DE3222226A1 - Thermodynamic converter - Google Patents

Abstract

The TDC can be constructed as a dynamic power station in the one watt to megawatt range. It operates with an efficiency of up to 100 percent. It is also capable in one function of using sources of relatively low thermal energy it converts directly into dynamic energy on the axis of the gas turbine: solar heat, atmospheric heat, water heat, ground heat, industrial waste heat, heat of oxidisation, heat from nuclear fission and nuclear fusion, and domestic waste heat. The TDC can be non-positively connected to a generator for producing current and to mechanical-pneumatic-hydraulic power transmission systems. Thus, as long as it is fed with heat, the TDC is a self-sufficient conversion unit which converts heat into mechanical energy and will compete with the conventional prime movers of all sorts and classes and one day replace them. The theoretical basis of the invention is the application of the observations of a natural world on which the so-called kinetic theory of gases and heat is based.

Description

DESCRIPTION

TITLE THERMODYNAMIC CONVERTER Type of registration subject Information on the genus The invention relates to a thermodynamic converter according to the preamble of claim 1.

The thermodynamic converter belongs to the genus of power plants that convert heat energy into dynamic energy and its forms of conversion.

Stand of Teobnik The conventional thermal power plants convert only one relatively small part of the generated heat amount into dynamic energy. The highest , currently achievable efficiencies of such thermal power plants are oa.

45%.

The primary energy is therefore with oa. 55% as heat to the environment submitted.

Criticism of the state of the art In thermal power plants more conventional Origin is the efficiency - as described in the prior art - unsatisfactory.

The waste heat from the aforementioned power plants is a considerable burden on the environment represent.

The high percentage of the currently nooh non-convertible amounts of thermal energy Essentially, the noble energy electricity is the most expensive at the moment Energiefora is.

The air pollution from exhaust gases is considerable.

Due to the inadequate utilization of the energy sources, the re # ourcen of our fossil and atomic fuels prematurely exhausted0 The environmental heat can cannot yet be converted directly into Dgnamik.

The task at hand is therefore to heat rationally, as perfectly as possible and environmentally friendly, as required to convert into dynamic energy.

L ö 5 u n g s According to the invention, this problem is met by the generic ones Devices by means of the features of claim 1 characterizing the invention. solved.

ACHIEVABLE BENEFITS s The wealth of societies is proportional addicted on the amount of energy available.

The thermodynamic converter, as it siob from the patent earring represents, practically converts the existing heat, insofar as this is via a primary energy source can be fed to the thermodynamic converter.

This can be in detail s solar heat, air heat, water heat , Soil heat, waste heat from industry, heat from oxidation, heat generated by nuclear fission and from nuclear fusion, household waste heat.

The thermodynamic converter is not suitable only in a force-fit coupling to be used with a generator as a power generator Mechanical and pneumatic-related hydraulic power transmission systems are also conclusive be accepted.

The energy supply can be decentralized The thermodynamic Converter can be designed as a drive unit, as an alternative to the conventional ones Combustion engines The thermodynamic converter can also be used in space technology Find application.

Economic aspects The invention makes all products cheaper , for the production of which ENERGY is necessary. Obtain cheaper products new markets.

New markets increase the gross national product.

Since fewer energy sources have to be imported, it improves the foreign trade balance. The application of the invention leads directly to independence compared to the suppliers of conventional energy sources.

Ecological aspects:: The ecological burden on the environment in industrialized countries durob conventional power plants is substantial.

After the introduction and application of the invention, one finds a whole Considerable relief for the environment takes place .: First, thanks to the almost complete utilization fossil fuels, second, through the revival of the waste heat problem t third , duroh decentralization of the power plants, with the line systems for electrical Energy can be dispensed with.

In warm and hot countries there is the possibility of using the invention with appropriate dimensioning to change the climate locally. This is possible by turning the thermodynamic converter into dynamic air heat Converted energy and its forms of transformation.

This conversion process results in a lower ambient temperature. In this reduced ambient temperature, new habitats for plants, Animals and humans are created The Tbermodynamisobe converter can be used for large-scale Seawater desalination can be used That with seawater desalination The fresh water obtained can be used to irrigate the cooled rooms. The invention enables the transformation of previously hostile spaces in living-friendly spaces. Cultural aspects Culture arises in societies , in which the primary needs of the people, which the cultural achievement are able to produce, deoed are Durob the invention can the proportion of human Labor in production can be reduced.

This brings a lot of free time. That leads to more free time to greater creative activity.

