CN1419948A - Liquid delivery pump and liquid transfer pipeline degassing device - Google Patents
Liquid delivery pump and liquid transfer pipeline degassing device Download PDFInfo
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- CN1419948A CN1419948A CN 01134937 CN01134937A CN1419948A CN 1419948 A CN1419948 A CN 1419948A CN 01134937 CN01134937 CN 01134937 CN 01134937 A CN01134937 A CN 01134937A CN 1419948 A CN1419948 A CN 1419948A
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- depassing unit
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- infusion pump
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Abstract
A degassing device for liquid delivering pump and pipeline used in clinic perfusion system, liquid-phase chromatography system, etc is disclosed. The degassing device for pressurized liquid is composed of liquid inlet channel and outlet channel, hollow cavity, and gas (liquid)-gas mixture escaping channel with damper. The degassing device for the microflow chippipeline consists of liquid channel, capillary microarray, and gas escaping channel or liquid-gas mixture escaping channel.
Description
Technical field
The present invention relates to a kind of device that is used for getting rid of infusion pump or the contained gas of liquid transmission pipeline liquid.It is to utilize that oversaturated gas is higher than bottom liquid or utilizes hydrophobic pore principle to get rid of the method for gas in liquid concentration at the middle and upper levels in the liquid, belongs to a kind of method of utilizing the physical principle degasification.
Background technology
Often relate to the problem of getting rid of the contained gas of liquid in infusion pump or the liquid transmission pipeline in the modern analysis chemistry.The generation form of the gas in the solution is diversified, the gas that various possible reactions (as electrode reaction) produce or be dissolved in gas in the liquid originally, and the system with liquid gas poised state exists often.Originally be in the system of liquid gas poised state in the solution, when arriving point of application by infusion pump or liquid transmission pipeline, dissolved gases may reach supersaturation and overflows because condition changes.For example, the system that liquid is in the liquid-gas equilibrium state during high pressure infuser is through overload and pressure when reducing, and the former gas that is dissolved in the liquid because of supersaturation the gas evolution phenomenon takes place.The carrying out of gas effusion meeting interference experiment from solution.For example, in the micro column liquid chromatography, during high pressure infuser in the mobile phase dissolved gases can form bubble after through the chromatographic column decompression and overflow serious Interference Detection process.
In fact, fields such as clinical medicine trace transfusion system, liquid chromatographic system, flow analysis system often relate to the occasion that needs to get rid of bubble or get rid of excessive dissolved gas in the liquid, owing to inevitable electrode reaction, the eliminating of bubble seems particularly important in the fluid in particularly electric driving or the electromagnetic driving system.In recent years, in order to realize the conveying of micro-flow liquid, having occurred with sound, electricity, light, magnetic, heat etc. is the Micropump miscellaneous of basic excitation form, for example piezoelectric type, thermal type, sound wave type, electrohydrodynamic formula, magneto hydrodynamic formula, electric osmose formula or the like.These Micropumps are in when transfusion, often contain bubble in the output liquid owing to electrode reaction or other reason make.In most of the cases, do not wish to contain in the fluid bubble.Electricity drives or Electromagnetic Drive is that micrometeor drives and the control technology important method, and when electricity drove, electrode surface always will produce gas, the time long slightly bubble that just forms when electrochemical process takes place.In direct driving system, bubble enters in the fluid inevitably, and electric-force gradient becomes at the bubble place greatly, and the part produces higher Joule heat and makes bubble volume expansion, causes liquid stream to open circuit and the electric osmose interruption; In indirect driving system, the gathering of gas can cause that bubble is counter goes in the fluid, and the electric osmose process is interrupted.Because can dissolve a certain amount of gas by nature in the solution, the gas of removing fully in the liquid is impossible, also there is no need, and needs only insatiety and just can not produce bubble, does not also just influence application.
