CN209687989U - Composite Field formula magneto-rheological vibration damper - Google Patents
Composite Field formula magneto-rheological vibration damper Download PDFInfo
- Publication number
- CN209687989U CN209687989U CN201920125250.6U CN201920125250U CN209687989U CN 209687989 U CN209687989 U CN 209687989U CN 201920125250 U CN201920125250 U CN 201920125250U CN 209687989 U CN209687989 U CN 209687989U
- Authority
- CN
- China
- Prior art keywords
- piston
- permanent magnet
- coil
- vibration damper
- rheological vibration
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Landscapes
- Fluid-Damping Devices (AREA)
Abstract
The utility model discloses a kind of Composite Field formula magneto-rheological vibration dampers, including working cylinder, guiding end cap, piston and floating piston, the piston coaxial is slidably mounted in working cylinder, piston includes coaxial mounted piston rod and piston body, permanent magnet and coil are fixed with inside piston body, generate resultant field, collective effect is in magnetorheological fluid, the utility model uses a kind of Composite Field formula magnetorheological damper structure of innovation, magneto-rheological vibration damper under compared with the prior art, without the damping force needed for also can provide under most of operating condition that is powered;It ensure that and still provide damping force in the case where fault;Compared with the prior art, it is only necessary to which the current value of half can reach identical damping force variation range;It is more advantageous to the high-precision and quick response of electric-control system, is more convenient for demarcating;Energy consumption is further saved, is had a good application prospect.
Description
Technical field
The utility model belongs to antivibration area, and in particular to a kind of Composite Field formula magneto-rheological vibration damper.
Background technique
Damper is a kind of device for generating decaying between the relative motion two objects by damping action.It is usually used in vapour
In vehicle, train chassis or other machinery equipment, very important work is played to the ride comfort of vehicle driving and equipment operation process
With.Due to damper in automobile suspension system using wide, operating condition is more complex, and performance requirement is higher, so this is practical
Novel description and analysis is by taking the application of damper in vehicle suspension system as an example, but it is also applied for other mechanical vibration damping necks
Domain.
In the driving process of vehicle, what wheel encountered, which jolts, can make to generate the opposite fortune of vertical direction between wheel and vehicle body
Dynamic, the effect of damper is exactly to pass through to absorb mechanical energy and be converted into heat diffusion, and forms the attenuation to movement.It is resonable
In the damper course of work thought, the damping force size generated should be corresponding with the speed of relative motion, for any opposite fortune
Dynamic speed, damping force bigger than normal or less than normal can all seriously affect ride comfort: damping force deficiency is then ineffective to the decaying of movement, vibration
Duration is long;Damping force is excessive, and the impact transmitted is excessively strong, and buffering effect is poor.Magneto-rheological vibration damper is using magnetorheological
The electronic control shock absorber that the electromagnetic property of liquid developed, by moving piston, the suffered resistance in magnetorheological fluid generates damping force.
Magnetorheological fluid in damper good fluidity, generated damping force in non-magnetic environment is small;With magnetic field strength enhancing its
Viscosity constantly becomes larger, and generated damping force also becomes larger.
Magneto-rheological vibration damper in the prior art, which needs to be powered always, to work;Damper in the case where fault
Damping action almost fails;During calibration and active control, curent change range is also relatively large, is unfavorable for electricity
The high-precision and quick response of control system.
Summary of the invention
The purpose of the utility model is to provide a kind of Composite Field formula magneto-rheological vibration dampers, solve magnetorheological in the prior art subtract
A series of problems of vibration device: needing to be powered always could work;Resistance of shock absorber effect is almost complete in the case where fault
Full failure;During calibration and active control, curent change range is also relatively large, is unfavorable for the high-precision of electric-control system
And quick response.
In order to solve the above technical problems, the utility model is achieved through the following technical solutions:
A kind of Composite Field formula magneto-rheological vibration damper, including working cylinder, guiding end cap, piston and floating piston, the work
Plug coaxially slide is mounted in working cylinder, and piston includes coaxial mounted piston rod and piston body, is fixed with forever inside piston body
Magnet and coil, coil are connect by the harness in piston rod with external control system;The guiding end cap is solid by snap ring
It is scheduled on working cylinder end, piston rod stretches out working cylinder from guiding end cap mesoporous, and guiding end cap leads sliding axially for piston
To, and the connection of the connection of guiding end cap and working cylinder, guiding end cap and piston rod is sealed;
Magnetorheological fluid in working cylinder is taken up space and is separated into upper oil cavitie and lower oil cavitie by the piston body;The piston
Reciprocatory movement in, piston rod protrudes into the volume change in oil pocket, is obtained by the breathing of the compressed gas in gas chamber volume
It must compensate;The floating piston is coaxially mounted in working cylinder, compressed gas and magnetorheological fluid isolation is opened, and by work
Make the adjustment that gas chamber volume is completed in sliding in cylinder.
