JP5046125B2 - Automatic eco compressor - Google Patents

Description

  The present invention relates to an automatic eco-compressor that converts potential energy such as tides, dams, rainwater, and melted snow water into air pressure, and can increase its own pressure by using the obtained low-pressure air.

The present invention relates to an automatic eco-compressor that compresses 100% purity gas at low cost.

At present, rainwater and melted snow are not used as renewable natural energy other than hydroelectric power generation. In addition, the potential energy of the water before flowing into the dam and the water not flowing into the dam is disappearing without being recovered.

In recent years, global warming has progressed, and water disasters due to torrential rains occur every year around the world.

The air compressor used in the industry is the reciprocating drive type, and the lubricant is used to prevent seizure of the piston and cylinder, and the lubricant mixed in the compressed air is removed. Various filters must be used. Still, it does not become 100% pure compressed air, is expensive, and is inefficient.

The first issue is to provide a technology that can recover and use renewable natural energy at low cost.

The second problem is to provide an automatic eco-compressor that can compress gas with a purity of 100% at low cost.

The present invention includes a compressor (6) comprising a sealed container for compressing gas at a water surface pressure provided with a check valve (7) for sucking the atmosphere into the upper surface, and rainwater and high water from the compressor (6) to 5000 m. A water storage tank (1) for storing melted snow is provided, and a tank (17) having an open / close valve 10 (16) for releasing compressed air to the atmosphere is provided on the upper surface up to 1000 m, and The lower surface of the compressor (6) and the lower surface of the water storage tank (1) are pumped with rainwater or snow melt water from the water storage tank (1) to the compressor (6) via the on-off valve 1 (4 ). In order to compress the air inside, the water distribution pipe (2) communicates with the water distribution pipe (2) between the lower surface of the compressor (6) and the on-off valve 1 (4) via the on-off valve 3 (5). Pump the water from the tank (17) to the compressor (6) Withstand pipe to further compress the compressed air in the suppressor (6) (20) with communicates with the lower surface of the tank (17), the tube between the opening and closing valve 1 (4) and the on-off valve 3 (5) Drainage A valve 2 (3) is provided, and the upper surfaces of the compressor (6) and the tank (17) are connected to each other by piping via an on-off valve 4 (9) and an on-off valve 5 (12). 9) and the open / close valve 5 (12) communicate with the air tank 1 (10) for storing compressed air through a pipe, and the primary compressed air compressed by the compressor (6) passes through the open / close valve 4 (9). The air compressed in the air tank 1 (10) is introduced into the tank (17) from the air tank 1 (10) through the on-off valve 5 (12), while the compressor (6 ) And the upper surface of the tank (17) via the on-off valve 6 (11) and the on-off valve 7 (13). Ties in the pipe Te, the on-off valve 6 (11) and the pipe between the on-off valve 7 (13) communicates with the tube with the air tank 2 (21) to accumulate the compressed air, the air tank 1 (10) The primary compressed air stored in the tank is introduced into the upper part of the compressor (6) through the on-off valve 4 (9), and then the primary compressed air introduced into the tank (17) and the water in the tank (17) are opened and closed. By being pumped to the compressor (6) by the drop h through the valve 3 (5), the primary compressed air introduced into the upper part of the compressor (6) is further compressed into secondary compressed air, and the compressor (6 ) To the air tank 2 (21) via the on-off valve 6 (11), on the other hand, a gas tank 3 (18) and a gas tank 4 (19) are provided to store the compressed gas, and the on-off valve 8 ( 14) through the gas tank 3 (18) and the on-off valve 9 (1 5) is connected to the gas tank 4 (19) through a pipe with the upper surface of the compressor (6), and the low-pressure gas stored in the gas tank 3 (18) passes through the on-off valve 8 (14). Te is compressed is sent to the upper part of the compressor (6), the compressed gas is accumulated in the compressor-off valve 9 (6) (15) through the gas tank 4 (19) Rutotomoni, opened and closed automatically controlled The valve 1 is opened, the air in the compressor is compressed by the water surface pressure, the on-off valve 4 is opened, and stored in the air tank 1. Next, the on-off valves 1 and 4 are closed, the drain valve 2 is opened, the water is discharged, the check valve is opened, air is sucked in, the drain valve 2 is closed again, and the on-off valves 1 and 4 are opened. Thus, the compressed air was repeatedly stored in the air tank 1, and the on-off valves 1, 5, 6, 7, 8, 9 and the drain valve 2 were closed, the on-off valve 3 was opened, and the air tank 1 was stored. Compressed air is introduced into the upper part of the compressor through the on-off valve 4, the on-off valve 4 is closed, the on-off valve 5 is opened, and compressed air is introduced from the air tank 1 to the upper part of the tank. The water pressure is further compressed, and the on-off valve 6 is opened and stored in the air tank 2. Then, the on-off valves 5 and 6 are closed, the compressed air in the upper part of the tank is released by the on-off valve 10, the on-off valve 4 is opened, the compressed air from the air tank 1 is again put into the upper part of the compressor, and the on-off valve 4 is closed again. 6 is opened, and compressed air having a pressure higher than that of the air tank 1 is repeatedly stored in the air tank 2 in this manner. The compressed air stored in the air tank 2 can be further compressed in the same manner. Furthermore, when gas is compressed, the on-off valves 1, 4 , 5 , 6 , 7 , 9, and the drain valve 2 are closed, the on-off valve 8 is opened, and the compressed gas stored in the gas tank 3 is placed in the upper part of the compressor. When the on-off valve 8 is closed, the on-off valve 7 is opened, and the compressed air stored in the air tank 2 is put into the upper part of the tank, the gas is compressed to the air pressure of the air tank 2 + the water pressure of the drop h, and the gas is passed through the on-off valve 9. Stored in tank 4. Then, the on-off valve 9 is closed and the on-off valve 5 is opened. The compressed air in the upper part of the tank is collected in the air tank 1, the on-off valve 5 is closed, the on-off valve 8 is opened, gas is again put in the upper part of the compressor, and the on-off valve 8 is closed. The on-off valve 7 is opened, and the compressed gas repeatedly stored in the gas tank 3 in this manner can be further compressed and stored in the gas tank 4.

