CN105889231A - Oil filter using full frequency variable structure working condition self-adapting filtering, electrifying and centrifuging - Google Patents
Oil filter using full frequency variable structure working condition self-adapting filtering, electrifying and centrifuging Download PDFInfo
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- CN105889231A CN105889231A CN201610321511.2A CN201610321511A CN105889231A CN 105889231 A CN105889231 A CN 105889231A CN 201610321511 A CN201610321511 A CN 201610321511A CN 105889231 A CN105889231 A CN 105889231A
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B21/00—Common features of fluid actuator systems; Fluid-pressure actuator systems or details thereof, not covered by any other group of this subclass
- F15B21/04—Special measures taken in connection with the properties of the fluid
- F15B21/041—Removal or measurement of solid or liquid contamination, e.g. filtering
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B21/00—Common features of fluid actuator systems; Fluid-pressure actuator systems or details thereof, not covered by any other group of this subclass
- F15B21/008—Reduction of noise or vibration
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- Chemical & Material Sciences (AREA)
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- Fluid Mechanics (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Centrifugal Separators (AREA)
Abstract
The invention relates to an oil filter using full frequency variable structure working condition self-adapting filtering, electrifying and centrifuging. The oil filter using the full frequency variable structure working condition self-adapting filtering, electrifying and centrifuging comprises a filter, a U-shaped particle separating module, an oil return barrel and an outer barrel. The filter, the U-shaped particle separating module, the oil return barrel and the outer barrel are arranged on a base plate in order. The filter, using a full frequency variable structure working condition self-adapting filter, is connected with the U-shaped particle separating module. The U-shaped particle separating module comprises a U-shaped pipe which is provided with an electrifying module, a separating module, a first absorbing module, a mechanical centrifuging module, a second absorbing module and a demagnetization module in order. The top of the U-shaped particle separating module is connected with the top of the oil return barrel by an oil inlet pipe of the oil return barrel. An inner barrel is arranged in the outer barrel and is installed on an end cap. A spiral flow channel is contained in the inner barrel and is connected with the U-shaped particle separating module by the oil inlet pipe of the inner barrel, wherein the oil inlet pipe of the inner barrel is located in the oil inlet pipe of the oil return barrel. A filter element is arranged on the inner wall of the inner barrel. The oil filter has the advantages of being good in filtering property, high in adaptability and integration, long in service life and like.
Description
[technical field]
The present invention relates to a kind of hydraulic oil filter, be specifically related to one full frequency band structure changes operating mode certainly
Adaptive filtering, the oil filter electrifying and being centrifuged, belong to technical field of hydraulic equipment.
[background technology]
Statistics both domestic and external show, the fault of hydraulic system about 70%~85% is due to oil
Liquid pollution causes.Solid particle is then the pollutant the most universal in oil contamination, damaging effect is maximum.
The hydraulic system fault caused by solid grain contamination accounts for the 70% of gross contamination fault.In hydraulic system
In particulate pollutant in fluid, metal filings accounting is between 20%~70%.Adopt an effective measure
Filter the solid grain contamination in fluid, be the key of Pollution Control in Hydraulic System, be also system peace
The Reliable guarantee of row for the national games.
Filter is the key element that hydraulic system filters solid grain contamination.Solid in hydraulic oil
Particulate pollutant, outside the precipitable a part of larger particles of oil removal box, filters mainly by oil-filtering apparatus.
Especially high pressure filtering device, is mainly used to filter flow direction control valve and the hydraulic oil of hydraulic cylinder, to protect
Protect the Hydraulic Elements of this kind of contamination resistance difference, therefore the cleannes of hydraulic oil are required higher.
But, the high pressure filter that existing hydraulic system uses has the disadvantage that (1) all kinds of liquid
The cleannes of fluid are required different by pressure element, and the size of the solid particle in fluid is the most each
Differ, need for this multiple dissimilar wave filter to be installed, thus at the diverse location of hydraulic system
Bring cost and the problem installing complexity;(2) filter in hydraulic system mainly uses filter cake
Filter type, during filtration, filtrate is perpendicular to filter element surface flowing, and trapped solid particle is formed
Filter cake progressive additive, the rate of filtration is gradually reduced the most therewith until filtrate stops flowing out, and reduces
The service life of filtering element.
Therefore, for solving above-mentioned technical problem, becoming with full frequency band of a kind of innovation of necessary offer is tied
Structure operating mode adaptive-filtering, the oil filter electrifying and being centrifuged, to overcome described defect of the prior art.
[summary of the invention]
For solving above-mentioned technical problem, it is an object of the invention to provide a kind of strainability good, adapt to
Property and integration high, service life length with full frequency band structure changes operating mode adaptive-filtering, electrification and from
The oil filter of the heart.
For achieving the above object, the technical scheme that the present invention takes is: by full frequency band structure changes operating mode certainly
Adaptive filtering, the oil filter electrifying and being centrifuged, it includes base plate, wave filter, U-shaped separation of particles mould
Block, oil returning tube, inner core, helical flow path, filter element, outer barrel and end cap;Wherein, described wave filter,
U-shaped separation of particles module, oil returning tube, outer barrel are sequentially placed on base plate;Described wave filter includes input
Pipe, shell, outlet tube, corrugated tube and S type elastic thin-wall;Wherein, described input pipe is connected to
One end of shell, itself and hydraulic oil inlet docking;Described outlet tube is connected to the other end of shell,
Itself and U-shaped separation of particles module are docked;Described S type elastic thin-wall is installed on shell along the radial direction of shell
In, form expansion chamber and contraction chamber in it;Described input pipe, outlet tube and S type elastic thin-wall are common
Form a S type cavity volume wave filter;The resonance of cylinder is formed between described S type elastic thin-wall and shell
Cavity volume;Some taper structure changes damping holes, taper is uniformly had in the axial direction of described S type elastic thin-wall
Structure changes damping hole connection resonance cavity volume;Described taper structure changes damping hole is by cone shaped elastic damping hole pipe
Form with slot apertures;Described corrugated tube is wound on outside resonance cavity volume in the shape of a spiral, and resonance cavity volume is by multiple
Pipe connection is inserted in taper;Described corrugated tube is connected by some arms between respectively enclosing, and arm is provided with out
Close;Described corrugated tube and resonance cavity volume composition plug-in type spiral isomery cascaded H mode filter;Described U
Type separation of particles module includes a U-tube, U-tube is sequentially installed with electrification module, separation module,
First adsorption module, mechanical centrifugal module, the second adsorption module and demagnetization module;Described U-shaped microgranule
The top of separation module and oil returning tube is connected by an oil returning tube oil inlet pipe;Described inner core is placed in outer barrel
In, if it is installed on end cap by a top board and bolt stem;Described helical flow path is contained in inner core
In, connected by an inner core oil inlet pipe between itself and U-shaped separation of particles module;Described inner core oil inlet pipe
Being positioned at oil returning tube oil inlet pipe, and extend into the central authorities of U-shaped separation of particles module, its diameter is less than back
Oil cylinder oil inlet pipe diameter, and be coaxially disposed with oil returning tube oil inlet pipe;Described filter element is arranged on the interior of inner core
On wall, its precision is 1-5 micron;The bottom of said tub is provided with a hydraulic oil oil-out.
