite located inside the VCD, and their moving end surfaces are rigidly interconnected by a single rod with the possibility of simultaneous synchronous reciprocating motion with constant force on the rod.

The working end face of the rod is hermetically removed outside the housing of the VKD and is attached to the movable working element of the actuator of the device.

The moving parts of the surface of each working chamber can be made in the form of a bellows with a closed working end, which is hermetically attached to the fixed part of the surface of the working chamber; or in the form of a hollow cylinder with a closed working end, which is hermetically attached to the fixed part of the surface of the working chamber with the possibility of sliding reciprocating motion relative to it; or in the form of a flexible membrane, which is hermetically attached to the fixed part of the working chamber.

As the actuator of the claimed device, a linear electric current generator or a crank mechanism can be used, the crankshaft torque of which is subsequently converted into electrical energy or mechanical work.

Thus, the basic principle underlying the functioning of the claimed device is the creation of a force gradient due to the pressure difference in the working mechanism of the device, in this case, an artificially created vacuum medium inside the VCP, which makes it possible to use atmospheric pressure to generate mechanical work with subsequent transformation into electrical energy or useful work.

Opposed working chambers with variable volume, made in several alternative technical solutions described above, operate in the inventive device on the same physical principle, namely, the moving parts of the surface of both working chambers are always in a vacuum, which is constantly maintained inside the VCD:

a) in case of work in the atmosphere or other medium - by a vacuum pump;

b) in the case of work in outer space - natural permanent pumping through open openings of the VCD;

the movable ends of the chambers carry out reciprocating movements under the influence of atmospheric pressure due to the pressure difference in the VCD and in the working chamber.

The inventive device contains a fundamentally different, for example, internal combustion engine (ICE), operating mechanism of the working mechanism, which can produce useful work only if there are two opposed working chambers that make up the power pair connected by a rod.

The power pair of two chambers is a single unit in which the moving parts of the chamber surface located in the vacuum chamber in vacuum have the ability to move freely under the influence of environmental pressure, in this case, the atmosphere, which is cyclically poured into the working chamber, and the pressure on the outer surface its rolling end is compensated due to the constant pumping of the VCD.

The movable end surface of the working chamber does not experience the compensating pressure of the external environment — the atmosphere — on the outside, and when the atmosphere is inlet (which occurs naturally by opening the inlet valve), the working chamber makes a working stroke, increasing to the maximum size. In this case, the opposed working chamber at this time is in the pumping stage and does not resist the movement of the moving end surface of the first working chamber, decreasing to a minimum size under the action of the rod, i.e. For her, the idle cycle passes.

Thus, the energy costs of producing a working stroke by the device will be necessary only for the operation of vacuum pumps to pump out the working chambers during their idle and maintain the necessary vacuum in the VCD when working in the atmosphere or other environments.

The energy costs of vacuum pumping the working chambers can be significantly reduced through the use of a receiver of the required volume, which is calculated for a given given usable power of the device.

In accordance with the Boyle-Mariotte law, the ratio of the product of pressure наι by the volume VI of the working chamber to the product of pressure P ₂ by the volume ν _{2 of the} receiver at a constant temperature will be

Ρ, ν, = Ρ ₂ ν ₂ [1], respectively

- 2 021678

Whence, in order to maintain the pressure in the receiver about 100 times less than in the working chamber with the exhaust valve open with minimal energy for pumping, it is necessary to have a volume of U ₂ 100 times that of U ₁ . In this case, the pumping speed of the vacuum pump should be greater than the rate of inlet of the working medium - the atmosphere or gaseous medium from the working chamber into the receiver.

Thus, an increased energy consumption of the device is necessary only during the start-up period for preliminary pumping of the working mechanism, receiver and VKD by the vacuum system. When the device enters the operating mode, the energy consumption of the pumping system is significantly reduced, because the pumping system in this case only works to maintain a given pressure difference in the working chamber and the receiver.

