CN202484184U - Magnetic rotation and shaft driving electro-rheological fluid damper - Google Patents

Magnetic rotation and shaft driving electro-rheological fluid damper Download PDF

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Publication number
CN202484184U
CN202484184U CN2012200557257U CN201220055725U CN202484184U CN 202484184 U CN202484184 U CN 202484184U CN 2012200557257 U CN2012200557257 U CN 2012200557257U CN 201220055725 U CN201220055725 U CN 201220055725U CN 202484184 U CN202484184 U CN 202484184U
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China
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hollow cylindrical
cylindrical shaft
circular shaft
axis
shaft
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CN2012200557257U
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Chinese (zh)
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韩玉林
王芳
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Southeast University
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Southeast University
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Abstract

The utility model relates to a magnetic rotation and shaft driving electro-rheological fluid damper. Based on the blade rotation and piston shaft driving in a magnetic traction damper, when blade rotation and piston shaft driving are conducted, electro-rheological fluid flows through small round through holes on a blade and a piston and energy is consumed when the electro-rheological fluid flows through the small round through holes on the blade and the piston, thus playing a role in controlling the rotation around a piston axis and the vibration in the direction of the piston axis; and according to the vibration control requirements, the viscosity of the electro-rheological fluid is changed by changing the voltage between a positive electrode plate and a negative electrode plate, thus achieving the effect of actively controlling the vibration. As a movable sealing piece is not used, the damper hardly leaks the damp fluid.

Description

Magnetic force rotates and axle streaming current variant damper
Technical field
The utility model proposes a kind of " magnetic force rotates and axle streaming current variant damper ", belongs to field of vibration control.
Background technique
Fluid damper is a kind of effective structural damping device, but in the fluid damper working procedure, exists the possibility of fluid damper inner fluid seepage, and therefore in the occasion that does not allow leakage, the use of fluid damper just is restricted.The utility model proposes a kind of fluid damper, and this damper does not use dynamic seal, thereby the leakage fault be difficult for to take place, and this damper can be controlled along the linear displacement vibration of dampener hydraulic cylinder axis with around the rotate vibration of displacement of hydraulic cylinder axis simultaneously.
Summary of the invention
Technical problem:The purpose of the utility model is " magnetic force rotates and axle streaming current variant damper " a kind of through proposing, and is specially adapted to not allow the structural vibration control under the leakage condition.
Technological scheme:For solving the problems of the technologies described above, the technological scheme that the utility model provides is:
The utility model magnetic force rotates with axle streaming current variant damper and utilizes piston motion, blade rotation power consumption in the contactless promotion damper of magnetic force, plays the effect of control vibration.
Magnetic force rotates with axle streaming current variant damper and comprises: disc flange on the upper end that the bottom disc flange that comprises first disk, is oppositely arranged with first disk, with first disk and bottom disc flange do not have oil hydraulic cylinder that leakage is connected, upper end with opening has disc flange cylinder, stepped cylinder, the 3rd circular shaft, thrust-bearing, second disk, upper end have a cylinder of disc flange has; The upper-end surface of the 3rd circular shaft is connected with the lower end surface that the upper end has the cylinder of disc flange, and the lower end of the 3rd circular shaft is positioned at the upper grooves of stepped cylinder, and the 3rd circular shaft contacts with groove is smooth; The 3rd circular shaft has the cylinder of disc flange along the upper end a circumference is uniformly distributed with, and groove is equal with the 3rd circular shaft quantity and the position is corresponding one by one; Second disk is enclosed within on the oil hydraulic cylinder, and the inner ring surface of second disk links to each other with the outer peripheral surface of oil hydraulic cylinder, and the lower surface of second disk contacts with the upper surface of stepped cylinder is smooth;
Bottom disc flange, first disk and oil hydraulic cylinder are formed closed no leakage space; Electro rheological fluids is full of this closed no leakage space; This closed no leakage space part be positioned at the space that cylinder and upper end have the cylinder composition of disc flange; The upper end has built-in the 4th permanent magnetic iron block of lower end cylinder of the cylinder of disc flange, built-in the 3rd permanent magnetic iron block of cylinder; The scalariform cylinder is divided into bigger part of top external diameter and the less part of lower outer diameter; Two-part internal diameter is identical; The less part of the external diameter of stepped cylinder is enclosed within the blowout patche of thrust-bearing; The shoulder of stepped cylinder contacts with the upper surface of the blowout patche of thrust-bearing, and the lower end of the part that the external diameter of stepped cylinder is less does not contact with the bottom disc flange, and the relation of the less part of the external diameter of stepped cylinder and the blowout patche of thrust-bearing is an axle and the conventional matching relationship of the blowout patche of thrust-bearing; The seat ring of thrust-bearing is positioned at the annular groove of bottom disc flange, and the seat ring of thrust-bearing and the relation of annular groove are the seat ring of thrust-bearing and the conventional matching relationship of bearing saddle bore;
This magnetic force rotates with axle streaming current variant damper and also comprises piston, second Hollow Cylindrical Shaft and first permanent magnetic iron block; Rotor blade, first dividing plate, ring positive plate, second partition, the first circular shaft shape supporting frame, first circular shaft, second circular shaft, the second circular shaft shape supporting frame, ring negative plate, stator blade, first Hollow Cylindrical Shaft and second permanent magnetic iron block;
Same circumference along the second Hollow Cylindrical Shaft lower external face is evenly equipped with second round tube hole; The orthogonal axe of the axis of second round tube hole and second Hollow Cylindrical Shaft, the same circumference on the top of the edge second Hollow Cylindrical Shaft outer surface is evenly equipped with the 3rd round tube hole, the orthogonal axe of the axis of the 3rd round tube hole and second Hollow Cylindrical Shaft; Be with second circular shaft that top is hollow, the bottom is solid in second Hollow Cylindrical Shaft; Same circumference along the second circular shaft outer surface of upper is evenly equipped with the 4th round tube hole, the orthogonal axe of the axis of the 4th round tube hole and second Hollow Cylindrical Shaft, correspondence and the dead in line one by one of the 3rd round tube hole and the 4th round tube hole; The length of second circular shaft is less than the length of second Hollow Cylindrical Shaft; The lower end surface of second circular shaft is higher than the lower end surface of second Hollow Cylindrical Shaft, and the upper-end surface of second circular shaft flushes with the upper-end surface of second Hollow Cylindrical Shaft, is with first circular shaft in the top hollow shaft of second circular shaft; The first circular shaft length is less than the length of the top Hollow Cylindrical Shaft of second circular shaft; The top of first circular shaft flushes with the top of second circular shaft, and the ring positive plate is positioned on the upper surface of bottom disc flange, links to each other with an end of the first circular shaft shape supporting frame; The other end of the first circular shaft shape supporting frame passes second round tube hole and links to each other with second circular shaft; The ring negative plate is positioned under the lower surface of first disk, is connected with an end of the second circular shaft shape supporting frame, and the other end of the second circular shaft shape supporting frame passes the 3rd round tube hole and links to each other with first circular shaft with the 4th round tube hole; The second circular shaft top is passed manhole through second lead and is linked to each other with external power supply is anodal, and the top of first circular shaft is passed manhole through first lead and linked to each other with the external power supply negative pole;
The upper surface of ring negative plate does not contact with the lower surface of first disk; The lower surface of ring positive plate does not contact with the upper surface of bottom disc flange; The ring positive plate does not all contact with oil hydraulic cylinder, second Hollow Cylindrical Shaft with the ring negative plate; The ring positive plate only contacts with electro rheological fluids with the first circular shaft shape supporting frame, and the ring negative plate only contacts with electro rheological fluids with the second circular shaft shape supporting frame; The first circular shaft shape supporting frame does not contact with second Hollow Cylindrical Shaft; The first circular shaft shape supporting frame does not contact with the bottom disc flange; The second circular shaft shape supporting frame does not contact with second Hollow Cylindrical Shaft, and the packing material insulated enclosure is used in the space between space, second circular shaft and first circular shaft between space, second circular shaft and second Hollow Cylindrical Shaft between the space between the space between the first circular shaft shape supporting frame and second Hollow Cylindrical Shaft, the second circular shaft shape supporting frame and second Hollow Cylindrical Shaft, the second circular shaft shape supporting frame and second circular shaft respectively;
Piston is positioned at the inside of oil hydraulic cylinder, and piston middle part is provided with first round tube hole, has the second little round tube hole on the piston, when the line of action of making a concerted effort of electro rheological fluids suffered damping force of piston during through the second roundlet through hole and the dead in line of second Hollow Cylindrical Shaft; First permanent magnetic iron block is arranged on internal piston; The 4th permanent magnetic iron block and first permanent magnetic iron block attract each other through magnetic force; The 4th permanent magnetic iron block is identical with the first permanent magnetic iron block quantity, and the position is corresponding one by one, and the component of making a concerted effort in the horizontal direction of the suffered magnetic force of all first permanent magnetic iron blocks is zero; First dividing plate is positioned at the below of piston, and the inner ring surface of first dividing plate links to each other with the outer peripheral surface of second Hollow Cylindrical Shaft, and the outer ring surface of first dividing plate links to each other with the inner peripheral surface of oil hydraulic cylinder; Second partition is positioned at the top of ring positive plate, and the inner ring surface of second partition contacts with second Hollow Cylindrical Shaft is smooth, and the outer ring surface of second partition contacts with oil hydraulic cylinder is smooth; Second Hollow Cylindrical Shaft is passed first round tube hole, first dividing plate and second partition, and the second Hollow Cylindrical Shaft lower end surface does not have leakage with the bottom disc flange and is connected, and the upper-end surface of second Hollow Cylindrical Shaft flushes with the upper-end surface of first disk and do not have to leak and is connected;
Rotor blade is between first dividing plate and second partition; The height of rotor blade is identical with the height of first Hollow Cylindrical Shaft, and first Hollow Cylindrical Shaft is enclosed within on second Hollow Cylindrical Shaft, and rotor blade links to each other with first Hollow Cylindrical Shaft near an end in the center of circle; Rotor blade contacts with oil hydraulic cylinder is smooth away from an end in the center of circle; And the upper end of rotor blade contacts with first dividing plate is smooth, and the lower end of rotor blade contacts with second partition is smooth, and rotor blade is along highly having the first little round tube hole; The orthogonal axe of the axis of the first little round tube hole and second Hollow Cylindrical Shaft; When electro rheological fluids when the first roundlet through hole, the master vows to be zero, the axis normal of the acting surface of main square and second Hollow Cylindrical Shaft during suffered damping force reduction of force system of rotor blade some to the second Hollow Cylindrical Shaft axis; Stator blade links to each other with oil hydraulic cylinder away from an end in the center of circle, and stator blade contacts with first Hollow Cylindrical Shaft is smooth near an end in the center of circle; The second Hollow Cylindrical Shaft lower end surface does not have leakage with the bottom disc flange and is connected, and the upper-end surface of second Hollow Cylindrical Shaft flushes with the upper-end surface of first disk and do not have to leak and is connected; Rotor blade evenly distributes along the first Hollow Cylindrical Shaft cylindrical contour, and stator blade evenly distributes along oil hydraulic cylinder inner circumference line, and is provided with a rotor blade in the middle of per two stator blades; Second permanent magnetic iron block is arranged on rotor blade inside; The 3rd permanent magnetic iron block is identical with the second permanent magnetic iron block quantity; The position is corresponding one by one; The 3rd permanent magnetic iron block and second permanent magnetic iron block attract each other through magnetic force, and the suffered magnetic force of the 3rd permanent magnetic iron block system when being simplified to some on the second Hollow Cylindrical Shaft axis master vow to be zero, the axis normal of the acting surface of main square and second Hollow Cylindrical Shaft; The master vowed to be zero, the axis normal of the acting surface of main square and second Hollow Cylindrical Shaft when suffered magnetic force of second permanent magnetic iron block system was simplified to some on the second Hollow Cylindrical Shaft axis; The distribution of the first little round tube hole also has following dual mode: a, the first little round tube hole to change to be located on the stator blade; Have the first little round tube hole on b, stator blade and the rotor blade simultaneously.