Optionally, permanent magnet and coil fixed inside the piston body are to be co-axially mounted, and permanent magnet is in coil inside.
Optionally, permanent magnet and coil fixed inside the piston body are to be co-axially mounted, and permanent magnet is in coil outer.
Optionally, permanent magnet and coil fixed inside the piston body are to be co-axially mounted, and permanent magnet is by two parts group
At being located at two endface positions of piston body, coil is mounted among two parts permanent magnet.
When damper is compressed or is stretched, the overall movement of piston makes side oil pocket have the tendency that volume becomes larger, and pressure becomes
It is small;Other side oil pocket has the tendency that volume becomes smaller, and pressure becomes larger;The pressure difference of the piston upper and lower surface, which is formed, transports piston
Dynamic resistance, and drive magnetorheological fluid in high-voltage oil cavity through piston hole clearance flow to low pressure oil pocket;The movement velocity of piston determines
Magnetorheological fluid passes through the flow velocity of piston hole;And magnetorheological fluid with the resistance that certain speed flows through piston hole determine piston by
The resistance arrived, i.e. damping power.
Different viscosities are presented in the magnetorheological fluid under different magnetic field intensity, and then generate different resistances;The work
The magnetic field strength that coil in plug generates is controlled by external control system, and the magnetic field strength that permanent magnet generates is steady state value, line
Resultant field intensity comprehensive function caused by circle and permanent magnet is in magnetorheological fluid.
The magnetic field strength that the permanent magnet generates is set to the magnetic field of the most frequently used resistance of magneto-rheological vibration damper generation
Intensity value, even if coil no power, magneto-rheological vibration damper still provides the most frequently used resistance.When the coil forward direction is powered, generate
The magnetic field in the same direction with magnetic field of permanent magnet;When the coil is reversely powered, generate and the field-reversed magnetic field of permanent magnet magnetic.
Advantages and beneficial effects of the utility model lie in that
The utility model use a kind of innovation Composite Field formula magnetorheological damper structure, compared with the prior art under magnetic
Rheology damper, without the damping force needed for also can provide under most of operating condition that is powered;It ensure that in the case where fault
Still provide damping force;Compared with the prior art, it is only necessary to which the current value of half can reach identical damping force variation range;
It is more advantageous to the high-precision and quick response of electric-control system, is more convenient for demarcating;Further save energy consumption.Before good application
Scape.
Detailed description of the invention
Fig. 1 is a kind of schematic diagram of embodiment of Composite Field formula magneto-rheological vibration damper of the utility model
Fig. 2 is a kind of structure sectional view of embodiment of Composite Field formula magneto-rheological vibration damper of the utility model
Fig. 3 is a kind of compression travel cross-sectional view of embodiment of Composite Field formula magneto-rheological vibration damper of the utility model
Fig. 4 is a kind of stretching travel cross-sectional view of embodiment of Composite Field formula magneto-rheological vibration damper of the utility model
In figure:
1, working cylinder;2, it is oriented to end cap;3, piston;4, floating piston;
5, magnetorheological fluid;6, compressed gas;7, upper oil cavitie;8, lower oil cavitie;9, gas chamber;
21, snap ring;31, piston rod;32, harness;33, piston body;34, permanent magnet;35, coil;
331, piston hole.
Specific embodiment
With reference to the accompanying drawing and specific embodiment is described in further detail the utility model.
Will referring to figs. 1 and 2, a kind of Composite Field formula magneto-rheological vibration damper of the utility model, including working cylinder 1,
Guiding end cap 2, piston 3 and floating piston 4,3 coaxially slide of piston are mounted in working cylinder 1, and piston 3 includes coaxial peace
The piston rod 31 and piston body 33 of dress, permanent magnet 34 and coil 35 are fixed with inside piston body 33, and coil 35 passes through piston rod 31
Interior harness 32 is connect with external control system;
The guiding end cap 2 is fixed on 1 end of working cylinder by snap ring 21, and piston rod 31 is stretched from guiding 2 mesoporous of end cap
Working cylinder 1 out, be oriented to being axially sliding to piston 3 of end cap 2, and to guiding end cap 2 and working cylinder 1 connection, lead
It is sealed to the connection of end cap 2 and piston rod 31;
Magnetorheological fluid 5 in working cylinder 1 is taken up space and is separated into upper oil cavitie 7 and lower oil cavitie 8 by the piston body 33;It is described
Piston 3 reciprocatory movement in, piston rod 31 protrudes into the volume change in oil pocket, passes through the compressed gas in 9 volume of gas chamber
The breathing of body 6 is compensated;The floating piston 4 is coaxially mounted in working cylinder 1, by compressed gas 6 and magnetorheological fluid 5 every
It opens absolutely, and completes the adjustment of 9 volume of gas chamber by sliding in working cylinder 1.
