KR100935082B1 - The thermal reaction engine which use the compound - Google Patents

Abstract

PURPOSE: A thermal reaction engine using a compound is provided to increase expansion force by lengthening the decomposition time of a sodium compound at the room temperature and converting it into power. CONSTITUTION: A thermal reaction engine using a compound comprises a feed part, a composite cylinder apparatus(26), an oil tank, and a combined electric plug(17). The feed part mixes hydrogen peroxide and a sodium compound. The composite cylinder apparatus is connected to the feed part through a material intake valve(7). The oil tank is provided outside of the composite cylinder apparatus and partly connected to the composite cylinder apparatus. The combined electric plug is fitted to a combined electric plug connection groove(1) provided in the lower region of the composite cylinder apparatus. The composite cylinder apparatus comprises a power piston part(18) which is connected with a connecting rod(28) and a transfer piston(20), a compression piston part(9) which is arranged adjacent to the power piston part and has a transfer cylinder(19) forming the space in which the transfer piston is accepted and moves, a decomposition reaction device(2) which forms a material layer charged with materials from the feed part, and a heating part(5) which is provided in the place where the combined electric plug is coupled.

Description

The thermal reaction engine which use the compound

The present invention relates to a thermal reaction engine using a compound, and more particularly, to an engine using thermal decomposition and reaction of a mixture of hydrogen peroxide and a sodium compound to extend the decomposition reaction time of a sodium compound at room temperature to convert power. It relates to a thermal reaction engine using a compound that makes it possible.

Existing external combustion engines have used steam engines and sterling engines. Steam engines discharge power from inside cylinders by expanding the inside of cylinders with steam generated by heating fuel to heat transfer media such as water to obtain power. The water vapor or gas is made of a material that does not change in the original state can be reduced back to the transfer medium, but the heat efficiency is low because the amount of heat required to generate water vapor is high.

The Stirling engine has a combustion chamber 80 and a heating coil 78 at the top of the cylinder to compensate for the disadvantage of low thermal efficiency, and the reheater 76 and the cooling coil 74 of the heat storage type are installed at the outer circumference of the cylinder. The inside of the cylinder is divided into a high temperature portion 82 and a low temperature portion 86 by an exclusion piston 84, and the two piston movements of exclusion and output are defined by a lozenge drive gear so that the connecting rod 88 of the two pistons is provided. 90 is connected by a crank 70 which is synchronized with two gears, and as the output piston 92 rises, the working gas in the low temperature of the cylinder is isothermally compressed, and the exclusion piston is lowered so that the cylinder lowers to the high temperature. At constant volume, the gas moves as it is heated, preheated in a preheater regenerated in the previous cycle, heated in a heating coil, and the gas in the high temperature section of the cylinder The two pistons of exclusion and output descend together to work, and when they are raised, the output piston remains as it is, and only the exclusion piston rises, so that the working gas is maintained in a constant volume from the high temperature to the low temperature of the cylinder, and the cooling is performed. Although the coils are moved while cooling, the initial efficiency of heat is not effectively improved by using air as the working gas. After that, hydrogen or helium is used as a suitable working gas, and the heat exchanger is improved. The heat durability of the heating unit is low, and the generated energy is low compared to the internal combustion engine has a disadvantage.

The internal combustion engine does not solve the problem of the fuel supply and the exhaust gas to the environment has a disadvantage.

Literature Information of the Prior Art

[Document 1] WO 2007019815 A1 (GIMSA, Andreas) 2007.02.22

[Document 2] EP 1683955 A1 (Japan Aerospace Exploration Agency) 2006.07.26

[3] Energy. Analysis of the stirling heat engine at maximum power conditions, (L. Berrin Erbay and Hasbi Yavuz) 1997, Vol. 22, ISSUE: 7, S3060-5442 (96) 00159-4, 645-650

[Reference 4] CeBIT 2008 Information and Communication Technology Exhibition. MSI, 'Air power cooler' by stirling engine 2008. 3. (Date: 2008.04.10.)