In above-mentioned magnetic force rotation and axle streaming current variant damper, add first spring, obtain the another kind of style of a magnetic force rotation and a streaming current variant damper; Wherein: the upper end of first spring is connected with the piston lower surface, and the lower end of first spring is connected with second Hollow Cylindrical Shaft, and the lower end of first spring is positioned at the top of the upper surface of first dividing plate; First spring is to the line of action of making a concerted effort of the active force of piston and the dead in line of second Hollow Cylindrical Shaft.
In above-mentioned magnetic force rotation and axle streaming current variant damper, add second spring, obtain the another kind of style of a magnetic force rotation and a streaming current variant damper; Wherein: the lower end of second spring is connected with the upper surface of piston, and the upper end of second spring is connected with the top of second Hollow Cylindrical Shaft, and the upper end of second spring is positioned at the below of the second circular shaft shape supporting frame lower surface; Second spring is to the line of action of making a concerted effort of the active force of piston and the dead in line of second Hollow Cylindrical Shaft.
In above-mentioned magnetic force rotation and axle streaming current variant damper, add second spring, first spring, obtain the another kind of style of a magnetic force rotation and a streaming current variant damper; Wherein: the lower end of second spring is connected with piston upper surface, and the upper end of second spring is connected with the top of second Hollow Cylindrical Shaft, and the upper end of second spring is positioned at the below of the second circular shaft shape supporting frame lower surface; The upper end of first spring is connected with the piston lower surface, and the lower end of first spring is connected with second Hollow Cylindrical Shaft, and the lower end of first spring is positioned at the top of the upper surface of first dividing plate; Second spring is to the line of action of making a concerted effort of the active force of piston and the dead in line of second Hollow Cylindrical Shaft; First spring is to the line of action of making a concerted effort of the active force of piston and the dead in line of second Hollow Cylindrical Shaft.
In above-mentioned various forms of magnetic force rotations and axle streaming current variant damper, add the 3rd spring, obtain the another kind of style of a magnetic force rotation and a streaming current variant damper; The upper end of the 3rd spring is connected the upper end and has on the lower end surface of upper end disc flange of cylinder of disc flange, and the lower end of the 3rd spring is connected on the upper surface of first disk.
During use; The upper end disc flange that the upper end has the cylinder of disc flange is fixed on the oscillating body (or static basis); The upper surface of upper end disc flange that the upper end has the cylinder of disc flange contacts with oscillating body (or static basis); The bottom disc flange is fixed on the static basis (or oscillating body), and the upper end has the distance of upper surface of lower surface and first disk of upper end disc flange of cylinder of disc flange greater than the maximum vibration displacement of oscillating body with respect to the basis; The upper end has the axis of the cylinder of disc flange, the axis of bottom disc flange, the axis of oil hydraulic cylinder, the axis of first disk, the axis of second Hollow Cylindrical Shaft, the axis of piston, the axis of first Hollow Cylindrical Shaft, the axis of cylinder, the axis of first dividing plate, the axis of ring positive plate, the axis of the axis of the axis of the axis of second partition, the first circular shaft shape supporting frame, the axis of first circular shaft, second circular shaft, the axis of the second circular shaft shape supporting frame, ring negative plate, the axis of second spring, the axis of first spring and the dead in line of the 3rd spring.Because first permanent magnetic iron block in the piston has the magnetic attraction effect between the 4th permanent magnetic iron block in the cylinder of disc flange with the upper end; When oscillating body is static; Piston is in the static balance state under the acting in conjunction of gravity, magnetic force, second spring 34 and first spring etc.; When oscillating body vibrates, the cylinder that the upper end has a disc flange will draw piston and move along second Hollow Cylindrical Shaft, during piston motion; Electro rheological fluids flows through the second little round tube hole on the piston, and electro rheological fluids flows through the second roundlet through hole dissipative structure vibrational energy on the piston; Because second permanent magnetic iron block in the rotor blade is with the magnetic attraction effect between the 3rd permanent magnetic iron block in the cylinder, when oscillating body was static, rotor blade was in the static balance state under effects such as magnetic force, and was positioned at the centre of two stator blades; When oscillating body vibrates; Cylinder and cylinder that the upper end has a disc flange will draw rotor blade and rotate around second Hollow Cylindrical Shaft; When rotor blade rotates; Electro rheological fluids will flow through the first little round tube hole on the rotor blade, and electro rheological fluids flows through the first roundlet through hole dissipative structure vibrational energy on the rotor blade.
Beneficial effect:Oil hydraulic cylinder, bottom disc flange, disk are formed does not have the confined space of leakage; Blade is rotated around Hollow Cylindrical Shaft in this confined space by Magnetic force tracting on the one hand; When blade rotation; Damp liquid flows through the little round tube hole on the blade, and damp liquid consumes energy when flowing through the roundlet through hole on the blade, plays the effect that suppresses vibration; Magnetic force also can draw piston and in this confined space, moves along Hollow Cylindrical Shaft on the other hand, and when piston motion, damp liquid flows through the small sircle hole on the piston, and damp liquid consumes energy when flowing through the small sircle hole on the piston, plays the effect that suppresses vibration.When no matter having only rotational vibrations or having only axial vibration, when perhaps rotational vibrations and axial vibration took place simultaneously, this damper can provide effective vibration control damping.Owing to do not use Sealing, blade and piston only do not move in having the confined space of leakage, and the phenomenon of leakage of general fluid damper in the vibration control process can not appear in this fluid damper.The distance of the distance of first permanent magnetic iron block 4 and the 4th permanent magnetic iron block 30 and second permanent magnetic iron block 14 and the 3rd permanent magnetic iron block 26 can be very near, do not receive the influence of vibration displacement, presses the electromagnetism principle, and magnetic force is bigger, thereby bigger damping force can be provided.Because damp liquid adopts electro rheological fluids, the viscosity through adjustment external voltage control electro rheological fluids plays the effect of ACTIVE CONTROL.And because the 3rd circular shaft 100 moves up and down in groove with the cylinder that the upper end has disc flange; Only rotation is passed to stepped cylinder; Make stepped cylinder and the 3rd inner permanent magnetic iron block 26 only do rotation around hydraulic cylinder axis; The 3rd permanent magnetic iron block 26 and 14 of second permanent magnetic iron blocks do not take place along the change in location of hydraulic cylinder axis direction, can obtain maximum magnetic force.
