SE544383C2 - Method and device for separation and separation of oxygen in air - Google Patents

Abstract

Method for separation and separation of oxygen in air in a device consisting of at least one cylinder, a drive device belonging to the cylinder consisting of an electric machine an impeller fixed inside the cylinder, an opening for passage of air located in the center of the cylinder, a fitting connected to the opening comprising an opening and closable outlet for air without oxygen and an opening and closable line for separated oxygen leading to a compressor with tank.

Description

Method and device for separation and separation of oxygen in air Oxygen is usually produced by distillation of air or electrolysis of water. It is known that separation of exhaust gases such as oxygen can be achieved via centrifugation, which the method and device proposed here makes possible and which more specifically applies to batch separation of oxygen.

The air consists mostly of nitrogen, about 78 percent, and oxygen, about 21 percent. The air also contains very small amounts of other gases such as argon, carbon dioxide, neon and water vapor.

The invention is based on the fact that molecules in different gases weigh differently. For example, oxygen weighs 32 u (02, molar mass 2 * 16 u), nitrogen 14 u (N, molar mass 14 u), water vapor 18 u (H 2 O, molar mass 2 + 16 u), nitrogen oxide 30 u (NO, molar mass 14 + 16 u ), carbon dioxide 44 h (CO 2, molecular weight 12 h + 32 h).

In air, oxygen has a large volume fraction and the molecule is heavy. Carbon dioxide is heavier, but its volume share is so small that it is disregarded in this context. Centrifugation is therefore well suited as a method for pre-separation of oxygen.

The invention typically comprises a new type of centrifugal compressor, which operates in three stages: Step 1 means that the compressor is rotated at increasing speeds, whereby gas is sucked in centrally and compressed by radially acting g-force while giving off heat to a cooling medium.

Step 2 means that during a substantially constant speed, continued heat is emitted from the compressed gas and that gas continues to be sucked in and compressed as long as heat is emitted.

Step 3 means that the compressor is caused to rotate at decreasing speed, whereby the gas expands during the absorption of heat and is evacuated centrally.

Steps 1 and 2 are labor intensive and performed by an electric machine. Step 3 is employer due to the breeding machine being brought to slow down the rotation by generating electricity and thereby recovering some of the electrical energy consumed during Steps 1 and 2.

The invention comprises an impeller in a cylinder which is caused to rotate via an electric machine. By rotating, air is sucked into the cylinder via an opening in its center and forced by centrifugal force against the periphery of the cylinder. At a given constant speed, the supply of air stops when the centrifugal force effect of the molecules in the air is balanced by the pressure in the compressed air. During continued rotation, separation of different gases occurs due to. different molecular masses and there is an accumulation of mainly oxygen next to the peripheral cylinder wall as its molecule, when ignoring the extremely small proportion of carbon dioxide, is heavier than other gas molecules in the air. During compression, the riser temperature and the cylinder wall heat up. If the cylinder is cooled by ambient air or other cooling medium during rotation, additional supply of combustion gases takes place due to the cooling lowering the pressure in the air being compressed. This can in principle last until the same temperature is in the cylinder wall as in the cooling medium. Compression takes place during simultaneous cooling, which is a positive fuel economy. If the cylinder is heated up in such a way that heat in the air which is compressed via the cylinder wall is dissipated to coolant as the heat is generated, in principle the compression can take place isothermally.

Then the oxygen, after decision by an electronic control system, must be sufficiently separated the brake rotation whereby the contents of the cylinder flow out via the opening where the air was supplied. In a luminaire surrounding the opening there is a sensor which via the control system senses when oxygen begins to flow, whereby a valve in the luminaire causes the flow of oxygen to flow in a line to a compressor where the oxygen, noticeably cold after expansion, is compressed and stored in a tank or gas cylinder.

For maximum production of separated oxygen, the process must be repeated optimally, which may be tested in terms of laboratory and conditions and control parameters are specified in the electronic control system. "The cylinder is rotated up to a constant speed, oxygen is separated, the rotation of the cylinder is slowed down, air without oxygen is led to the environment, the separated oxygen gas is led to a compressor".

The repeated process described above takes place characteristically in batches, which means that the method can be carried out in a simple and small manner, with the attendant low cost for manufacture and operation.

The following figure description complements the above description of the invention. An electronically based control system with associated software and sensors / sensors as well as control devices is a matter of course today. It is included in the device and is not specifically described, but control systems and control means are mentioned when it may be appropriate.

