CN108187433A - A kind of zero gas consumption compressed air drier by afterheat regeneration - Google Patents
A kind of zero gas consumption compressed air drier by afterheat regeneration Download PDFInfo
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- CN108187433A CN108187433A CN201810133474.1A CN201810133474A CN108187433A CN 108187433 A CN108187433 A CN 108187433A CN 201810133474 A CN201810133474 A CN 201810133474A CN 108187433 A CN108187433 A CN 108187433A
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- B01D53/34—Chemical or biological purification of waste gases
- B01D53/74—General processes for purification of waste gases; Apparatus or devices specially adapted therefor
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- B01D2259/804—UV light
Abstract
The invention discloses a kind of zero gas consumption compressed air drier by afterheat regeneration, which includes compressed air inlet, ultraviolet catalyzed oil expeller, adsorption tower, thermoelectric converter, accumulator, heating controller, electric heater, external power supply, cooler A, gas-liquid separator A, cooler B, gas-liquid separator B, bag filter, drying compressed air outlet and 5 sets of shut-off valves.This system is different from existing compression heat regeneration absorption drier, its creative design, which has achieved, only needs 1 adsorption tower just can complete the dehydration and drying of compressed air for needing 2 adsorption towers that could complete originally and the regeneration overall process of adsorbent, has good drying process effect.This system also creativeness employs thermoelectric generation technology and ultraviolet catalytic decomposition technique, and extra heat can be converted to electric energy, greatly reduce system energy consumption by thermoelectric generation technology;And ultraviolet catalytic decomposition technique can efficiently remove mineral oil contained in air.
Description
Technical field
The present invention relates to a kind of zero gas consumption compressed air drier by afterheat regeneration.
Background technology
Compressed air is because having the characteristics that easily to store, easy to control, good fluidity and safe and environment-friendly, is only second to electric power
Second power source is widely used in many fields such as food, electric power, chemical industry, pharmacy, mining and machine-building.Application
Field is different, also different to the quality requirement of compressed air, but be unable to do without efficient, energy-saving and environmental protection themes always.
Air is after compressor compresses, so that it may obtain the compressed air with elevated pressures.But due to air compressor
Itself contains lubricating oil, when carrying out compression work, necessarily has parts of lubricating oil to be mixed into compressed air, in addition, natural
The air on boundary is in itself also containing some solid particles and moisture etc., and therefore, the compressed air generated by compressor is not pure
's.Directly pneumatic circuit can be made to break down using this air without purified treatment in pneumatic circuit, damage pneumatic group
Part, reduces component service life, and production efficiency declines or even causes the accident.According to statistics, the disorderly closedown of pneumatic system has 85%
It is due to the use of caused by compressed air that is unholiness, not drying above.To find out its cause, the moisture in compressed air can cause portion
Part corrosion, winter can condense icing, result in blockage;Oil gas condensation precipitate to be formed greasy dirt often result in sealing element aging, failure;Powder
Dirt then accelerates the abrasion of moving parts, and deposition results in blockage, and causes meaningless pressure loss etc..Therefore, these compressions are purified
Air is an essential important link in baric systerm to obtain pure compressed air.
Wherein, it is exactly moisture contained in compressed air maximum factor to be influenced on pneumatic system.Moisture is in surrounding air
In be widely present, can not remove, after this part water enters compressor compresses, due to the variation of temperature, pressure, will have cold completely
Condensate is precipitated, and seriously affects the operation of Compressor Group and the function life-span of other gas equipments, therefore remove the water in air
It is very necessary to divide.