Description of drawings
Fig. 1 be magnetic force rotate with axle streaming current variant damper face the sectional structure schematic representation;
Fig. 2 be among Fig. 1 cylindrical shape oil hydraulic cylinder 17 and be installed in the cylindrical shape oil hydraulic cylinder 17 parts K-K to overlook the sectional structure schematic representation;
Fig. 3 is the plan view of rotor blade 20 among Fig. 1;
Fig. 4 is that the A-A of rotor blade 20 among Fig. 3 is to the sectional structure schematic representation;
Fig. 5 is that the B-B of rotor blade 20 among Fig. 3 is to the sectional structure schematic representation;
Fig. 6 is the worm's eye view of the 3rd quadrilateral briquetting 10 among Fig. 3;
Fig. 7 is the worm's eye view that the upper end has the cylinder 35 of disc flange among Fig. 1;
Fig. 8 is that the upper end has disc flange among Fig. 7 the C-C of cylinder 35 is to the sectional structure schematic representation;
Fig. 9 is that the upper end has disc flange among Fig. 7 the D-D of cylinder 35 is to bottom cylinder sectional structure schematic representation;
Figure 10 is the worm's eye view of the second quadrilateral briquetting 5 among Fig. 7;
Figure 11 is the worm's eye view of cylinder 11 among Fig. 1;
Figure 12 is that the E-E of cylinder 11 among Figure 11 is to structural representation;
Figure 13 is that the F-F of cylinder 11 among Figure 11 is to structural representation;
Figure 14 is the worm's eye view of the 4th quadrilateral briquetting 23 among Figure 11
Figure 15 is the plan view of piston 48 among Fig. 1;
Figure 16 is that the G-G of piston 48 among Figure 15 is to the sectional structure schematic representation;
Figure 17 be piston 48 among Figure 15 H-H to the structural representation of the 3rd T shape quadrilateral groove 49;
Figure 18 is the worm's eye view of the first quadrilateral briquetting 3 among Figure 15;
Figure 19 is that replacement column permanent magnetic iron block is the worm's eye view that the upper end of ring permanent magnetic iron block has the cylinder 35 of disc flange among Fig. 1;
Figure 20 be among Figure 19 I-I to the upper end have disc flange cylinder 35 the bottom cylinder and be installed in that the upper end has parts on the cylinder 35 of disc flange face the sectional structure schematic representation;
Figure 21 be the cylinder 35 that has disc flange of the upper end among Figure 20 face the sectional structure schematic representation;
Figure 22 is the structural representation of the 2nd T shape annular groove 67 among Figure 21;
Figure 23 is that replacement column permanent magnetic iron block is the plan view of the piston 48 of ring permanent magnetic iron block among Fig. 1
Figure 24 be among Figure 21 J-J to piston 48 and be installed in parts on the piston 48 face the sectional structure schematic representation;
Figure 25 be among Figure 24 piston 48 face the sectional structure schematic representation;
Figure 26 is the structural representation of a T shape annular groove 56 among Figure 25;
Have among the above figure: first disk, 1, the first bolt, 2, the first quadrilateral briquettings, 3, the first column permanent magnetic iron blocks, 4, the second quadrilateral briquettings, 5, the first tapped holes 6; First unthreaded hole, 7, the first dividing plates, 8, the second bolts, 9, the three quadrilateral briquettings 10, cylinder 11, the second unthreaded holes 12; Second tapped hole, 13, the second column permanent magnetic iron blocks, 14, the first roundlet through holes, 15, the first Hollow Cylindrical Shaft 16, cylindrical shape oil hydraulic cylinder 17, the second Hollow Cylindrical Shaft 18; Bottom disc flange 19, rotor blade 20, the first bolts hole 21, the three bolts 22, the four quadrilateral briquettings 23, the three unthreaded holes 24; The 3rd tapped hole 25, the three column permanent magnetic iron blocks 26, the first coil component springs 27, the second roundlet through holes 28, the four bolts 29, the four column permanent magnetic iron blocks 30; The 4th tapped hole 31, the four unthreaded holes 32, the first round tube holes 33, the second coil component springs 34, cylinder 35, the second bolts hole 36 of upper end band disc flange; The 3rd coil component spring 37, cylindrical body 38, the less quadrilateral groove 42 of lower width of quadrilateral groove 41, the one T shape quadrilateral grooves 40 that the upper width of through hole 39, the one T shape quadrilateral grooves 40, the one T shape quadrilateral grooves 40 is bigger; The bigger quadrilateral groove 45 of lower width of quadrilateral groove 44, the two T shape quadrilateral grooves 43 that the upper width of the 2nd T shape quadrilateral groove 43, the two T shape quadrilateral grooves 43 is less, stator blade 46, the upper end has the upper end disc flange 47 of the cylinder 35 of disc flange, piston 48; The bigger quadrilateral groove 54 of lower width of quadrilateral groove 53, the four T shape quadrilateral grooves 52 that the upper width of quadrilateral groove 51, the four T shape quadrilateral grooves 52, the four T shape quadrilateral grooves 52 that the lower width of quadrilateral groove 50, the three T shape quadrilateral grooves 49 that the upper width of the 3rd T shape quadrilateral groove 49, the three T shape quadrilateral grooves 49 is bigger is less is less; Annular groove 58, the first ring permanent magnetic iron blocks 59, the first ring briquettings 60 that the upper width of annular groove 57, the one T shape annular grooves 56 that the lower width of electro rheological fluids 55, the one T shape annular grooves 56, the one T shape annular grooves 56 is less is bigger; The 5th tapped hole 61, the six tapped holes 62, the five unthreaded holes 63, the six unthreaded holes 64, the five bolts 65, the six bolts 66; Annular groove 69, the second ring permanent magnetic iron blocks 70, the second ring briquettings 71, the seven tapped holes 72 that the lower width of annular groove 68, the two T shape annular grooves 67 that the upper width of the 2nd T shape annular groove 67, the two T shape annular grooves 67 is less is bigger; The 8th tapped hole 73, the seven unthreaded holes 74, the eight unthreaded holes 75, the seven bolts 76, the eight bolts 77, ring positive plate 78; Second partition 79, the nine bolts 80, the second round tube holes 81, the nine tapped holes 82, packing material 83, the first circular shaft shape supporting frames 84 that not only insulate but also seal; The 3rd bolt hole 85, counterbore 86, the four bolts hole 87, the five bolts hole 88, the three round tube holes 89; The tenth tapped hole 90, the first circular shafts 91, the second circular shafts 92, the four round tube holes 93, the ten bolts 94; The second circular shaft shape supporting frame 95, ring negative plate 96, manhole 97, the first leads 98, the second leads 99; The 3rd circular shaft 100, thrust-bearing 101, groove 102, annular groove 103, the second disks 104.
Embodiment
Below in conjunction with accompanying drawing the utility model is further specified.
The utility model proposes a kind of magnetic force and rotates and axle streaming current variant damper; The blade rotation, the piston shaft that utilize magnetic force to promote in the damper are moving; When blade rotation (piston shaft moving); Damp liquid flows through the little round tube hole (damping hole) on the blade (piston), and the effect that control is vibrated is played in power consumption when damp liquid flows through the small sircle hole (damping hole) on the blade (piston).
The embodiment's of the utility model description in fact only is exemplary, and purpose never is to limit the application or the use of the utility model.
This magnetic force rotates with a characteristic of streaming current variant damper and also is to remove simultaneously second coil component spring 34 and first coil component spring 27, still obtains effective magnetic force and rotates and axle streaming current variant damper.
This magnetic force rotates with a characteristic of streaming current variant damper and also is to remove second coil component spring 34, still obtains effective magnetic force and rotates and axle streaming current variant damper.
This magnetic force rotates with a characteristic of streaming current variant damper and also is to remove first coil component spring 27, still obtains effective magnetic force and rotates and axle streaming current variant damper.
This magnetic force rotates with a characteristic of streaming current variant damper and also is to remove the 3rd coil component spring 37, still obtains effective magnetic force and rotates and axle streaming current variant damper.
