DE2241847C3 - Process for increasing the yield of electricity by supplying heat - Google Patents

Description

From DE-OS 20 48 534 a method for the direct conversion of thermal energy into electrical energy Energy known, using two arranged in a closed vessel, of At least approximately electrolyte-free water surrounded electrodes by the water being heated and attached an electrical voltage is drawn from the electrodes led out of the vessel.

The voltage taken from the electrodes is low. At 100 ^° C. it is approx. 1.5 volts. The electrical power that can be achieved by the process is too low to allow economical use.

The invention relates to a method for increasing the yield of electrical power by supplying heat.

The object of the invention is to create a new method based on the known method, with which a significant increase in performance is achieved in order to convert thermal energy into electrical energy.

This object is achieved according to the invention in that a pair at a small distance from each other, in a closed vessel, surrounded by electrolyte-free water, for water syrup alternating current is supplied to catalytically active electrodes, the closed vessel by means of a heat source heated and the obtained stream of the two lead out of the vessel in a pressure-tight manner and on Electrodes connected to a circuit are removed and fed to the common circuit. In contrast to the prior art, according to the invention there are two catalytically active electrodes used, wob ?! especially nickel electrodes are advantageous. The invention is the combination of one Electrolysis and electrocatalysis of thermally dissociated heat molecules. If you move around one Apparatus that works according to the invention has a balancing group, so this balancing group becomes an electrical one Excitation energy and thermal energy supplied. Due to the synthesis of water with the result of utility electricity generation the water cools down. To maintain a stable procedural state = Therefore, heat must be supplied to keep the water temperature at the original level . keep. Useful electrical energy is then taken from the balancing group, whereby it is essential that the Usable current is greater than the excitation current.

On one electrode of the closed vessel, the positive pole, through this stream of decomposition a water molecule becomes oxygen and at the other electrode, the negative pole, deposited hydrogen. A chemical reaction with the Electrodes do not take place The decomposition products oxygen and hydrogen adhere, electrostatically tied to the surface of the electrodes. You are in the ionic state, i.e. i.e., they are energetic and highly reactive. In addition to this decomposition due to the excitation current, there is also dissociation More water molecules instead of heat supply These dissociated water molecules are due to the extended dipole property also reactive.

The electrolytic decomposition products adhering to the electrodes are due to their ability to act itself again the cause of a new, secondary cleavage of thermally dissociated water molecules in opposite sense to splitting by the decomposition current, producing oxygen and hydrogen on one electrode and hydrogen with oxygen on the other electrode with catalytic support of the electrodes each cause a water synthesis.

The result is a water synthesis at each electrode, namely the chemical reaction between Oxygen and hydrogen to water with the release of high energy of formation. This educational energy occurs usually in the form of walls on it, however in the method according to the invention due to the fact that the reaction occurs directly at the electrode unwound as electrical energy obtained, which is taken from the electrodes led out of the vessel can be.

Through the combination of electrolysis of thermally split water molecules and catalysis takes place there is a constant, rapid alternation between water splitting and water synthesis.

Decomposition current, which can also be referred to as the excitation current and which is produced by water synthesis newly produced electricity flows inevitably in a common circuit, from which, however, useful electricity can be taken as energy gain from water synthesis. The proportion of the erosion current can in a similar way to the magnetic excitation current in modern dynamo generators through the return line in the uninterrupted cycle can be fully used again, so that practically only the heat share as Energy use comes into consideration. The method according to the invention is therefore a high-performance one Direct conversion of thermal energy into electrical energy. According to the amount of useful electricity drawn, Provided that there is good thermal insulation, all that needs to be done is that which is newly formed by water synthesis Water content can be dissociated again by applying appropriate heat.

Alternating current has proven to be advantageous. At the apex of the current strength and voltage of each phase, the short-term effect of an alternating current is to be equated with the permanent effect of a direct current. The short-term peak of the current intensity is sufficient for water decomposition and subsequent water synthesis through reaction with the thermally dissociated water molecules. one on both electrodes at the same time. During the transition phase in the Kuliwert, the electrodes are de-energized again for a short time interval - it flows in the reverse direction, a polarization current as in a gelade · ¹ hen battery without Zwischenfeäktiöneri chemically transformed electrodes affinhätsgebun ^

which limit the potential difference -. When climbing a water synthesis is thus prepared again in the peak value problem-free. The rhythmic and rapid repetition of the leading to a water synthesis Functions enables a high current density. The use of alternating current is particularly evident advantageous over direct current because alternating current can be easily converted to any desired Transforms tension. As already stated, the level of the voltage has a favorable effect on water decomposition and thus promotes the reaction process the end. Alternating current can be used as single-phase or multi-phase current.

