CN1177569A - Method for production of oxygen-rich gases with multiple kinds of concentration and apparatus thereof - Google Patents
Method for production of oxygen-rich gases with multiple kinds of concentration and apparatus thereof Download PDFInfo
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- CN1177569A CN1177569A CN 97102768 CN97102768A CN1177569A CN 1177569 A CN1177569 A CN 1177569A CN 97102768 CN97102768 CN 97102768 CN 97102768 A CN97102768 A CN 97102768A CN 1177569 A CN1177569 A CN 1177569A
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- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 title claims abstract description 98
- 239000001301 oxygen Substances 0.000 title claims abstract description 98
- 229910052760 oxygen Inorganic materials 0.000 title claims abstract description 98
- 238000004519 manufacturing process Methods 0.000 title claims abstract description 16
- 239000007789 gas Substances 0.000 title claims description 45
- 238000001179 sorption measurement Methods 0.000 claims description 219
- 238000000034 method Methods 0.000 claims description 43
- 239000002808 molecular sieve Substances 0.000 claims description 37
- URGAHOPLAPQHLN-UHFFFAOYSA-N sodium aluminosilicate Chemical compound [Na+].[Al+3].[O-][Si]([O-])=O.[O-][Si]([O-])=O URGAHOPLAPQHLN-UHFFFAOYSA-N 0.000 claims description 37
- 238000003795 desorption Methods 0.000 claims description 26
- 238000010521 absorption reaction Methods 0.000 claims description 22
- 238000003825 pressing Methods 0.000 claims description 20
- 238000010926 purge Methods 0.000 claims description 19
- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 claims description 18
- 229910052757 nitrogen Inorganic materials 0.000 claims description 9
- 230000000694 effects Effects 0.000 description 3
- 229910021536 Zeolite Inorganic materials 0.000 description 2
- HNPSIPDUKPIQMN-UHFFFAOYSA-N dioxosilane;oxo(oxoalumanyloxy)alumane Chemical compound O=[Si]=O.O=[Al]O[Al]=O HNPSIPDUKPIQMN-UHFFFAOYSA-N 0.000 description 2
- 238000005516 engineering process Methods 0.000 description 2
- 238000002955 isolation Methods 0.000 description 2
- 238000011084 recovery Methods 0.000 description 2
- 239000010457 zeolite Substances 0.000 description 2
- 238000010586 diagram Methods 0.000 description 1
- 238000002474 experimental method Methods 0.000 description 1
- 239000003607 modifier Substances 0.000 description 1
- 238000006213 oxygenation reaction Methods 0.000 description 1
- 239000002994 raw material Substances 0.000 description 1
- 238000000926 separation method Methods 0.000 description 1
- 230000009466 transformation Effects 0.000 description 1
- 239000002699 waste material Substances 0.000 description 1
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Abstract
The present invention relates to a method for producing oxygen-enriched air with different concentrations and its equipment. Said invented equipment includes air storage tank, two adsorbing columns and product air storage tank. Said air storage tank is respectively connected with two adsorbing columns via inlet valves, and the exhaust valves of two adsorbing columns are connected to atmosphere. Said two adsorbing columns are respectively connected with the product air storage tank after they are communicated mutually via outlet valves and flow-limiting valves, and the lower ends of two outlet valves are parallel-connected with equalizing valves. Its keyboard is respectively connected with every valve by means of one-chip computer and every relay to control opening and closing order of all valves and their opening and closing time to obtin various combinations with different oxygen concentrations. Besides, it can use the keyboard to select the required parameter program to output the...
Description
The present invention relates to the air is raw material, by the method and the device of pressure change absorption production oxygen rich air.
The oxygen rich gas current demand is very big, as make the gas of combustion-supporting usefulness at industrial sector, cultures oxygenation, and medical department is used for oxygen uptake.They all are to utilize zeolite molecular sieve that the mixed gas that mainly contains nitrogen and oxygen is carried out the transformation adsorption treatment, can realize separating to the oxygen in the mixed gas, nitrogen, prepare purity and reach 90 ± 3% oxygen rich air.