To solve the second problem, the compressor described in claim 1 is used to provide a tank at a height of up to 1000 m, and a pressure-resistant pipe is connected between the tank and the compressor through the on-off valve 3, and the on-off valves 1, 2 , 5, 6, 7, 8.9 are closed, the on-off valve 3 is opened, the compressed air stored in the air tank 1 is put into the upper part of the compressor through the on-off valve 4, the on-off valve 4 is closed, and the on-off valve 5 is opened. When compressed air is introduced into the upper part of the tank from the air tank 1, the same-pressure air placed in the upper part of the compressor is further compressed by the water pressure of the drop h, and the opening / closing valve 6 is opened and stored in the air tank 2. Then, the on-off valves 5 and 6 are closed, the compressed air in the upper part of the tank is released by the on-off valve 10, the on-off valve 4 is opened, the compressed air from the air tank 1 is again put into the upper part of the compressor, and the on-off valve 4 is closed again. 5 and 6 are opened, and compressed air having a pressure higher than that of the air tank 1 is repeatedly stored in the air tank 2 in this manner. The compressed air stored in the air tank 2 can be further compressed in the same manner.

Further, as described above, the on-off valves 1, 2, 4, 5, 6, 7, and 9 shown in FIG.
, The compressed gas stored in the gas tank 3 is put into the upper part of the compressor, the on-off valve 8 is closed, the on-off valve 7 is opened, and the compressed air from the air tank 2 is put into the upper part of the tank. The air pressure is compressed to a water pressure of a drop h and is stored in the gas tank 4 through the on-off valve 9.
Then, the on-off valve 9 is closed, the on-off valve 5 is opened, and the air at the top of the tank is collected in the air tank 1,
Close the on-off valve 5 and open the on-off valve 8 and refill the top of the compressor with gas.
Is closed, the on-off valve 7 is opened, and the compressed gas thus stored in the gas tank 3 can be further compressed and stored in the gas tank 4.

With the spread of this technology, renewable natural energy can be recovered, and water disasters caused by torrential rain can be mitigated and prevented. The stored compressed air can be used in urban areas where disaster prevention and air pressure are used, and it can be useful for the realization of a low-carbon society by actively using pneumatic energy such as water supply to areas with little water. .