The present invention with full frequency band structure changes operating mode adaptive-filtering, electrify and the oil filter that is centrifuged enters one
Step is set to: the axis of described input pipe and outlet tube is the most on the same axis;Described taper structure changes
The wider place of damping hole opening is positioned at resonance cavity volume, and its taper angle is 10 °;Described taper structure changes hinders
The Young's modulus of Buddhist nun hole cone shaped elastic damping hole pipe is bigger than the Young's modulus of elastic thin-wall, can be with fluid
Pressure change stretching or compression;The Young's modulus of slot apertures is wanted than the Young's modulus of cone shaped elastic damping hole pipe
Greatly, can be with fluid opened by pressure or closedown;Described taper is inserted the wider place of tube opening and is positioned at corrugated tube,
Its taper angle is 10 °.
The present invention with full frequency band structure changes operating mode adaptive-filtering, electrify and the oil filter that is centrifuged enters one
Step is set to: described electrification module includes some electrodes and an electrode controller;Described some electrodes
Being installed on the first oil return pipe, it is respectively connecting to electrode controller.
The present invention with full frequency band structure changes operating mode adaptive-filtering, electrify and the oil filter that is centrifuged enters one
Step is set to: described separation module uses uniform magnetic field separation module, this uniform magnetic field separation module bag
Include aluminum matter pipeline, two magnetic poles and magnetic pole controller;Wherein, said two magnetic pole is separately positioned on
On aluminum matter pipeline, the opposite polarity of these two magnetic poles, and in being oppositely arranged;Said two magnetic pole is respectively
It is electrically connected on magnetic pole controller.
The present invention with full frequency band structure changes operating mode adaptive-filtering, electrify and the oil filter that is centrifuged enters one
Step is set to: described separation module uses rotating excitation field separation module, this rotating excitation field separation module bag
Include aluminum matter pipeline, iron shell, three-phase symmetric winding and three-phase symmetrical current module;Described three-phase
Symmetric winding is wound on outside aluminum matter pipeline;Described iron shell is coated on aluminum matter pipeline;Described three relative
Current module is claimed to connect described three-phase symmetric winding.
The present invention with full frequency band structure changes operating mode adaptive-filtering, electrify and the oil filter that is centrifuged enters one
Step is set to: described separation module uses helical pipe magnetic field separation module, and this helical pipe magnetic field is divided
Aluminum matter helical pipe, solenoid and solenoid control circuit is included from module;Wherein, described aluminum matter
Helical pipe is arranged in solenoid;Described solenoid and solenoid control circuit are electrically connected with.
The present invention with full frequency band structure changes operating mode adaptive-filtering, electrify and the oil filter that is centrifuged enters one
Step is set to: described first adsorption module and second is inhaled adsorption module and used homopolarity adjacent type absorbing ring,
This homopolarity adjacent type absorbing ring includes aluminium ring shape pipeline, forward solenoid, reverse solenoid and ferrum
Matter magnetic conduction cap;Described forward solenoid and reverse solenoid are respectively arranged in aluminium ring shape pipeline, and two
Person is connected with electric current in opposite direction so that forward solenoid and reverse solenoid adjacent produce same sex magnetic
Pole;Described irony magnetic conduction cap is arranged on the inwall of aluminium ring shape pipeline, its be positioned at forward solenoid and
Reverse solenoid adjacent and forward solenoid and the intermediate point of reverse solenoid axis.
The present invention with full frequency band structure changes operating mode adaptive-filtering, electrify and the oil filter that is centrifuged enters one
Step is set to: the homopolarity that described first adsorption module and second inhales the adsorption module charged hammer of employing is adjacent
Type absorbing ring, the homopolarity adjacent type absorbing ring of this charged hammer includes aluminium ring shape pipeline, forward helical
Pipe, reverse solenoid, irony magnetic conduction cap, dividing plate, electric shock hammer and electric magnet;Described forward helical
Pipe and reverse solenoid are respectively arranged in aluminium ring shape pipeline, and both are connected with electric current in opposite direction,
Forward solenoid and reverse solenoid adjacent is made to produce like pole;Described irony magnetic conduction cap is arranged
On the inwall of aluminium ring shape pipeline, its be positioned at forward solenoid and reverse solenoid adjacent and
Forward solenoid and the intermediate point of reverse solenoid axis;Described dividing plate is positioned at forward solenoid with reverse
Between solenoid;Described electric shock hammer and electric magnet are between dividing plate;Described electric magnet connects and can push away
Galvanic electricity hammer, makes electric shock hammer tap aluminium ring shape inner-walls of duct.
The present invention with full frequency band structure changes operating mode adaptive-filtering, electrify and the oil filter that is centrifuged enters one
Step is set to: described mechanical centrifugal module uses eddy flow to be centrifuged module;Described eddy flow is centrifuged module and includes
Eddy flow tube wall, the first flow deflector, the second flow deflector, motor and flow transducer;Wherein,
Described first flow deflector is provided with 3, and these 3 first flow deflectors are along tube wall inner periphery every 120 ° uniformly
Distribution, its laying angle is set to 18 °;Described second flow deflector and the first flow deflector structure are identical, and it sets
Put after the first flow deflector, and and the first flow deflector stagger 60 ° and be connected in tube wall, its laying angle sets
It it is 36 DEG C;The long limit of described first flow deflector is connected with tube wall, and minor face extends along the axis of tube wall;Its
Leading edge frustrates into obtuse, and trailing edge is processed into wing, and its height is 0.4 times of tube wall diameter, a length of pipe
1.8 times of wall diameter;Described motor connects and drives the first flow deflector and the second flow deflector, with
Regulation laying angle;Described flow transducer is arranged on the central authorities in tube wall.
The present invention with full frequency band structure changes operating mode adaptive-filtering, electrify and the oil filter that is centrifuged also sets
It is set to: the bottom of described oil returning tube is provided with an overflow valve, bottom this overflow valve, is provided with an automatically controlled regulation spiral shell
Silk;Described overflow valve is provided with an oil drain out, and this oil drain out is connected to a fuel tank by pipeline;Described
The bottom of inner core is rounding mesa-shaped, and it is connected by an inner core oil exit pipe and oil returning tube, inner core oil exit pipe
It is provided with an automatically controlled check-valves;The center upright of described inner core is provided with a hollow cylinder, hollow cylinder
Being arranged over pressure difference indicator, this pressure difference indicator is installed on end cap;Described inner core oil inlet pipe and spiral shell
The tangent connection in eddy flow road.
Compared with prior art, there is advantages that
1. pulsed by the pressure/flow of filter attenuation hydraulic oil, make filter element not occur
Vibration, to improve strainability;Hydraulic oil realizes dividing of solid particle in U-shaped separation of particles module
From, make the solid particle in fluid to vessel wall motion, at U-shaped separation of particles module outlet, rich in
The fluid of the near-wall of solid particle is back to fuel tank after entering oil returning tube by oil returning tube oil inlet pipe,
The only fluid of the pipeline center containing trace small particle microgranule is then entered by inner core oil inlet pipe entrance inner core
Row high-precision filtration, improves the service life of filter element, reduces filtering cost and complexity;Enter
The fluid of inner core oil inlet pipe flows into the helical flow path of inner core in the way of tangential influent stream, and inner tube wall is filter
Core, then filtrate is close to filter core flow under the influence of centrifugal force, and the surface that filtrate is parallel to filter element is quick
Flowing, the hydraulic oil after filtration is then perpendicular to cartridge surface direction and flows out to urceolus, and this cross flows through
The microgranule of cartridge surface is implemented to sweep stream effect by filter mode, it is suppressed that the increase of filter cake thickness, is deposited on
Pollution granule bottom inner core regularly can be discharged to oil returning tube by automatically controlled check-valves, thus improves filter element
Service life.