Fig. 1. A cylinder seen from the front 1 and from the side 2 which is to be caused to rotate via a drive device, for example an electric machine 3, connected to the cylinder via a drive shaft 4. In the cylinder there is an impeller 5 not visible from the outside, which is illustrated in Fig. 2. The impeller is fixedly fixed in the cylinder, which causes the local cylinder to rotate, at the same time causing the impeller to rotate. In the middle of the front of the cylinder there is an opening 6, for the passage of air. The ratio between the diameter of the cylinder, from the front 1, and its length, from the side 2, may be different from that indicated in the figure. Exv. the cylinder can be made relatively longer.

Fig. 2. Cylinder, seen from the front 1 and from the side 2, which is caused to rotate via a drive device, single machine 3, connected to the cylinder via a drive shaft 4. In the cylinder, an impeller 5 is gas-tight and fixed between the front and back of the cylinder. According to the figure, the impeller does not connect to the cylinder-peripheral inside, which it can do in an alternative embodiment. When the cylinder is caused to rotate, air is sucked into the cylinder via an opening for the passage of air 6. The supplied air, caused by radial-acting centrifugal force, is moved under compression towards the peripheral inside of the cylinder and the heaviest molecules, mainly oxygen, accumulate at the outer wall. The cylinder is surrounded by a cooling medium, for example ambient air 12. When the rotation of the cylinder is slowed down, the gas in the cylinder expands under falling temperature and flows out via the opening 6, the separated oxygen gas flowing out last when it is furthest from the opening. During deceleration, energy can be recovered by causing the electric machine 3 to generate electricity which is returned to the mains or stored in a battery, not shown in the figure.

Fig. 3. A luminaire 7 is gas-tightly mounted at the opening 6 but without rotating at the rotation of the cylinder. to a compressor with tank11. Via the line 10 and the opening 6, supply of air takes place when the cylinder is rotated and partial supply of air without oxygen when the rotation of the cylinder is slowed down. Via line 9, only the export of oxygen takes place. The sensor 8 and the opening and closing wires 9 and 10 are connected to an electronic control system, not shown in the figure, and the wires are controlled to be opened or closed by control means connected control means, not shown in figure.

The invention is not limited to the exemplary embodiments shown in the figures, but the modifications may be made within the scope of the following claims.

Claims (1)

1. Procedure for batchwise separation and separation of oxygen in air with a device consisting of at least one cylinder (1,2), a cooling medium (12) that surrounds the cylinder, a cylinder-related drive device consisting of, for example, an electric machine (3) with a drive shaft ( 4), an impeller (5) fixed inside the cylinder, an opening (6) located in the center of the cylinder for the passage of air, a fixture (7) connected to the opening (6) including a sensor (8) for detecting oxygen and an opening and closable outlet for air without oxygen (10), an opening and closable line for oxygen (9) connected to the armature (7) which leads to a compressor with a tank (11), whereby the cylinder is brought into rotation and air is sucked into the cylinder via the opening (6) after which the rotation is brought to an end whereby air flows out of the cylinder via the opening (6) and separated oxygen flows out of the cylinder last via the opening (6). characterized in that the batch-wise procedure takes place repeatedly. Method according to claim 1, characterized in that when the cylinder (1) together with the impeller (5) is caused to rotate via the drive device, air is sucked into the cylinder via the opening (6) and is forced due to radially acting g-forces caused by the rotation during simultaneous cooling compression to move towards the periphery of the cylinder. Method according to claim 2, characterized in that the cylinder is spun up to a constant speed determined by the control system, whereby oxygen is separated and accumulated near the periphery of the cylinder. Method according to claim 3, characterized in that the cylinder is spun down via braking of the drive device, whereby outflow, of air cooled by expansion, takes place via the opening (6) to the fixture (7), whereby the outgoing air is led to the environment via the outlet (10) added to the control system, upon signal from the sensor (8) which detects oxygen, orders the control device to close the outlet (10) and to open the line (9) ) for oxygen gas to the compressor with tank (11). Device for carrying out the method according to claims 1-4, characterized in that it comprises at least one cylinder (1,2), a cooling medium (12) surrounding the cylinder, a drive device belonging to the cylinder consisting of an electric machine (3) with a drive shaft (4), an impeller (5) fixed inside the cylinder, an opening in the center of the cylinder (6) for the passage of air, to the opening (6) connected fixture (7) comprising an opening and closing outlet for air without oxygen (10), an opening and closing line for oxygen (9) leading to a compressor with tank (11).