The present invention is an engine using pyrolysis and reaction of a mixture of hydrogen peroxide and sodium-based compounds to extend the decomposition reaction time of sodium-based compounds at room temperature to power conversion to increase the thermal efficiency to increase the thermal efficiency by expanding power The purpose of the present invention is to provide a thermal reaction engine using a compound that can increase the thermal durability of the engine due to room temperature, and to reduce the harm to the environment of the emissions generated after the operation in the engine.

The above object is a thermal reaction engine that generates power by decomposition reaction of a compound at room temperature, comprising: a raw material unit in which hydrogen peroxide and sodium compound are mixed; A composite cylinder device 26 connected to the raw material part by a raw material suction valve 7; An oil tank (17) provided at an outer side of the compound cylinder device (26) and partially connected to the compound cylinder device (26); And a mixed electric plug coupled to the mixed electric plug connection groove 1 provided in the lower region of the compound cylinder device 26, wherein the compound cylinder device 26 is coupled to the connecting rod 28 and is disposed at one side thereof. A power piston unit 18 to which the delivery piston 20 is coupled; A compression piston part 9 disposed adjacent to the power piston part 18 and having a delivery cylinder 19 for forming a space in which the delivery piston 20 is received and moved; A decomposition reactor (2) formed inside the bottom and provided with a raw material layer from the raw material; And a heating part 5 provided in an area in which the mixed electric plug is fastened, and the upper oil part 22 and the oil tank 17 between the delivery cylinder 19 and the delivery piston 20 are provided. It is connected by the oil inlet and outlet (15), the connection line is connected to the atmospheric valve (14), the lower oil portion formed on the lower portion of the upper oil portion 22 and provided outside the delivery cylinder (19) 24 and the oil tank 17 is connected by the oil inlet and outlet b (12), the connection line is provided with a transfer valve 11, the connecting rod through the upper and lower oil parts (22, 24) ( 28) is achieved by a thermal reaction engine using a compound, characterized in that to delay and transfer the expansion force of the thermal reaction to the power piston portion 18 combined with.

Here, the raw material suction port 6 may be provided with a nozzle (3) connected to the rubber tube a (8) protruding to the outside by forming a groove penetrating to the center point in a portion of the lower surface of the compression piston (9).

The compression piston 9 has an upper head 25 having a ring a 10, a lower head 27 having a ring b 4, and a delivery cylinder 19 formed integrally therewith. Can be.

The power piston unit 18 may be integrally formed with the transfer piston 20 having a ring d 21 at a lower surface thereof.

The upper oil part 22 is provided by forming the oil inlet / outlet a 15 in the delivery cylinder 19 of the compressed piston part 9, and the lower oil part 24 is connected to the upper head 25. It may be prepared by installing a layer separation membrane having a ring c 23 around the intermediate portion of the connecting rod 13 of the transfer cylinder 19 to form the oil inlet and outlet b 12 in the lower layer.

In the mixed electric plug, an exhaust valve 38 and an exhaust port 37 may be formed at a central portion thereof, and an electrode tube 1 35 and an electrode tube 2 36 having double layers may be provided at the outside thereof.

Electricity applied to the electrode tube 1 (35) and the electrode tube 2 (36) of the mixed electric plug may be an AC voltage of 50V to 500V.

The thermal reaction engine has a six stroke of 'suction', 'compression', 'wait', 'reaction', 'exhaust' as one cycle, and the amount of components of the composite cylinder device 26 having a phase difference of 360 ° is at least three. The crankshaft rotational speed during one cycle is the same as the number of components, and the execution time of the 'reaction' stroke may vary depending on the number of components.

The raw material portion may be a liquid in which hydrogen peroxide, which is an aqueous solution having a concentration of 30% or more, and sodium carbonate, which is a kind of sodium compound, have a standard ratio of 2: 1.

The said raw material part can be made into the liquid which mixed hydrogen peroxide which is aqueous solution of 30% or more of concentration, and sodium hydrogencarbonate which is a kind of sodium type compound with a reference ratio of 2: 1.

The raw material portion may be a liquid in which hydrogen peroxide, which is an aqueous solution having a concentration of 30% or more, and sodium hydrocarbon, which is a kind of sodium compound, have a standard ratio of 2: 1.

The thermal reaction engine maintains a raw material portion made of a mixture containing impurities in a semiconductor state, and then directly applies an alternating voltage to the raw material portion to generate heat from the raw material portion itself, thereby enabling the decomposition reaction to be performed in a short time.