These each parts that do not have to leak damper remove the first column permanent magnetic iron block 4, the second column permanent magnetic iron block 14, the 3rd column permanent magnetic iron block 26; The 4th column permanent magnetic iron block 30; The first ring permanent magnetic iron block 59 and beyond the first ring permanent magnetic iron block 70; Other parts are all made with non-ferromagnetic metal or alloy material (for example aluminum alloy, stainless steel etc.); That first dividing plate 8 adopts is nonmetal, Nonferromugnetic material insulating material such as (for example) plastics is made.The process of fluid damping implement body manufacturing can follow these steps to carry out:
The first step: according to the vibration control requirement, selected first disk 1, piston 48, the first dividing plates 8, second partition 79; First Hollow Cylindrical Shaft 16, bottom disc flange 19, the upper end has the cylinder 35 of disc flange, the upper end disc flange 47 of the cylinder 35 of upper end band disc flange, cylinder 11; Cylindrical shape oil hydraulic cylinder 17, the second Hollow Cylindrical Shaft 18, the first coil component springs 27, the second coil component springs 34, the three coil component springs 37; Cylindrical body 38, annular groove 103, thrust-bearing 101,, the size of second disk 104; Selected white clay/titanium oxide Nano composite granules ER fluid is as electro rheological fluids 55; Selected self-aligning thrust roller bearing is as thrust-bearing 101; Selected room temperature silica gel is as the packing material 83 that not only insulate but also seal; According to the vibration control requirement, less quadrilateral groove 42, the two T shape quadrilateral grooves 43 of lower width of quadrilateral groove 41, the one T shape quadrilateral grooves 40 that the upper width of a selected T shape quadrilateral groove 40, the one T shape quadrilateral grooves 40 is bigger; The less quadrilateral groove 51 of lower width of quadrilateral groove 50, the three T shape quadrilateral grooves 49 that the upper width of quadrilateral groove 44, the three T shape quadrilateral grooves 49, the three T shape quadrilateral grooves 49 that the upper width of quadrilateral groove 45, the two T shape quadrilateral grooves 43 that the lower width of the 2nd T shape quadrilateral groove 43 is bigger is less is bigger; Quadrilateral groove 53, the first quadrilateral briquettings 3, the second quadrilateral briquettings 5 that the upper width of quadrilateral groove 54, the four T shape quadrilateral grooves 52 that the lower width of the 4th T shape quadrilateral groove 52, the four T shape quadrilateral grooves 52 is bigger is less; The 4th quadrilateral briquetting 23, the three quadrilateral briquettings 10, the first column permanent magnetic iron blocks 4, the three column permanent magnetic iron blocks 26, the second column permanent magnetic iron blocks 14; The 4th column permanent magnetic iron block 30, the first tapped holes 6, the second tapped holes 13, the three tapped holes 25, the four tapped holes 31; First unthreaded hole, 7, the second unthreaded holes, 12, the three unthreaded holes, 24, the four unthreaded holes, 32, the first bolts 2; Second bolt, 9, the three bolts, 22, the four bolts 29, stator blade 46, rotor blade 20; First bolt hole, 21, the second bolts hole, 36, the first roundlet through holes, 15, the second roundlet through holes, 28, the first round tube holes 33; Through hole 39, the nine bolts 80, the second round tube holes 81, the nine tapped holes 82, the first circular shaft shape supporting frames 84; The 3rd bolt hole 85, counterbore 86, the four bolts hole 87, the five bolts hole 88, the three round tube holes 89; The tenth tapped hole 90, the first circular shafts 91, the second circular shafts 92, the four round tube holes 93; The tenth bolt 94, the second circular shaft shape supporting frames 95, ring negative plate 96, manhole 97; First lead, 98, the second leads, 99, the three circular shafts 100, the quantity of groove 102, position and size.48 the 3rd T shape quadrilateral groove 49 positions, quantity are corresponding one by one in the 4th T shape quadrilateral groove 52 in the cylinder 11 and the piston; Be that the 4th T shape quadrilateral groove 52 in the cylinder 11 is identical with the 3rd T shape quadrilateral groove 49 quantity in the piston 48, one the 4th T shape quadrilateral groove 52 with and only be distributed on the same ray perpendicular to first disk, 1 axis with one the 3rd T shape quadrilateral groove 49; It is corresponding one by one that the upper end has position, the quantity of the T shape quadrilateral groove 40 in the 2nd T shape quadrilateral groove 43 and the rotor blade 20 in the cylinder 35 of disc flange; Promptly the 2nd T shape quadrilateral groove 43 that has in the cylinder 35 of disc flange of upper end is identical with a T shape quadrilateral groove 40 quantity in the rotor blade 20, one the 2nd T shape quadrilateral groove 43 and and only be distributed on the same ray perpendicular to first disk, 1 axis with one the one T shape quadrilateral groove 40; The quantity of groove 102 and the 3rd circular shaft 100 equates, the position is corresponding one by one.For example: after installing at damper; Piston 48 is in the equilibrium of forces state under the acting in conjunction of power such as magnetic force, second coil component spring 34, first coil component spring 27 and gravity, confirmed the parameter of second coil component spring 34 and first coil component spring 27 by conventional Mechanics Calculation.Cylinder 35 height that the upper end has a disc flange according to " with the 4th column permanent magnetic iron block 30 divide equally for two-part plane up and down with the first column permanent magnetic iron block 4 is divided equally be two-part planes up and down " definite with " length of the 3rd coil component spring 37 is not less than the maximum vibration displacement of oscillating body " these two conditions; The height of cylinder 11 according to " with the second column permanent magnetic iron block 14 divide equally for two-part plane up and down with the 3rd column permanent magnetic iron block 26 is divided equally be two-part planes up and down " confirm; For example when vibration is simple harmonic oscillation; The upper surface of piston 48 is not less than the maximum vibration displacement of oscillating body to the distance of the lower surface of the second circular shaft shape supporting frame 95, and the lower surface of piston 48 is not less than the maximum vibration displacement of oscillating body to the distance of the upper surface of first dividing plate 8; The groove depth of groove 102 is greater than the maximum vibration displacement of oscillating body; Respectively 4 of the selected first circular shaft shape supporting frame 84 and the second circular shaft shape supporting frames 95; After being predefined in the following step and the first circular shaft shape supporting frame 84 and the second circular shaft shape supporting frame 95 are installed are finished; 4 first circular shaft shape supporting frames 84 are uniformly distributed with about the axis symmetry of second Hollow Cylindrical Shaft 18, and 4 second circular shaft shape supporting frames 95 are uniformly distributed with about the axis symmetry of second Hollow Cylindrical Shaft 18.
Second step: the second column permanent magnetic iron block 14 is placed in the less quadrilateral groove 42 of the lower width of a T shape quadrilateral groove 40 of rotor blade 20, the magnetic pole of the second column permanent magnetic iron block 14 points to the axial direction and the axial direction that points to away from second Hollow Cylindrical Shaft 18 of second Hollow Cylindrical Shaft 18 respectively; The lower surface of the lower surface of the second column permanent magnetic iron block 14 and a T shape quadrilateral groove 40 is fitted, i.e. the lower surface applying of the less quadrilateral groove 42 of the lower width of the lower surface of the second column permanent magnetic iron block 14 and a T shape quadrilateral groove 40; The 3rd quadrilateral briquetting 10 is placed in the bigger quadrilateral groove 41 of the upper width of a T shape quadrilateral groove 40; The upper surface of the lower surface of the 3rd quadrilateral briquetting 10 and the second column permanent magnetic iron block 14 is fitted, the flush of the upper surface of the 3rd quadrilateral briquetting 10 and rotor blade 20; Dead in line with second tapped hole 13 of a T shape quadrilateral groove 40 of the axis of second unthreaded hole 12 on the 3rd quadrilateral briquetting 10 and rotor blade 20; The threaded end of second bolt 9 is passed second unthreaded hole 12 be screwed into second tapped hole 13 and tighten, when second bolt 9 was tightened, second bolt 9 compressed the 3rd quadrilateral briquetting 10.
The 3rd step: the lower end surface of second Hollow Cylindrical Shaft 18 is welded on the upper surface of bottom disc flange 19, all must guarantees the axis of bottom disc flange 19 and the dead in line of second Hollow Cylindrical Shaft 18 before and after the welding; Insert second circular shaft 92 in second Hollow Cylindrical Shaft 18; With the axis of second circular shaft 92 and the dead in line of second Hollow Cylindrical Shaft 18; The upper-end surface of second circular shaft 92 is flushed with the upper-end surface of second Hollow Cylindrical Shaft 18; With the dead in line of the axis and second round tube hole 81 of the 7th tapped hole 82, the threaded end of the first circular shaft shape supporting frame 84 is passed second round tube hole 81 be screwed into the 7th tapped hole 82 and tighten; Ring positive plate 78 is enclosed within on second Hollow Cylindrical Shaft 18; Dead in line with the axis and the 3rd bolt hole 85 of counterbore 86; Pass counterbore 86 and the 3rd bolt hole 85 and tighten with the 9th bolt 80, the ring positive plate 78 and the first circular shaft shape supporting frame 84 are linked together;
The 4th step: pour an amount of room temperature silicone rubber into along the sidewall of second Hollow Cylindrical Shaft 18; The amount of room temperature silicone rubber is the shared volume in space half the between second Hollow Cylindrical Shaft 18 and second circular shaft 92; After the cooling of room temperature silicone rubber, second Hollow Cylindrical Shaft 18 and second circular shaft 92 are fixed together; Inject room temperature silicone rubber along the gap of hole wall between second round tube hole 81 and the first circular shaft shape supporting frame 84 of second round tube hole 81 again, after the cooling of room temperature silicone rubber, the sealing of the air space insulation between second round tube hole 81 and the first circular shaft shape supporting frame 84 is filled;
The 5th step: the end of stator blade 46 away from the center of circle is welded on the cylindrical shape oil hydraulic cylinder 17; Cylindrical shape oil hydraulic cylinder 17 is enclosed within outside the rotor blade 20; The upper surface welding of the lower end surface of cylindrical shape oil hydraulic cylinder 17 and bottom disc flange 19 all must guarantee axis and the dead in line of cylindrical shape oil hydraulic cylinder 17, the axis of bottom disc flange 19 and the dead in line of cylindrical shape oil hydraulic cylinder 17 of stator blade 46 before and after the welding; In cylindrical shape oil hydraulic cylinder 17, pour an amount of a certain amount of white clay/titanium oxide Nano composite granules ER fluid into, the flush of the horizontal plane of ER fluid and ring positive plate 23; Second partition 79 is enclosed within on second Hollow Cylindrical Shaft 18, and second partition 79 is positioned at the top of ring positive plate 78, the smooth contact of upper surface of the lower surface of second partition 79 and ring positive plate 78, second partition 79 and second Hollow Cylindrical Shaft, 18 smooth contacts.
The 6th step: the end of rotor blade 20 near the center of circle is welded on first Hollow Cylindrical Shaft 16; Must guarantee that all the lower surface of rotor blade 20 flushes with the lower surface of first Hollow Cylindrical Shaft 16 before and after the welding; First Hollow Cylindrical Shaft 16 is enclosed within on second Hollow Cylindrical Shaft 18 smooth contact of upper surface of the lower surface of rotor blade 20 and bottom disc flange 19; In cylindrical shape oil hydraulic cylinder 17, pour an amount of white clay/titanium oxide Nano composite granules ER fluid into; The flush of the horizontal plane of ER fluid and rotor blade 20; First dividing plate 8 is enclosed within on second Hollow Cylindrical Shaft 18; The smooth contact of upper surface of the lower surface of first dividing plate 8 and the upper surface and the stator blade 46 of rotor blade 20; With the inner ring surface of first dividing plate 8 and the outer peripheral surface welding of second Hollow Cylindrical Shaft 18, the inner peripheral surface welding of the outer ring surface of first dividing plate 8 and cylindrical shape oil hydraulic cylinder 17 all must guarantee the axis of first dividing plate 8, the axis of second Hollow Cylindrical Shaft 18 and the dead in line of cylindrical shape oil hydraulic cylinder 17 before and after the welding.