Increased creative activity leads to a cultural upswing in companies Aspects The invention enables a decentralized energy supply. It requires no special location. The power plants can be mounted in mobile versions will. The power plants can be built as Sobiff engines with great benefit , inde # seawater heat is converted into dynamics. Theobnological breakthrough: The invention heralds a technological breakthrough. By means of the invention previous work and production processes can use significantly less energy carried out than before.

Example: Distillation of water (seawater desalination) The energy v which is necessary to heat a certain amount of water to the boiling point , as well as the energy that is necessary to produce this particular amount of water in vapor form to transfer is equivalent to the condensation and subsequent cooling released amount of energy Political aspect The invention makes it possible to convert this amount of energy back into dynamic force. This dynamic Power can be converted into electrical energy, which further heats up and causes evaporation of water. So here circular processes develop more circulating Energies off.

These circuits, which can be constructed with the invention, cause im In contrast to the previous systems, a radical reduction in the need for primary energies, The independence from the supplier of foa sil energy carriers inevitably leads to a relaxation of the world energy economy. The danger of a warlike conflict such resources will be eliminated in the long term. Durob the finding will be the Third world, which is mostly in the warm to hot zone, favors.

With the KNOW HOW and the export of these devices on the one hand, and durob the import of agricultural products, their production only through the invention is possible, these deliveries and services can be paid for The third party The world would no longer be a one-sided recipient of services, but would be able to compensate.

This would enable the countries of the third world to develop independently carry out.

Further embodiment of the invention in a supplementary description of the four individually identified patent claims of the preamble to 1.

THE THREE - K - GEFBESS, its design and arrangement in the system of the Tbermodynamisoben converter Fig.l + 2 box "h" This vessel, which is designed as an example in Fig. 2, composed of a pressure-resistant jacket, which wraps around the inner capillary system.

The three-component vessel has a larger flow cross-section than that Sum of the flow cross-sections of the G e 5 a m t capillary system.

The inner capillary system, its design and arrangement in the Thermodynamic converter system.

Fig. 1 + 2 box "o The inner capillary system consists of one, each Depending on the design of the device, a certain number of capillary tubes These capillary tubes consist of materials of high thermal conductivity and adequate mechanical Strength These capillary tubes can be forked.

The outer 5 e capillary system its design and arrangement in the Thermodynamic converter system.

Fig. 1 + 2 box "d The outer capillary system forms the Continuation of the inner capillary system, which emerged from the DREI-K vessel in Form of the outer capillary system emerges. The external carpillary system opens into the gas inlet opening of a gas turbine.

The heat is transferred to the outer capillary system by a liquid or gaseous heat medium Das accordingly. Heat medium can in closed pipe systems in such a way as to circulate the heat from the The heat source is transferred to the outer capillary system by the flow of the medium will.

The condensate collection container, its design and arrangement in the system of the thermodynamic converter. Fig 1 + 2 box "b", the condensate collecting container forms the continuation of the DREI-K system. It is used to collect the in DREI - K-vessel boobverdiobteten, resp. liquefied working medium The condensate collecting container can be separated from the DRsI-K vessel by means of a valve. Fig. 2 Box "k" of the condensate collecting container can by means of one or more valves be separated from the entrance of the inner capillary system. Fig. 2 Kasteni In this The working medium can be deposited in the container when the device is idle.

Furthermore, the container can be filled with the working medium through a valve and are emptied Fig.2 box "m" an integral part of the condensate collection container can be a pump Fig. 1 + 2 box "a". This pump connects the condensate collector with the inner capillary system.

Description of the operation of the thermodynamic converter, F u n k t i o n 5 a b 1 a u f and A g g r e g a t z u S t 8 e nd e of the working medium.

The invention is based on the idea of VIBRATION LINK (see also on this "Disclosure of the functional mechanisms") We use this to designate the link different levels of oscillation. The theoretical basis for this is what is known as the "Kinetic Gas and Heat Theory".

The functional description of the invention in connection with the figures 1 and 2 Box n b ″ denote the condensate collecting tank, which is designed here as a device foot who condensed it, respectively.

Contains liquefied working medium.

Fig. 2 Box "m" denotes the inlet valve through which the Working medium in the condensate collecting container Fig. 1 + 2 box "b" for the first time the thermodynamic Converter is fed.

Fig. 1 + 2 box "a" indicates the conventional feed pump Design type. Fig. 1 + 2 circle "1" marks the beginning of the inner capillary system , in which the working medium introduced by the pump Fig. 1 + 2 box "a" will . The beginning of the inner capillary system cools what is housed in the base of the device Condensate collecting container with the working medium located in it by receiving it the heat of vaporization.