2. by making the particulate matter charged polymeric in fluid to electrode applying voltage, and promote colloid
Grain decomposition is melted;Efficient absorption is formed by adsorption module;Utilize small by fluid of mechanical centrifugal
Granule " separates " and gathers near-wall, captures molecule with adsorbent equipment;Filled by demagnetization
Put and avoid residual particles demagnetization endangering Hydraulic Elements, so that solid particle is gathered into big in fluid
Grain moves to near-wall.
3. the generation of non-uniform magnetic-field that magnetization needs, need multipair forward and reverse coil to and by different greatly
Little electric current, and current values can numeral setting online.
[accompanying drawing explanation]
Fig. 1 be the present invention with full frequency band structure changes operating mode adaptive-filtering, the oil strain that electrifies and be centrifuged
The structural representation of device.
Fig. 2 is the structural representation of the wave filter in Fig. 1.
Fig. 3 is plug-in type H mode filter schematic diagram.
Fig. 4 is the H mode filter frequency characteristic constitutional diagram of single H mode filter and series connection.Wherein,
Solid line is single H mode filter frequency characteristic.
Fig. 5 is the structural representation of S type cavity volume wave filter.
Fig. 6 is the cross sectional representation of S type elastic thin-wall.
Fig. 7 is the schematic diagram of taper structure changes damping hole in Fig. 3.
Fig. 7 (a) to Fig. 7 (c) is the working state figure of taper structure changes damping hole.
Fig. 8 is the schematic diagram of the U-shaped separation of particles module in Fig. 1.
Fig. 9 is the structural representation of the electrification module in Fig. 8.
Figure 10 be the separation module in Fig. 8 be the structural representation of uniform magnetic field separation module.
Figure 11 be the separation module in Fig. 8 be the structural representation of rotating excitation field separation module.
Figure 12 be the separation module in Fig. 8 be the structural representation of helical pipe magnetic field separation module.
Figure 13 be the first adsorption module (the second adsorption module) in Fig. 8 be homopolarity adjacent type absorption
The structural representation of ring.
Figure 14 is the homopolarity that the first adsorption module (the second adsorption module) is charged hammer in Fig. 8
The structural representation of adjacent type absorbing ring.
Figure 15 is the horizontal schematic diagram of the mechanical centrifugal module of Fig. 8.
Figure 16 is the radial direction schematic diagram of the mechanical centrifugal module of Fig. 8.
[detailed description of the invention]
Referring to shown in Figure of description 1 to accompanying drawing 16, the present invention is one full frequency band structure changes
Operating mode adaptive-filtering, the oil filter electrifying and being centrifuged, it is by base plate 6, wave filter 8, U-shaped microgranule
Separation module 3, oil returning tube 7, inner core 15, helical flow path 17, filter element 18, outer barrel 19 and end
Several parts compositions such as lid 25.Wherein, described wave filter 8, U-shaped separation of particles module 2, oil returning tube
7, outer barrel 19 is sequentially placed on base plate 6.
Described wave filter 8 for hydraulic oil is inputted, and can decay in hydraulic system high, medium and low
The fluctuation pressure of frequency range, and suppression flowed fluctuation.Described wave filter 8 by input pipe 81, shell 88,
Several parts compositions such as outlet tube 89, corrugated tube 83 and S type elastic thin-wall 87.
Wherein, described input pipe 81 is connected to one end of shell 89, and itself and a hydraulic oil inlet 1 are right
Connect;Described outlet tube 811 is connected to the other end of shell 89, itself and U-shaped separation of particles module 3
Docking.Described S type elastic thin-wall 87 is installed in shell 88 along the radial direction of shell, is formed swollen in it
Swollen chamber 71 and contraction chamber 72.The axis of described input pipe 81 and outlet tube 89 the most on the same axis,
So can improve the filter effect of more than 10%.
Described input pipe 81, outlet tube 89 and S type elastic thin-wall 87 are collectively forming a S type cavity volume filter
Ripple device, thus hydraulic system high frequency pressure pulsations of decaying.The filtering obtained after processing by lumped-parameter method
Device transmission coefficient is:
Velocity of sound L contraction chamber length D expansion chamber diameter Z characteristic resistance in a medium
Anti-
γ transmission coefficient f pressure oscillation frequency dIInput pipe diameter d contraction chamber
Diameter
k1Expansion chamber coefficient k2Contraction chamber coefficient
From above formula, S type cavity volume wave filter is similar with the electric capacity effect in circuit.Different frequency
When pressure pulse wave is by this wave filter, transmission coefficient is different with frequency.Frequency is the highest, then transmission
Coefficient is the least, and this shows that the pressure pulse wave of high frequency is decayed the most severe when device after filtering, thus
Serve the effect eliminating high frequency pressure pulsations.Meanwhile, in the S type holding cavity structure of the present invention, expand
Transitions smooth between chamber and contraction chamber, contributes to reducing the system pressure damage that cavity diameter sudden change brings
Lose.
The design principle of described S type cavity volume wave filter is as follows: when the flow of change is entered by input pipe
During the expansion chamber of S type cavity volume, liquid stream exceedes average discharge, and the expansion chamber of expansion can absorb unnecessary liquid
Stream, and when less than average discharge, release liquid stream, thus absorption pressure pulsation energy.Multiple expansion chamber
Combination with contraction chamber then improves the fluctuation pressure absorbability of wave filter, namely filtering performance.Swollen
Use curved surface to smoothly transit between swollen chamber and contraction chamber, then avoid the edge brought by fluid boundary sudden change
Stroke pressure loss and heating.
Described S type elastic thin-wall 87 weakens hydraulic system medium-high frequency pressure by being forced to mechanical vibration
Pulsation.The S type elastic thin-wall natural frequency obtained after processing by lumped-parameter method is:
K S type elastic thin-walled structures coefficient h S type elastic thin-wall thickness R S type bullet
Property thin-walled radius
The mass density of the Young's modulus ρ S type elastic thin-wall of E S type elastic thin-wall
The Poisson's ratio of the current-carrying factor mu S type elastic thin-wall of η S type elastic thin-wall.
Substitute into actual parameter, above formula is carried out simulation analysis it is found that the consolidating of S type elastic thin-wall 87
There is frequency generally high than the natural frequency of H mode filter, and its attenuation band also ratio H mode filter
Wide.In relatively wide frequency band range, S type elastic thin-wall has good decay to pressure fluctuation
Effect.Meanwhile, the S type elastic thin-wall radius in the filter construction of the present invention is bigger and relatively thin, its
Natural frequency, closer to Mid Frequency, can realize effectively declining to the medium-high frequency pressure fluctuation in hydraulic system
Subtract.
The design principle of described S type elastic thin-wall 87 is as follows: when producing intermediate frequency pressure fluctuation in pipeline,
Double-pipe plug-in type cavity volume wave filter is more weak to the damping capacity of pressure oscillation, flows into Double-pipe plug-in type cavity volume
Periodically pulsing pressure continuous action on the inside and outside wall of S type elastic thin-wall, between inside and outside wall
Having the fixing connection of pillar, inside and outside S type elastic thin-wall does periodic vibration by the frequency of fluctuation pressure simultaneously,
This forced vibration consumes the pressure fluctuation energy of fluid, thus realizes the filtering of Mid Frequency pressure.By void
Merit principle understands, when S type elastic thin-wall consumes ability and its forced vibration of fluid pulsation pressure energy
Potential energy and kinetic energy sum directly related, in order to improve Mid Frequency filtering performance, S type elastic thin-wall
Radial design is much larger than pipe radius, and the thickness of thin-walled is less, and representative value is less than 0.1mm.