Drying is opposite, that is, is considered as dry air in certain demand, is regarded as not in other purposes
Enough dryings.Therefore, compressed air needs the drying of which kind of degree, first when being design or selection drying machine which kind of demand met
The factor to be considered.Because selection does not need to the drying machine of too low dew point, buying and operating cost will be increased.According to above several
Different theoretical methods, the compressed air drying method developed and used at present mainly include following several:
(1)It is adsorbed by drying method:
Method is adsorbed by drying using adsorbent to the absorption property of moisture, such as silica gel, activated alumina and molecular sieve etc., they are to water
Dividing all has very strong adsorption capacity.The moisture absorption process of adsorbent is physical change, is reproducible, adsorbs under high pressure, low
Pressure desorption, i.e. pressure-variable adsorption(PSA);Also it can be adsorbed in normal pressure, when heating regenerates, i.e. temp.-changing adsorption(TSA);Or high pressure is normal
Temperature absorption, constant-pressure and high-temperature desorption(PTC).This kind of aridity being adsorbed by drying can reach -70 DEG C of dew points at normal pressure.
(2)Deliquescence seasoning:
Deliquescence formula drier is also with adsorbent to the characterization of adsorption of moisture, and only the adsorbent of deliquescence formula is in adsorption moisture
Afterwards, become liquid to discharge, the adsorbent after deliquescence cannot regenerate, and can cause environmental pollution.This method is also known as chemistry
Method.This kind of drier can reach -38 DEG C or so of dew point.
(3)Freeze-drying:
Freeze-drying is that the cold generated using refrigeration compressor cools down compressed air, and compressed air is made to reach its pressure
Dew-point temperature corresponding to power so as to which the moisture in compressed air is precipitated, reaches drying purpose.The aridity of this kind of seasoning
- 23 DEG C of dew points at normal pressure can be reached.
(4)UF membrane seasoning:
It is a kind of extremely promising drying mode that compressed air, which is dried, using membrane separation technique.Compressed air is by hollow
During fiber membrane, the osmotic pressure of each substance is different, water is made to be separated from compressed air, so as to reach drying effect.
Existing compressed air drying method generally existing operating cost is high, absorption material expends big, service life of equipment
The shortcomings of short, and its drying effect is also difficult to meet the higher and higher use gas requirement of equipment.For this reason, it may be necessary to find new method
This problem is solved with approach.
Invention content
In order to solve many deficiencies of the prior art, the present invention provides zero gas consumption residual heat regenerating compressed airs of one kind to do
Dry device, the system include compressed air inlet, ultraviolet catalyzed oil expeller, adsorption tower, thermoelectric converter, accumulator, heating
Controller, electric heater, external power supply, cooler A, gas-liquid separator A, cooler B, gas-liquid separator B, bag filter,
Drying compressed air exports and 5 sets of shut-off valves.Wherein, it after air enters this system by compressed air inlet, initially enters
Ultraviolet catalyzed oil expeller, the air path after its deoiling treatment are divided into A, B two-way, and the connection mode on A roads is:Air according to
It is secondary by shut-off valve A, thermoelectric converter, shutoff valve C, eventually enter into adsorption tower;The connection mode on B roads is:Air passes sequentially through
Shut-off valve B, cooler B, gas-liquid separator B, shut-off valve D, eventually enter into adsorption tower.Wherein, compressed air outlet gas flow path is one
Road, air pass sequentially through cooler A, gas-liquid separator A, bag filter, are finally exported and sent out by drying compressed air, conveying
To gas equipment.Wherein, gas-liquid separator A and gas-liquid separator B are respectively equipped with automatic drain valve and Manual draining valve.Its
In, the transport path of electric energy is:The electric energy that electric energy caused by thermoelectric converter and external power supply provide, is deposited into accumulator
Storage, and the electric heater inside adsorption tower is conveyed to after the regulation and control of heated controller.Wherein, outside ultraviolet catalyzed oil expeller
It covers for stainless steel, bottom and top are respectively equipped with air intake valve and drain tap, are internally provided with 1 ultraviolet light and occur
Device, and pass through 4 fixing brackets and be individually fixed in equipment quadrangle, ultraviolet light generator passes through two sections of connecting wires and device external
Electric control gear be connected, be enclosed with tungstic acid catalysis net on the outside of ultraviolet light generator.Compressed air containing mineral oil passes through
Air intake valve positioned at ultraviolet catalyzed oil expeller bottom enters inside equipment, air and three oxygen being fixed on inside reaction unit
Change tungsten catalysis net to be in contact, at this point, regulation and control of the ultraviolet light generator among tungstic acid catalysis net in electric control gear
Lower start-up operation, ultraviolet light is emitted into whole equipment, when under ultraviolet wavelength irradiation condition, the tungsten atom in tungstic acid
Meeting Ultraviolet radiation absorbing, low-lying level electrons are excited by light, and energy level transition occurs, while are generated accordingly on original cost band
Hole so as to generate a large amount of free radicals, and the mineral oil component exhaustive oxidation in air is cracked, and primary product is water vapour
And carbon dioxide, the compressed air after deoiling treatment is discharged through the drain tap at the top of equipment, into next treatment process.