In the prior art field, the existing method of oxygen rich air and the oxygen rich air that device can only be exported a kind of oxygen concn of preparing, just can reach the oxygen rich air of higher concentration, but in actual applications, sometimes need the oxygen rich air of low concentration, in order to reach this purpose, U.S. Pat 4822384 once used pressurized air to sneak into the oxygen concn of oxygen rich air with the reduction oxygen rich air, but influenced output flow this moment.Therefore, this patent has been used complicated means such as flow control, has increased many additional valves and can export 40% and 90% two kind of oxygen concn to reach.
The objective of the invention is: adopt Single Chip Microcomputer (SCM) program control to realize the multiple combination of valve operation, thereby produce the method for multiple concentration oxygen rich air, can solve the problem that exists in the background technology by air.
To achieve the above object of the invention, the technical solution adopted in the present invention is: it comprises the compressed air reservoir that contains aerobic, nitrogen, and two adsorption columns of the molecular sieve of selective adsorption nitrogen are housed, a product gas gas-holder.Each valve all is in closing condition before the work, the opening and closing time of adopting Single Chip Microcomputer (SCM) program control to realize each valve.When pressurized air enters from the intake valve of compressed air reservoir by first adsorption column, the pressure of adsorption column is raise, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder from the air outlet valve of adsorption column, second adsorption column is then opened vent valve in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, behind first adsorption column pressurization absorption and the second adsorption column desorb certain hour, close the intake valve of first adsorption column, air outlet valve, close the vent valve of second adsorption column and open equalizing valve, make the part oxygen rich air in first adsorption column carry out supercharging to second adsorption column, realize all pressing until two adsorption columns, all after the end of pressure time, close equalizing valve.When pressurized air enters from the intake valve of compressed air reservoir by second adsorption column, the pressure of adsorption column is raise, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder from the air outlet valve of adsorption column, first adsorption column is then opened vent valve in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, behind second adsorption column pressurization absorption and the first adsorption column desorb certain hour, close the intake valve of second adsorption column, air outlet valve, close the vent valve of first adsorption column, open equalizing valve, make the part oxygen rich air in second adsorption column carry out supercharging, realize all pressing until two adsorption columns to first adsorption column, all after the end of pressure time, close equalizing valve, go round and begin again, can obtain oxygen rich air.
The device of producing multiple concentration oxygen rich air is: it comprises the air gas-holder, two adsorption columns of the molecular sieve of selective adsorption nitrogen is housed, product gas gas-holder.The air gas-holder is communicated with first adsorption column and second adsorption column through intake valve respectively, the vent valve of the vent valve of first adsorption column and second adsorption column leads to atmosphere, first adsorption column is through air outlet valve, flow-limiting valve and second adsorption column product gas gas-holder of practicing midwifery after another air outlet valve, another flow-limiting valve are communicated with, two air outlet valve lower end parallel connection equalizing valves, and keyboard is through the micro-chip control parts, through rly. separately, connect intake valve respectively, vent valve, air outlet valve, equalizing valve is controlled the break-make of each valve.
Find out that from above-mentioned control process the opening time of each valve must be done accurate control with micro-chip, with the automatic control of implementation procedure.When adsorption column pressurization absorption, the opening time of intake valve and air outlet valve can have very big influence to the oxygen concn in the product gas.Time as intake valve open is oversize, then because molecular sieve adsorption reaches capacity, nitrogen is overflowed from outlet, as air outlet valve Kai Detai early, does not reach optimal separation pressure during adsorption column absorption, can make the separating effect variation.Pressure equalizing also is very important in addition, can improve on the one hand the rate of recovery of oxygen, a part of oxygen rich air is imported into before the desorb emptying in another adsorption column and is fully utilized; Pressure equalizing can make the adsorption column of firm desorb arrive first a higher pressure when absorption operation beginning on the other hand, thereby make molecular sieve that stronger separating effect (promptly being in higher operating pressure) be arranged in back to back adsorption process, certainly all press the time oversize, then can pollute the adsorption column of desorb, thereby influence next step adsorption process.Another will utilize oxygen rich air to the reverse purge of the adsorption column of desorb to the reverse purge process of the adsorption column of desorb sometimes, can make the abundant desorb of molecular sieve, but purge exaggerates, and then will waste a large amount of product gas, and the rate of recovery is reduced.The open-interval of each valve sooner or later and the length of switching time has bigger influence to the productive rate and the concentration of product gas in a word.Organize the unlatching of each valve effectively, realize preferable combining and configuring, then can realize adjusting, to adapt to different needs the oxygen concn of product gas.