Further, the resonance forming cylinder between described S type elastic thin-wall 87 and shell 88 is held
Chamber 85.Some taper structure changes damping holes 86 are uniformly had in the axial direction of described S type elastic thin-wall 87,
To ensure all to realize plug-in type connection in series-parallel filtering in the range of whole wave filter.Taper structure changes hinders
Buddhist nun hole 86 connection resonance cavity volume 85.The wider place of described taper structure changes damping hole opening is positioned at resonance and holds
Intracavity, its taper angle is 10 °, for broadening frequency filtering scope, after processing by lumped-parameter method
To wave filter natural angular frequency be:
Velocity of sound L damping hole long S damping hole cross-sectional area V parallel resonance in a medium
Cavity volume volume.
Described corrugated tube 83 is wound on outside resonance cavity volume 85 in the shape of a spiral, and resonance cavity volume 85 is by many
Individual taper is inserted pipe 82 and is connected.Described taper is inserted the wider place of pipe 82 opening and is positioned at corrugated tube 83,
Its taper angle be 10 ° for broadening frequency filtering scope.If described corrugated tube 83 passes through between respectively enclosing
Heavenly Stems and Earthly Branches pipe 810 connects, and arm 810 is provided with switch 84.Described corrugated tube 83 and resonance cavity volume 85
Composition plug-in type spiral isomery cascaded H mode filter.
From the figure 3, it may be seen that cascaded H mode filter has 2 natural angular frequencies, filter effect at crest
Preferably, at trough, the most substantially do not has filter effect;Plug-in type spiral isomery cascaded H mode filter
In have employed corrugated tube 83 structure of spiral isomery, corrugated tube itself has elasticity, works as hydraulic system
Flow and pressure fluctuation through corrugated tube, fluid media (medium) causes the vibration of hydraulic pressure-spring system, offsets
Wave energy, thus play filter action;Meanwhile, the some arms 810 between each circle corrugated tube 83
Connection or disconnection, cause interference and the superposition of ripple, thus the frequency changing cascaded H mode filter be special
Property;Reasonable arrangement filter parameter and the connection quantity of arm and position, can make cascaded H type filter
The trough of the frequency characteristic of device is raised, and makes wave filter have good filtering at whole medium and low frequency Duan Jun
Can, it is achieved the entire spectrum filtering of medium and low frequency section.
Further, described taper structure changes damping hole 86 is by cone shaped elastic damping hole pipe 16 and slot apertures
15 compositions, taper narrow end is opened on elastic thin-wall 7.The wherein poplar of cone shaped elastic damping hole pipe 16
The Young's modulus of family name's modular ratio elastic thin-wall 7 wants big, can be with change in fluid pressure stretching or compression;Seam
The Young's modulus in hole 15 is bigger than the Young's modulus of cone shaped elastic damping hole pipe 16, can be with fluid pressure
It is turned on and off.Therefore when the fluctuating frequency of pressure falls at high band, S type cavity volume filter construction plays filter
Ripple effect, cone shaped elastic damping hole pipe 16 and slot apertures 15 are all in Fig. 7 (a) state;And when pulsation
Frequency falls when Mid Frequency, and filter construction becomes S type cavity volume filter construction and elastic thin-wall 7 is filtered
Wave structure concurs, and cone shaped elastic damping hole pipe 16 and slot apertures 15 are all in Fig. 7 (a) state;
When ripple frequency falls at some specific Frequency, filter construction becomes plug-in type connection in series-parallel H
Mode filter, S type cavity volume filter construction and elastic thin-wall filter structure concur, Conical Projectile
Property damping hole pipe 16 and slot apertures 15 all in Fig. 7 (b) state, owing to plug-in type connection in series-parallel H type is filtered
The natural frequency of ripple device is designed to consistent with these particular low frequency ripple frequencies, big to fundamental frequency energy
System can play preferable filter effect;When ripple frequency falls the low-frequency range beyond some characteristic frequency
Time, cone shaped elastic damping hole pipe 16 and slot apertures 15 are all in Fig. 7 (c) state.Such structure changes
Wave filter design both ensure that the full frequency band full working scope filtering of hydraulic system, reduces again under nominal situation
The pressure loss of wave filter, it is ensured that the hydraulic pressure rigidity of system.
This wave filter 8 can also the pulsation decay of solid line operating mode self-adaptive pressure.When hydraulic system working conditions change
Time, both executive component stopped suddenly or ran, and when the opening of valve changes, can cause pipe-line system
Characteristic impedance undergo mutation, so that former pipeline pressure is in time with the curve of change in location the most therewith
Change, then the position of pressure peak also changes.Owing to the axial length of the wave filter of the present invention sets
It is calculated as more than system main pressure pulsation wavelength, and the plug-in type spiral isomery cascaded H type filter of wave filter
The cavity volume length of ripple device, the length of S type cavity volume wave filter and the length of elastic thin-wall and wave filter axis
Length is equal, it is ensured that pressure peak position is constantly in the effective range of wave filter;Insert
The taper structure changes damping hole of formula spiral isomery cascaded H mode filter is opened on S type elastic thin-wall, edge
Axis direction is uniformly distributed, and corrugated tube and the taper insertion pipe resonated between cavity volume that spiral isomery is wound around exist
Axially it is uniformly distributed so that the performance of wave filter is had little to no effect by pressure peak change in location, from
And achieve operating mode adaptive-filtering function.In view of three kinds of filter structure axial dimensions and wave filter phase
When, this bigger size also ensure that hydraulic filter possesses stronger pressure fluctuation damping capacity.
This wave filter 8 is used to carry out the method for hydraulic pulsation filtering as follows:
1), hydraulic fluid enters S type cavity volume wave filter by input pipe, and it is unnecessary that the cavity volume of expansion absorbs
Liquid stream, completes the filtering of high frequency pressure pulsations;
2), by S type elastic thin-wall 87 forced vibration, the pressure fluctuation energy of fluid is consumed, complete
Become the filtering of intermediate frequency pressure fluctuation;
3), by plug-in type spiral isomery cascaded H mode filter, taper structure changes damping hole, taper
Insert pipe and fluid produces resonance, consume pulsation energy, complete the filtering of low frequency pulsation;
4), the axial length of wave filter is designed as more than hydraulic system main pressure pulsation wavelength, and
Plug-in type connection in series-parallel H mode filter length, Double-pipe plug-in type filter length and S type elastic thin-wall
87 length are equal with filter length, make pressure peak position be constantly in the useful effect model of wave filter
Enclose, it is achieved the filtering of pressure fluctuation when system condition changes;
5), by stretching of the cone shaped elastic damping hole pipe of taper structure changes damping hole and opening of slot apertures
Close, complete pressure fluctuation adaptive-filtering.
Described U-shaped separation of particles module 3 includes a U-tube 31, and U-tube 31 is sequentially installed with
Electrification module 32, separation module the 33, first adsorption module 34, mechanical centrifugal module 36, second are inhaled
Attached module 37 and demagnetization module 35.
Described electrification module 32 makes the metallic particles material in fluid charged, and it is by some electrodes 321
And one electrode controller 322 form.Described some electrodes 321 are installed in U-tube 31, its
It is respectively connecting to electrode controller 252.Described electrode controller 322 is electrically connected with to be executed to electrode 321
Making alive, makes the particulate matter in fluid charged.
Described separation module 33 make particle charge that quality is bigger poly-be incorporated under centrifugal action get rid of to
Cavity wall, it can use uniform magnetic field separation module, rotating excitation field separation module or helical pipe magnetic field to divide
From module.
When described separation module 33 uses uniform magnetic field separation module, it is by 331, two, aluminum matter pipeline
Magnetic pole 332 and magnetic pole controller 333 form.Wherein, said two magnetic pole 332 is separately positioned on
On aluminum matter pipeline 331, the opposite polarity of these two magnetic poles 332, and in being oppositely arranged.Said two
Magnetic pole 332 is respectively and electrically connected on magnetic pole controller 333.