The inventive device can operate in a closed loop, i.e. without inflowing and evacuating the atmosphere, while the working fluid discharged into the working chambers of the opposed pair, for example inert gas, is pumped and pumped by the pumping system in a closed loop using a preliminary rarefaction receiver, as shown above.

In this case, the total energy consumption of the pumping system may increase, however, in this case, the efficiency of the claimed device will not depend on the height above sea level, which is a significant advantage. At the same time, the working mechanism of the device does not release the spent working environment into the environment, i.e. The device is environmentally friendly.

The presence of vacuum in the VCD eliminates the resistance of the external environment to the moving parts of the working mechanism, which makes it possible to use working chambers with end surfaces of large diameter and any shape — flat, concave or convex and to choose the optimal shapes to obtain the maximum usable power output.

To ensure long-term operation of the inventive device in outer space, it is very essential to minimize the presence of rubbing pairs in it. To this end, in the inventive design of the device, a form of execution of the movable end surfaces of the working chambers in the form of at least two membranes of elastic material, for example, rubber made on the basis of nanotechnology, is proposed. It is in such conditions of use of the claimed device that the use of membranes as an alternative embodiment of the moving parts of the surface of the working chambers, in contrast to their execution as a hollow cylinder with a closed working end, is preferred because it greatly simplifies the design and reduces the weight of the device.

In addition, such an alternative solution has the ability to arrange several additional membranes sequentially mounted on the rod in opposite pairs in parallel from one and the other side of the VCD, which will significantly increase the power of the power pair without changing the radial dimensions of the device. The working chambers formed in this way are filled and pumped out synchronously through a single system of pumping and inlet valves, so the forces of the membranes acting synchronously on the rod are summed accordingly.

In outer space, the energy consumption for maintaining the operation of the device with maximum efficiency will be minimal relative to the given useful power, because pumping VKD in this case does not require energy costs.

The inventive device can operate in an aqueous medium, while for pumping the external environment of the liquid should be used vacuum liquid ring pumps or other means of pumping liquids, depending on the purpose of use of the device.

As follows from the above, the claimed alternative structural solutions of the moving parts of the surface of the chambers with a variable volume of the working mechanism of the device do not violate the principle of unity of the invention. Because in any of the claimed alternative solutions, the working chambers perform the same function, operate in the inventive device on the same physical principle, in which the movable ends of the chambers, regardless of the form of their execution, perform reciprocating movements under the influence of atmospheric pressure due to the pressure difference in the VCD and in the working the camera.

And in combination with the other structural elements of the device, they equally contribute to the achievement of the same technical result when using the device - obtaining mechanical work from an external source of non-thermal energy.

Alternative embodiments of the moving parts of the surface of the working chambers are caused solely by special conditions in which the claimed device can be used, as well as the manufacturing technology and the required resource of the device as a power plant. That will allow flexible use depending on the destination.

So, the design of the claimed device with the implementation of the moving parts of the surface of its working chambers in the form of bellows can be used economically to generate electric current of small and medium capacities for non-industrial purposes - to power residential buildings, household appliances, etc.

- 3 021678

The design of the claimed device with the implementation of the moving parts of the surface of its working chambers in the form of hollow cylinders can be used for industrial generators with a design generated power of 50 kW to 2-10 MW.

The design of the claimed device with the implementation of the moving parts of the surface of its working chambers in the form of flexible membranes can be used in small-sized mobile generators for various purposes, including in special conditions of space or water space, as noted above.

In general, in the inventive device, it is fundamental that, as mentioned above, it is the artificially created vacuum medium in the VCD that creates a change in the equilibrium of the forces of two media acting on the moving end surfaces of the working chambers - the atmosphere and vacuum. Those. the external environment, in this case atmospheric pressure, when the atmosphere is poured into the working chamber is a source of force that drives the device.

Thus, in this case, the diametrically opposite, in contrast to the internal combustion engine operation principle, physical principle of closed pneumatic and hydraulic systems, in which a working medium with increased pressure reaching up to 10 ⁷ Pa, is a source of force controlling the working and actuating mechanisms of the device, is used.