The present invention compares with background technology, the useful effect that is had is: it is by the precedence and the switching time thereof of each valve switch of Single Chip Microcomputer (SCM) program Controlling System, can obtain a large amount of combinations, determine the oxygen concn value that each combination is corresponding by experiment, with its parameter write-in program, can select to export oxygen rich air on demand by keyboard.This is simple and compact for structure, easy to operate, can produce the oxygen rich air of different oxygen concentrations, to satisfy the needs of different departments.
The synoptic diagram of Fig. 1, structure of the present invention;
Fig. 2, principle of keyboard design figure of the present invention;
One of Fig. 3, technological process of production figure of the present invention;
Two of Fig. 4, technological process of production figure of the present invention;
Three of Fig. 5, technological process of production figure of the present invention.
In order to understand the present invention better, by description, provide details of the present invention to embodiment below in conjunction with accompanying drawing.
As shown in Figure 1, air gas-holder D is communicated with adsorption column A and adsorption column B through intake valve 1,3 respectively, the vent valve 2 of adsorption column A and the vent valve of adsorption column B 4 logical atmosphere, adsorption column A is through air outlet valve 5, flow-limiting valve 8 and the adsorption column B product gas gas-holder C that practices midwifery after air outlet valve 6, flow-limiting valve 9 is communicated with, air outlet valve 5,6 lower ends equalizing valve 7 in parallel, keyboard F is through micro-chip control parts E, rly. separately taps into air valve 1,3 respectively, vent valve 2,4, air outlet valve 5,6, equalizing valve 7 is controlled the break-make of each valve.
At internal diameter Φ 120mm, implement on two adsorption column devices of long 250mm, on two adsorption columns the 2kg zeolite molecular sieve is housed respectively.Following three kinds of embodiment are arranged:
Embodiment 1: as shown in Figure 1, when pressurized air enters by the intake valve 1 of adsorption column A from compressed air reservoir D, the pressure of adsorption column A is raise, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder C from the air outlet valve 5 of adsorption column A, adsorption column B then opens vent valve 4 in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, behind adsorption column A pressurization absorption and adsorption column B desorb certain hour, shut-off valve 1,4,5, open equalizing valve 7, make the part oxygen rich air among the adsorption column A carry out supercharging to adsorption column B, realize all pressing until two adsorption columns, all after the end of pressure time, close equalizing valve 7; When pressurized air enters by the intake valve 3 of adsorption column B from compressed air reservoir D, the pressure of adsorption column B is raise, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder C from the air outlet valve 6 of adsorption column B, adsorption column A then opens vent valve 2 in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, behind adsorption column B pressurization absorption and adsorption column A desorb certain hour, shut-off valve 2,3,6, open equalizing valve 7, make the part oxygen rich air among the adsorption column B carry out supercharging to adsorption column A, realize all pressing until two adsorption columns, all after the end of pressure time, close equalizing valve 7, go round and begin again, can obtain oxygen rich air.