In a closed vessel of any shape with at least approximately pure, electrolyte-free water there are two inactive, catalytically active electrodes with a nickel surface. The two electrodes are arranged as close to each other as possible. A small amount of water is sufficient to absorb the Electrodes just surrounds The vessel is heated in some way

This supply of heat causes the water molecules to dissociate. The dipolarity increases as the Water temperature more pronounced. In order to set the process according to the invention in motion, the after An excitation current can be applied to externally guided electrode contacts. Because of this current, a Splitting of the water molecules at the electrodes. The inner resistance to the switched on Decomposition current decreases with increasing water temperature, so that it adheres to the electrodes Separate oxygen ions and hydrogen ions. These oxygen ions and hydrogen ions adhere to the electrode surfaces without entering into chemical compounds with them. The from The electrostatic forces emanating from these oxygen or hydrogen ions act on the thermally extended dipoles of the surrounding hot water mass. The result is mutual attraction between oxygen on one electrode and hydrogen from the water dipole on the one hand and between hydrogen at the other electrode with oxygen from the water dipole on the other hand. Of the The catalyst accelerates the reaction of the ions contacting its water surface, without itself doing so to experience lasting changes. Any reaction that leads to water synthesis in this way has a considerable educational energy result.

The amount of tension as well as the amount of Temperatures of the water mass are variable for the method according to the invention, with which the method can be controlled in terms of the amount of useful current and efficiency. With the same Temperature can change the voltage of the electrical decomposition current The rate of reaction of the catalysis can be regulated within wide limits. The higher the tension of the Decomposition current (excitation current), the more intense the electrostatic attraction of the Electrodes secreted hydrogen and oxygen ions on the thermally dissociated water molecules.

Thanks to the use of alternating current as the excitation current occurs at the apex of the current inten ^ Each phase has a simultaneous decomposition of water subsequent water synthesis through reaction with the thermally dissociated water molecules. At the zero crossing the electrodes are de-energized for a very short period of time and therefore free for an in polarization current flowing in the opposite direction with formation of water synthesis with release electrical energy as compared to the battery.

The rhythmic and rapid repetition of the electricity-supplying reactions make a high level possible Current density. Excitation current and the useful current newly obtained from water synthesis flow into one

common circuit from which the excess energy can be drawn as electrical current.

The method according to the invention can be carried out at relatively low working temperatures and is characterized This differs from previously known proposals for the direct conversion of heat into electric current. Furthermore, the method according to the invention can be used significantly achieve better performance and the devices operating according to the method according to the invention are absolutely maintenance-free, since the ongoing decomposition of water with accompanying new formation takes place in the hermetically sealed vessel without that the amount of water changes qualitatively and quantitatively

This device is therefore particularly suitable for continuous operation. It is also particularly advantageous that due to the choice of temperature and the choice of the level of excitation voltage the new method to the can be adapted to respective requirements. Since the hermetically sealed used in the invention The vessel only contains the two electrodes and just as much electrolyte-free water as to cover it the electrodes is necessary is an extremely space-saving arrangement for generating electrical Electricity created from thermal energy. Such devices operating according to the new method are therefore particularly suitable for the electric drive of vehicles.

The invention will be explained in more detail on the basis of test examples. It shows

F i g. 1 is a circuit diagram of the experimental set-up, FIG. 2 is a tabular compilation of the Test results and

Fig. 3 is a graphical representation of the test set-up according to FIG. 1 results obtained.

In Fig. 1 the excitation circuit is denoted by 10. There is a primary voltage of 220 volts alternating current before. The primary circuit 10 is connected to the secondary circuit 14 via a control transformer 12. In addition to the measuring instruments shown, this has the two in a hermetically sealed one Vessel 16 arranged electrodes. The electrodes are surrounded by water. The vessel is de-heated. the "The water temperature was measured in each case and in the

ι ¹ ; Table according to FIG. 2 and the graphic representation according to FIG. J is held. The secondary circuit 14 also contains the load resistor 18.

The Gßfäß 16 used had the following dimensions: 120 mm × 70 mm × 20 mm. The vessel contained 80 cm ^{3 of} distilled water. The two nickel electrodes in the vessel 116 had an area of 65 mm × 100 mm, that is to say a mutually effective surface of 65 cm ² .

In Fig. 3 contains two curves. The dashed curve represents the excitation current as a function of the Water temperature. The solid lines represent the course of the useful current also in Dependence on the water quality.

As can be seen from the graphic representation according to FIG. 3, the excitation current is greater than the useful current at low temperatures, for example at room temperature, so that economical operation cannot be achieved at these temperatures. If the water temperature in the vessel 16 is around 40 ° C., the useful current and the excitation current are approximately the same. Above this temperature, the useful current exceeds the excitation current and, as can be seen from the graph, the Sfrom gain is greater, the higher _a .i.die; ji: water temperature. -The tests were only run with a maximum water temperature of 113 ° C. At this temperature, the excitation current was 228.8 watts and the useful current was 252.0 watts. The difference represents the power gain.

This experiment with the described experiment on ^ construction according to Fig. I was driven several times in a row and the result was the same each time of the performance curves in the primary area and in the secondary area, depending on the respective water temperature.

1 sheet of drawings

Claims (1)

Claim: Process for increasing the yield of electricity by supplying heat, thereby characterized in that a pair at a short distance from each other, in a closed Vessel arranged, surrounded by electrolyte-free water, catalytic for water synthesis Acting electrodes supplied with alternating current, the closed vessel by means of a heat source heated and the obtained stream of the two lead out of the vessel in a pressure-tight manner and on Electrodes connected to a circuit are removed and fed to the common circuit will.