In order to perform the decomposition reaction of the raw material portion, the heat generated in the heating unit 5 may be controlled to 60 ℃ to 350 ℃.

The present invention is the engine using the thermal decomposition and reaction of hydrogen peroxide and sodium compound mixed material by extending the decomposition reaction time of the sodium-based compound at room temperature by power conversion to increase the power due to the expansion of the expansion force to increase the thermal efficiency In addition, it is possible to increase the thermal durability of the engine due to room temperature, and to reduce the harm to the environment of the emissions generated after operation in the engine.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 to 5 are structural diagrams and six-stroke static cycle acupressure diagrams of a thermal reaction engine generating power by decomposition reaction of a compound at room temperature according to the present invention, wherein a raw material portion is mixed with hydrogen peroxide and a sodium compound. A decomposition reactor (2) having a raw material sublayer is formed inside the bottom, a mixed electric plug connecting groove (1) is formed, and the oil inlet and outlet (b) to connect and install the delivery valve (11) and the oil tank (17). And an exhaust valve 38 and an exhaust port 37 formed in the lower portion of the composite cylinder device 26 to form an electrode tube 1 35 and an electrode tube 2 36. There is a heating part 5 to which a mixed electric plug is fastened, and the oil inlet and outlet a 15 is formed inside the compound cylinder device 26 so as to connect and install the atmospheric valve 14 and the oil tank 17. Compression piston section 9, in which raw material suction port 6 is formed in the lower and lower surfaces. It is provided in the compression piston portion 9, there is an oil portion consisting of the upper oil portion 22 and the lower oil portion 24, the power piston portion 18 coupled with the connecting rod 28 through the oil portion Delays the expansion of the thermal reaction.

The raw material suction port 6 is formed by installing a nozzle 3 connected to a rubber tube b 8 which protrudes to the outside by forming a groove penetrating to the center point in a part of the lower surface of the compression piston part 9.

The raw material suction valve 7 is provided in the rubber tube b 8 of the raw material suction port 6.

The compression piston 9 is formed of an upper head 25 having a ring a 10, a lower head 27 having a ring b 4, and a delivery cylinder 19.

The power piston portion 18 is formed by integrally the transfer piston 20 having a ring d (21) in the lower portion.

The oil portion forms an oil inlet and outlet (15) in the delivery cylinder (19) of the compressed piston (9), and installs a rubber tube (16) and a standby valve (14) to connect the oil layer (17) to the upper oil portion ( 22 is formed, a layer separation membrane having a ring c 23 is provided around the middle of the connecting rod 13 of the upper head 25 and the delivery cylinder 19 to form the oil inlet and outlet b 12 in the lower layer. The lower oil part 24 provided with the valve 11 and connected to the oil tank 17 is comprised.

In the mixed electric plug, an exhaust valve 38 and an exhaust port 37 are formed at the center thereof, and the electrode tube 1 35 and the electrode tube 2 36 are formed in double layers at the outside.

The heat reaction engine has 6 strokes as one cycle, and the top dead center where the exhaust port a 30 of the composite cylinder device a 29 is equal to or more than the middle of the top dead center and the bottom dead center of the compression piston part 9 shown in FIG. It is additionally formed in the neighborhood and has 4 strokes.

Looking at the operation of the thermal reaction engine using the compound as shown in Figure 2 in the state configured as described above in Figure 5 as follows.

First, looking at the material of the raw material to enable the decomposition reaction by injecting the mixed electric plug as shown in Figure 4 to the thermal reaction engine of Figure 2, the concentration of 30% or more aqueous solution of hydrogen peroxide and sodium Sodium carbonate, sodium bicarbonate, and sodium hydrocarbon, which are a kind of compound, can be mixed separately and three kinds of raw materials can be used, and the mixing ratio is twice as high as that of sodium compound. .