The inventive device operates in a single-cycle mode, in which each stroke of the power pair is a worker with a constant uniform force on the rod. Those. any movement of the power pair back and forth is a working stroke, in contrast to the classic two and four-stroke cycles of internal combustion engines, in which the pistons move in the opposed pair towards each other.

This allows you to effectively use linear generators in the inventive device as converters of mechanical energy into electrical energy, which, in turn, if the device is required to be operated under non-standard conditions, eliminates the crank actuator as a link in the kinematic chain of the device and, as a result, simplifies the kinematics devices and increase the power output with the same given parameters.

Thus, the totality of the claimed features of the invention is necessary and sufficient to achieve the goal.

A diagram of the claimed device is presented in the drawings, where the moving parts of the surface of both working chambers are made:

FIG. 1 - in the form of a bellows with a closed working end, hermetically connected to the fixed part of the surface of the working chamber;

FIG. 2 - in the form of a hollow cylinder with a closed working end, hermetically connected to the fixed part of the surface of the working chamber, with the possibility of sliding reciprocal-gradual movement relative to it;

FIG. 3 - in the form of a flexible membrane, hermetically connected to the fixed part of the surface of the working chamber.

The claimed device (see Fig. 1, or 2, or 3) contains left 1 and right 1a working chambers with variable volume with movable working ends 2 and 2a, respectively, which are rigidly interconnected by a single rod 3, the working end 4 of which is hermetically withdrawn beyond the enclosure of the VCD 5 and is kinematically connected to a movable element of the actuator (not shown in the diagrams), which turns non-thermal energy of the working medium into useful work.

The moving parts of the surface of both working chambers are oppositely located inside the VKD 5, in which the vacuum pump 6 is also located.

The system of inlet and vacuum pumping of the working medium contains the inlet 7 and outlet 8 valves of the left working chamber and the corresponding valves 7a and 8a of the right working chamber, the receiver 9 and the vacuum pump 10.

In this case, the inlet and outlet valves are made in the fixed parts of the working chambers located outside the VDK 5 (the contour of the VDK 5 is conventionally marked by a thickened line in all the circuits).

The working chambers 1 and 1a are connected to various atmospheric inlet systems through valves 7 and 7a and to one pumping system through valves 8 and 8a, receiver 9 and vacuum pump 10.

All drawings show an open circuit of the circulation of the working medium for each vacuum working chamber, ensuring the operation of the power pair of the device in an open circuit - with direct inlet of the working medium (atmosphere) through valves 7 and 7a into the working chamber and pumping the working medium into the environment through valves 8 and 8a into the receiver 9 and the vacuum pump 10.

The device operates as follows.

In the initial position, the receiver 9 and the vacuum decompensation chamber 5 are pumped out to a pressure of P ₀ = 10 ² Pa and are constantly pumped out by vacuum pumps 10 and 6.

At the beginning of the cycle, the evacuation valve 8 and the inlet valve 7a open, and the inlet valves 7 and the evacuation valve 8a are closed.

In this case, the movable ends of both working chambers synchronously move towards the compression of the working volume of the left chamber 1 under the action of atmospheric pressure on the inner movable end surface of the right working chamber 1a, which begins to fill with the atmosphere through the filter

- 4 021678 open valve 7A, performing a stroke. The left working chamber 1 is in the evacuated state through the open valve 8.

After that, the evacuation valve 8 and the inlet valve 7a are closed, and the evacuation valves 8a and inlet 7 are opened. In this case, the movable ends of both working chambers synchronously move in the direction of compression of the working volume of the right chamber 1a under the action of atmospheric pressure on the end surface of the left working chamber 1, which is filled with atmosphere through the valve filter 7.

Those. the movable end of the left chamber 1 carries out a working stroke, and the working chamber 1a is compressed without resistance, because it is pumped out to a pressure equal to the pressure in the vacuum decompensation chamber 5. In this case, the force of the movable end of the left chamber 1 through the rod 3 is transmitted to the movable working element of the actuator of the device, which is kinematically connected to the working end 4 of the rod 3 and which converts the non-thermal energy of the working medium into useful work.