The complete working period of this system is divided into following two stages:
(1)Adsorbent absorbs water the stage:In this stage, shut-off valve A and shutoff valve C are opening, and shut-off valve B and shut-off valve
D is in off state.This system is entered by compressed air inlet by air compressor compressed air, by ultraviolet catalyzed
After the deoiling treatment of oil expeller, thermoelectric converter is entered by the shut-off valve A of unlatching, air is herein converted to a part of heat
Electric energy, and be stored in accumulator.Air significant hypothermal after heat to electricity conversion enters absorption by the shutoff valve C of unlatching
Tower, at this time the electric heater in adsorption tower be in off state, dehydration of the air by the activated alumina adsorbents in adsorption tower
After effect, temperature and moisture are substantially reduced.Air after adsorption treatment escapes and enter cooler from adsorption tower
A is further cooled herein, and then into gas-liquid separator A, air is completed the separation of moisture, isolated herein
Waste liquid through automatic drain valve A drainage gas-liquid separators, be also manually operable Manual draining valve A when automatic drain valve A failures
Carry out urgent draining.By gas-liquid separation, treated that dry air enters bag filter, further removes various grain sizes
After dust impurities, discharge this system is exported by drying compressed air, being delivered to gas equipment supply by air pipe line uses.
When adsorbent absorbs water close to saturation, system is automatically into second stage, i.e. adsorbent dehydration regeneration stage.
(2)The adsorbent dehydration regeneration stage:In this stage, shut-off valve B and shut-off valve D are opening, and shut-off valve A
It is in off state with shutoff valve C.This system is entered by compressed air inlet by air compressor compressed air, by purple
After the deoiling treatment of outside line catalysis oil expeller, cooler B is entered by the shut-off valve B of unlatching, is tentatively cooled herein,
Then enter gas-liquid separator B, air completes the separation of partial moisture herein, and the waste liquid isolated is discharged through automatic drain valve B
Gas-liquid separator is also manually operable Manual draining valve B when automatic drain valve B failures and carries out urgent draining.By gas-liquid point
From treated, partial desiccation air enters adsorption tower by the shut-off valve D of unlatching, and the electric heater in adsorption tower is opens at this time
State after the heated controller regulation and control of electric energy that accumulator was stored in a upper stage, is delivered to electric heater, to adsorption tower
Interior adsorbent is heated, and is being heated under the double action of air purging, adsorbent dehydrates, the moisture of abjection
Adsorption tower is taken out of by air and enters cooler A, is further cooled herein, it is empty then into gas-liquid separator A
Gas completes the separation of moisture herein, and the waste liquid isolated is through automatic drain valve A drainage gas-liquid separators, when automatic drain valve A events
Also Manual draining valve A is manually operable during barrier and carries out urgent draining.By gas-liquid separation, treated that dry air enters cloth bag
Deduster after the dust impurities for further removing various grain sizes, exports discharge this system, by air hose by drying compressed air
Road is delivered to supply at gas equipment and use.
After adsorbent dehydrates, system is automatically into first stage, i.e. adsorbent water suction stage.
Wherein, the dischargeable capacity of adsorption tower is 230m3, the internal adsorbent filled is spherical activated alumina
(Al2O3), a diameter of 4 ~ 6mm, heap density is 0.80g/m3, specific surface area 340m2/ g, intensity are more than 130N/.