The design principle of described uniform magnetic field separation module 33 is as follows: charged particle flows into speed V
Uniform magnetic field separation module 33, two magnetic poles 332 of uniform magnetic field separation module 33 produce and speed
The uniform magnetic field that V direction is vertical, according to left hand rule, then charged particle is at uniform magnetic field separation module
By being perpendicular to acting on of the Loulun magnetism of velocity attitude and magnetic direction in 33, this power does not change charged
The speed of granule, it only changes the direction of motion of charged particle, makes charged particle under this force
To the vessel wall motion of aluminum matter pipeline 331, so that the granule in fluid " separates " out from fluid,
Assemble to tube wall, it is simple to subsequent adsorbtion captures.Owing to fluid has certain viscosity, granule is to tube wall
Motor process is also acted on by viscous drag.In order to ensure separating effect, need to regulate magnetic field strong
Degree B makes the granule of distance tube wall farthest to move at tube wall within the action time of separation module,
Quantitative analysis is as follows:
Assuming that particle mass is m, speed is v, and magnetic field intensity is B, and carried charge is q, separation module
A diameter of D, a length of L, then:
Acting on the Loulun magnetism on charged particle is
Fl=qvB
The viscous drag that charged particle is subject to is
Fd=6 π η r v
Charged of the radius v of η hydraulic pressure oil viscosity r charged particle
Grain movement velocity
It not general, it is assumed that the granule in fluid has reached stable state when entering separation module, the most charged
Granule can be approximated by the time of separation module and represent with following formula
The charged particle of distance tube wall farthest moves to the time t at tube wall2Can be solved by following formula
Regulation B so that t1>t2, i.e. can reach separating effect.
When described separation module 33 uses rotating excitation field separation module, it is by aluminum matter pipeline 331, irony
The parts compositions such as shell 334, three-phase symmetric winding 335 and three-phase symmetrical current module 336.Institute
State three-phase symmetric winding 335 to be wound on outside aluminum matter pipeline 331.Described iron shell 334 is coated on aluminum matter
On pipeline 335.Described three-phase symmetrical current module 336 connects described three-phase symmetric winding 335.
The design principle of described rotating excitation field separation module 33 is as follows: charged particle flows into speed V
Rotating excitation field separation module 33, three-phase symmetrical current module 336 makes to flow through in three-phase symmetric winding 335
Three-phase symmetrical electric current, this electric current produces rotating excitation field in aluminum matter pipeline 331, and charged particle is rotating
By being perpendicular to acting on of the Loulun magnetism of velocity attitude and magnetic direction under the action of a magnetic field, this power does not changes
Becoming the speed of charged particle, it only changes the direction of motion of charged particle, makes charged particle in this power
Spirally advance under effect, and to vessel wall motion.Reasonable adjusting magnetic field intensity can make in fluid
Granule " separates " out from fluid, is gathered in near-wall, it is simple to subsequent adsorbtion captures.Due to
Fluid has certain viscosity, and granule is also acted on by viscous drag during vessel wall motion.For
Guarantee separating effect, need to make the microgranule on aluminum matter pipeline 331 axis can be in the effect of separation module
Moving in time at tube wall, quantitative analysis is as follows:
Assuming that particle mass is m, speed is v, and magnetic field intensity is B, and carried charge is q, separation module
A diameter of D, a length of L, then:
Acting on the Loulun magnetism on charged particle is
Fl=qvB
The viscous drag that charged particle is subject to is
Fd=6 π η r v
Charged of the radius v of η hydraulic pressure oil viscosity r charged particle
Grain movement velocity
Assuming that the granule in fluid has reached stable state when entering separation module, then charged particle is by separating
The time of module can approximate and represent with following formula
Charged particle on conduit axis moves to the time t at tube wall2Can be solved by following formula
Regulation B so that t1>t2, i.e. can reach separating effect.
When described separation module 33 uses helical pipe magnetic field separation module, it is by aluminum matter helical pipe
338, solenoid 339 and solenoid control circuit 336 form.Wherein, described aluminum matter serpentine pipe
Road 338 is arranged in solenoid 339.Described solenoid 339 and solenoid control circuit 336 are electrical
Connect.Described solenoid control circuit 336 is electrically connected to ECU3.
The design principle of described helical pipe magnetic field separation module 33 is as follows: carry the oil of charged particle
Liquid advances along aluminum matter helical pipe 338, thus produces at pipeline exit and have certain spin direction
Eddy flow, the charged particle of heavier mass rotates along with fluid, produces under the influence of centrifugal force to tube wall
Radial motion;Simultaneously as the Way in of aluminum matter helical pipe 338 and energization solenoid 339
Axial magnetic field direction vertical, enter the charged particle of aluminum matter helical pipe 338 by Lip river with speed v
The effect of logical sequence magnetic force, direction is perpendicular to magnetic direction and the Way in of aluminum matter helical pipe 338.Lip river
Logical sequence magnetic force makes charged particle spin in pipeline forward travel, due to entering of aluminum matter helical pipe 338
Mouthful direction and magnetic direction are close to vertical, and charged particle mainly rotates in a circumferential direction motion, and fluid is the most not
Impacted, thus realize granule " separation " from fluid, in order to realize the absorption to granule.For
Ensure " separation " effect, need to make the microgranule on aluminum matter conduit axis can be when the effect of separation module
In move at tube wall, quantitative analysis is as follows:
Assuming that particle mass is m, speed is v, and carried charge is q, a diameter of D of aluminum matter helical pipe,
The number of turn of aluminum matter helical pipe is n, the Way in of aluminum matter helical pipe and energization solenoid axial
The angle of magnetic direction is θ, and the solenoid number of turn is N, and electric current is I, and magnetic field intensity is B, Vacuum Magnetic
Conductance is μ0, then:
Acting on the Loulun magnetism on charged particle is
Fl=qvB
The viscous drag that charged particle is subject to is
Fd=6 π η r v
Charged of the radius v of η hydraulic pressure oil viscosity r charged particle
Grain movement velocity
Charged particle can be approximated by the time of separation module and represent with following formula
Charged particle on conduit axis moves to the time t at tube wall2Can be solved by following formula
Magnetic field intensity within solenoid can be approximately constant
Regulation I so that t1>t2, i.e. can reach separating effect.
Described first adsorption module 34 is the most micro-for adsorbing the magnetic polymeric after separated module 33 separates
, it can use homopolarity adjacent type absorbing ring, and this homopolarity adjacent type absorbing ring is by aluminium ring shape pipeline
341, the parts such as forward solenoid 342, reverse solenoid 343 and irony magnetic conduction cap 344 composition.
Wherein, described forward solenoid 342 and reverse solenoid 343 are respectively arranged in aluminium ring shape pipeline
341, both are connected with electric current in opposite direction so that forward solenoid 342 and reverse solenoid 343
Adjacent produces like pole.Described irony magnetic conduction cap 344 is arranged in the interior of aluminium ring shape pipeline 341
On wall, it is positioned at forward solenoid 342 and reverse solenoid 343 adjacent and forward solenoid
342 and the intermediate point of reverse solenoid 343 axis.