As shown in Fig. 2, in an embodiment of the present invention, fixed 34 He of permanent magnet inside the piston body 33
Coil 35 is to be co-axially mounted, and permanent magnet 34 is inside coil 35.
Optionally, as another embodiment of the utility model, fixed permanent magnet 34 inside the piston body 33
It is to be co-axially mounted with coil 35, permanent magnet 34 is outside coil 35.
Optionally, as another embodiment of the utility model, fixed permanent magnet 34 inside the piston body 33
It is to be co-axially mounted with coil 35, permanent magnet 34 consists of two parts, and is located at two endface positions of piston body 33, coil 35
It is mounted among two parts permanent magnet 34.
As shown in Figure 3 and Figure 4, when damper is compressed or is stretched, the overall movement of piston 3 makes side oil pocket have volume change
Big trend, pressure become smaller;Other side oil pocket has the tendency that volume becomes smaller, and pressure becomes larger;The pressure of 3 upper and lower surface of piston
Power difference forms the resistance moved to piston 3, and the magnetorheological fluid 5 in high-voltage oil cavity is driven to flow to low pressure oil through piston hole 331
Chamber;The movement velocity of piston 3 determines magnetorheological fluid 5 by the flow velocity of piston hole 331;And magnetorheological fluid 5 is with certain speed stream
Resistance through piston hole 331 determines the resistance that piston 5 is subject to, i.e. damping power.
Different viscosities are presented in the magnetorheological fluid 5 under different magnetic field intensity, and then generate different resistances;The work
The magnetic field strength that coil 35 in plug 3 generates is controlled by external control system, and the magnetic field strength that permanent magnet 34 generates is constant
It is worth, resultant field intensity comprehensive function caused by coil 35 and permanent magnet 34 is in magnetorheological fluid 5.
The magnetic field strength that the permanent magnet 34 generates is set to the magnetic of the most frequently used resistance of magneto-rheological vibration damper generation
Field intensity value, even if 35 no power of coil, magneto-rheological vibration damper still provide the most frequently used resistance.The coil 35 is positive to be powered
When, it generates and 34 magnetic field of permanent magnet magnetic field in the same direction;When the coil 35 is reversely powered, generate and 34 reverse magnetic field of permanent magnet
Magnetic field.
The course of work of the utility model is:
Fig. 3 and Fig. 4 is a kind of impulse stroke cross-sectional view of embodiment of Composite Field formula magneto-rheological vibration damper of the utility model,
When damper is compressed (as shown in Figure 3) or stretches (as shown in Figure 4), the overall movement of piston 3 makes side oil pocket have volume change
Big trend, pressure become smaller;Other side oil pocket has the tendency that volume becomes smaller, and pressure becomes larger.The pressure difference shape of 3 upper and lower surface of piston
The resistance that pairs of piston 3 moves, and drive magnetorheological fluid in high-voltage oil cavity through piston hole clearance flow to low pressure oil pocket.Due to magnetic current
Become liquid be it is incompressible, piston movement speed determine magnetorheological fluid pass through piston hole flow velocity;And magnetorheological fluid is with one
The resistance that constant speed degree flows through piston hole determines that the resistance that piston is subject to, i.e. damper generate under this piston movement speed
Damping force.