Wherein, thermoelectric converter is alkali metal thermo-electric conversion regime, and ranging from 105 ~ 900 DEG C of Acclimation temperature converts effect
Rate can reach 40% or so, and continuous generating dutation can reach 14000 hours.
Wherein, the working pressure range of ultraviolet catalyzed oil expeller is 0.06 ~ 0.95MPa, dischargeable capacity 15m3, it is purple
The operating voltage of outer optical generator is 35V, and power 100W, luminescent spectrum energy is focused primarily upon at 320nm wavelength, average
Service life was up to 8000 hours.
By this system treated compressed air, moisture removal efficiency is up to 99.4%.
The advantage of the invention is that:
(1)Existing compression heat regeneration absorption drier needs at least two adsorption tower and Two-way Cycle gas circuit that could complete entirely
Dehydration and drying and adsorbent reactivation process, and the Creative Design of this system makes it that 1 adsorption tower only be needed just to complete compression sky
The dehydration and drying of gas and the regeneration overall process of adsorbent have good drying process effect, and have been reduced significantly equipment
Volume and weight.
(2)This system employs advanced thermoelectric generation technology, and extra heat is converted to electric energy, greatly reduces and is
System energy consumption.
(3)This system creativeness employs ultraviolet catalytic decomposition technique, can be thorough by mineral oil contained in air
Removal is decomposed, is effectively protected rear end equipment.
(4)This system employs double gas circuit periodic transformation formula plenum systems, and cooperation electrical heating method carries out again adsorbent
Raw processing can realize no air loss, effectively save production cost, and can be provided for rear end gas equipment lasting, high-quality
Air supply.
Description of the drawings
Fig. 1 is the system structure diagram of the present invention.
In figure:1- compressed air inlets, 2- ultraviolet catalyzeds oil expeller, 3- adsorption towers, 4- thermoelectric converters, 5- electric power storages
Pond, 6- heating controllers, 7- electric heaters, 8- external power supplys, 9- cooler A, 10- gas-liquid separator A, 11- coolers B, 12-
Gas-liquid separator B, 13- bag filter, the outlet of 14- drying compressed airs, 15- shut-off valve A, 16- shut-off valve B, 17- shut-off valves
C, 18- shut-off valves D, 19- automatic drain valves A, 20- Manual draining valves A, 21- automatic drain valve B, 22- Manual draining valves B
Fig. 2 is the schematic diagram of ultraviolet catalyzed oil expeller.
In figure:21- air intake valves, 22- stainless steels outer cover, 23- ultraviolet light generators, 24- tungstic acids catalysis net, 25-
Fixing bracket, 26- electric control gears, 27- connecting wires, 28- drain taps.
Specific embodiment
As shown in Figure 1, zero gas consumption compressed air drier by afterheat regeneration, which includes compressed air inlet 1, ultraviolet
It is line catalysis oil expeller 2, adsorption tower 3, thermoelectric converter 4, accumulator 5, heating controller 6, electric heater 7, external power supply 8, cold
But device A9, gas-liquid separator A10, cooler B11, gas-liquid separator B12, bag filter 13, drying compressed air outlet 14,
Shut-off valve A15, shut-off valve B16, shutoff valve C 17, shut-off valve D18, automatic drain valve A19, Manual draining valve A20, Auto-drainage
Valve B21, Manual draining valve B22.Wherein, after air enters this system by compressed air inlet 1, ultraviolet catalyzed is initially entered
Oil expeller 2, the air path after its deoiling treatment are divided into A, B two-way, and the connection mode on A roads is:Air, which passes sequentially through, to be cut
Only valve A15, thermoelectric converter 4, shutoff valve C 17, eventually enter into adsorption tower 3;The connection mode on B roads is:Air, which passes sequentially through, to be cut
Only valve B16, cooler B11, gas-liquid separator B12, shut-off valve D18, eventually enter into adsorption tower 3.Wherein, compressed air goes out gas circuit