Prepare the raw materials and see the six-stroke operation sequence and contents of 'suction', 'compression', 'waiting', 'response' and 'exhaust' of the thermal reaction engine. First, rotate the crankshaft The intake stroke (7) and exhaust valve (38), the transfer valve (11) and the standby valve (14) are operated as a medium, and the suction stroke is operated in a state in which AC electricity can be applied to the mixed electric plug. The contents are opened by opening the raw material intake valve 7, closing the exhaust valve 38, switching the transfer valve 11 to the open state, closing the standby valve 14, and the connecting rod 28 by the crankshaft. When rising, the power piston 18 is raised, the upper oil portion 22 is fixed, the oil of the lower oil portion 24 moves to the oil tank 17, the compressed piston 9 is raised The raw material is transferred to the decomposition reactor 2 through the nozzle 3 of the raw material suction opening 6 formed in the compressed piston 9. Inhalation stroke is performed by spraying.

When the suction stroke is completed as described above, the raw material suction valve 7 is closed, and the crankshaft is rotated by 180 °, and from 181 °, the connecting rod 28 descends by the crankshaft, so that the power piston part 18 The lower oil part 22 is fixed, and the oil in the oil tank 17 moves to the lower oil part 24, and the power piston part 18 lowers the compressed piston part 9 to decompose the reactor. A compression stroke is performed to compress the raw material injected in (2).

When the compression stroke is completed as described above, the crankshaft is rotated 360 °, and in the decomposition reactor 2, the electrode tube 1 35 and the electrode tube 2 36 formed of the mixed electric plug of the heating unit 5. Applying alternating current to the conductive material, the raw material part is in a conductive state, and is measured by electrode tube 1 (35) and electrode tube 2 (36) so that the raw material part has a resistive capacity of about 30 Ω. Determine the spacing of tube 2 (36), and apply the alternating voltage below 50V to 500V to electrode tube 1 (35) and electrode tube 2 (36). I (current) = V (voltage) / R (resistance) The starting point is due to hydrogen peroxide, which is a catalyst for pyrolysis because P (power) = VI (voltage * current) is supplied with power of about 83.3W to 8.3KW or less and generates heat of 60 ℃ to 350 ℃ in the raw material itself. This shortened pyrolysis occurs, and the carbonic acid contained in the compound consisting of ionic bonds is separated, and the crankshaft is 361 °. Closes the delivery valve 11, opens the atmospheric valve 14, the connecting rod 28 rises, and the power piston unit 18 rises, the oil in the oil tank 17 flows through the atmospheric valve 14. The upper oil part 22 is moved, the lower oil part 24 and the compressed piston part 9 are kept in a fixed state, and in the decomposition reactor 2, an atmospheric stroke which continues pyrolysis in a static heating state is performed. do.

When the standby stroke is completed as described above, the crankshaft is rotated by 540 °, the connecting rod 28 is switched to descending from 541 °, the power piston 18 is lowered, and the upper oil portion 22 The oil moves to the oil tank (17), and inside the decomposition reactor (2), the compound is pyrolyzed and the separated carbonic acid is in a thermal reaction state that expands due to the temperature rise of the heating part (5), hydrogen and oxygen, and A reaction stroke is performed in which the expansion force of the liquid and gaseous components including carbonic acid is generated.

When the reaction stroke is completed as described above, the crankshaft is rotated by 720 °, the connecting rod 28 is raised from 721 °, the power piston 18 is raised to the oil of the oil tank 17 is the upper oil If the crankshaft reaches 735 ° and the crankshaft reaches 735 °, the alternating current applied to the mixed electric plug is cut off, the transfer valve 11 is opened, and the standby valve 14 is closed. The expansion force in the inside raises the compression piston part 9, the oil of the lower oil part 24 moves to the oil tank 17, and the upper oil part 22 is fixed to the delivery cylinder of the compression piston part 9 19, the expansion force is transmitted to the delivery piston 20 of the power piston unit 18, the transmission stroke is generated to generate the rotational energy due to the expansion pressure of the gas and liquid to the crankshaft through the connecting rod 28 do.

When the transmission stroke is completed as described above, the crankshaft is rotated by 900 °, the connecting rod 28 descends from 901 °, and opens the exhaust valve 38 formed at the center of the mixed electric plug, The piston 18 is lowered to move the oil in the oil tank 17 to the lower oil portion 24, and the compression piston 9 is lowered to allow gas and liquid to flow through the exhaust valve 38 and the exhaust port 37. By carrying out the exhaust stroke, the crankshaft is rotated at 1080 °, and six strokes in the order of 'suction', 'compression', 'waiting', 'response', 'delivery' and 'exhaust' are completed in one cycle.

