DE102016109639A1 - Device for the atomic or molecular restructuring of educts - Google Patents

Abstract

The invention relates to a device for atomic or molecular restructuring of a first starting material and at least one second starting material for forming a product, with a reaction chamber, with a first feed line for supplying the first starting material into the reaction chamber, and with a second feed line for supplying the second starting material into the reaction chamber, wherein the reactants collide in the reaction chamber and the kinetic energy of the educts is used at least in part for the atomic or molecular restructuring.

Description

The invention relates to a device for atomic or molecular restructuring of a first starting material and at least one second starting material to form a product.

From the WO 2013/156556 A1 a device for producing a single-phase stable liquid is known in which water is supplied as the first reactant and diesel as a second educt a mixing chamber. Thereafter, in the device of WO 2013/156556 A1 the static pressure of the mixture is brought under the vapor pressure of at least one of the liquids, in which case the single-phase stable liquid is to be formed. There is a need for further devices that allow atomic or molecular conversion to the product in an efficient and reproducible manner.

The object underlying the invention is to provide a further device by means of which a first starting material and at least one second starting material can be converted into a product with high efficiency by atomic or molecular restructuring.

The object underlying the invention is achieved with the device according to claim 1. Embodiments of the invention can be taken from the subclaims.

According to the invention it is provided that the device comprises a reaction chamber which is fluidly connected to a first supply line for supplying the first starting material and to a second supply line for supplying the second starting material. The device is designed such that both educts collide in the reaction chamber at a comparatively high velocity and the kinetic energy of the educts is used at least in part for the atomic or molecular restructuring. Preferably, the kinetic energy is used at least 40, 60, 80 or even 90% for atomic or molecular restructuring. In other words, the kinetic energy is thus converted into chemical energy.

A flow cross section of the first supply line may be larger than a flow cross section of the second supply line. Preferably, the supply line is used with the smaller flow cross-section for the supply of the starting material, which has a greater density compared to the other starting material. The density of the educts does not necessarily have to be different. Preferably, one of the educts is water and the other educt is a liquid hydrocarbon (for example, methanol, kerosene, diesel). The product may then be another hydrocarbon with a different chemical structure.

The first supply line and the second supply line preferably have a circular flow cross-section. However, it is also conceivable that the flow cross-section deflects from the circular shape, for example, it may be oval-shaped or polygonal.

In one embodiment, the first supply line and the second supply line face each other and are preferably arranged on a common central axis. Thus, the educts meet in this arrangement of the leads frontally in the reaction chamber to each other. In other words, the first supply line ends or opens on one side of the reaction chamber, while the second supply line terminates or opens on an opposite side of the reaction chamber.

The reaction chamber may be rotationally symmetrical, in particular cylindrical, conical or partially cylindrical and partially conical.

For example, the reaction chamber may be formed as a cylindrical tube piece, which has an inner diameter of 0.2 to 5 mm, preferably 0.4 to 4 mm. The cylinder inner wall may be formed slightly bulbous, wherein a diameter of the envelope of this outwardly curved cylinder inner wall by at least the factor 1.02 may be greater than the (basic) diameter of the reaction chamber. The factor may for example be 1.05 to 1.1.

The reaction chamber may be designed to be movable at least to the first supply line or the second supply line. In one embodiment, the reaction chamber is designed to be movable relative to the first supply line and the second supply line.

For example, the reaction chamber may be formed in a rotatably mounted turret cylinder, wherein in a working position of the turret cylinder, the first supply line and second supply line are fluidly connected to the reaction chamber or open into the reaction chamber and wherein in a flushing position, the reaction chamber is fluidly connected to an emptying device. In the working position of the turret cylinder, the reactants are fed to the reaction chamber and the restructuring takes place until the reaction chamber is completely filled with the product or with the residues of the educts. Thereafter, the revolving cylinder is rotated until the reaction chamber is fluidly connected to the emptying device, for example, by the air Reaction chamber freeze again. Thereafter, the revolving cylinder can be rotated back into the working position.

The turret cylinder can have at its periphery a plurality of juxtaposed reaction chambers, so that the turret cylinder must always be rotated only by a certain angle in order to connect the respective reaction chamber with the leads. The same applies mutatis mutandis to the emptying device.

Alternatively or additionally, a channel may be provided, from which the product can escape from the reaction chamber. In one embodiment, the channel has a flow cross section that is variable over the channel length. Preferably, the flow cross-section increases with increasing distance from the reaction chamber. The flow cross section can increase linearly or non-linearly with the channel length (calculated from the reaction chamber).

In one embodiment of the invention, the reaction chamber is integrally formed on the second or first supply line.

Based on the embodiments shown in the figures, the invention will be explained in more detail. Show it:

1 a first embodiment;

2 a reaction chamber of the embodiment of 1 ;

3 schematically another arrangement of flow directions;

4 an embodiment with a revolving cylinder;

5 another view of the embodiment of 4 ;

6 an embodiment with a fixed reaction chamber; and

7 another embodiment with fixed reaction chamber.

1 shows a device according to the invention, in its entirety with 1 referred to as. The device 1 includes a first supply line 10 and a second supply line 20 that have a common central axis 2 exhibit. The supply lines 10 . 20 For example, they can be hoses, pipes or nozzles. Between the opposing supply lines 10 . 20 is a reaction chamber 30 arranged. The reaction chamber 30 is as a cylindrical piece of pipe with a slightly bulbous cylinder inner wall 31 educated. In 2 it can be seen that a diameter 32 an envelope of the cylinder inner wall 31 larger than an inner diameter 33 the reaction chamber 30 at the front ends thereof 34 , The diameter 32 may be 2% to 20 or 3% to 10% larger than the diameter 33 , The diameter 33 can be 0.2 mm to 5 cm. An axial length of the reaction chamber 30 is in one embodiment, 1 mm to 5 cm. It is also possible to choose larger axial lengths.