Diameter is all the way, air passes sequentially through cooler A9, gas-liquid separator A10, bag filter 13, is finally gone out by drying compressed air
Mouth 14 is sent out, and is delivered at gas equipment.Wherein, gas-liquid separator A10 and gas-liquid separator B12 are respectively equipped with automatic drain valve
A19, automatic drain valve B21 and Manual draining valve A20, Manual draining valve B22.Wherein, the transport path of electric energy is:Heat to electricity conversion
After the electric energy that electric energy caused by device 4 and external power supply 8 provide, stores into accumulator 5, and heated controller 6 regulates and controls
The electric heater 7 being conveyed to inside adsorption tower 3.Wherein, 2 outer cover of ultraviolet catalyzed oil expeller be stainless steel, bottom
Portion and top are respectively equipped with air intake valve 21 and drain tap 28, are internally provided with 1 ultraviolet light generator 23, and pass through 4
Fixing bracket 25 is individually fixed in equipment quadrangle, and ultraviolet light generator 23 is automatically controlled by two sections of connecting wires 27 and device external
Device 26 is connected, and 23 outside of ultraviolet light generator is enclosed with tungstic acid catalysis net 24.Compressed air containing mineral oil passes through
Air intake valve 21 positioned at 2 bottom of ultraviolet catalyzed oil expeller enters inside equipment, and air is with being fixed on inside reaction unit
Tungstic acid catalysis net 24 is in contact, at this point, the ultraviolet light generator 23 among tungstic acid catalysis net 24 is automatically controlled
It starts to work under the regulation and control of device 26, ultraviolet light is emitted into whole equipment, when under ultraviolet wavelength irradiation condition, three aoxidize
Tungsten atom meeting Ultraviolet radiation absorbing in tungsten, low-lying level electrons are excited by light, and energy level transition occurs, while in original cost band
It is upper to generate corresponding hole, so as to generate a large amount of free radicals, and the mineral oil component exhaustive oxidation in air is cracked, it is main
Product is water vapour and carbon dioxide, and the compressed air after deoiling treatment is discharged through the drain tap 28 at the top of equipment, into
Enter next treatment process.
The complete working period of this system is divided into following two stages:
(1)Adsorbent absorbs water the stage:In this stage, shut-off valve A15 and shutoff valve C 17 are opening, and shut-off valve B16 and
Shut-off valve D18 is in off state.This system is entered by compressed air inlet 1 by air compressor compressed air, is passed through
After the deoiling treatment of ultraviolet catalyzed oil expeller 2, thermoelectric converter 4 is entered by the shut-off valve A15 of unlatching, air is herein by one
Partial heat is converted to electric energy, and is stored in accumulator 5.Air significant hypothermal after heat to electricity conversion, passes through unlatching
Shutoff valve C 17 enters adsorption tower 3, and the electric heater 7 in adsorption tower 3 is in off state at this time, and air is by the work in adsorption tower 3
After the dehydration of property alumina adsorbant, temperature and moisture are substantially reduced.Air after adsorption treatment, from suction
Attached tower 3 escapes and enter cooler A9, is further cooled herein, and then into gas-liquid separator A10, air exists
This completes the separation of moisture, and the waste liquid isolated is through automatic drain valve A19 drainage gas-liquid separators, when automatic drain valve A19 events
Also Manual draining valve A20 is manually operable during barrier and carries out urgent draining.By gas-liquid separation, treated that dry air enters cloth
Bag dust collector 13, after the dust impurities for further removing various grain sizes, by 14 discharge this system of drying compressed air outlet, by
Air pipe line is delivered to supply at gas equipment and use.
When adsorbent absorbs water close to saturation, system is automatically into second stage, i.e. adsorbent dehydration regeneration stage.