There is a need for the safety of the air that is packed in respiratory cylinders. In response to this, the present invention can obtain 100% compressed air with low cost and safety.

Since no foreign matter such as lubricating oil is used, 100% purity gas can be compressed at low cost.

Represents a method for recovering renewable natural energy by converting the potential energy of rainwater and snow melt water into high pressure. This represents a mechanism that can compress 100% pure gas at low cost. Overall view of the present invention

Explanation of symbols

1 Water tank installed at high place 2 Water distribution pipe 3 Drain valve 2
6 Compressor body 7 Check valve 8 for sucking into the atmosphere 8 Compressed air piping 10 Compressed air storage tank 1 for primary compression
17 gas tank 3 installed in 17 high places
19 gas tank 4
20 pressure-resistant piping 21 secondary compressed air storage air tank 2
h Liquid drop

Claims (1)

A compressor (6) consisting of a sealed container that compresses gas with water surface pressure equipped with a check valve (7) for sucking air into the upper surface, and rainwater and snow melt water at a height of 5000 m from this compressor (6) A water storage tank (1) is provided, and a tank (17) having an on- off valve 10 (16) for releasing compressed air to the atmosphere is provided on the upper surface up to 1000 m, and the compressor (6 ) And the lower surface of the water storage tank (1) are pumped with rainwater or snow-melted water from the water storage tank ( 1) to the compressor (6) via the on-off valve 1 (4). In order to compress, the water pipe (2) communicates, and the water pipe (2) between the lower surface of the compressor (6) and the on-off valve 1 (4) is connected to the tank (17) via the on-off valve 3 (5 ). Water is pumped to the compressor (6) and the compressor (6 ) To further compress the compressed air in the pipe , the pressure-resistant pipe (20) communicates with the lower surface of the tank (17), and a drain valve 2 (in the pipe between the on-off valve 1 (4) and the on-off valve 3 (5) 3), and the upper surfaces of the compressor (6) and the tank (17) are connected to each other by piping via the on-off valve 4 (9) and the on-off valve 5 (12), and the on-off valve 4 (9) The pipe between the on-off valve 5 (12) communicates with the air tank 1 (10) for storing compressed air through a pipe, and the primary compressed air compressed by the compressor (6) is supplied to the air through the on-off valve 4 (9). While being stored in the tank 1 (10), the primary compressed air is introduced from the air tank 1 (10) into the tank (17) via the on-off valve 5 (12), while the compressor (6) and the tank Each upper surface of (17) is connected by piping through on-off valve 6 (11) and on-off valve 7 (13). Rising, communicates with a pipe air tank 2 (21) to accumulate the compressed air in the piping between the on-off valve 6 (11) and the on-off valve 7 (13), are accumulated in the air tank 1 (10) The primary compressed air is introduced into the upper portion of the compressor (6) through the on-off valve 4 (9), and then the primary compressed air introduced into the tank (17) and the water in the tank (17) are supplied to the on-off valve 3 ( 5), the primary compressed air introduced into the upper part of the compressor (6) is further compressed into secondary compressed air by being sent to the compressor (6) by the drop h through 5), and is opened and closed from the compressor (6). The gas tank 3 (18) and the gas tank 4 (19) are provided to store the compressed gas in the air tank 2 (21) through the valve 6 (11) , and the on-off valve 8 (14) is provided. Via the gas tank 3 (18) and also via the on-off valve 9 (15) The gas tank 4 (19) Te, communicates with the upper surface and the tube of each of the compressor (6), a compressor low pressure gas being貯存to the gas tank 3 (18) via an on-off valve 8 (14) (6 ) is sent to the top of the compression, the compressed gas is accumulated in the compressor (gas tank through the opening and closing valve 9 (15) 6) 4 (19) Rutotomoni, the air tank 1 (10) In order to store compressed gas in the air tank 2 (21), the gas tank 3 (18), and the gas tank 4 (19), the on-off valve 1 (4), the on- off valve 3 (5) to all the on-off valves 10 (16) An automatic eco-compressor characterized by controlling the drain valve 2 (3) and the check valve (7).