Fig. 2 box "i" identifies the cut-off valve, which when Starting process, respectively. closed while the working medium is being fed into the device remain. This stripping valve opens when the thermodynamic converter has settled is. (This term is further defined by the "Disclosure of Functional Acceptances "m) Fig. 1 + 2 circle" 1 "identifies the inlet of the inner capillary system durob which the working medium is introduced.

Fig. 1 + 2 box "o" indicates the further course of the inner Capillary system in which the working medium evaporates and the so-called Absorbs evaporation heat. In doing so, it cools itself as well as its immediate Working environment from Fig. 1 + 2 box "o" indicates the inner capillary system, in which a further expansion of the working medium takes place Fig. 1 + 2 circle "2 n denotes the passage of the inner capillary system through the container wall of the THREE - K - vessel and its continuation in the outer capillary system Fig. 1 + 2 Box "d" indicates the outer capillary system to which the Heat passes over Fig. 1 + 2 Box "e" indicates the moving warm primary energy carrier , which in contact with the outer capillary system transfers its heat to it and thereby abküblt itself Fig. 1 + 2 @ @@ Circle "3" indicates the heat input induced dynamics of the working medium Fig. 1 + 2 circle "3" marks the end of the outer capillary system. The capillary tubes arriving at the beer are bundled here instead of. And in such a way that the bundling of the working relationships is optimal the subsequent gas turbine is adapted.

Fig. 1 + 2 box "g" indicates a conventional gas turbine Fig. 1 + 2 circle "4 n" indicates that entering the DREI-K-vessel from the turbine Working medium.

Fig. 1 + 2 box "b" indicates the DREI - K - vessel. Expanded here the flow cross section of the working medium emerging from the turbine. As a result, the flow rate of the working medium decreases and the Druok of the working medium too. The increase in pressure leads to a higher temperature of the gas. As shown in Fig. 1 circle "II", give this heat to the inner capillary system over. The removal of heat axJf the inner capillary system asked that the density of the working medium in the DREI-K-vessel constantly increasing Fig. 1 + 2 edges "h" denotes in the lower area of the THREE-K vessel the act of condensation. This is the so-called heat of vaporization free, which is equal in amount to the previously absorbed heat of vaporization . This heat of vaporization is transferred to the capillary walls of the lower inner capillary system over and thereby causes the attenuation of the in this capillary area Working medium.

Fig. 1 + 2 circle n 5 "indicates the path on which the reliquefied Working medium flows back into the condensate collecting tank Fig. 1 + 2 circle " 1 "marks the beginning of the inner capillary system in which the working medium is introduced by the pump, Fig. 1 + 2 box "a" This is the functional sequence of the thermodynamic converter described O f e n 1 e g u n g der F u n k t i o n s 1 e o h a n i o in e n Concept of oscillation (linear oscillation) The Invention is based on the knowledge that every process in the material and understood in the non-material realm as a vibration or as a vibration component can be.

The concept of vibration is defined as follows t Any vibration lets consider siob in two basic components.

Basic component A: The d y n a m i s o h e component basic component B s The p o t en t i e 1 1 e component The dynamic component of an oscillation corresponds to the inertia of moving mass. (Kinetic Energy) The potential component of a vibration equals the imbalance of two Potentials The equalization of these potentials always causes the acceleration of mass. This effect becomes when external forces inhibit the moving mass act, the cause of a new strength potential.

These regularities apply to a 1 1 e forms of linear oscillations . If the oscillation components change in a periodic sequence, then we speak of a linear, periodic oscillation. Is the oscillation process randomly so we speak of regular vibrations.

Whenever there is a potential and dynamic vibration component we speak of one linear oscillation Another form of oscillation is the term circular oscillation of oscillation (circular oscillation) A circular oscillation is always characterized by this that the dynamic oscillation component and the potential oscillation component coexist with one oscillation.

The kinetic energy of the mass moving in a circle arises dor dynamic oscillation component.

The amount of the centripetal force corresponds to the lateral acceleration from cash, is therefore the cause of the circular character of the circular oscillation.

The vector of the force that causes the steady transverse acceleration , always acts at an angle of 90 degrees to the vector of the direction of movement.

The lateral acceleration, which is the cause of the circle character the oscillation, corresponds to the potential oscillation component of potential and dynamic vibration component are mutually dependent and are therefore directly linked in their energy amounts.