(2)The adsorbent dehydration regeneration stage:In this stage, shut-off valve B16 and shut-off valve D18 are opening, and are cut
Only valve A15 and shutoff valve C 17 are in off state.This is entered by compressed air inlet 1 by the compressed air of air compressor
System after the deoiling treatment of ultraviolet catalyzed oil expeller 2, enters cooler B11, herein by the shut-off valve B16 of unlatching
It is tentatively cooled, then into gas-liquid separator B12, air completes the separation of partial moisture herein, and that isolates is useless
Liquid is also manually operable Manual draining valve through automatic drain valve B21 drainage gas-liquid separators when automatic drain valve B21 failures
B22 carries out urgent draining.By gas-liquid separation, treated that partial desiccation air enters adsorption tower 3 by the shut-off valve D18 of unlatching,
At this time the electric heater 7 in adsorption tower 3 be opening, the heated control of electric energy that accumulator 5 was stored in a upper stage
After device 6 regulates and controls, electric heater 7 is delivered to, the adsorbent in adsorption tower 3 is heated, purged in heating and air dual
Under effect, adsorbent dehydrates, and the moisture of abjection takes adsorption tower 3 out of by air and enters cooler A9, carries out herein
It further cools, then into gas-liquid separator A10, air completes the separation of moisture herein, the waste liquid warp isolated
Automatic drain valve A19 drainage gas-liquid separators, be also manually operable when automatic drain valve A19 failures Manual draining valve A20 into
The urgent draining of row.By gas-liquid separation, treated that dry air enters bag filter 13, further removes various grain sizes
After dust impurities, by 14 discharge this system of drying compressed air outlet, being delivered to gas equipment supply by air pipe line makes
With.After adsorbent dehydrates, system is automatically into first stage, i.e. adsorbent water suction stage.Wherein, adsorption tower 2 has
Effect volume is 230m3, the internal adsorbent filled is spherical activated alumina(Al2O3), a diameter of 4 ~ 6mm, heap density is
0.80g/m3, specific surface area 340m2/ g, intensity are more than 130N/;Wherein, thermoelectric converter 3 is alkali metal thermo-electric conversion side
Formula, ranging from 105 ~ 900 DEG C of Acclimation temperature, transfer efficiency can reach 40% or so, and it is small that continuous generating dutation can reach 14000
When;Wherein, the working pressure range of ultraviolet catalyzed oil expeller 2 is 0.06 ~ 0.95MPa, dischargeable capacity 15m3, ultraviolet light
The operating voltage of generator 23 is 35V, power 100W, and luminescent spectrum energy focuses primarily upon at 320nm wavelength, averagely make
With the service life up to 8000 hours.
By this system treated compressed air, moisture removal efficiency is up to 99.4%.
Claims (1)
1. a kind of zero gas consumption compressed air drier by afterheat regeneration, which is characterized in that urged including compressed air inlet, ultraviolet light
Change oil expeller, adsorption tower, thermoelectric converter, accumulator, heating controller, electric heater, external power supply, cooler A, gas-liquid point
From device A, cooler B, gas-liquid separator B, bag filter, drying compressed air outlet and 5 sets of shut-off valve etc.;Wherein, it is empty
Gas enters ultraviolet catalyzed oil expeller by compressed air inlet, and the air path after its deoiling treatment is divided into A, B two-way,
The connection mode on A roads is:Air passes sequentially through shut-off valve A, thermoelectric converter, shutoff valve C, eventually enters into adsorption tower;The company on B roads
The mode of connecing is:Air passes sequentially through shut-off valve B, cooler B, gas-liquid separator B, shut-off valve D, eventually enters into adsorption tower;Wherein,
Compressed air outlet gas flow path is all the way, air passes sequentially through cooler A, gas-liquid separator A, bag filter, finally by drying
Compressed air outlet is sent out, and is delivered at gas equipment;Wherein, gas-liquid separator A and gas-liquid separator B are respectively equipped with automatic row