The design principle of described homopolarity adjacent type absorbing ring is as follows: energising forward solenoid 342, reversely
Solenoid 343, adjacent forward solenoid 342, reverse solenoid 343 are connected with electricity in opposite direction
Stream so that forward solenoid 342, reverse solenoid 343 adjacent produce like pole;Meanwhile,
Aluminium ring shape pipeline 341 can improve magnetic circuit, strengthens the magnetic field intensity at inner-walls of duct, strengthens irony
The magnetic conduction cap 344 capture absorbability to granule.Each forward solenoid 342, reverse solenoid 343
Electric current can be different with concentration and change, to obtain optimal adsorption performance according to the size of granule.
Further, described first adsorption module 34 may be used without the homopolarity adjacent type suction of charged hammer
Follower ring, the homopolarity adjacent type absorbing ring of this charged hammer is by aluminium ring shape pipeline 341, forward solenoid
342, reverse solenoid 343, irony magnetic conduction cap 344, dividing plate 345, electric shock hammer 346 and electromagnetism
Ferrum 347 parts such as grade form.Wherein, described forward solenoid 342 and reverse solenoid 343 cloth respectively
Being placed in aluminium ring shape pipeline 341, both are connected with electric current in opposite direction so that forward solenoid 342
Like pole is produced with reverse solenoid 343 adjacent.Described irony magnetic conduction cap 344 is arranged in aluminum matter
On the inwall of circulating line 341, its be positioned at forward solenoid 342 and reverse solenoid 343 adjacent,
And forward solenoid 342 and the intermediate point of reverse solenoid 343 axis.Described electric shock hammer 346 Hes
Electric magnet 347 is between dividing plate 345.Described electric magnet 347 connects and can promote electric shock hammer 346,
Make electric shock hammer 346 percussion aluminium ring shape pipeline 342 inwall.
The design principle of the homopolarity adjacent type absorbing ring of described charged hammer is as follows: energising forward solenoid
342, reverse solenoid 343, adjacent forward solenoid 342, reverse solenoid 343 are connected with direction
Contrary electric current so that forward solenoid 342, reverse solenoid 343 adjacent produce like pole;
Meanwhile, aluminium ring shape pipeline 341 can improve magnetic circuit, strengthens the magnetic field intensity at inner-walls of duct, increases
The strong irony magnetic conduction cap 344 capture absorbability to granule.Each forward solenoid 342, reverse helical
Pipe 343 electric current can be different with concentration and change, to obtain best adsorption according to the size of granule
Energy.And by the setting of electric shock hammer 346, prevent granule bulk deposition at irony magnetic conduction cap 344,
Affect adsorption effect.Now, controlled in electric shock hammer 346 percussion pipeline 341 by electric magnet 347
Wall so that adsorbed granule scatter to both sides.Meanwhile, when cleaning pipeline 341, electric shock hammer
The percussion of 346 can also improve cleaning performance.
Described first adsorption module 34 is designed to U-shaped, when fluid enters U-shaped absorption pipeline,
Grain gravity, centrifugal force effect under, to side, tube wall moves, plus magnetic field force effect, radially
Translational speed is accelerated, and the efficiency of granular absorption is improved;Leave U-shaped absorption pipeline at fluid to rise
Time, gravity and magnetic field force make a concerted effort so that granule diagonally under direction motion, extend numerical density
Time, improve the efficiency of granular absorption.
Described mechanical centrifugal module 36 makes the magnetization aggregated particles not to be adsorbed in fluid at centrifugal work
It is thrown toward tube wall under with.Described mechanical centrifugal module 36 selects eddy flow to be centrifuged module 36, this eddy flow from
Core module 36 uses the mode of energy loss, and its design principle is as follows: arrange certain height in the duct
The flow deflector of the distortion of degree and length, and make blade face tangent line angled with axis, because of pipe flow border
Changing and fluid can be made to produce spiral flow in pipes, this spiral flow can be analyzed to the circumferential flow around pipe axle
With axial straight flowing, the particulate matter carried in fluid produces off-axis alignment heart screw.This eddy flow
Centrifugal device 36 is by eddy flow tube wall the 361, first flow deflector the 362, second flow deflector 363, stepping electricity
Several parts compositions such as machine 364 and flow transducer 365.
Wherein, described first flow deflector 362 is provided with 3, and these 3 first flow deflectors 362 are along tube wall
361 inner peripherys are uniformly distributed every 120 °, its laying angle (the first flow deflector 362 and eddy flow tube wall 361
Between angle) be set to 18 °, to ensure optimal tangential flowing.Described second flow deflector 363 and
One flow deflector 362 structure is identical, after it is arranged on the first flow deflector 362, and and the first flow deflector 362
Staggering 60 ° and be connected in tube wall 361, its laying angle is set to 36 DEG C, is used for reducing resistance and strengthening week
Intensity to flowing.It addition, the 3rd or more water conservancy diversion can be arranged the most again according to actual separation effect
Sheet, laying angle gradually increases.Described motor 364 connects and drives the first flow deflector 362 and
Two flow deflectors 363, to regulate laying angle, thus can obtain more preferable centrifugal effect, know and make water conservancy diversion
Sheet 362,363 adapts to different operating modes.Described flow transducer 365 is arranged in tube wall 361
Central authorities, by the numerical analysis cyclonic separation effect of reading flow quantity sensor 365, and control step accordingly
Entering motor 364, motor 364 regulates the laying angle of each flow deflector 362,363, to obtain more
Separating effect.
Described second adsorbent equipment 37 is identical with described first adsorbent equipment 34 structure, function and effect
Mechanism is the most identical, and it can adsorb the granule separated through mechanical centrifugal module 36 further.
Described demagnetization module 35 gives magnetized particles demagnetization, prevents residual magnetism microgranule from being entered by oil returning tube
Oil pipe enters hydraulic circuit, and sensitive to pollution Hydraulic Elements cause damage.
An oil returning tube oil inlet pipe 22 is passed through in the top of described U-shaped separation of particles module 3 and oil returning tube 7
Connect;By U-shaped separation of particles module 3 process after, the fluid of U-tube 31 near-wall rich in
Aggregated particles, is back to fuel tank after entering oil returning tube 7 by oil returning tube oil inlet pipe 22.
The bottom of described oil returning tube 7 is provided with an overflow valve 8, is provided with an automatically controlled tune bottom this overflow valve 8
Joint screw 9;Described overflow valve 8 is provided with an oil drain out 10, and this oil drain out 10 is by pipeline 20 even
It is connected to a fuel tank 11.
Described inner core 15 is placed in outer barrel 19, if it is installed by a top board 13 and bolt stem 21
On end cap 25.Described helical flow path 17 is contained in inner core 15, itself and U-shaped separation of particles mould
Connected by an inner core oil inlet pipe 12 between block 3, specifically, described inner core oil inlet pipe 12 and spiral shell
The tangent connection in eddy flow road 17.The fluid of the U-tube 31 pipeline center only small particle microgranule Han trace is logical
Cross inner core oil inlet pipe 12 to enter inner core 15 and realize high-precision filtration, thus realize solid particle and separate.
Further, described inner core oil inlet pipe 12 is positioned at oil returning tube oil inlet pipe 22, and extends into U-shaped micro-
The central authorities of grain separation module 3, its diameter is less than oil returning tube oil inlet pipe 22 diameter, and enters with oil returning tube
Oil pipe 22 is coaxially disposed.
Further, the bottom of described inner core 15 is rounding mesa-shaped, and it passes through an inner core oil exit pipe 23
Connecting with oil returning tube 7, inner core oil exit pipe 23 is provided with an automatically controlled check-valves 24.Described inner core 15
Center upright is provided with a hollow cylinder 16, hollow cylinder 16 be arranged over pressure difference indicator 14, should
Pressure difference indicator 14 is installed on end cap 25.
Described filter element 18 is arranged on the inwall of inner core 15, and its precision is 1-5 micron.
