1. Field of the Invention
The present invention relates generally to oxygenated water, particularly to a method and an apparatus of making high-oxygenated water.
2. Description of the Related Art
Water is the basic element of life. Good water is helpful to metabolism. The high-oxygenated water sold in the market is simply made by dissolving oxygen in water. Oxygen will go into body when one drinks such water and be directly absorbed by tissue that may have a growth stimulatory effect on normal cells and keep you away from illnesses.
A conventional method of making high-oxygenated water is compressing pure oxygen in water and wait for oxygen dissolution process. At the same time, some gases (such as nitrogen and carbon dioxide) which are already dissolved in the water will escape and mix in the pure oxygen. Therefore, operator has to exhaust all the gas out, pump new pure oxygen in, and wait for oxygen dissolution process. It has to repeat above steps for several times to obtain the high-oxygenated water.
In the conventional method of making high-oxygenated water, the usage rate of oxygen is very low (only about 10%) so that the manufacture has to provide a huge oxygen tank to reduce the repeating times for dissolving oxygen. However, it is afforded for a mass production, and not for personal use. Besides, it takes a long time to wait for oxygen dissolution process and is not efficient enough.
The primary objective of the present invention is to provide a method and an apparatus of making high-oxygenated water, which has a high usage rate of oxygen and a short time of manufacture.
According to the objective of the present invention, an apparatus of making high-oxygenated water includes an oxygen supply, an exchange tank, and a pressure tank. The oxygen supply respectively supplies the exchange tank and the pressure tank with pure oxygen. The pure oxygen is dissolved in water in the exchange tank in a normal pressure environment to obtain oxygenated water. The oxygenated water is drained to the pressure tank, and then the pure oxygen is dissolved in the oxygenated water in the exchange tank in a high pressure environment to obtain high-oxygenated water.
In an embodiment, the exchange tank has a first water inlet and an air outlet at a top thereof and a first water outlet and a first air inlet at a bottom thereof. The pressure tank has a second water inlet at a top thereof and a second water outlet and a second air inlet at a bottom thereof. The oxygen supply respectively connects to the first air inlet of the exchange tank and the second air inlet of the pressure tank. The first water outlet of the exchange tank connects to the second water inlet of the pressure tank.
A method of making high-oxygenated water includes the following steps:
a) Supply an exchange tank with water via a top of the exchange tank.
b) Supply the exchange tank with pure oxygen via a bottom of the exchange tank for dissolving the pure oxygen in the water in a normal pressure environment to obtain oxygenated water.
c) Drain the oxygenated water to a pressure tank; and
d) Supply the pressure tank with pure oxygen via a bottom of the pressure tank for dissolving the pure oxygen in the oxygenated water in a high pressure environment to obtain high-oxygenated water.
Therefore, it will speed up the oxygen dissolution process and raise the dissolved oxygen in the high pressure environment.
As shown in
The oxygen supply is an oxygen cylinder 10 to supply pure oxygen.
The first oxygen dissolving device includes an exchange tank 12 and a slow-down unit.
The exchange tank 12 has a first water inlet 12a and an air outlet 12b at a top thereof, and has a first water outlet 12c and a first air inlet 12d at a bottom thereof. A water source W is connected to the first water inlet 12a to supply the exchange tank 12 water. The oxygen cylinder 10 is connected to the first air inlet 12d to supply the exchange tank 12 with pure oxygen.
As shown in
The second oxygen dissolving device includes a pressure tank 16. The pressure tank 16 has a second water inlet 16a and an air outlet 16b at a top thereof, and has a second water outlet 16c and a second air inlet 16d at a bottom thereof. The second water inlet 16a is connected to the first water outlet 12c of the exchange tank 12 through a hose. The compressor has a motor 18 to drain the oxygenated water in the exchange tank 12 to the pressure tank 16 through the hose. The oxygen cylinder 10 is connected to the second air inlet 16d to supply the pressure tank 16 with pure oxygen and create a high pressure environment in the pressure tank 16. In the pressure tank 16 the oxygen will be dissolved in the oxygenated water again to increase the dissolved oxygen in the water. A faucet 20 is connected to the second water outlet 16c of the.
The water source W supplies the exchange tank 12 and the pressure tank 16 with water before the apparatus 1 is running. The preferable water is drinking water, such as water processed by reverse osmosis. When the apparatus 1 is running, water and pure oxygen are supplied to the apparatus 1 at the same time, or water first, or pure oxygen first.
The water source W supplies the exchange tank 12 with water through the first water inlet 12a. At the same time, oxygen cylinder 10 supplies the pressure tank 16 with pure oxygen through the second air inlet 16d, and then the pure oxygen go out of the pressure tank 16 via the air outlet 16b and go to the exchange tank 12 via the first air inlet 12d. Oxygen keeps going through the continuous S-shaped passageway in the exchange tank 12 and stays in the dissolving rooms 14a to be dissolved in the oxygenated water to obtain oxygenated water. The oxygenated water may come out of the exchange tank 12 through the first water outlet 12c.
The undissolved oxygen and other gases, which are already dissolved in the water, including nitrogen, carbon dioxide and hydrogen, will go out of the exchange tank 12 through the air outlet 12b. Therefore, the pressure in the exchange tank 12 is about one atmosphere (1 atm), and the dissolved oxygen of the oxygenated water coming out of the first water outlet 12c is about 9.07 ppm.
Next, the motor 18 drains the oxygenated water coming out of the exchange tank 12 through the first water outlet 12c, and then sends it to the pressure tank 16 via the second water inlet 16a. Oxygen in the pressure tank 16 is dissolved in the oxygenated water in a high pressure environment (about 11 atms) so that oxygen is dissolved into the oxygenated water continuously. Therefore, the dissolved oxygen of the water coming out of the faucet 20 will be 99.77 ppm, and that is high-oxygenated water.
It is noted that the gas coming out of the air outlet 12b of the exchange tank 12 may be provided to the water source W while the water in the water source W is drinking water. Therefore, the water supplied to the exchange tank 12 to the pressure tank 16 already has dissolved oxygen.
The advantages of the present invention include:
1. Water enters the tanks 12, 16 from the tops thereof, and oxygen enters the tanks 12, 16 from the bottoms thereof so that it may be shorten the time for oxygen dissolution process to obtain high-oxygenated water.
2. Before the oxygen escape, it goes through the pressure tank 16 and the exchange tank 12 in sequence to be dissolved in water. The usage rate of oxygen will be over 90% in the present invention.
3. Because of the high usage rate of oxygen the apparatus 1 of the present invention may be small enough to be operated in an ordinary house.
4. The slow-sown unit in the exchange tank 12 is helpful to the oxygen dissolution process because it provide the oxygen contacting with water for a long time that may obtain higher dissolved oxygen.
and through the pressure tank 16. It will have more oxygen in the exchange tank 12 to get more oxygen dissolved in the water.
The description above is a few preferred embodiments of the present invention and the equivalence of the present invention is still in the scope of claim construction of the present invention.