When the oxygen concn content of production oxygen rich air was 45 ± 3%, as shown in Figure 3, air gas-holder output pressure was 3kg/cm
2, adsorption column goes out atmospheric pressure and is 2.4kg/cm to the maximum
2, its technical process is:
The first step: open valve 1,4,5 and carry out adsorption and desorption, the time is 20 seconds;
Second step: shut-off valve 1,4,5, to open equalizing valve 7 and all press, the time is 3 seconds;
The 3rd step: open valve 2,3,6 and carry out adsorption and desorption, the time is 20 seconds;
The 4th step: shut-off valve 2,3,6, to open equalizing valve 7 and all press, the time is 3 seconds.
Embodiment 2: as shown in Figure 1, when pressurized air enters by the intake valve 1 of adsorption column A from compressed air reservoir D, the pressure of adsorption column A is raise, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder C from the air outlet valve [5] of adsorption column A, adsorption column B then opens vent valve 4 in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, in the opportune moment of emptying, air outlet valve 6 is opened, utilized the part oxygen rich air that the adsorption column B in the desorb is carried out reverse purge, behind adsorption column A pressurization absorption and adsorption column B desorb certain hour, shut-off valve 1,4,5,6, open equalizing valve 7, make the part oxygen rich air among the adsorption column A carry out supercharging, realize all pressing until two adsorption columns to adsorption column B, all after the end of pressure time, close equalizing valve 7; When pressurized air enters by the intake valve 3 of adsorption column B from compressed air reservoir D, the pressure of adsorption column B is raise, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder C from the air outlet valve 6 of adsorption column B, adsorption column A opens vent valve 2 in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, in the opportune moment of emptying, air outlet valve 5 is opened, utilize the part oxygen rich air that the adsorption column A in the desorb is carried out reverse purge, behind adsorption column B pressurization absorption and adsorption column A desorb certain hour, shut-off valve 2,3,5,6, opening equalizing valve 7 makes the part oxygen rich air among the adsorption column B carry out supercharging to adsorption column A, realize all pressing until two adsorption columns, all after the end of pressure time, close equalizing valve 7, go round and begin again, can obtain oxygen rich air.
When the oxygen concn content 75 ± 3% of production oxygen rich air, as shown in Figure 4, air gas-holder output pressure is 3kg/cm
2, adsorption column goes out atmospheric pressure and is 2.3kg/cm to the maximum
2, its technical process is:
The first step: open valve 1,4,5 and carry out adsorption and desorption, the time is 8 seconds;
Second step: open air outlet valve 6, carry out reverse purge, the time is 7 seconds;
The 3rd step: shut-off valve 1,4,5,6, to open equalizing valve 7 and all press, the time is 2.5 seconds;
The 4th step: close equalizing valve 7, open valve 2,3,6 and carry out adsorption and desorption, the time is 8 seconds;
The 5th step: open air outlet valve 5, carry out reverse purge, the time is 7 seconds;
The 6th step: close 2,3,5,6, open equalizing valve door 7 and all press, the time is 2.5 seconds.
Embodiment 3: as shown in Figure 1, when air gas-holder D enters by the intake valve 1 of adsorption column A, the valve 4 of opening adsorption column B makes its emptying, the pressure of adsorption column A raises, after the selective adsorption by molecular sieve, the pressurization certain hour, oxygen rich air is transported to product gas gas-holder C from the air outlet valve 5 of adsorption column A, adsorption column B then makes the gas that is adsorbed in the molecular sieve be drained in desorption process simultaneously, in the opportune moment of emptying, air outlet valve 6 is opened, utilize the part oxygen rich air that the adsorption column B in the desorb is carried out reverse purge, behind adsorption column A pressurization absorption and adsorption column B desorb certain hour, shut-off valve 1,4,5,6, open equalizing valve 7 and make the part oxygen rich air among the adsorption column A carry out supercharging adsorption column B, realize all pressing until two adsorption columns, all after the end of pressure time, close equalizing valve 7; When pressurized air enters by the intake valve 3 of adsorption column B from compressed air reservoir D, the valve 4 of opening adsorption column A makes its emptying, the pressure of adsorption column B raises, selection by molecular sieve is adsorbed behind certain hour, oxygen rich air is transported to product gas gas-holder C from the air outlet valve 6 of adsorption column B, adsorption column A then makes the gas that is adsorbed in the molecular sieve be drained in desorption process simultaneously, in the opportune moment of emptying, air outlet valve 5 is opened, utilized the part oxygen rich air that the adsorption column A in the desorb is carried out reverse purge, behind adsorption column B pressurization absorption and adsorption column A desorb certain hour, shut-off valve 2,3,5,6, open equalizing valve 7, make the part oxygen rich air among the adsorption column B carry out supercharging, realize all pressing until two adsorption columns to adsorption column A, all after the end of pressure time, close equalizing valve 7, go round and begin again, can obtain oxygen rich air.