The bottom of said tub 19 is provided with a hydraulic oil oil-out 5, is incited somebody to action by hydraulic oil oil-out 5
The hydraulic oil filtered is discharged.
In the present invention, due to U-shaped separation of particles module 3, solid particle separation of polymeric in fluid is made
With, in the fluid in U-shaped separation of particles module 3 exit, the fluid at the center only small particle Han trace
Microgranule, this part fluid is flowed into inner core 15 from inner core oil inlet pipe 12 and carries out high-precision filtration;And manage
Fluid near wall is rich in aggregated particles, and this part fluid enters oil return by oil returning tube oil inlet pipe 22
Cylinder 7, then flow back to fuel tank 11 through the oil drain out 10 of overflow valve 8, thus realize solid particle by particle
Footpath shunting filtering.Herein, oil returning tube 7 and overflow valve 8 serve aforesaid macrofiltration, thus save
Save filter number, reduce system cost and complexity.The automatically controlled set screw 9 of overflow valve 8
For regulating oil pressure relief, its pressure is adjusted to slightly below pressure at filtering outlet, to ensure inner core
15 filtering traffics.
It addition, traditional filter mainly uses cake filtration mode, during filtration, filtrate is perpendicular to filter
Element surface flows, and trapped solid particle forms filter cake progressive additive, and the rate of filtration is the most therewith
It is gradually reduced, until filtrate stops flowing out, reduces the service life of filter element.In this present invention
In, carry in the filtrate of small particle microgranule flows in the way of tangential influent stream from inner core oil inlet pipe 12
The helical flow path 17 of cylinder 15, inner core 15 wall of helical duct 17 side is high-precision filter element 18, filter
Liquid is close to filter element 18 surface under the influence of centrifugal force, and filtrate is parallel to the surface of filter element 18 and quickly flows
Dynamic, the hydraulic oil after filtration is then perpendicular to filter element 18 surface direction and flows out to urceolus 19, the two stream
Dynamic direction is orthogonal staggered, therefore is called cross flow and filters.The quickly flowing of filtrate is to being gathered in
The microgranule on filter element 18 surface is applied with shearing and sweeps stream effect, thus inhibits the increase of filter cake thickness,
Making rate of filtration near constant, filter pressure also will not raise with the passing of time, making of filter element
With the life-span thus increase substantially.Along with the accumulation of filtration time, it is deposited at the bottom of inner core 15 inverted round stage
The pollution granule in portion is stepped up, and the rate of filtration slowly declines, unfiltered filtrate edge in inner core 15
The hollow cylinder 16 at center rises, and now, pressure difference indicator 14 works, and monitors the change of its pressure,
That is the stopping state of filter element 18 bottom inner core 15, if exceeding threshold value, then regulate automatically controlled set screw
9 reduce oil pressure relief, and open check-valves 24 simultaneously, make bottom inner core 15 containing more pollution granule
Filtrate under differential pressure action, be discharged to oil returning tube 7 by inner core oil exit pipe 23, it is to avoid bottom filter element
18 blockage deteriorate, thus extend filter element 18 service life.
The processing step using above-mentioned oil filter to process backflow force feed is as follows:
1), the fluid in fluid pressure line pass through wave filter 8, wave filter 8 decay the height in hydraulic system,
In, the fluctuation pressure of low-frequency range, and suppression flowed fluctuation;
2), backflow force feed enters the electrification module 32 of U-shaped separation of particles module 3, makes in fluid
Particulate matter is charged, delivers to separation module 33 afterwards;
3), the charged corpuscle in fluid is made to gather to tube wall under the effect of external force by segregation apparatus 33
Closing, the first adsorbent equipment 34 is delivered in oil return afterwards;
4), being adsorbed the magnetic polymeric microgranule in oil return by the first adsorption module 34, oil return afterwards is sent
To mechanical centrifugal module 36;
5), magnetic microparticles not to be adsorbed is centrifuged by mechanical centrifugal module 36, and oil return afterwards is sent
To the second adsorption module 37;
6), the magnetic polymeric microgranule in the second adsorption module 37 second adsorption oil return;
7), magnetic particle magnetic is eliminated by demagnetization module 35;
8), the fluid of the most U-shaped separation of particles module 3 near-wall passes through oil returning tube oil inlet pipe 22
Being back to fuel tank after entering oil returning tube 7, the fluid of the pipeline center containing trace small particle microgranule then leads to
Cross inner core oil inlet pipe 12 to enter inner core 15 and carry out high-precision filtration;
9) fluid, carrying small particle microgranule flows into the spiral flow of inner core 15 in the way of tangential influent stream
Road 17, fluid is close to filter core flow under the influence of centrifugal force, and is carried out high-precision filtration;
10), the fluid after high-precision filtration enters urceolus 19, and by the hydraulic oil bottom urceolus 19
Oil-out 5 is discharged.
Above detailed description of the invention is only the preferred embodiment of this creation, not in order to limit this wound
Make, all any modification, equivalent substitution and improvement etc. done within this spirit created and principle,
Within should be included in the protection domain of this creation.
Claims (10)
1. with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterised in that: include base plate, wave filter, U-shaped separation of particles module, oil returning tube, inner core, helical flow path, filter element, outer barrel and end cap;Wherein, described wave filter, U-shaped separation of particles module, oil returning tube, outer barrel are sequentially placed on base plate;Described wave filter includes input pipe, shell, outlet tube, corrugated tube and S type elastic thin-wall;Wherein, described input pipe is connected to one end of shell, itself and hydraulic oil inlet docking;Described outlet tube is connected to the other end of shell, and itself and U-shaped separation of particles module are docked;Described S type elastic thin-wall is installed in shell along the radial direction of shell, forms expansion chamber and contraction chamber in it;Described input pipe, outlet tube and S type elastic thin-wall are collectively forming a S type cavity volume wave filter;The resonance cavity volume of cylinder is formed between described S type elastic thin-wall and shell;Some taper structure changes damping holes, taper structure changes damping hole connection resonance cavity volume is uniformly had in the axial direction of described S type elastic thin-wall;Described taper structure changes damping hole is made up of cone shaped elastic damping hole pipe and slot apertures;Described corrugated tube is wound on outside resonance cavity volume in the shape of a spiral, inserts pipe with resonance cavity volume by multiple tapers and connects;Described corrugated tube is connected by some arms between respectively enclosing, and arm is provided with switch;Described corrugated tube and resonance cavity volume composition plug-in type spiral isomery cascaded H mode filter;Described U-shaped separation of particles module includes a U-tube, and U-tube is sequentially installed with electrification module, separation module, the first adsorption module, mechanical centrifugal module, the second adsorption module and demagnetization module;The top of described U-shaped separation of particles module and oil returning tube is connected by an oil returning tube oil inlet pipe;Described inner core is placed in outer barrel, if it is installed on end cap by a top board and bolt stem;Described helical flow path is contained in inner core, is connected by an inner core oil inlet pipe between itself and U-shaped separation of particles module;Described inner core oil inlet pipe is positioned at oil returning tube oil inlet pipe, and extends into the central authorities of U-shaped separation of particles module, and its diameter is less than oil returning tube oil inlet pipe diameter, and and oil returning tube oil inlet pipe be coaxially disposed;Described filter element is arranged on the inwall of inner core, and its precision is 1-5 micron;The bottom of said tub is provided with a hydraulic oil oil-out.