A circular oscillation forms a dynamic potential, which in relative calm to its initial system, no external forces are active the vibrating system, the amounts of dynamic and potential change Vibration component not However, accelerating respectively. When the forces slow down, the potential and dynamic vibration components change in a fixed relationship to one another concept of oscillation (Elyptic oscillation ) The Blyptisobe oscillation is a mixed form of the previously described types of oscillation , namely the linear oscillation and the circular oscillation.

This peculiarity results from the rise and fall of the energy content it the potential and the dynamic vibration component.

The vector of obedience to movement of those accelerated in the elliptisobic orbit Checkout does not change its direction, however, concept of the vibrational connection We differentiate between different levels of oscillation t The macrocosmic level of oscillation (Generic term) vibrations in the planetary arena (subordinate term) vibrations in the mechanical area (sub-term) The microcosmic vibration level (generic term ) Vibrations in the molecular - atomic range: (sub-term) heat vibrations Vibrations on the atomic level itself s (sub-term) Strablungs emission Die The naming of the vibration levels is only an example. Vibrations can be of from one vibration level to the other. This transition into another The oscillation level always happens in such a way that a dynamically initiated potential lies on another level of oscillation and in a balance dynamic energy on this other level of oscillation induces the linkage of the levels of oscillation usually happens in such a way that the vibrations of a higher one pass a lower level of vibration Examples of vibrational links The circular oscillation of the biondes around the becoming causes ebb and flow.

The dynamisobic oscillation component of the circular oscillation of the moon reduced by the amount of oscillation induced on the mechanical level , the tides. So here are planetary and mechanical planes of vibration with each other connected.

The friction brake converts kinetic energy into heat. this happens by having the kinetisobic energy at the meobanisobic level potentially affecting the atomic - molecular level of vibration. There these potentials induce the so-called heat oscillation The frequency of the oscillation decreases from the macrocosmisobe towards the microcosmisobic oscillation level. The increase in frequency behaves in reverse proportional to the oscillating mass. The energetic creature in this way from One level of oscillation passes over to the other level of oscillation, always arises exactly the amount of energy by which the vibration on the other vibration level The invention is the logical application of the principles described here the linkage of vibrations.

Functional Mechanisms of the Invention The working cycle of the working medium is explained here in chronological order.

The gas enters the capillary system at a high density Fig. 1 + 2 circle "1 Since its boiling point is considerably below the temperature of the capillary system is located, the gas evaporates while absorbing the heat of evaporation.

Fig. 1 + 2 box "o The vaporized gas had a very high diobte The gas takes on the temperature of the capillary tube Fig. 1 circle "II Through this it forms a gas pressure.

This gas pressure can be siobed due to the pressure given by the pump Direction of movement only with the print of the DREI-K-vessel out ## i -above.

The Ges expands therefore in Riobung's THREE-K vessel, thus wins in flow velocity relative to the surrounding capillary system. Fig. 1 + 2 box "o", circle "2", box "d" and circle "3".

At the end of the outer capillary system, the gas has its highest speed , relative to the surrounding capillary system, and its smallest diobes. Fig. 1 + 2 circle "3 After the end of the outer capillary system, the gas hits the Turbine and loses part of its kinetic potential as a directed dynamical potential Energy . Fig. 1 + 2 box "g The amount by which the kinetic energy of the gas becomes less, corresponds to the amount that is taken off as work on the turbine obse will . Fig. 1 + 2 box "g", circle "III", box "f".

After the turbine, the flow cross-section widens considerably in the specially designed DREI -K vessel.

Fig. 1 + 2 box "g", circle "4", box "h".

The force acting on the gas column in the form of Druok decreases here in the the same wetness as the flow cross section increases, and the flow velocity decreases.

This requires a compression of the gas, which with a simultaneous temperature increase is connected. (Adiabatic compression) The The temperature of the gas in the DREI-K vessel goes to the capillaries of the inner capillary system over and thereby causes gas pressure according to line 447 B1.14 Fig. 1 box "b", circle "II", box "c" Due to the permanent temperature transfer of the gas in the DREI - K vessel on the capillaries of the inner capillary system and the one located therein liquid resp. high gas, compresses the gas in the DREI-K-vessel up to to liquefy it The liquefied gas flows into the condensate collecting container.

Fig. 1 + 2 box "h", circle "5 n, box" b ". From the pump promoted, the gas re-enters the inner capillary system description of the potential and dynamic vibration components. The diagram in FIG. 1 is divided into four sectors durob two dashed lines.

These lines serve to verify the functional processes in the Thermodinamic converter.

The polarities that cause the circular oscillation become Compared below in connection with FIG. 1, AB - lowest density of the gas - DC o highest diobte of the gas.