When the oxygen concn content 90 ± 3% of production oxygen rich air, as shown in Figure 5, air gas-holder output pressure is 3kg/cm
2, adsorption column goes out atmospheric pressure and is 2.2kg/cm to the maximum
2, its technical process is:
The first step: open valve 1,4, this moment adsorption column A absorption and supercharging, adsorption column B desorb, the time is 3 seconds;
Second step: open valve 1,4,5,6 and carry out adsorption and desorption, reverse purge, the time is 12 seconds;
The 3rd step: shut-off valve 1,4,5,6, to open equalizing valve 7 and all press, the time is 2.5 seconds;
The 4th step: open valve 2,3, this moment adsorption column B absorption and supercharging, adsorption column A desorb, the time is 3 seconds;
The 5th step: open valve 2,3,5,6 and carry out adsorption and desorption, reverse purge, the time is 12 seconds;
The 6th step: close 2,3,5,6, open equalizing valve 7 and all press, the time is 2.5 seconds.
Find out from above three embodiment, adopt the method for Single Chip Microcomputer (SCM) program control, under the situation of modifier not, realize the multiple combination of valve operation, thereby make the finished product oxygen rich air concentration of output adjustable.Being programmed to several groups of relatively independent programsegments, each programsegment is corresponding to corresponding valve operation combination.Be illustrated in figure 2 as principle of keyboard design figure of the present invention, with button ground connection after the end parallel connection of K1, K2, K3, K4, K5, its the other end is respectively with forward diode D1, oppositely diode D2, forward diode D3, oppositely diode D4 parallel connection, wherein in parallel behind button K1, K3, K5 difference series resistance R1, R2, the R3, connect power Vcc, three pins of P3.0, P3.1, P3.2 in the 8031 micro-chip P3 mouths are connected to the common port of resistance R 1 and button K1, resistance R 2 and button K3, resistance R 3 and button K5 respectively.It utilizes the unidirectional conduction of diode, realizes the isolation and the connection of line, with the purpose of the multinomial selection that realizes three pins.Promptly when pressing key K1, the P3.0 pin is a lower level, because the reverse isolation of D1, make P3.1 not become high level, when pressing key K2, because the conducting of D1, D2, making P3.0, P3.1 is lower level, because D3 is in oppositely, makes P3.2 not become high level, when pressing key K3, because D2, D3 are in oppositely, have only P3.1 to become lower level, other are constant, such and the like.
It is K1, K2, K3, K4, K5 that this keyboard has five buttons, and when button was motionless, the state of three pin all was that high level (value 1) is (1,1,1), when pressing key K1, K2 respectively ... during K5, corresponding state is respectively (0,1,1), (0,0,1), (1,0,1), (1,0,0) (1,1,0), therefore can be according to the difference (promptly pressing different keys) of input aperture signal, the program run that makes micro-chip is in different programsegments, thereby reaches the purpose of by-pass valve control operation, finally obtains the oxygen rich air of needed oxygen concn.Its oxygen concentration is by pressing key control, when button is motionless, will keep (1,1,1) state, program will keep former running status constant, in case press new button, this state is promptly remembered in inside, (there is not new signal when finishing Deng a last working procedure section, it is with infinite loop), promptly enter new running status, thereby can obtain the gas of new oxygen level.So as long as click button simply, can change at any time, very convenient, be applicable to multiple application.