After that, the evacuation valves 8 and inlet 7a are opened again, and the evacuation valves 8a and inlet 7 are closed, and the cycle repeats. Those. Now the right chamber carries out a working stroke while moving the movable ends of both chambers in the opposite direction of compression of the working volume of the left chamber.

Thus, a single-cycle cycle is carried out in which each stroke of a power pair of two chambers is a working one.

In FIG. 1 and 2 show the moment of operation of the device when a power pair of two chambers is in the middle of the stroke of the stroke, that is, when the right and left working chambers have the same volume.

In FIG. Figure 3 shows the moment of operation of the device when the power pair is at the end of the stroke of the working stroke of the left working chamber, that is, when the left 1 and right 1a working chambers at this point have maximum and minimum volumes, respectively.

Thus, the opposed movable end parts of the surface of both working chambers, forming a coherent design, synchronously move to one side during the cycle, providing a continuous in time working stroke with constant force on the rod in one direction and continuing the working stroke with constant force in the other direction, that is, on a single cycle cycle.

To enable cyclic, periodically returning to the initial position of the movement of the moving ends of the working chambers under the influence of atmospheric pressure P _at , or the pressure of another external environment in which the power pair is located, it is necessary to ensure consistent rapid pumping to a pressure of P ₀ <10 ^-1 -10 ^{- 2} P _at and inlet of the working medium to a pressure of P1 = P _at into the working chambers of the power pair.

This is achieved due to the fact that the working chambers of the power pair are connected to the systems of inlet and pumping of the working medium through the inlet and outlet valves located at their fixed ends.

In turn, providing the ability to quickly change the pressure in the working chamber allows you to get a continuous cyclic process of moving the moving ends of the power pair, which performs the work on a single-cycle vacuum-atmospheric cycle. In this case, the force acting on the moving ends is constant in magnitude over the entire length of the working stroke and is determined only by the area of the moving end surface of the chamber and the difference in external and internal pressure in the chambers.

To reduce energy losses and losses of the working environment, as well as to ensure the possibility of the device in outer space, the pumping system can be connected to the inlet system, thereby providing a closed cycle of movement of the working medium. At the same time, a gas with optimal parameters (for example, hydrogen, helium, argon, etc.) is chosen as the working medium for efficient pumping of the working chambers with the selected types of pumps.

The presence of a power pair of two opposed working chambers, which are rigidly fastened by a single rod, allows for a constant force in time during the cycle, which ensures smooth operation of the device nodes without jerking and vibration.

The balance of the pumping and inlet systems consumed and the useful power delivered to the power pair by the rod is determined by the speeds of the pumping systems of the working chamber and the systems of filling the working medium into the chamber, as well as the number of cycles per unit time.

In the case of the alternative implementation of the moving parts of the surface of both working chambers in the form of flexible membranes, the fastening of the membrane to the fixed part of the surface of the working chamber can be vacuum tight rigidly fixed or sliding and is determined by the structural feasibility of using the inventive device.

The possibility of vacuum tight sliding along the walls of the VCP allows you to increase the usable volume of the working chamber to the specified design dimensions and, accordingly, the power output for other specified device parameters.

As mentioned above, the claimed device can operate in a closed cycle, i.e. without letting in and pumping out the atmosphere.

When working on a closed loop of the working medium, a power pair can perform increased work relative to the base cycle, for example, double during one cycle.

This can happen if the vacuum pump, when pumping out the first working chamber, provides at the outlet in the intermediate receiver a pressure P _{1 of the} working medium, which

- 5 021678 inlet into the opposed working chamber will, for example, double the atmospheric pressure of the external atmosphere P _at . In this case, the pressure Po in the first chamber at idle should be provided by means of pumping at the level of P ₀ <10 ^-1 -10 ^{-2 -2} P _at , which is constantly maintained in the decompensation chamber. In this case, each working chamber has a continuous working stroke with a double force on the rod.