The top dead center of the composite cylinder device 26, as shown in the composite cylinder device a (29) of FIG. Four additional strokes are possible by forming additional points in the vicinity, and the contents are 'suction', 'compression', and 'suction', 'waiting' and 'reaction' 'Exhaust' and 'exhaust' are complex strokes, and 'wait' and 'reaction' are independent strokes, completing one cycle of four strokes.

When the phase difference of the composite cylinder device 26 is 360 ° and the phase difference between strokes is 180 °, the basic configuration of the six-stroke composite cylinder device 26 is three, and the rotation of the crankshaft is completed while one cycle is completed. The number of rotations is three revolutions, and the basic configuration of the four-stroke composite cylinder device a (29) is two, and the rotation speed of the crankshaft is two revolutions during one cycle.

In the six strokes and four strokes of the thermal reaction engine, there is no restriction on the quantity due to the effect of the atmospheric stroke in the addition of the composite cylinder device 26 and the composite cylinder device a (29), and the execution time of the 'reaction' stroke Due to the transfer valve 11 and the standby valve 14 may vary depending on the number of components of the compound cylinder device 26 and the compound cylinder device a (29).

Wherein the exhaust port a (30) of the composite cylinder device (29) is further formed to enable a complex stroke that is performed simultaneously with the 'compression' during the four stroke intake stroke, and the raw material intake (6) compression piston It is formed inside the part 9 to prevent the raw material is decomposed before being injected into the decomposition reactor 2, the mixed electric plug shown in Figure 4 discharges the gas and some residual liquid generated during the reaction stroke In order to form the exhaust valve 38 and the exhaust port 37 in the center to form the electrode tube 1 (35) and the electrode tube 2 (36) in double layers on the outside so that the electrode can be installed in the entire portion of the raw material. .

Accordingly, the oil portion is operated by the transfer valve 11 and the standby valve 14 to delay and transmit the expansion force generated in the decomposition reactor 2 to the power piston unit 18 to transfer the volume of the six-stroke static cycle shown in FIG. 5. As the chiropractic diagram showing (V) and pressure (P) states, part of the atmospheric stroke, the reaction stroke, and the transfer stroke are statically heated, so they receive the heat quantity of Q1, Q2, and Q3 and release it to Q4 by heat compression and heat expansion transfer. Since the thermal efficiency of the static cycle can be obtained, the expansion force in the decomposition reactor 2 is increased and the rotational energy converted is increased. Consequently, the thermal efficiency can be increased. The raw material used in the thermal reaction engine is a mixture of hydrogen peroxide and sodium compound. As it is a substance, the gas and liquid components released after operation in the engine are composed of trace amounts of carbonic acid, sodium water, hydrogen and oxygen. Since the temperature generated in the heating unit is less than 60 ℃ to 350 ℃ room temperature has the advantage that can increase the thermal durability of the decomposition reactor (2) by heat.

1 is a cross-sectional view of a conventional sterling engine.

2 is a cross-sectional view of a thermal reaction engine using the compound according to the present invention.

Figure 3 is a cross-sectional view formed for the four strokes of the thermal reaction engine using the compound according to the present invention.

4 is a cross-sectional view of a mixed electric plug fastened to the composite cylinder device and the composite cylinder device a of the thermal reaction engine using the compound according to the present invention.

5 is a six-stroke static cycle shiatsu diagram of a thermal reaction engine using the compound according to the present invention.