Claims (8)
1. method of producing multiple concentration oxygen rich air, it comprises and contains aerobic, the compressed air reservoir of nitrogen, two adsorption columns of the molecular sieve of selective adsorption nitrogen are housed, a product gas gas-holder, it is characterized in that steps of the method are: each valve all is in closing condition before the work, the opening and closing time of adopting Single Chip Microcomputer (SCM) program control to realize each valve, when pressurized air enters from the intake valve [1] of compressed air reservoir [D] by adsorption column [A], the pressure of adsorption column [A] is raise, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder [C] from the air outlet valve [5] of adsorption column [A], adsorption column [B] is then opened vent valve [4] in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, behind adsorption column [A] pressurization absorption and adsorption column [B] desorb certain hour, shut-off valve [1], [4], [5], open equalizing valve [7], make the part oxygen rich air in the adsorption column [A] carry out supercharging to adsorption column [B], realize all pressing until two adsorption columns, all after the end of pressure time, close equalizing valve [7]; When pressurized air enters from the intake valve [3] of compressed air reservoir [D] by adsorption column [B], make the pressure of adsorption column [B] be elevated to certain value, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder [C] from the air outlet valve [6] of adsorption column [B], adsorption column [A] is then opened vent valve [2] in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, behind adsorption column [B] pressurization absorption and adsorption column [A] desorb certain hour, shut-off valve [2], [3], [6], open equalizing valve [7], make the part oxygen rich air in the adsorption column [B] carry out supercharging to adsorption column [A], realize all pressing until two adsorption columns, all after the end of pressure time, close equalizing valve [7], go round and begin again, can obtain oxygen rich air.
2. the method by air production oxygen rich air according to claim 1 is characterized in that: air gas-holder [D] output pressure is 3kg/cm
2, adsorption column goes out atmospheric pressure and is 2.4kg/cm to the maximum
2, technical process is:
1) open valve [1], [4], [5] and carry out adsorption and desorption, the time is 20 seconds;
2) shut-off valve [1], [4], [5] are opened equalizing valve [7] and are all pressed, and the time is 3 seconds;
3) open valve [2], [3], [6] and carry out adsorption and desorption, the time is 20 seconds;
4) shut-off valve [2], [3], [6] are opened equalizing valve [7] and are all pressed, and the time is 3 seconds; The oxygen concn that can obtain oxygen rich air is 45 ± 3%.
3. the method by air production oxygen rich air according to claim 1, it is characterized in that steps of the method are: when pressurized air enters from the intake valve [1] of compressed air reservoir [D] by adsorption column [A], the pressure of adsorption column [A] is raise, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder [C] from the air outlet valve [5] of adsorption column [A], adsorption column [B] is then opened vent valve [4] in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, in the opportune moment of emptying, air outlet valve [6] is opened, utilize the part oxygen rich air that the adsorption column in the desorb [B] is carried out reverse purge, behind adsorption column [A] pressurization absorption and adsorption column [B] desorb certain hour, shut-off valve [1], [4], [5], [6], open equalizing valve [7], make the part oxygen rich air in the adsorption column [A] carry out supercharging, realize all pressing until two adsorption columns to adsorption column [B], all after the end of pressure time, close equalizing valve [7]; When pressurized air enters from the intake valve [3] of compressed air reservoir [D] by adsorption column [B], the pressure of adsorption column [B] is raise, after the selective adsorption by molecular sieve, oxygen rich air is transported to product gas gas-holder [C] from the air outlet valve [6] of adsorption column [B], adsorption column [A] is opened vent valve [2] in desorption process simultaneously, the gas that is adsorbed in the molecular sieve is drained, in the opportune moment of emptying, air outlet valve [5] is opened, utilize the part oxygen rich air that the adsorption column in the desorb [A] is carried out reverse purge, behind adsorption column [B] pressurization absorption and adsorption column [A] desorb certain hour, shut-off valve [2], [3], [5], [6], open equalizing valve [7], make the part oxygen rich air in the adsorption column [B] carry out supercharging, realize all pressing until two adsorption columns to adsorption column [A], all after the end of pressure time, close equalizing valve [7], go round and begin again, can obtain oxygen rich air.