The magneto-rheological vibration damper of the utility model is realized by the resultant field intensity in control piston 3 to damping force
Control: generating intensity using the permanent magnet 34 of 3 core of piston is B0Constant magnetic field, and utilize coil 35 in variable-current
Intensity is generated up to BIVariable magnetic field, the superposition in two kinds of magnetic fields constitutes the compound of final control magnetorheological fluid viscosity property
Magnetic field BF.The magnetic field strength B0 of permanent magnet 34 is set to the most frequently used value, so also can provide under most of operating condition without being powered
Required damping force also ensures that damper stills provide damping force in the case where fault.In the magnetic field of permanent magnet 35
B0On the basis of give coil 35 the positive available maximum resultant field B that is poweredFMAx=B0+BI;Reversely be powered available minimum
Resultant field BFMIN=B0-BI, intensity is in BFMINTo BFMAXThe resultant field changed in range, needed for being capable of providing under all operating conditions
Damping force.And the magnetic field strength B of permanent magnet 340Be set to the most frequently used value so that conduction time is shorter, electrical current compared with
Small, energy-saving effect is significant;In addition the energization intensity of both forward and reverse directions and time are essentially identical, counteract electromagnetic field to permanent magnet 34
Most magnetizations are conducive to keep 34 magnetic field strength B of permanent magnet0Stabilization.Generating maximum value using coil 35 is only BI
Magnetic field, pass through positive and negative both direction and 34 magnetic field B of permanent magnet0It is overlapped, resultant field can be realized and be up to 2BIVariation
Amplitude.So magneto-rheological vibration damper compared with the prior art, the damper of the utility model only needs the current value of half
Reach identical damping force variation range.The maximum value for reducing required electric current, be more conducive to electric-control system high-precision and
Quick response easily facilitates in calibration, also further saves energy consumption.
The above is preferred embodiments of the present invention, it is noted that for the ordinary skill of the art
For personnel, under the premise of not departing from principle described in the utility model, several improvements and modifications can also be made, these improvement
It also should be regarded as the protection scope of the utility model with retouching.
Claims (8)
1. a kind of Composite Field formula magneto-rheological vibration damper, including working cylinder (1), guiding end cap (2), piston (3) and floating piston
(4), it is characterised in that:
Described piston (3) coaxially slide is mounted in working cylinder (1), piston (3) include coaxial mounted piston rod (31) and
Piston body (33), piston body (33) is internal to be fixed with permanent magnet (34) and coil (35), and coil (35) passes through in piston rod (31)
Harness (32) connect with external control system;
The guiding end cap (2) is fixed on working cylinder (1) end by snap ring (21), and piston rod (31) is from guiding end cap (2)
Mesoporous stretches out working cylinder (1), and guiding end cap (2) is axially sliding piston (3), and to guiding end cap (2) and work
The connection for making cylinder (1), the connection for being oriented to end cap (2) and piston rod (31) are sealed;
The piston body (33), which takes up space working cylinder (1) interior magnetorheological fluid (5), is separated into upper oil cavitie (7) and lower oil cavitie
(8);In the reciprocatory movement of the piston (3), piston rod (31) protrudes into the volume change in oil pocket, passes through gas chamber (9)
The breathing of compressed gas (6) in volume is compensated;The floating piston (4) is coaxially mounted in working cylinder (1), will be pressed
Contracting gas (6) and magnetorheological fluid (5) isolation are opened, and pass through the adjustment of sliding completion gas chamber (9) volume in working cylinder (1).
2. a kind of Composite Field formula magneto-rheological vibration damper according to claim 1, it is characterised in that:
Fixed permanent magnet (34) and coil (35) are to be co-axially mounted inside the piston body (33), and permanent magnet (34) is in coil
(35) internal.
3. a kind of Composite Field formula magneto-rheological vibration damper according to claim 1, it is characterised in that:
Fixed permanent magnet (34) and coil (35) are to be co-axially mounted inside the piston body (33), and permanent magnet (34) is in coil
(35) external.
4. a kind of Composite Field formula magneto-rheological vibration damper according to claim 1, it is characterised in that:
Fixed permanent magnet (34) and coil (35) are to be co-axially mounted inside the piston body (33), and permanent magnet (34) is by two
It is grouped as, is located at two endface positions of piston body (33), it is intermediate that coil (35) is mounted on two parts permanent magnet (34).
5. a kind of Composite Field formula magneto-rheological vibration damper according to claim 1, it is characterised in that:
When damper is compressed or is stretched, the overall movement of piston (3) makes side oil pocket have the tendency that volume becomes larger, and pressure becomes
It is small;Other side oil pocket has the tendency that volume becomes smaller, and pressure becomes larger;The pressure difference of described piston (3) upper and lower surface is formed to work
The resistance of (3) movement is filled in, and the magnetorheological fluid (5) in high-voltage oil cavity is driven to flow to low pressure oil pocket through piston hole (331);Piston
(3) movement velocity determines that magnetorheological fluid (5) pass through the flow velocity of piston hole (331);And magnetorheological fluid (5) is with certain speed stream
Resistance through piston hole (331) determines the resistance that piston (3) is subject to, i.e. damping power.