Water valve and Manual draining valve;Wherein, the transport path of electric energy is:What electric energy caused by thermoelectric converter and external power supply provided
Electric energy, the electric heater being conveyed into accumulators store, and after the regulation and control of heated controller inside adsorption tower;
The complete working period of the present apparatus is divided into following two stages:
(1)Adsorbent absorbs water the stage:In this stage, shut-off valve A and shutoff valve C are opening, and shut-off valve B and shut-off valve
D is in off state, and enters the present apparatus by compressed air inlet by the compressed air of air compressor, by ultraviolet catalyzed
After the deoiling treatment of oil expeller, thermoelectric converter is entered by the shut-off valve A of unlatching, air is herein converted to a part of heat
Electric energy, and be stored in accumulator, the air significant hypothermal after heat to electricity conversion enters absorption by the shutoff valve C of unlatching
Tower, at this time the electric heater in adsorption tower be in off state, dehydration of the air by the activated alumina adsorbents in adsorption tower
After effect, temperature and moisture are substantially reduced, and the air after adsorption treatment escapes and enter cooler from adsorption tower
A further cools herein, and then into gas-liquid separator A, air completes the separation of moisture herein, and that isolates is useless
Liquid is through automatic drain valve A drainage gas-liquid separators, and when automatic drain valve A failures, manual operation Manual draining valve A carries out urgent
Draining, by gas-liquid separation, treated that dry air enters bag filter, further removes the dust impurities of various grain sizes
Afterwards, the discharge present apparatus is exported by drying compressed air, being delivered to gas equipment supply by air pipe line uses;
(2)The adsorbent dehydration regeneration stage:When adsorbent absorbs water close to saturation, device is adsorbed automatically into second stage
Agent dehydration regeneration stage, shut-off valve B and shut-off valve D are opening, and shut-off valve A and shutoff valve C are in off state, by sky
The compressed air of air compressor enters the present apparatus by compressed air inlet, by the deoiling treatment of ultraviolet catalyzed oil expeller
Afterwards, cooler B is entered by the shut-off valve B of unlatching, is tentatively cooled herein, then into gas-liquid separator B, air
The separation of partial moisture is completed herein, and the waste liquid isolated is through automatic drain valve B drainage gas-liquid separators, as automatic drain valve B
Manual operation Manual draining valve B carries out urgent draining during failure, and by gas-liquid separation, treated that partial desiccation air passes through unlatching
Shut-off valve D enter adsorption tower, the electric heater in adsorption tower is opening at this time, and accumulator stored in a upper stage
The regulation and control of electric energy heated controller after, be delivered to electric heater, the adsorbent in adsorption tower heated, in heating and empty
Under the double action that air-blowing is swept, adsorbent dehydrates, and the moisture of abjection takes adsorption tower out of by air and enters cooler
A is further cooled herein, and then into gas-liquid separator A, air is completed the separation of moisture, isolated herein
Waste liquid through automatic drain valve A drainage gas-liquid separators, when automatic drain valve A failures, manual operation Manual draining valve A is carried out
Urgent draining, by gas-liquid separation, treated that dry air enters bag filter, further removes the dust of various grain sizes
After impurity, the discharge present apparatus is exported by drying compressed air, being delivered to gas equipment supply by air pipe line uses;Work as suction
After attached dose of dehydration and drying, device is automatically into first stage, i.e. adsorbent water suction stage;
Ranging from 105 ~ 900 DEG C of its Acclimation temperature;
The dischargeable capacity of adsorption tower is 230m3, the internal adsorbent filled is spherical activated alumina, a diameter of 4 ~ 6mm,
Heap density is 0.80g/m3, specific surface area 340m2/ g, intensity are more than 130N/.