2. as claimed in claim 1 with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterised in that: the axis of described input pipe and outlet tube is the most on the same axis;The wider place of described taper structure changes damping hole opening is positioned at resonance cavity volume, and its taper angle is 10 °;The Young's modulus of described taper structure changes damping hole cone shaped elastic damping hole pipe is bigger than the Young's modulus of elastic thin-wall, can be with change in fluid pressure stretching or compression;The Young's modulus of slot apertures is bigger than the Young's modulus of cone shaped elastic damping hole pipe, can be with fluid opened by pressure or closedown;Described taper is inserted the wider place of tube opening and is positioned at corrugated tube, and its taper angle is 10 °.
3. as claimed in claim 1 with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterised in that: described electrification module includes some electrodes and an electrode controller;Described some electrodes are installed on the first oil return pipe, and it is respectively connecting to electrode controller.
4. as claimed in claim 1 with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterized in that: described separation module uses uniform magnetic field separation module, and this uniform magnetic field separation module includes aluminum matter pipeline, two magnetic poles and magnetic pole controller;Wherein, said two magnetic pole is separately positioned on aluminum matter pipeline, the opposite polarity of these two magnetic poles, and in being oppositely arranged;Said two magnetic pole is respectively and electrically connected on magnetic pole controller.
5. as claimed in claim 1 with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterized in that: described separation module uses rotating excitation field separation module, and this rotating excitation field separation module includes aluminum matter pipeline, iron shell, three-phase symmetric winding and three-phase symmetrical current module;Described three-phase symmetric winding is wound on outside aluminum matter pipeline;Described iron shell is coated on aluminum matter pipeline;Described three-phase symmetrical current module connects described three-phase symmetric winding.
6. as claimed in claim 1 with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterized in that: described separation module uses helical pipe magnetic field separation module, and this helical pipe magnetic field separation module includes aluminum matter helical pipe, solenoid and solenoid control circuit;Wherein, described aluminum matter helical pipe is arranged in solenoid;Described solenoid and solenoid control circuit are electrically connected with.
7. as claimed in claim 1 with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterized in that: described first adsorption module and second is inhaled adsorption module and used homopolarity adjacent type absorbing ring, and this homopolarity adjacent type absorbing ring includes aluminium ring shape pipeline, forward solenoid, reverse solenoid and irony magnetic conduction cap;Described forward solenoid and reverse solenoid are respectively arranged in aluminium ring shape pipeline, and both are connected with electric current in opposite direction so that forward solenoid and reverse solenoid adjacent produce like pole;Described irony magnetic conduction cap is arranged on the inwall of aluminium ring shape pipeline, and it is positioned at forward solenoid and reverse solenoid adjacent and forward solenoid and the intermediate point of reverse solenoid axis.
8. as claimed in claim 1 with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterized in that: described first adsorption module and second is inhaled adsorption module and used the homopolarity adjacent type absorbing ring of charged hammer, and the homopolarity adjacent type absorbing ring of this charged hammer includes aluminium ring shape pipeline, forward solenoid, reverse solenoid, irony magnetic conduction cap, dividing plate, electric shock hammer and electric magnet;Described forward solenoid and reverse solenoid are respectively arranged in aluminium ring shape pipeline, and both are connected with electric current in opposite direction so that forward solenoid and reverse solenoid adjacent produce like pole;Described irony magnetic conduction cap is arranged on the inwall of aluminium ring shape pipeline, and it is positioned at forward solenoid and reverse solenoid adjacent and forward solenoid and the intermediate point of reverse solenoid axis;Described dividing plate is between forward solenoid and reverse solenoid;Described electric shock hammer and electric magnet are between dividing plate;Described electric magnet connects and can promote electric shock hammer, makes electric shock hammer tap aluminium ring shape inner-walls of duct.
9. described in claim 1 with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterised in that: described mechanical centrifugal module uses eddy flow to be centrifuged module;Described eddy flow is centrifuged module and includes eddy flow tube wall, the first flow deflector, the second flow deflector, motor and flow transducer;Wherein, described first flow deflector is provided with 3, and these 3 first flow deflectors are uniformly distributed along tube wall inner periphery every 120 °, and its laying angle is set to 18 °;Described second flow deflector and the first flow deflector structure are identical, after it is arranged on the first flow deflector, and and the first flow deflector stagger 60 ° and be connected in tube wall, its laying angle is set to 36 DEG C;The long limit of described first flow deflector is connected with tube wall, and minor face extends along the axis of tube wall;Its leading edge frustrates into obtuse, and trailing edge is processed into wing, and its height is 0.4 times of tube wall diameter, 1.8 times of a length of tube wall diameter;Described motor connects and drives the first flow deflector and the second flow deflector, to regulate laying angle;Described flow transducer is arranged on the central authorities in tube wall.
10. described in claim 1 with full frequency band structure changes operating mode adaptive-filtering, the oil filter that electrifies and be centrifuged, it is characterised in that: the bottom of described oil returning tube is provided with an overflow valve, is provided with an automatically controlled set screw bottom this overflow valve;Described overflow valve is provided with an oil drain out, and this oil drain out is connected to a fuel tank by pipeline;The bottom of described inner core is rounding mesa-shaped, and it is connected by an inner core oil exit pipe and oil returning tube, and inner core oil exit pipe is provided with an automatically controlled check-valves;The center upright of described inner core is provided with a hollow cylinder, hollow cylinder be arranged over pressure difference indicator, this pressure difference indicator is installed on end cap;Described inner core oil inlet pipe and the tangent connection of helical flow path.
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Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN85109568A (en) * | 1985-12-26 | 1987-07-01 | 中国人民解放军工程兵工程学院野战工程系工程机械教研室 | The purification mechanism and the structure of multimachine reason high accuracy oil conditioner |
CN87101425A (en) * | 1987-11-21 | 1988-08-24 | 李培滋 | Filter |
CN2463660Y (en) * | 2000-12-22 | 2001-12-05 | 中国船舶重工集团公司第七研究院第七○四研究所 | Pipeline vibration and fluid pressure pulsation attenuator |
CN104028391A (en) * | 2013-03-08 | 2014-09-10 | 深圳中环科环保科技有限公司 | Magnetic hydrocyclone separation method and magnetic hydrocyclone separation device |
WO2015001296A1 (en) * | 2013-07-04 | 2015-01-08 | Sony Europe Limited | A method, apparatus and system for image processing |
CN204102661U (en) * | 2014-07-14 | 2015-01-14 | 郑铁 | A kind of fluid magnetizer |
-
2016
- 2016-05-12 CN CN201610321511.2A patent/CN105889231A/en active Pending
Patent Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN85109568A (en) * | 1985-12-26 | 1987-07-01 | 中国人民解放军工程兵工程学院野战工程系工程机械教研室 | The purification mechanism and the structure of multimachine reason high accuracy oil conditioner |
CN87101425A (en) * | 1987-11-21 | 1988-08-24 | 李培滋 | Filter |
CN2463660Y (en) * | 2000-12-22 | 2001-12-05 | 中国船舶重工集团公司第七研究院第七○四研究所 | Pipeline vibration and fluid pressure pulsation attenuator |
CN104028391A (en) * | 2013-03-08 | 2014-09-10 | 深圳中环科环保科技有限公司 | Magnetic hydrocyclone separation method and magnetic hydrocyclone separation device |
WO2015001296A1 (en) * | 2013-07-04 | 2015-01-08 | Sony Europe Limited | A method, apparatus and system for image processing |
CN204102661U (en) * | 2014-07-14 | 2015-01-14 | 郑铁 | A kind of fluid magnetizer |
Non-Patent Citations (1)
Title |
---|
桑青青: "多薄板振动式脉冲衰减器滤波机理与特性分析", 《中国优秀硕士学位论文全文数据库工程科技Ⅱ辑》 * |
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Application publication date: 20160824 |