6. a kind of Composite Field formula magneto-rheological vibration damper according to claim 5, it is characterised in that:
Different viscosities are presented in the magnetorheological fluid (5) under different magnetic field intensity, and then generate different resistances;
The magnetic field strength that coil (35) in the piston (3) generates is controlled by external control system, and permanent magnet (34) produces
Raw magnetic field strength is steady state value, and resultant field intensity comprehensive function caused by coil (35) and permanent magnet (34) is in magnetorheological
Liquid (5).
7. a kind of Composite Field formula magneto-rheological vibration damper according to claim 6, it is characterised in that:
The magnetic field strength that the permanent magnet (34) generates is set to the magnetic field of the most frequently used resistance of magneto-rheological vibration damper generation
Intensity value, even if coil (35) no power, magneto-rheological vibration damper still provide the most frequently used resistance.
8. a kind of Composite Field formula magneto-rheological vibration damper according to claim 6, it is characterised in that:
When coil (35) forward direction is powered, generate and permanent magnet (34) magnetic field magnetic field in the same direction;
When the coil (35) is reversely powered, the magnetic field with permanent magnet (34) reverse magnetic field is generated.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201920125250.6U CN209687989U (en) | 2019-01-24 | 2019-01-24 | Composite Field formula magneto-rheological vibration damper |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201920125250.6U CN209687989U (en) | 2019-01-24 | 2019-01-24 | Composite Field formula magneto-rheological vibration damper |
Publications (1)
Publication Number | Publication Date |
---|---|
CN209687989U true CN209687989U (en) | 2019-11-26 |
Family
ID=68600114
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201920125250.6U Active CN209687989U (en) | 2019-01-24 | 2019-01-24 | Composite Field formula magneto-rheological vibration damper |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN209687989U (en) |
-
2019
- 2019-01-24 CN CN201920125250.6U patent/CN209687989U/en active Active
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN103423362B (en) | The energy-saving vibration-reduction device that a kind of damping is adjustable | |
CN106678256B (en) | A kind of electric vehicle magneto-electric self-powered suspension damper | |
CN105508492B (en) | A kind of spring damping is used to hold integral type suspension | |
CN107606041B (en) | Hybrid damper formed by combining magneto-rheological damper and electric vortex damper | |
CN102494080A (en) | Integral shock absorber device of inertial container and damper in coaxial parallel connection | |
CN104315073A (en) | Variable-stiffness variable-damping shock absorber based on magnetorheological damper | |
CN104632979A (en) | Adjustable damping shock absorber | |
CN204419973U (en) | A kind of energy magneto-rheological vibration damper | |
CN102937159A (en) | Integrated hydro-pneumatic spring device | |
CN103352956A (en) | Magneto-rheological damper with asymmetrical controllable damping characteristic | |
CN108412940B (en) | Magneto-rheological valve control damping stepless adjustable shock absorber | |
CN103423364A (en) | Hydraulic damper with adjustable damping | |
CN208719246U (en) | A kind of double acting automatic adjustable automobile magneto-rheological vibration damper | |
CN106801719B (en) | A kind of current liquescent damper | |
CN111734773B (en) | Magnetorheological fluid vibration absorber with variable wide-range rigidity damping by utilizing permanent magnetic mechanism | |
CN208519105U (en) | A kind of double bar-type magneto-rheological dampers out extending damp channel length | |
CN109667878A (en) | Composite Field formula magneto-rheological vibration damper | |
CN102305262B (en) | Energy collection absorber and implementation method thereof | |
CN105387120A (en) | Single-actuating type magneto-rheological shock absorber used for aircraft landing gear | |
CN103423363A (en) | Hydraulic damper with actively-adjustable damping | |
CN103625233A (en) | Integrated Inerter suspension for vehicle | |
CN201273355Y (en) | Self-protecting variable-damping hydraulic buffer | |
CN102364154B (en) | Passive damping adjustable magneto-rheological fluid shock absorber | |
CN102927191A (en) | Coil internally-installed type magnetorheological damper with oil needle | |
CN204852153U (en) | Magnetorheological suspensions shock absorber with highly resistance tensile properties |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant | ||
TR01 | Transfer of patent right |
Effective date of registration: 20230831 Address after: 313000 Building 1, No. 788 Xifeng Road, South Taihu New District, Wuxing District, Huzhou City, Zhejiang Province Patentee after: Zhejiang Kong Hui Automobile Technology Co.,Ltd. Address before: Experimental Building, No. 5177 Chaoda Road, High tech Development Zone, Changchun City, Jilin Province, 130000 Patentee before: KH AUTOMOTIVE TECHNOLOGIES (CHANGCHUN) CO.,LTD. |
|
TR01 | Transfer of patent right |