The 7th step: the first column permanent magnetic iron block 4 is placed in the less quadrilateral groove 51 of the lower width of the 3rd T shape quadrilateral groove 49 of piston 48, the magnetic pole of the first column permanent magnetic iron block 4 points to the axial direction and the axial direction that points to away from piston 48 of piston 48 respectively; The lower surface of the lower surface of the first column permanent magnetic iron block 4 and the 3rd T shape quadrilateral groove 49 is fitted, i.e. the lower surface applying of the less quadrilateral groove 51 of the lower width of the lower surface of the first column permanent magnetic iron block 4 and the 3rd T shape quadrilateral groove 49; The first quadrilateral briquetting 3 is placed in the bigger quadrilateral groove 50 of the upper width of the 3rd T shape quadrilateral groove 49; The upper surface of the lower surface of the first quadrilateral briquetting 3 and the first column permanent magnetic iron block 4 is fitted, the flush of the upper surface of the first quadrilateral briquetting 3 and piston 48; Dead in line with the 4th tapped hole 31 of the 3rd T shape quadrilateral groove 49 of the axis of the 4th unthreaded hole 32 on the first quadrilateral briquetting 3 and piston 48; The threaded end of first bolt 2 is passed the 4th unthreaded hole 32 be screwed into the 4th tapped hole 31 and tighten, when first bolt 2 was tightened, first bolt 2 compressed the first quadrilateral briquetting 3.
The 8th step: first coil component spring 27 is enclosed within on second Hollow Cylindrical Shaft 18, and first coil component spring 27 places the top of first dividing plate 8, and piston 48 is enclosed within on second Hollow Cylindrical Shaft 18 through first round tube hole 33 ,Piston 48 places the top of first coil component spring 27, and an end of first coil component spring 27 is welded on the lower surface of piston 48, and the other end of first coil component spring 27 is welded on the cylndrical surface of second Hollow Cylindrical Shaft 18, that is to say the top of first dividing plate, 8 upper surfaces; Second coil component spring 34 is enclosed within on second Hollow Cylindrical Shaft 18; Second coil component spring 34 is positioned at the top of piston; One end of second coil component spring 34 is welded on piston 48 upper surfaces; The other end of second coil component spring 34 is welded on the top of the cylndrical surface of second Hollow Cylindrical Shaft 18, that is to say plane, the 3rd round tube hole 89 least significant ends places below; All must guarantee the axis of second Hollow Cylindrical Shaft 18, the axis of piston 48, the axis of second coil component spring 34 and the dead in line of first coil component spring 27 before and after the welding.
The 9th step: insert first circular shaft 91 in the top Hollow Cylindrical Shaft of second circular shaft 92; Dead in line with the axis and second circular shaft 92 of first circular shaft 91; Flush with the upper surface and second circular shaft 92 of first circular shaft 91; With the axis of the tenth tapped hole 90 and the axis of the 3rd round tube hole 89, the dead in line of the 4th round tube hole 93, the threaded end of the second circular shaft shape supporting frame 95 is passed the 3rd round tube hole 89 and the 4th round tube hole 93 be screwed into the tenth tapped hole 90 and tighten; Ring negative plate 96 is enclosed within on second Hollow Cylindrical Shaft 18; Ring negative plate 96 is positioned at the top of the second circular shaft shape supporting frame 95; Dead in line with the axis and the 4th bolt hole 87 of the 5th bolt hole 88; Pass the 5th bolt hole 88 and the 4th bolt hole 87 and tighten with the tenth bolt 94, the ring negative plate 96 and the second circular shaft shape supporting frame 95 are linked together; Inject room temperature silicone rubber along the sidewall of second Hollow Cylindrical Shaft 18 and the sidewall of second circular shaft, 92 top Hollow Cylindrical Shaft respectively again, when after the cooling of room temperature silicone rubber the air space insulation sealing between the sealing of the air space insulation between second Hollow Cylindrical Shaft 18 and second circular shaft 92 filling, second circular shaft 92 and first circular shaft 91 being filled; Again along the hole wall of the 3rd round tube hole 89; Room temperature silicone rubber is injected in gap between the 3rd round tube hole 89 and the second circular shaft shape supporting frame 95, after the cooling of room temperature silicone rubber, the sealing of the air space insulation between the 3rd round tube hole 89 and the second circular shaft shape supporting frame 95 is filled.
The tenth step: the circle centre position at first disk 1 bores circular hole a, and the diameter of circular hole a is a bit larger tham the diameter (getting concrete numerical value by conventional welding conditions) of second Hollow Cylindrical Shaft 18, the dead in line of the axis of circular hole a and first disk 1; Axis symmetry about first disk 1 is bored small sircle hole b and small sircle hole c on first disk 1 again; Half of small sircle hole b and small sircle hole c axis separately equal cylindrical shape oil hydraulic cylinder 17 from the distance of the axis of first disk 1 inside radius and the radius sum of circular hole a; The radius of small sircle hole b and small sircle hole c deduct less than the inside radius of cylindrical shape oil hydraulic cylinder 17 circular hole a radius numerical value 1/2nd, and require small sircle hole b and the small sircle hole c can not be over against the top of rotor blade 20 and stator blade 46.
The 11 step: then the 6th step was inserted in the top of second Hollow Cylindrical Shaft 18 and bore among the circular hole a, the lower surface of first disk 1 is placed on the upper-end surface of cylindrical shape oil hydraulic cylinder 17.The upper-end surface of cylindrical shape oil hydraulic cylinder 17 is welded on the lower surface of first disk 1; Again with the upper-end surface of second Hollow Cylindrical Shaft 18 and first disk 1 the 6th the step institute circular hole a place of boring weld, weld front and back and all must guarantee the axis of cylindrical shape oil hydraulic cylinder 17, the axis of first disk 1, the dead in line of second Hollow Cylindrical Shaft 18.
The 12 step: use funnel white clay/titanium oxide Nano composite granules ER fluid to fill with cylindrical shape oil hydraulic cylinder 17 earlier by the 6th step small sircle hole b that bores; After observing damp liquid and filled with cylindrical shape oil hydraulic cylinder 17 through small sircle hole b and small sircle hole c, the 6th step small sircle hole b that bores of institute and small sircle hole c are welded block again; Second disk 104 is enclosed within on the oil hydraulic cylinder 17; The inner ring surface of second disk 104 and the outer peripheral surface of oil hydraulic cylinder 17 are welded; Guarantee the axis of second disk 104 and the dead in line of oil hydraulic cylinder 17 before and after the welding, and smooth contact of upper surface of the lower surface of second disk 104 and stepped cylinder 11.
The 13 step: the 3rd column permanent magnetic iron block 26 is placed in the less quadrilateral groove 44 of the upper width of the 2nd T shape quadrilateral groove 43 of cylinder 11; The magnetic pole of the 3rd column permanent magnetic iron block 26 points to the axial direction and the axial direction that points to away from cylinder 11 of cylinder 11 respectively, and the 3rd column permanent magnetic iron block 26 is opposite near the magnetic polarity of cylindrical shape oil hydraulic cylinder 17 1 ends near the magnetic polarity and the second column permanent magnetic iron block 14 of cylindrical shape oil hydraulic cylinder 17 1 ends; The upper surface of the upper surface of the 3rd column permanent magnetic iron block 26 and the 2nd T shape quadrilateral groove 43 is fitted, i.e. the upper surface applying of the less quadrilateral groove 44 of the upper width of the upper surface of the 3rd column permanent magnetic iron block 26 and the 2nd T shape quadrilateral groove 43; The 4th quadrilateral briquetting 23 is placed in the bigger quadrilateral groove 45 of the lower width of the 2nd T shape quadrilateral groove 43; The lower surface of the upper surface of the 4th quadrilateral briquetting 23 and the 3rd column permanent magnetic iron block 26 is fitted, and the lower surface of the 4th quadrilateral briquetting 23 flushes with the lower surface of cylinder 11; Axial alignment (coincidence) with axis with the 3rd tapped hole 25 of the 2nd T shape quadrilateral groove 43 of cylinder 11 of the 3rd unthreaded hole 24 on the 4th quadrilateral briquetting 23; The threaded end of the 3rd bolt 22 is passed the 3rd unthreaded hole 24 be screwed into the 3rd tapped hole 25 and tighten, when the 3rd bolt 22 was tightened, the 3rd bolt 22 compressed the 4th quadrilateral briquetting 23.
The 14 step: place the upper end to have in the less quadrilateral groove 53 of the upper width of the 4th T shape quadrilateral groove 52 of cylinder 35 of disc flange the 4th column permanent magnetic iron block 30; The magnetic pole of the 4th column permanent magnetic iron block 30 point to respectively the upper end have disc flange cylinder 35 axial direction with point to the axial direction that has the cylinder 35 of disc flange away from the upper end, the 4th column permanent magnetic iron block 30 is opposite near the magnetic polarity of cylindrical shape oil hydraulic cylinder 17 1 ends near the magnetic polarity and the first column permanent magnetic iron block 4 of cylindrical shape oil hydraulic cylinder 17 1 ends; The upper surface of the upper surface of the 4th column permanent magnetic iron block 30 and the 4th T shape quadrilateral groove 52 is fitted, i.e. the upper surface applying of the less quadrilateral groove 53 of the upper width of the upper surface of the 4th column permanent magnetic iron block 30 and the 4th T shape quadrilateral groove 52; The second quadrilateral briquetting 5 is placed in the bigger quadrilateral groove 54 of the lower width of the 4th T shape quadrilateral groove 52; The lower surface of the upper surface of the second quadrilateral briquetting 5 and the 4th column permanent magnetic iron block 30 is fitted, and the lower surface of the second quadrilateral briquetting 5 flushes with the lower surface that the upper end has the cylinder 35 of disc flange; The axial alignment (coincidence) of first tapped hole 6 of the 4th T shape quadrilateral groove 52 that the axis of first unthreaded hole 7 on the second quadrilateral briquetting 5 and upper end is had the cylinder 35 of disc flange; The threaded end of the 4th bolt 29 is passed first unthreaded hole 7 be screwed into first tapped hole 6 and tighten, when the 4th bolt 29 was tightened, the 4th bolt 29 compressed the second quadrilateral briquetting 5.