4. the method by air production oxygen rich air according to claim 3 is characterized in that: air gas-holder [D] output pressure is 3kg/cm
2, adsorption column goes out atmospheric pressure and is 2.3kg/cm to the maximum
2, technical process is:
1) open valve [1], [4], [5] and carry out adsorption and desorption, the time is 8 seconds;
2) open air outlet valve [6], carry out reverse purge, the time is 7 seconds;
3) shut-off valve [1], [4], [5], [6] are opened equalizing valve [7] and are all pressed, and the time is 2.5 seconds;
4) close equalizing valve [7], open valve [2], [3], [6] and carry out adsorption and desorption, the time is 8 seconds;
5) open air outlet valve [5], carry out reverse purge, the time is 7 seconds;
6) close [2], [3], [5], [6], open equalizing valve door [7] and all press, the time is 2.5 seconds; The oxygen concn that can obtain oxygen rich air is 75 ± 3%.
5. the method by air production oxygen rich air according to claim 3, it is characterized in that steps of the method are: when pressurized air enters from the intake valve [1] of compressed air reservoir [D] by adsorption column [A], the valve [4] of opening adsorption column [B] makes its emptying, the pressure of adsorption column [A] raises, after the selective adsorption by molecular sieve, the pressurization certain hour, oxygen rich air is transported to product gas gas-holder [C] from the air outlet valve [5] of adsorption column [A], adsorption column [B] then makes the gas that is adsorbed in the molecular sieve be drained in desorption process simultaneously, in the opportune moment of emptying, air outlet valve [6] is opened, utilize the part oxygen rich air that the adsorption column in the desorb [B] is carried out reverse purge, behind adsorption column [A] pressurization absorption and adsorption column [B] desorb certain hour, shut-off valve [1], [4], [5], [6], open equalizing valve [7] and make the part oxygen rich air in the adsorption column [] carry out supercharging, realize all pressing until two adsorption columns to adsorption column [B], all after the end of pressure time, close equalizing valve [7]; When pressurized air enters from the intake valve [3] of compressed air reservoir [D] by adsorption column [B], the valve [4] of opening adsorption column [A] makes its emptying, the pressure of adsorption column [B] raises, selection by molecular sieve is adsorbed behind certain hour, oxygen rich air is transported to product gas gas-holder [C] from the air outlet valve [6] of adsorption column [B], adsorption column [A] then makes the gas that is adsorbed in the molecular sieve be drained in desorption process simultaneously, in the opportune moment of emptying, air outlet valve [5] is opened, utilize the part oxygen rich air that the adsorption column in the desorb [A] is carried out reverse purge, behind adsorption column [B] pressurization absorption and adsorption column [A] desorb certain hour, shut-off valve [2], [3], [5], [6], open equalizing valve [7], make the part oxygen rich air in the adsorption column [B] carry out supercharging, realize all pressing until two adsorption columns to adsorption column [A], all after the end of pressure time, close equalizing valve [7], go round and begin again, can obtain oxygen rich air.
6. the method by air production oxygen rich air according to claim 5 is characterized in that: air gas-holder [D] output pressure is 3kg/cm
2, adsorption column goes out atmospheric pressure and is 2.2kg/cm to the maximum
2, technical process is:
1) open valve [1], [4], adsorption column this moment [A] absorption and supercharging, adsorption column [B] desorb, the time is 3 seconds;
2) open valve [1], [4], [5], [6] and carry out adsorption and desorption, reverse purge, the time is 12 seconds;
3) shut-off valve [1], [4], [5], [6] are opened equalizing valve [7] and are all pressed, and the time is 2.5 seconds;
4) open valve [2], [3], adsorption column this moment [B] absorption and supercharging, adsorption column [A] desorb, the time is 3 seconds;
5) open valve [2], [3], [5], [6] and carry out adsorption and desorption, reverse purge, the time is 12 seconds;
6) close [2], [3], [5], [6], open equalizing valve door [7] and all press, the time is 2.5 seconds; The oxygen concn that can obtain oxygen rich air is 90 ± 3%.