Summary of the invention
The present invention is exactly at above-mentioned background, its objective is provide a kind of simple and effective depassing unit, this device can get rid of effectively bubble in the mechanical type infusion pump trickle, electricity drive the gas that transfusion produces because of electrode reaction and be dissolved in gas in the liquid originally and the microfluidic chip on since electricity drive the gas that produces or be dissolved in gas in the liquid originally.The present invention is applicable to the occasion that clinical transfusion system, liquid chromatographic system, flow analysis system etc. need to get rid of bubble or get rid of excessive dissolved gas in the liquid, and the liquid that is specially adapted to electricity driving or electromagnetic driving system is removed.Whole gas removal device can also design and produce on chip, is applicable to get rid of the gas in the liquid in the micrometeor system.
Liquid degassing device of the present invention mainly comprises the liquid input channel, the liquid output channel, and reservoir compartment has the gas evolution passage of antivibrator; Further distinguish, liquid degassing device of the present invention can be divided into band press liquid depassing unit and chip depassing unit, wherein the discharge channel with the press liquid depassing unit is a leakage fluid dram of being with antivibrator by being provided with on the reservoir compartment top, and the discharge channel of chip depassing unit is provided with microcapillary array (passage) and porous damping layer.Band press liquid depassing unit is to utilize physical principle, and gas moves, assembles to the upper strata in liquid, makes the gas content in the upper solution higher, by damper tube liquid-gas mixed liquor is discharged and reaches the purpose of getting rid of gas.The chip depassing unit has utilized the thin pore of hydrophobic microtriche (HMCV) principle, the microcapillary array in the device, and sectional dimension is littler than circulation road size.The microcapillary inwall has hydrophobicity, and negative capillarity has stoped fluidic intrusion, and gas can pass through wherein easily.Higher and when surpassing surface tension capillaceous when liquid pressure, liquid-gas mixed liquor is known from experience by microcapillary and porous damping layer and is flowed out, and makes that gas is discharged from the liquid.
In addition, in above-mentioned depassing unit, the flow of discharging for the liquid output channel of band press liquid depassing unit is the 10-80% of liquid input channel input flow rate.
In addition, in above-mentioned depassing unit, band press liquid depassing unit reservoir compartment volume is more than or equal to 1/3 of liquid per minute flow.And the microcapillary array sectional dimension of chip depassing unit is compared less than 2/3 with channel size.
Description of drawings
Fig. 1 is the sketch map of band press liquid depassing unit;
Fig. 2 is applied to high pressure electroosmotic pump sketch map for band press liquid depassing unit;
Fig. 3 is an air scavenge schematic representation of apparatus on the chip;
Fig. 4 is applied to the sketch map of chip for chip air scavenge device
Among the figure: 1-fills capillary microchannel (electric osmose post); The 2-conduit; 3-conducts electricity coreless armature; The 4-band is pressed depassing unit; 5-constant voltage/constant current control device; The 14-liquid inlet; The 15-liquid outlet; 16-air vent (on damping is arranged); 101-fills the microchannel; 102-etching microchannel (transfusion catheter); The 103-electrode is positioned to flow to go up and fills the both sides, microchannel; 104-chip air scavenge device; 105-chip fluid control device; The 106-liquid storage tank; 1021-microcapillary array (on cover porous damping layer 1025); The 1022-gas passage; The 1023-fine droplet; 1024-chip air scavenge device side view; 1025-porous damping layer.
The specific embodiment
Infusion pump depassing unit of the present invention is divided into band press liquid depassing unit (Fig. 1) and chip depassing unit (Fig. 3).