The 15 step: the lower end welding of the cylinder of the cylinder 35 that upper end and the upper end of the 3rd circular shaft 100 had disc flange, the welding front and back all must guarantee the dead in line of the axis and the cylinder 35 that the upper end has disc flange of the 3rd circular shaft 100; The lower end of the 3rd circular shaft 100 is inserted in the corresponding groove 102; The lower end of the 3rd coil component spring 37 is welded on the upper surface of first disk 1, the upper end of the 3rd coil component spring 37 is welded on the lower surface of this cylindrical body 38.All must guarantee the axis of the 3rd coil component spring 37, the axis of cylindrical shape oil hydraulic cylinder 17 and the dead in line of cylindrical body 38 before and after the welding.Second disk 104 must not be interfered with the 3rd circular shaft 100 and groove 102.
The 16 step: the seat ring of self-aligning thrust roller bearing is put into annular groove 103; Cylindrical shape oil hydraulic cylinder 17 is inserted in cylinder 35 that the upper end has disc flange and the stepped cylinder 11, guarantees that simultaneously cylindrical body 38 is enclosed within the through hole 39; The less part of stepped cylinder 11 external diameters is enclosed within the blowout patche of self-aligning thrust roller bearing, guarantees that simultaneously the shoulder of stepped cylinder 11 contacts with the upper surface of the blowout patche of self-aligning thrust roller bearing; Cylindrical body 38 and upper end are had upper end disc flange 47 welding of the cylinder 35 of disc flange; The upper-end surface of upper end disc flange 47 that the upper-end surface that welding requirements guarantees cylindrical body 38 and upper end have the cylinder 35 of disc flange flushes, and the lower end surface of upper end disc flange 47 that the lower end surface of cylindrical body 38 and upper end have the cylinder 35 of disc flange flushes.
If with the 5th bolt 65 and the 6th bolt 66 replacements the 4th bolt 29; The second ring briquetting, 71 replacements, the second quadrilateral briquetting 5; The second ring permanent magnetic iron block, 70 replacements the 4th column permanent magnetic iron block 30; Simultaneously with the 7th bolt 76 and the 8th bolt 77 replacements first bolt 2, the first ring briquettings 60 replacements first quadrilateral briquetting 3, the first ring permanent magnetic iron blocks 59 replacements first column permanent magnetic iron block 4; Be similar to the magnetic force that 13 steps of the above-listed first step to the also can obtain possessing the another kind of form of said function and rotate and an axle streaming current variant damper, the concrete process of making can follow these steps to carry out:
The first step: according to the vibration control requirement, selected first disk 1, piston 48, the first dividing plates 8, the first Hollow Cylindrical Shaft 16; Bottom disc flange 19, upper end have the cylinder 35 of disc flange, the upper end disc flange 47 of the cylinder 35 of upper end band disc flange, cylinder 11, cylindrical shape oil hydraulic cylinder 17; Second Hollow Cylindrical Shaft, 18, the first coil component springs, 27, the second coil component springs, 34, the three coil component springs 37; Cylindrical body 38, annular groove 103, the size of thrust-bearing 101, the second disks 104; Selected white clay/titanium oxide Nano composite granules ER fluid is as electro rheological fluids 55; Selected self-aligning thrust roller bearing is as thrust-bearing 101; Selected room temperature silica gel is as the packing material 83 that not only insulate but also seal; According to the vibration control requirement, the bigger annular groove 69 of lower width of annular groove 57, the two T shape annular grooves 67, the two T shape annular grooves 67 that the lower width of annular groove 58, the one T shape annular grooves 56 that the upper width of a selected T shape annular groove 56, the one T shape annular grooves 56 is bigger is less; The bigger quadrilateral groove 45 of lower width of quadrilateral groove 42, the two T shape quadrilateral grooves 43, the two T shape quadrilateral grooves 43 that the lower width of quadrilateral groove 41, the one T shape quadrilateral grooves 40 that the upper width of annular groove 68, the one T shape quadrilateral grooves 40, the one T shape quadrilateral grooves 40 that the upper width of the 2nd T shape annular groove 67 is less is bigger is less; Quadrilateral groove 44, the first ring briquettings 60, the second ring briquettings 71, the four quadrilateral briquettings 23, the three quadrilateral briquettings 10 that the upper width of the 2nd T shape quadrilateral groove 43 is less; The first ring permanent magnetic iron block, 59, the second ring permanent magnetic iron blocks, 70, the three column permanent magnetic iron blocks, 26, the second column permanent magnetic iron blocks, 14, the second tapped holes 13; The 3rd tapped hole 25, the seven tapped holes 72, the eight tapped holes 73, the six tapped holes 62, the five tapped holes 61; Second unthreaded hole, 12, the three unthreaded holes, 24, the five unthreaded holes, 63, the six unthreaded holes, 64, the seven unthreaded holes 74; The 8th unthreaded hole 75, the second bolts 9, the three bolts 22 the 5th bolt 65, the six bolts 66, the seven bolts 76; The 8th bolt 77, stator blade 46, rotor blade 20, the first bolts hole 21, the second bolts hole 36; The first roundlet through hole, 15, the second roundlet through holes, 28, the first round tube holes 33, through hole 39, the nine bolts 80; Second round tube hole, 81, the nine tapped holes, 82, the first circular shaft shape supporting frames, 84, the three bolts hole 85, counterbore 86; The 4th bolt hole 87, the five bolts hole 88, the three round tube holes 89, the ten tapped holes 90, the first circular shafts 91; Second circular shaft, 92, the four round tube holes, 93, the ten bolts, 94, the second circular shaft shape supporting frames 95, ring negative plate 96; Manhole 97, the first leads 98, the second leads 99, the three circular shafts 100, the quantity of groove 102, position and size.48 the 3rd T shape quadrilateral groove 49 positions, quantity are corresponding one by one in the 4th T shape quadrilateral groove 52 in the cylinder 11 and the piston; Be that the 4th T shape quadrilateral groove 52 in the cylinder 11 is identical with the 3rd T shape quadrilateral groove 49 quantity in the piston 48, one the 4th T shape quadrilateral groove 52 with and only be distributed on the same ray perpendicular to first disk, 1 axis with one the 3rd T shape quadrilateral groove 49; It is corresponding one by one that the upper end has position, the quantity of the T shape quadrilateral groove 40 in the 2nd T shape quadrilateral groove 43 and the rotor blade 20 in the cylinder 35 of disc flange; Promptly the 2nd T shape quadrilateral groove 43 that has in the cylinder 35 of disc flange of upper end is identical with a T shape quadrilateral groove 40 quantity in the rotor blade 20, one the 2nd T shape quadrilateral groove 43 and and only be distributed on the same ray perpendicular to first disk, 1 axis with one the one T shape quadrilateral groove 40; The quantity of groove 102 and the 3rd circular shaft 100 equates, the position is corresponding one by one.For example: after installing at damper; Piston 48 is in the equilibrium of forces state under the acting in conjunction of power such as magnetic force, second coil component spring 34, first coil component spring 27 and gravity, confirmed the parameter of second coil component spring 34 and first coil component spring 27 by conventional Mechanics Calculation.Cylinder 35 height that the upper end has a disc flange according to " with the first ring permanent magnetic iron block 59 divide equally for two-part plane up and down with the second ring permanent magnetic iron block 70 is divided equally be two-part planes up and down " definite with " length of the 3rd coil component spring 37 is not less than the maximum vibration displacement of oscillating body " these two conditions; The height of cylinder 11 according to " with the second column permanent magnetic iron block 14 divide equally for two-part plane up and down with the 3rd column permanent magnetic iron block 26 is divided equally be two-part planes up and down " confirm; For example when vibration is simple harmonic oscillation; The upper surface of piston 48 is not less than the maximum vibration displacement of oscillating body to the distance of the lower surface of the second circular shaft shape supporting frame 95, and the lower surface of piston 48 is not less than the maximum vibration displacement of oscillating body to the distance of the upper surface of first dividing plate 8; The groove depth of groove 102 is greater than the maximum vibration displacement of oscillating body; Respectively 4 of the selected first circular shaft shape supporting frame 84 and the second circular shaft shape supporting frames 95; After being predefined in the following step and the first circular shaft shape supporting frame 84 and the second circular shaft shape supporting frame 95 are installed are finished; 4 first circular shaft shape supporting frames 84 are uniformly distributed with about the axis symmetry of second Hollow Cylindrical Shaft 18, and 4 second circular shaft shape supporting frames 95 are uniformly distributed with about the axis symmetry of second Hollow Cylindrical Shaft 18.
Second step: the second column permanent magnetic iron block 14 is placed in the less quadrilateral groove 42 of the lower width of a T shape quadrilateral groove 40 of rotor blade 20, the magnetic pole of the second column permanent magnetic iron block 14 points to the axial direction and the axial direction that points to away from second Hollow Cylindrical Shaft 18 of second Hollow Cylindrical Shaft 18 respectively; The lower surface of the lower surface of the second column permanent magnetic iron block 14 and a T shape quadrilateral groove 40 is fitted, i.e. the lower surface applying of the less quadrilateral groove 42 of the lower width of the lower surface of the second column permanent magnetic iron block 14 and a T shape quadrilateral groove 40; The 3rd quadrilateral briquetting 10 is placed in the bigger quadrilateral groove 41 of the upper width of a T shape quadrilateral groove 40; The upper surface of the lower surface of the 3rd quadrilateral briquetting 10 and the second column permanent magnetic iron block 14 is fitted, the flush of the upper surface of the 3rd quadrilateral briquetting 10 and rotor blade 20; Dead in line with second tapped hole 13 of a T shape quadrilateral groove 40 of the axis of second unthreaded hole 12 on the 3rd quadrilateral briquetting 10 and rotor blade 20; The threaded end of second bolt 9 is passed second unthreaded hole 12 be screwed into second tapped hole 13 and tighten, when second bolt 9 was tightened, second bolt 9 compressed the 3rd quadrilateral briquetting 10.