The flow direction of a first educt that passes through the first supply line 10 in the reaction chamber 30 is with an arrow 3 characterized. A flow direction or flow direction of a second starting material, through the second supply line 20 in the reaction, 30 arrives is with 4 characterized. In the reaction chamber 30 the two reactants collide, whereby the kinetic energy is used for the atomic or molecular restructuring of the two educts. The kinetic energy of the educts flowing into the reaction chamber at comparatively high speed is thus converted into chemical energy.

3 schematically shows that the flow directions 3 . 4 can not only face each other by 180 °, but also an angle 5 which deviates from 180 °. For example, the angle 5 90 ° to 170 °.

The 4 and 5 show an embodiment in which the reaction chamber 30 is formed in a rotatable component. The rotatable member is in the embodiment of 4 and 5 designed as revolving cylinder, with 50 referred to as. In the revolving cylinder 50 are a variety of circumferentially juxtaposed reaction chambers 30 educated. By turning around a turret axis 51 leaves one of the reaction chambers 30 in the in 4 shown position between the first supply line 10 and the second supply line 20 arranged and thus fluidly with these leads 10 . 20 connected to a position where they fluidly with an emptying device 60 connected is. Thus, the reactants of the reaction chamber 30 be supplied until the latter is completely filled. By rotation, then the filled reaction chamber of the emptying device 60 are fed, for example, by air blowing the product or a mixture of product and the unconverted educts from the filled reaction chamber. The thus evacuated reaction chamber can then return to the supply lines by further rotation 10 . 20 be supplied. It is understood that due to the large number of circumferentially arranged reaction chambers of Revolverzylinder in the operation of the device only by a few Angular degree must be turned to the supply lines 10 . 20 to supply a new, empty reaction chamber.

The 6 shows an embodiment in which the reaction chamber 30 in one piece on the first supply line 10 is formed. A diameter of the cylindrical reaction chamber 30 corresponds to the inner diameter of the first supply line 10 , The here on a common central axis 2 lying supply lines 10 . 20 have a small distance A, which may be 0.2 to 5 mm, for example. The second supply line 20 has a positive cone 21 on while the first supply line 10 a negative cone 11 having. By the distance A and the two Koni 11 . 21 creates an outwardly opening, annular channel 6 between the supply lines 10 . 20 , passing through this channel 6 the product from the reaction chamber 30 can escape. An angular difference between the angle of inclination of the cone 21 and the angle of inclination of the cone 11 is with 7 characterized. The angular difference can assume values between 1 ° and 10 °. Again 6 can be seen increases with increasing distance to the reaction chamber 30 the flow cross-section of the channel 6 at.

7 shows a further embodiment with a reaction chamber 30 that are integral with the first supply line 10 is trained. As well as in the embodiment of 6 is an inside diameter 12 the first supply line 10 larger than an inner diameter 22 the second supply line 20 , A difference of the inner diameter 12 . 22 can be 0.1 to 5 mm. In the embodiment of 7 is also a distance A drawn through which the channel 6 to escape the product from the reaction chamber 30 given is. The flow cross section of the channel 6 gets bigger towards the outside.

By varying the distance A, the inner diameter 12 . 22 and the formation of the reaction chamber 30 , in the 7 a conical part 35 As well as by the variation of the pressures or the velocities, with which the educts of the reaction chamber 30 can be used to control the reaction and thus influence the yield of the product and the quality of the product.

Depending on the setting of the above-mentioned parameters, certain sound waves are formed during operation of the device, the frequency spectrum of which can be recorded. This frequency spectrum is in a certain ratio to the product, which results from the atomic or molecular restructuring of the educts. The frequency spectrum can thus be used to control or regulate the chemical reaction. For example, by varying the individual pressures with which the starting materials are shot into the reaction chamber, the chemical structure of the product can be influenced. Since this also changes the frequency spectrum, the process can be controlled by variation of the above parameters with known dependence between the frequency spectrum and the achievable product based on the frequency spectrum.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2013/156556 A1 [0002, 0002]

Claims (9)

Apparatus for the atomic or molecular restructuring of a first starting material and at least one second starting material to form a product, having a reaction chamber, with a first feed line for feeding the first starting material into the reaction chamber, and with a second feed line for feeding the second feedstock into the reaction chamber, wherein the reactants collide in the reaction chamber and the kinetic energy of the reactants is used at least in part for atomic or molecular restructuring. Apparatus according to claim 1, characterized in that a diameter of the first supply line is greater than a diameter of the second supply line. Apparatus according to claim 1 or 2, characterized in that the first supply line and the second supply line facing each other and are arranged on a common central axis. Device according to one of claims 1 to 3, characterized in that the reaction chamber is rotationally symmetrical, in particular cylindrical, conical or partially cylindrical and partially conical. Device according to one of claims 1 to 4, characterized in that the reaction chamber is designed to be movable at least to the first supply line or the second supply line. Apparatus according to claim 5, characterized in that the reaction chamber is formed in a rotatably mounted turret cylinder, wherein in a working position of Revolzwylinder the first supply line and the second supply line are fluidly connected to the reaction chamber and in a flushing position, the reaction chamber is fluidly connected to an emptying device , Device according to one of claims 1 to 6, characterized in that a channel is provided, from which the product can pass from the reaction chamber. Apparatus according to claim 7, characterized in that the channel has a variable over the channel length opening cross-section. Device according to one of claims 1 to 8, characterized in that the reaction chamber is integrally formed on the second supply line or the first supply line.

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