Band press liquid depassing unit (Fig. 1) is made of the reservoir compartment (inwall hydrophobicity) 4 of a carrying liqs input port 14, delivery outlet 15 and air vent 16 (on antivibrator is arranged), from liquid inlet 14 input liquid, liquid outlet 15 drains through hollow chamber 4 bottoms are discharged and contain the outlet 16 that the liquid of gas is provided with by reservoir compartment top (on antivibrator is arranged); Its principle is: gas because the effect of gravity is moved, assembled to the upper strata, makes the gas content in the upper solution higher in liquid.For hydrophilic liquid, gas is easy to overflow, assemble in the solution under the high pressure in order to make, and cavity wall can be processed into hydrophobicity; Otherwise for hydrophobicity liquid, the chamber wall can be processed into hydrophilic.Upper liquid constantly flows out through antivibrator, and flow is about the 10%-80% of liquid inlet 14, can regulate as required, makes gas and contain the high liquid of concentration of dissolved gas constantly to discharge, and guarantees that the liquid of trickle delivery outlet 15 does not have bubble.The making of antivibrator can be used little porous sintered stainless steel material, also can use the capillary tube packed column, in add microparticle (filler can select for use in silica gel, finishing silica gel, ion exchange resin, polymer microsphere, inorganic ball-type or unformed filler, the interior molding filler a kind of).
Air scavenge device (Fig. 3) on the chip mainly comprises 2, one microcapillary arrays of liquid communication path 10 (passage) 1021, gas evolution path 10 22, and microcapillary array sectional dimension is littler than channel size 102.Its principle is to have utilized the thin pore of hydrophobic microtriche (HMCV) principle, and for hydrophilic liquid, gas is easy to overflow, assemble in the solution in order to make, the microcapillary inwall uses hydrophobic material to make, otherwise for hydrophobicity liquid, the microcapillary inwall then uses hydrophilic material to make.Often to need the hydrophilic liquid of conveying on the chip is example, and at this moment the microcapillary inwall has hydrophobicity, and negative capillarity has stoped fluidic intrusion, and gas can be easily by wherein getting rid of fluid passage 102.When if liquid pressure surpasses surface tension capillaceous than high energy, additional one deck porous damping after microcapillary makes liquid-gas mixing material flow out by microcapillary and porous damping layer, promptly keeps liquid pressure, and the gas in the liquid is discharged.
The described device materials of infusion pump depassing unit of the present invention adopts metal, alloy, plastics, composite, quartz, pottery, glass or conductive material, silicon matrix material.
Infusion pump depassing unit of the present invention can be withstand voltage, the withstand voltage 0-100MPa of band press liquid depassing unit, the withstand voltage 0-1MPa of chip depassing unit.
Infusion pump depassing unit of the present invention, there is not fixed restriction for plant bulk, usually, reservoir compartment 4 inner volumes of band press liquid depassing unit (Fig. 1) are to carry more than 1/3 of liquid per minute flow, are to decide according to the desired balance volume of infusion flow size; The geometry of reservoir compartment 4 is unrestricted, is generally column type or prismatic.The physical dimension of air scavenge device (Fig. 3) is tens to receive and rise to tens microlitres on the chip, is mainly reflected in liquid communication path 10 2, and microcapillary array (passage) 1021 on the porous damping layer, requires microcapillary array sectional dimension littler than channel size 102.
Infusion pump depassing unit of the present invention, band press liquid depassing unit and chip depassing unit can be independent parts, the latter also can directly design and produce on chip, to satisfy the liquid degassing requirement of micrometeor system.
Embodiment 1: single-stage drives electroosmotic pump, copper hollow two logical internal diameter 200 μ m adopt column length 20.0cm, internal diameter 75 μ m packed columns as electrode and fluid passage, in fill out the silica filler of particle diameter 1 μ m, blank pipe internal diameter 10 μ m, series connection band press liquid aerofluxus removal apparatus, device to remove sap cavity be the cylindrical cavity of diameter 1.0mm, the withstand voltage 20Mpa of antivibrator passage, liquid I/O passage internal diameter is 200 μ m, effectively degasification, and pump can uninterruptedly be infused continuously;
Embodiment 2: the chip level Four drives electroosmotic pump, and chip air scavenge device is made in the etching series connection.It is 50 μ m that internal diameter is amounted in the electroosmotic pump fluid passage, and the microcapillary array and the porous damping layer of chip air scavenge device all are processed into hydrophobicity, and it is always amounted to and is of a size of 20 μ m, total withstand voltage 0.2Mpa, and the transfusion requirement is satisfied in effectively degasification.