7. the device of the multiple concentration oxygen rich air of production according to claim 1, it comprises the air gas-holder, two adsorption columns of the molecular sieve of selective adsorption nitrogen are housed, product gas gas-holder, it is characterized in that: air gas-holder [D] is respectively through intake valve [1], [3] be communicated with first adsorption column [A] and second adsorption column [B], the vent valve [2] of first adsorption column [A] and the vent valve [4] of second adsorption column [B] lead to atmosphere, first adsorption column [A] is through air outlet valve [5], flow-limiting valve [8] and second adsorption column [B] are through air outlet valve [6], the product gas gas-holder [C] of practicing midwifery after flow-limiting valve [9] is communicated with, two air outlet valves [5], [6] lower end equalizing valve [7] in parallel, keyboard [F] is through micro-chip control parts [E], tap into air valve [1] respectively through separately rly., [3], vent valve [2], [4], air outlet valve [5], [6], equalizing valve [7] is controlled the break-make of each valve.
8. the device of the multiple concentration oxygen rich air of production according to claim 7, it is characterized in that: the button on the keyboard [K1], [K2], [K3], [K4], ground connection after the one end parallel connection of [K5], its the other end is respectively with forward diode [D1], reverse diode [D2], forward diode [D3], oppositely diode [D4] parallel connection, button [K1] wherein, [K3], [K5] be series resistance [R1] respectively, [R2], [R3] back is in parallel, connect power Vcc, [P3.0] in 8031 micro-chips [P3] mouth, [P3.1], [P3.2] three pins are connected to resistance [R1] and button [K1], resistance [R2] and button [K3], the common port of resistance [R3] and button [K5].
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN97102768A CN1052701C (en) | 1997-04-08 | 1997-04-08 | Method for production of oxygen-rich gases with multiple kinds of concentration and apparatus thereof |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN97102768A CN1052701C (en) | 1997-04-08 | 1997-04-08 | Method for production of oxygen-rich gases with multiple kinds of concentration and apparatus thereof |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CN1177569A true CN1177569A (en) | 1998-04-01 |
| CN1052701C CN1052701C (en) | 2000-05-24 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN97102768A Expired - Fee Related CN1052701C (en) | 1997-04-08 | 1997-04-08 | Method for production of oxygen-rich gases with multiple kinds of concentration and apparatus thereof |
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| Country | Link |
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| CN (1) | CN1052701C (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102269979A (en) * | 2010-12-31 | 2011-12-07 | 北京谊安医疗系统股份有限公司 | Method and device for controlling gas circuit switching mechanism of oxygenator |
Family Cites Families (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP2562326B2 (en) * | 1987-08-07 | 1996-12-11 | 住友精化株式会社 | How to get high concentration oxygen from air |
| JP2683806B2 (en) * | 1988-03-17 | 1997-12-03 | 住友精化株式会社 | Concentrated oxygen recovery method |
| JP3654661B2 (en) * | 1994-06-02 | 2005-06-02 | 大陽日酸株式会社 | Oxygen generation method by pressure fluctuation adsorption separation method |
| JP3309197B2 (en) * | 1995-03-02 | 2002-07-29 | 住友精化株式会社 | Recovery method of concentrated oxygen |
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1997
- 1997-04-08 CN CN97102768A patent/CN1052701C/en not_active Expired - Fee Related
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102269979A (en) * | 2010-12-31 | 2011-12-07 | 北京谊安医疗系统股份有限公司 | Method and device for controlling gas circuit switching mechanism of oxygenator |
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| Publication number | Publication date |
|---|---|
| CN1052701C (en) | 2000-05-24 |
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