Claims (17)

In a thermal reaction engine that generates power by decomposition reaction of a compound at room temperature, A raw material portion in which hydrogen peroxide and a sodium compound are mixed; A composite cylinder device 26 connected to the raw material part by a raw material suction valve 7; An oil tank (17) provided at an outer side of the compound cylinder device (26) and partially connected to the compound cylinder device (26); And And a mixed electric plug coupled to the mixed electric plug connection groove 1 provided in the lower region of the composite cylinder device 26. The composite cylinder device 26, A power piston unit 18 coupled to the connecting rod 28 and having a transmission piston 20 coupled to one side thereof; A compression piston part 9 disposed adjacent to the power piston part 18 and having a delivery cylinder 19 for forming a space in which the delivery piston 20 is received and moved; A decomposition reactor (2) formed inside the bottom and provided with a raw material layer from the raw material; And And a heating part 5 provided in a region to which the mixed electric plug is fastened. The upper oil part 22 and the oil tank 17 between the delivery cylinder 19 and the delivery piston 20 are connected by an oil inlet and outlet a 15, and a standby valve 14 is connected to the connection line. , The lower oil part 24 and the oil tank 17 formed at the lower portion of the upper oil part 22 and provided at the outside of the delivery cylinder 19 are connected by an oil inlet and outlet b 12. The transfer valve 11 is provided, Thermal reaction engine using a compound, characterized in that to delay and transfer the expansion force of the thermal reaction to the power piston (18) coupled with the connecting rod 28 through the upper and lower oil portion (22, 24). The method of claim 1, The fuel inlet 6 connected to the fuel intake valve 7 forms a groove penetrating to a center point in a portion of the lower surface of the compression piston part 9 to which the rubber tube a 8 protruding to the outside is connected. Thermal reaction engine using the compound, characterized in that the installation. The method of claim 2, The compression piston 9 has an upper head 25 having a ring a 10, a lower head 27 having a ring b 4, and a transfer cylinder 19 formed integrally therewith. Thermal reaction engine using a compound, characterized in that there is. The method of claim 1, The power piston unit (18) is a thermal reaction engine using a compound, characterized in that the transfer piston (20) having a ring d (21) is integrally formed on the lower surface. The method of claim 3, The upper oil part 22 is provided by forming the oil inlet and outlet a 15 in the delivery cylinder 19 of the compressed piston 9, The lower oil part 24 is provided with a layer separation membrane provided with a ring c 23 around an intermediate portion of the connecting rod 13 of the upper head 25 and the transfer cylinder 19, and the oil inlet and outlet b 12 is disposed on the lower layer. Thermal reaction engine using a compound, characterized in that is provided by forming). The method of claim 1, In the mixed electric plug, the exhaust valve 38 and the exhaust port 37 are formed at the center thereof, and the outer electrode electrode 1 35 and the electrode tube 2 36 are provided with double layers. Thermal reaction engine used. The method of claim 6, The electricity applied to the electrode tube 1 (35) and the electrode tube 2 (36) of the mixed electric plug is a thermal reaction engine using a compound, characterized in that the AC voltage 50V to 500V. The method of claim 1, The thermal reaction engine has a six stroke of 'suction', 'compression', 'wait', 'reaction', 'exhaust' as one cycle, and the amount of components of the composite cylinder device 26 having a phase difference of 360 ° is at least three. The crankshaft rotational speed for one cycle is the same as the number of components, and the execution time of the 'reaction' stroke is a thermal reaction engine using a compound, characterized in that can be changed according to the number of components. delete delete delete delete The method of claim 1, The raw material part is a thermal reaction engine using a compound, characterized in that the mixture of hydrogen peroxide, which is an aqueous solution having a concentration of 30% or more, and sodium carbonate, which is a kind of sodium-based compound, with a reference ratio of 2: 1. The method of claim 13, The raw material part is a thermal reaction engine using a compound, characterized in that the mixture of hydrogen peroxide, which is an aqueous solution having a concentration of 30% or more, and sodium bicarbonate, which is a kind of sodium-based compound, with a reference ratio of 2: 1. The method of claim 14, The raw material portion is a thermal reaction engine using a compound, characterized in that the mixture of hydrogen peroxide in an aqueous solution having a concentration of 30% or more and sodium hydrocarbon, which is a kind of sodium compound, in a ratio of 2: 1. The method of claim 1, The thermal reaction engine maintains a raw material portion made of a mixture containing impurities in a semiconductor state, and then applies an alternating voltage directly to the raw material portion to generate heat from the raw material portion itself to perform a decomposition reaction in a short time. Thermal reaction engine used. The method of claim 16, Thermal reaction engine using a compound, characterized in that for controlling the decomposition reaction of the raw material portion heat generated in the heating section 5 to 60 ℃ to 350 ℃.

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