Claims (7)
1. infusion pump and liquid transmission pipeline depassing unit, has the liquid input channel, the liquid output channel, reservoir compartment, with the gas that has antivibrator or liquid-gas mixed liquor discharge channel, it is characterized in that the discharge channel for band press liquid depassing unit is by the leakage fluid dram of band antivibrator is set on the reservoir compartment top; And be provided with a microcapillary array and porous damping layer for the discharge channel of microfluidic chip depassing unit.
2. infusion pump according to claim 1 and liquid transmission pipeline depassing unit is characterized in that the top in the described reservoir compartment or the first half are processed into hydrophobic surface.
3. infusion pump according to claim 1 and liquid transmission pipeline depassing unit, the sectional dimension that it is characterized in that described microcapillary array is compared little with fluid channel dimensions, and the microcapillary inwall has the character of hydrophobicity.
4. infusion pump according to claim 1 and liquid transmission pipeline depassing unit is characterized in that the flow of discharging for the liquid output channel of band press liquid depassing unit is the 10-80% of liquid input channel input flow rate.
5, infusion pump according to claim 1 and liquid transmission pipeline depassing unit is characterized in that with press liquid depassing unit reservoir compartment volume more than or equal to 1/3 of liquid per minute flow.
6, infusion pump according to claim 1 and liquid transmission pipeline depassing unit is characterized in that the microcapillary array sectional dimension of chip depassing unit is compared less than 2/3 with channel size.
7,, it is characterized in that device can be withstand voltage, the withstand voltage 0.001-100MPa of depassing unit, the withstand voltage 0-1MPa of chip depassing unit according to claim 1-5 depassing unit.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CNB011349379A CN1194785C (en) | 2001-11-15 | 2001-11-15 | Liquid delivery pump and liquid transfer pipeline degassing device |
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CNB011349379A CN1194785C (en) | 2001-11-15 | 2001-11-15 | Liquid delivery pump and liquid transfer pipeline degassing device |
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CN1419948A true CN1419948A (en) | 2003-05-28 |
CN1194785C CN1194785C (en) | 2005-03-30 |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN100346141C (en) * | 2005-04-25 | 2007-10-31 | 湖南大学 | Earthwork filling body settlement observation instrument |
CN101915683A (en) * | 2010-08-11 | 2010-12-15 | 湖南力合科技发展有限公司 | Metering device |
CN101991974A (en) * | 2010-09-15 | 2011-03-30 | 安徽皖仪科技股份有限公司 | Full-automatic mobile phase bubble separation device |
CN111213060A (en) * | 2017-10-11 | 2020-05-29 | 麦君宇 | Microfluidic metering and delivery system |
-
2001
- 2001-11-15 CN CNB011349379A patent/CN1194785C/en not_active Expired - Fee Related
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN100346141C (en) * | 2005-04-25 | 2007-10-31 | 湖南大学 | Earthwork filling body settlement observation instrument |
CN101915683A (en) * | 2010-08-11 | 2010-12-15 | 湖南力合科技发展有限公司 | Metering device |
CN101915683B (en) * | 2010-08-11 | 2013-06-19 | 力合科技(湖南)股份有限公司 | Metering device |
CN101991974A (en) * | 2010-09-15 | 2011-03-30 | 安徽皖仪科技股份有限公司 | Full-automatic mobile phase bubble separation device |
CN101991974B (en) * | 2010-09-15 | 2012-11-28 | 安徽皖仪科技股份有限公司 | Full-automatic mobile phase bubble separation device |
CN111213060A (en) * | 2017-10-11 | 2020-05-29 | 麦君宇 | Microfluidic metering and delivery system |
US11857960B2 (en) | 2017-10-11 | 2024-01-02 | Fitbit, Inc. | Microfluidic metering and delivery system |
CN111213060B (en) * | 2017-10-11 | 2024-02-09 | 麦君宇 | Microfluidic metering and delivery system |
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CN1194785C (en) | 2005-03-30 |
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