In this case, the work of the power pair A <. _n , which it can produce if P _sun = P _at = P1 will be equal to

And _cn = 2k P _at ϋ ² b [1], where k = n / 4 = 0.785;

And - the effective diameter of the surface of the moving end of the chamber, m;

B - the length of the working stroke of the moving end of the camera, m

In the case when P ₁ = 2P _BC at P ₀ = <10 ^-2 -10 ^-4 P _sun , the power pair performs work equal to

Example.

The working chamber in any of the declared alternative designs has a cylindrical shape, therefore its maximum volume V [m ³ ] will be equal to

where And is the effective diameter of the cross section of the camera, m;

B is the length of the working chamber, which is equal to the distance between the upper and lower points of the stroke of its movable end, m.

If the chamber is in vacuum, then the force P of atmospheric pressure P _at [Pa] on the end effective surface area of 8 [m ² ] will be equal to

P = P _at 8 [4], or

P = kP _at O ² [5].

If the working chamber is filled with atmospheric air to a pressure of P _at , then the work A [J] produced by it under the action of atmospheric pressure will be equal to

A = kP _et O ² b [6].

If the volume of the working chamber is 1 l, then at normal atmospheric pressure P _at = 101325 Pa, its moving end face in one cycle without taking into account possible losses can produce work A = 101 J.

Accordingly, a power pair in one cycle can produce work A _{with ||} = 202 J.

The cyclic change in pressure in the working chamber from P _at = 1.01 10 ⁵ Pa to 1.01 10 ³ -1.01 10 ² Pa provides the possibility of reciprocating movement of the moving ends of the power pair relative to the device’s body due to an external energy source - atmospheric pressure , i.e. to produce constant work in time, regardless of the time of day or weather conditions.

The use of this device to obtain mechanical work from an external energy source will create economical vacuum-atmospheric energy modules with increased efficiency and powerful engines with low fuel consumption, which will give significant fuel savings for combined autonomous gasoline and diesel power plants with the same power output.

A closed loop of the movement of the working medium in the inventive device eliminates emissions into the atmosphere, which ensures environmentally friendly operation of the device in the atmosphere and the ability to work in high altitude or open space.

Claims (3)

CLAIM 1. A device for obtaining mechanical work from a source of non-thermal energy, comprising a housing with an operating mechanism located inside it, a system of inlet and vacuum pumping of the working medium and an actuator containing a movable working element and converting the non-thermal energy of the working medium into useful work, while the working mechanism includes a working chamber with variable volume, connected through inlet and exhaust valves with inlet and vacuum pumping systems of the working medium, part of the surface of which is made movable with the possibility of its reciprocating movement under the action of pressure of the working medium and rigidly connected to the rod, kinematically connected to the movable working element of the actuating mechanism, characterized in that the device further comprises a vacuum decompensation chamber with a vacuum pump, and its operating mechanism contains an additional similar operating the chamber with variable volume coaxially with the first working chamber, while the surfaces of the moving parts of both working chambers are located opposite Uspekhi Mat chamber decompensation, and their movable end surfaces are fixedly connected by a single rod, with a simultaneous synchronous reciprocating motion with a constant force on the piston rod, the working end is sealingly withdrawn outside the vacuum chamber housing decompensation and is attached to the movable operating member of the actuator mechanism. - 6 021678 2. The device according to claim 1, characterized in that the moving parts of the surface of each working chamber are made in the form of a bellows with a closed working end, which is hermetically attached to the fixed part of the surface of the working chamber, or in the form of a hollow cylinder with a closed working end, which is hermetically attached to a fixed part of the surface of the working chamber with the possibility of a sliding reciprocating motion relative to it, or in the form of a flexible membrane that is hermetically attached to the fixed part of the working chamber. 3. The device according to PP.1, 2, characterized in that the actuator used a linear electric current generator or crank mechanism, the torque of the crankshaft of which is converted into electrical energy or mechanical work.