The 3rd step: the lower end surface of second Hollow Cylindrical Shaft 18 is welded on the upper surface of bottom disc flange 19, all must guarantees the axis of bottom disc flange 19 and the dead in line of second Hollow Cylindrical Shaft 18 before and after the welding; Insert second circular shaft 92 in second Hollow Cylindrical Shaft 18; With the axis of second circular shaft 92 and the dead in line of second Hollow Cylindrical Shaft 18; The upper-end surface of second circular shaft 92 is flushed with the upper-end surface of second Hollow Cylindrical Shaft 18; With the dead in line of the axis and second round tube hole 81 of the 7th tapped hole 82, the threaded end of the first circular shaft shape supporting frame 84 is passed second round tube hole 81 be screwed into the 7th tapped hole 82 and tighten; Ring positive plate 78 is enclosed within on second Hollow Cylindrical Shaft 18; Dead in line with the axis and the 3rd bolt hole 85 of counterbore 86; Pass counterbore 86 and the 3rd bolt hole 85 and tighten with the 9th bolt 80, the ring positive plate 78 and the first circular shaft shape supporting frame 84 are linked together;
The 4th step: pour an amount of room temperature silicone rubber into along the sidewall of second Hollow Cylindrical Shaft 18; The amount of room temperature silicone rubber is the shared volume in space half the between second Hollow Cylindrical Shaft 18 and second circular shaft 92; After the cooling of room temperature silicone rubber, second Hollow Cylindrical Shaft 18 and second circular shaft 92 are fixed together; Inject room temperature silicone rubber along the gap of hole wall between second round tube hole 81 and the first circular shaft shape supporting frame 84 of second round tube hole 81 again, after the cooling of room temperature silicone rubber, the sealing of the air space insulation between second round tube hole 81 and the first circular shaft shape supporting frame 84 is filled;
The 5th step: the end of stator blade 46 away from the center of circle is welded on the cylindrical shape oil hydraulic cylinder 17; Cylindrical shape oil hydraulic cylinder 17 is enclosed within outside the rotor blade 20; The upper surface welding of the lower end surface of cylindrical shape oil hydraulic cylinder 17 and bottom disc flange 19 all must guarantee axis and the dead in line of cylindrical shape oil hydraulic cylinder 17, the axis of bottom disc flange 19 and the dead in line of cylindrical shape oil hydraulic cylinder 17 of stator blade 46 before and after the welding; In cylindrical shape oil hydraulic cylinder 17, pour an amount of a certain amount of white clay/titanium oxide Nano composite granules ER fluid into, the flush of the horizontal plane of ER fluid and ring positive plate 23; Second partition 79 is enclosed within on second Hollow Cylindrical Shaft 18, and second partition 79 is positioned at the top of ring positive plate 78, the smooth contact of upper surface of the lower surface of second partition 79 and ring positive plate 78, second partition 79 and second Hollow Cylindrical Shaft, 18 smooth contacts.
The 6th step: the end of rotor blade 20 near the center of circle is welded on first Hollow Cylindrical Shaft 16; Must guarantee that all the lower surface of rotor blade 20 flushes with the lower surface of first Hollow Cylindrical Shaft 16 before and after the welding; First Hollow Cylindrical Shaft 16 is enclosed within on second Hollow Cylindrical Shaft 18 smooth contact of upper surface of the lower surface of rotor blade 20 and bottom disc flange 19; In cylindrical shape oil hydraulic cylinder 17, pour an amount of white clay/titanium oxide Nano composite granules ER fluid into, the flush of the horizontal plane of ER fluid and rotor blade 20; First dividing plate 8 is enclosed within on second Hollow Cylindrical Shaft 18; The smooth contact of upper surface of the lower surface of first dividing plate 8 and the upper surface and the stator blade 46 of rotor blade 20; With the inner ring surface of first dividing plate 8 and the outer peripheral surface welding of second Hollow Cylindrical Shaft 18; The inner peripheral surface welding of the outer ring surface of first dividing plate 8 and cylindrical shape oil hydraulic cylinder 17 all must guarantee the axis of first dividing plate 8, the axis of second Hollow Cylindrical Shaft 18 and the dead in line of cylindrical shape oil hydraulic cylinder 17 before and after the welding.
The 7th step: the first ring permanent magnetic iron block 59 is placed in the less annular groove 57 of the lower width of a T shape annular groove 56 of piston 48; The magnetic pole of the first ring permanent magnetic iron block 59 is at inside and outside two anchor rings, and the arctic is inwardly outwardly in the magnetic pole South Pole of the first ring permanent magnetic iron block 59; The lower surface of the lower surface of the first ring permanent magnetic iron block 59 and a T shape annular groove 56 is fitted, i.e. the lower surface applying of the less annular groove 57 of the lower width of the lower surface of the first ring permanent magnetic iron block 59 and a T shape annular groove 56; The first ring briquetting 60 is placed in the bigger annular groove 58 of the upper width of a T shape annular groove 56; The upper surface of the lower surface of the first ring briquetting 60 and the first ring permanent magnetic iron block 59 is fitted, the flush of the upper surface of the first ring briquetting 60 and piston 48; With the dead in line of the 5th tapped hole 61 of a T shape annular groove 56 of the axis of the 5th unthreaded hole 63 on the first ring briquetting 60 and piston 48, with the dead in line of the 6th tapped hole 62 of a T shape annular groove 56 of the axis of the 6th unthreaded hole 64 on the first ring briquetting 60 and piston 48; The threaded end of the 5th bolt 65 is passed the 6th unthreaded hole 64 to be screwed into the 6th tapped hole 62 and to tighten; The threaded end of the 6th bolt 66 is passed the 5th unthreaded hole 63 and is screwed into the 5th tapped hole 61 and tightens; When the 5th bolt 65 and the 6th bolt 66 were tightened, the 5th bolt 65 and the 6th bolt 66 compressed the first ring briquetting 60.
The 8th step: first coil component spring 27 is enclosed within on second Hollow Cylindrical Shaft 18, and first coil component spring 27 places the top of first dividing plate 8, and piston 48 is enclosed within on second Hollow Cylindrical Shaft 18 through first round tube hole 33 ,Piston 48 places the top of first coil component spring 27, and an end of first coil component spring 27 is welded on the lower surface of piston 48, and the other end of first coil component spring 27 is welded on the cylndrical surface of second Hollow Cylindrical Shaft 18, that is to say the top of first dividing plate, 8 upper surfaces; Second coil component spring 34 is enclosed within on second Hollow Cylindrical Shaft 18; Second coil component spring 34 is positioned at the top of piston; One end of second coil component spring 34 is welded on piston 48 upper surfaces; The other end of second coil component spring 34 is welded on the top of the cylndrical surface of second Hollow Cylindrical Shaft 18, that is to say plane, the 3rd round tube hole 89 least significant ends places below; All must guarantee the axis of second Hollow Cylindrical Shaft 18, the axis of piston 48, the axis of second coil component spring 34 and the dead in line of first coil component spring 27 before and after the welding.
The 9th step: insert first circular shaft 91 in the top Hollow Cylindrical Shaft of second circular shaft 92; Dead in line with the axis and second circular shaft 92 of first circular shaft 91; Flush with the upper surface and second circular shaft 92 of first circular shaft 91; With the axis of the tenth tapped hole 90 and the axis of the 3rd round tube hole 89, the dead in line of the 4th round tube hole 93, the threaded end of the second circular shaft shape supporting frame 95 is passed the 3rd round tube hole 89 and the 4th round tube hole 93 be screwed into the tenth tapped hole 90 and tighten; Ring negative plate 96 is enclosed within on second Hollow Cylindrical Shaft 18; Ring negative plate 96 is positioned at the top of the second circular shaft shape supporting frame 95; Dead in line with the axis and the 4th bolt hole 87 of the 5th bolt hole 88; Pass the 5th bolt hole 88 and the 4th bolt hole 87 and tighten with the tenth bolt 94, the ring negative plate 96 and the second circular shaft shape supporting frame 95 are linked together; Inject room temperature silicone rubber along the sidewall of second Hollow Cylindrical Shaft 18 and the sidewall of second circular shaft, 92 top Hollow Cylindrical Shaft respectively again, when after the cooling of room temperature silicone rubber the air space insulation sealing between the sealing of the air space insulation between second Hollow Cylindrical Shaft 18 and second circular shaft 92 filling, second circular shaft 92 and first circular shaft 91 being filled; Again along the hole wall of the 3rd round tube hole 89; Room temperature silicone rubber is injected in gap between the 3rd round tube hole 89 and the second circular shaft shape supporting frame 95, after the cooling of room temperature silicone rubber, the sealing of the air space insulation between the 3rd round tube hole 89 and the second circular shaft shape supporting frame 95 is filled.