AB - highest speed - DC = lowest speed of the Gas. of the gas AD - decreasing speed - BC - increasing speed of the gas. of the gas AD = increasing density of the - BC s decreasing diobes of the gas . Gases AD = heat emission. - BC - heat absorption AD = large flow cross - BC - small flow cross-section sohnitt.

Energy balance: Sector "D" # outflowing = Sector "C" = receiving Warm heat sector "A" # work. = Sector "B" # absorbed heat.

The invention is characterized in that it provides the linkage the microcosmisobic oscillation level (heat oscillations) into the maorokosmisobe Sobwingungsplane is able to do this in the thermodynamic converter by means of the Formation of elliptical circular vibrations. (See also "Concept of Oscillation / elliptical oscillation "sheet 12, line 5.) A u s f u 1 b r u n g s b e i s p i e 1 The Tbermodynamisobe shown schematically in Fig. 2 Converter is described here by way of example in a specific exemplary embodiment. And in accordance with the statements of the patent "Function Mechanisms of the invention "line 435 ff The condensate collecting container, Fig. 2 box" b "is designed as a gas pressure vessel and had a volume of 10 cubic decimeters.

Stainless steel version The working medium is a conventional one Pump fed into the inner capillary system. The flow cross-section of the feed vessel is 40 square millimeters.

This feed vessel branches out in its further course as an inner capillary system, initially in 40 spherical tubes of 10 square millimeters each Diameter Each of these 40 capillary tubes branches out in its further course to 10 capillary tubes, so that now 403 capillary tubes of 10 square millimeters each Flow cross-section through the THREE-K-vessel. The single lapillary tubes are made of copper The length of the individual capillaries inside the DREI - K - The vessel is 80 centimeters, these 400 individual capillary tubes pass through the container wall of the DREI - K vessel, Fig. 2, circle 2, and now form the outer capillary system with also SO centimeters in length, Fig. 2 box "d Die Ends of the 400 single capillary tubes of the outer capillary system are in front of the Turbine bundled in the same direction. Fig. 2 circle "3".

The relation of the conductor cross-sections between the liquid inlet (40 square millimeters) and the gas outlet, Fig. 2 circle "1 and Fig. 2 circle "3" (4000 square millimeters) therefore corresponds to the ratio 1: 100. The itself The pressure acting on the capillary ends is equivalent to the conductor cross-section , i.e. in a ratio of 1: 100.

The gas emerging from the bundled individual capillaries gives one e part of its kinetic energy to the downstream conventional gas turbine. Fig. 2 box "g" Now, after the turbine, the ladder cross-section widens in the training of the DREI - K * vessel up to 400,000. Square millimeters. execution of the DREI -K- vessel in stainless steel Fig. 2 Box "b The single capillary tube has an outer circumference of the above. 10 millimeters. The total length of a capillary tube is 160 centimeters in total. The entire capillary system has an external one Surface of 6.4 square meters of which 3.2 square meters are on the inside and 3.2 square meters of surface on the outer capillary system The heat feed in the outer capillary system as primary energy therefore takes place over an area of 3.2 square meters.

The heat input is here durob glycerine, which the individual capillaries of the outer capillary system flows around The glycerine circulates in a closed Circulation by means of a pump. It is fed warm to the outer capillary system gives off part of its thermal energy to the outer capillary system, and flows back to the heat source when it is colder, where it warms up again and begins its cycle again.

The regulation of the heat feed takes place depending on the operating conditions by applying the modern measurement and control system

Claims (1)

P A T E N T A N S P R U E C H E Generic term: 1. THERMODYNAMIC CONVERTER Energy converter for the worldwide supply of corporate customers with dynamic Energy, which with relatively small dimensions a relatively large amount theraiscber Energy with up to 100% efficiency, in designs from watts to megawatts up into dynamic energy converts its own waste heat again can be fed back in to generate dynamic energy, and to its Function can still use sources of relatively low thermal energy. Characterized by a compression - contraction - condensation vessel , from now on referred to as the THREE-K-vessel. Fig. 1 + 2 box "b" marked through an in n e r e 5 capillary system, the E x p a n s i o n 8 t e i 1. Fig. 1 + 2 box "c" Identified by an ä u 5 5 e r e 5 capillary system, the E z p a n 5 i n s t e i 1 Fig. 1 + 2 box "d t. Characterized by a condensate collecting container Fig. 1 + 2 box "b". The 25th Units such as pumps and turbines integrated in the thermodynamic converter , Generator, inlet and Durohgangventile and the operation of the invention necessary regulation and control devices.