Priority Applications (1)
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CN201810133474.1A CN108187433A (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
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CN201810133474.1A CN108187433A (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
CN201610476596.1A CN105964113B (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
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CN201810134111.XA Withdrawn CN108201775A (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
CN201810133126.4A Withdrawn CN108325345A (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
CN201810133119.4A Active CN108283867B (en) | 2016-06-27 | 2016-06-27 | Zero-gas-consumption waste heat regeneration compressed air drying device |
CN201810134080.8A Withdrawn CN108325346A (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
CN201810133474.1A Withdrawn CN108187433A (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
CN201810134112.4A Withdrawn CN108325347A (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
CN201610476596.1A Active CN105964113B (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
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CN201810133126.4A Withdrawn CN108325345A (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
CN201810133119.4A Active CN108283867B (en) | 2016-06-27 | 2016-06-27 | Zero-gas-consumption waste heat regeneration compressed air drying device |
CN201810134080.8A Withdrawn CN108325346A (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
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CN201610476596.1A Active CN105964113B (en) | 2016-06-27 | 2016-06-27 | A kind of zero gas consumption compressed air drier by afterheat regeneration |
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CN105944517B (en) * | 2016-06-27 | 2018-04-13 | 孙静洁 | A kind of zero gas consumption residual heat regenerating compressed air drying system |
CN110237660A (en) * | 2019-06-28 | 2019-09-17 | 苏州市建科建筑节能研究开发有限公司 | Utilize photovoltaic and the united drying compressed air system of paddy electricity and its control method |
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FR1584669A (en) * | 1967-09-25 | 1969-12-26 | ||
JP2006125302A (en) * | 2004-10-29 | 2006-05-18 | Hitachi Industrial Equipment Systems Co Ltd | Oil-free screw compressor |
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JPH10165746A (en) * | 1996-12-11 | 1998-06-23 | Nissin Electric Co Ltd | Condensation preventive device |
CN2378113Y (en) * | 1999-05-11 | 2000-05-17 | 中国科学院广州能源研究所 | Photocatalysis air processing device |
CN201279431Y (en) * | 2008-10-10 | 2009-07-29 | 成都市科达自动化控制工程有限公司 | Natural gas afterheat regeneration dehumidifier |
CN201493042U (en) * | 2009-05-18 | 2010-06-02 | 杭州山立净化设备有限公司 | Residual heat type combined low-dew point dryer |
CN101732954B (en) * | 2009-12-28 | 2012-05-23 | 杭州博大净化设备有限公司 | Zero-loss internal recycle type gas purifying method and device |
CN102451602B (en) * | 2010-10-22 | 2013-09-04 | 中国石油化工股份有限公司 | Zero gas consumption waste heat regeneration and drying method |
CN202569923U (en) * | 2012-05-29 | 2012-12-05 | 杭州加联净化设备有限公司 | Air dryer |
CN203002186U (en) * | 2013-01-07 | 2013-06-19 | 上海阿普达实业有限公司 | Adsorption type compressed gas dryer capable of shunting and regenerating moisture |
CN103272460A (en) * | 2013-05-29 | 2013-09-04 | 山东道先为能源科技有限公司 | Waste heat regeneration absorption dryer |
CN204395739U (en) * | 2015-01-06 | 2015-06-17 | 杭州钒钛机械有限公司 | A kind of zero gas consumption waste heat regeneration type dryer |
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- 2016-06-27 CN CN201810134111.XA patent/CN108201775A/en not_active Withdrawn
- 2016-06-27 CN CN201810133126.4A patent/CN108325345A/en not_active Withdrawn
- 2016-06-27 CN CN201810133119.4A patent/CN108283867B/en active Active
- 2016-06-27 CN CN201810134080.8A patent/CN108325346A/en not_active Withdrawn
- 2016-06-27 CN CN201810133474.1A patent/CN108187433A/en not_active Withdrawn
- 2016-06-27 CN CN201810134112.4A patent/CN108325347A/en not_active Withdrawn
- 2016-06-27 CN CN201610476596.1A patent/CN105964113B/en active Active
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Also Published As
Publication number | Publication date |
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CN108283867A (en) | 2018-07-17 |
CN108325346A (en) | 2018-07-27 |
CN108201775A (en) | 2018-06-26 |
CN108325347A (en) | 2018-07-27 |
CN105964113B (en) | 2018-04-13 |
CN108325345A (en) | 2018-07-27 |
CN108283867B (en) | 2020-06-26 |
CN105964113A (en) | 2016-09-28 |
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