The tenth step: the circle centre position at first disk 1 bores circular hole a, and the diameter of circular hole a is a bit larger tham the diameter (getting concrete numerical value by conventional welding conditions) of second Hollow Cylindrical Shaft 18, the dead in line of the axis of circular hole a and first disk 1; Axis symmetry about first disk 1 is bored small sircle hole b and small sircle hole c on first disk 1 again; Half of small sircle hole b and small sircle hole c axis separately equal cylindrical shape oil hydraulic cylinder 17 from the distance of the axis of first disk 1 inside radius and the radius sum of circular hole a; The radius of small sircle hole b and small sircle hole c deduct less than the inside radius of cylindrical shape oil hydraulic cylinder 17 circular hole a radius numerical value 1/2nd, and require small sircle hole b and the small sircle hole c can not be over against the top of rotor blade 20 and stator blade 46.
The 11 step: then the 6th step was inserted in the top of second Hollow Cylindrical Shaft 18 and bore among the circular hole a, the lower surface of first disk 1 is placed on the upper-end surface of cylindrical shape oil hydraulic cylinder 17.The upper-end surface of cylindrical shape oil hydraulic cylinder 17 is welded on the lower surface of first disk 1; Again with the upper-end surface of second Hollow Cylindrical Shaft 18 and first disk 1 the 6th the step institute circular hole a place of boring weld, weld front and back and all must guarantee the axis of cylindrical shape oil hydraulic cylinder 17, the axis of first disk 1, the dead in line of second Hollow Cylindrical Shaft 18; Second disk 104 is enclosed within on the oil hydraulic cylinder 17; The inner ring surface of second disk 104 and the outer peripheral surface of oil hydraulic cylinder 17 are welded; Guarantee the axis of second disk 104 and the dead in line of oil hydraulic cylinder 17 before and after the welding, and smooth contact of upper surface of the lower surface of second disk 104 and stepped cylinder 11.
The 12 step: use funnel white clay/titanium oxide Nano composite granules ER fluid to fill with cylindrical shape oil hydraulic cylinder 17 earlier by the 6th step small sircle hole b that bores; After observing damp liquid and filled with cylindrical shape oil hydraulic cylinder 17 through small sircle hole b and small sircle hole c, the 6th step small sircle hole b that bores of institute and small sircle hole c are welded block again.
The 13 step: the 3rd column permanent magnetic iron block 26 is placed in the less quadrilateral groove 44 of the upper width of the 2nd T shape quadrilateral groove 43 of cylinder 11; The magnetic pole of the 3rd column permanent magnetic iron block 26 points to the axial direction and the axial direction that points to away from cylinder 11 of cylinder 11 respectively, and the 3rd column permanent magnetic iron block 26 is opposite near the magnetic polarity of cylindrical shape oil hydraulic cylinder 17 1 ends near the magnetic polarity and the second column permanent magnetic iron block 14 of cylindrical shape oil hydraulic cylinder 17 1 ends; The upper surface of the upper surface of the 3rd column permanent magnetic iron block 26 and the 2nd T shape quadrilateral groove 43 is fitted, i.e. the upper surface applying of the less quadrilateral groove 44 of the upper width of the upper surface of the 3rd column permanent magnetic iron block 26 and the 2nd T shape quadrilateral groove 43; The 4th quadrilateral briquetting 23 is placed in the bigger quadrilateral groove 45 of the lower width of the 2nd T shape quadrilateral groove 43; The lower surface of the upper surface of the 4th quadrilateral briquetting 23 and the 3rd column permanent magnetic iron block 26 is fitted, and the lower surface of the 4th quadrilateral briquetting 23 flushes with the lower surface of cylinder 11; Axial alignment (coincidence) with axis with the 3rd tapped hole 25 of the 2nd T shape quadrilateral groove 43 of cylinder 11 of the 3rd unthreaded hole 24 on the 4th quadrilateral briquetting 23; The threaded end of the 3rd bolt 22 is passed the 3rd unthreaded hole 24 be screwed into the 3rd tapped hole 25 and tighten, when the 3rd bolt 22 was tightened, the 3rd bolt 22 compressed the 4th quadrilateral briquetting 23.
The 14 step: place the upper end to have in the less annular groove 68 of the upper width of the 2nd T shape annular groove 67 of cylinder 35 of disc flange the second ring permanent magnetic iron block 70; The magnetic pole of the second ring permanent magnetic iron block 70 is at inside and outside two anchor rings, and the arctic is inwardly outwardly in the magnetic pole South Pole of the second ring permanent magnetic iron block 70; The upper surface of the upper surface of the second ring permanent magnetic iron block 70 and the 2nd T shape annular groove 67 is fitted, i.e. the upper surface applying of the less annular groove 68 of the upper width of the upper surface of the second ring permanent magnetic iron block 70 and the 2nd T shape annular groove 67; The second ring briquetting 71 is placed in the bigger annular groove 69 of the lower width of the 2nd T shape annular groove 67; The lower surface of the upper surface of the second ring briquetting 71 and the second ring permanent magnetic iron block 70 is fitted, and the lower surface of the second ring briquetting 71 flushes with the lower surface of cylinder 11; With the dead in line of the 8th tapped hole 73 of the 2nd T shape annular groove 67 of the axis of the 8th unthreaded hole 75 on the second ring briquetting 71 and cylinder 11, the axial alignment of the 7th tapped hole 72 of the 2nd T shape annular groove 67 of the axis of the 7th unthreaded hole 74 on the second ring briquetting 71 and cylinder 11; The threaded end of the 8th bolt 77 is passed the 8th unthreaded hole 75 to be screwed into the 8th tapped hole 73 and to tighten; The threaded end of the 8th bolt 77 is passed the 7th unthreaded hole 74 and is screwed into the 7th tapped hole 72 and tightens; When the 8th bolt 77 and the 8th bolt 77 were tightened, the 8th bolt 77 and the 8th bolt 77 compressed the second ring briquetting 71.
The 15 step: the lower end welding of the cylinder of the cylinder 35 that upper end and the upper end of the 3rd circular shaft 100 had disc flange, the welding front and back all must guarantee the dead in line of the axis and the cylinder 35 that the upper end has disc flange of the 3rd circular shaft 100; The lower end of the 3rd circular shaft 100 is inserted in the corresponding groove 102; The lower end of the 3rd coil component spring 37 is welded on the upper surface of first disk 1, the upper end of the 3rd coil component spring 37 is welded on the lower surface of this cylindrical body 38.All must guarantee the axis of the 3rd coil component spring 37, the axis of cylindrical shape oil hydraulic cylinder 17 and the dead in line of cylindrical body 38 before and after the welding.Second disk 104 must not be interfered with the 3rd circular shaft 100 and groove 102.
The 16 step: the seat ring of self-aligning thrust roller bearing is put into annular groove 103; Cylindrical shape oil hydraulic cylinder 17 is inserted in cylinder 35 that the upper end has disc flange and the stepped cylinder 11, guarantees that simultaneously cylindrical body 38 is enclosed within the through hole 39; The less part of stepped cylinder 11 external diameters is enclosed within the blowout patche of self-aligning thrust roller bearing, guarantees that simultaneously the shoulder of stepped cylinder 11 contacts with the upper surface of the blowout patche of self-aligning thrust roller bearing; Cylindrical body 38 and upper end are had upper end disc flange 47 welding of the cylinder 35 of disc flange; The upper-end surface of upper end disc flange 47 that the upper-end surface that welding requirements guarantees cylindrical body 38 and upper end have the cylinder 35 of disc flange flushes, and the lower end surface of upper end disc flange 47 that the lower end surface of cylindrical body 38 and upper end have the cylinder 35 of disc flange flushes.
In aforementioned process, only remove second coil component spring 34 and first coil component spring 27 simultaneously, still obtain effective magnetic force and rotate and axle streaming current variant damper; Similarly, in aforementioned process, only remove second coil component spring 34, still obtain effective magnetic force and rotate and axle streaming current variant damper; Equally, in aforementioned process, only be to remove first coil component spring 27, still obtain effective magnetic force and rotate and axle streaming current variant damper.

Claims (10)

1. a magnetic force rotates and axle streaming current variant damper; It is characterized in that: this magnetic force rotates with axle streaming current variant damper and comprises: first disk (1), the bottom disc flange (19) that is oppositely arranged with first disk (1), the oil hydraulic cylinder (17) that first disk (1) is connected with the leakage of bottom disc flange (19) nothing, the upper end with opening have cylinder (35), stepped cylinder (11), the 3rd circular shaft (100), thrust-bearing (101) second disks (104) of disc flange, disc flange (47) on the upper end that the upper end has a cylinder (35) of disc flange has; The top of stepped cylinder (11) fluted (102); The upper-end surface of the 3rd circular shaft (100) is connected with the lower end surface that the upper end has the cylinder (35) of disc flange, and the lower end of the 3rd circular shaft (100) is positioned at groove (102), and the 3rd circular shaft (100) and smooth contact of groove (102); The 3rd circular shaft (100) has the cylinder (35) of disc flange along the upper end a circumference is uniformly distributed with, and groove (102) is equal with the 3rd circular shaft (100) quantity and the position is corresponding one by one; Second disk (104) is enclosed within outside the oil hydraulic cylinder (17) and is connected with oil hydraulic cylinder (17); The inner ring surface of second disk (104) links to each other with the outer peripheral surface of oil hydraulic cylinder (17), the smooth contact of upper surface of the lower surface of second disk (104) and stepped cylinder (11);
Bottom disc flange (19); First disk (1) and oil hydraulic cylinder (17) are formed closed no leakage space; Electro rheological fluids (55) is full of this closed no leakage space; This oil hydraulic cylinder (17) part be positioned at the space that cylinder (11) and upper end have cylinder (35) composition of disc flange, the upper end has built-in the 4th permanent magnetic iron block of lower end cylinder (30) of the cylinder (35) of disc flange, built-in the 3rd permanent magnetic iron block of cylinder (11) (26); Stepped cylinder (11) is divided into bigger part of top external diameter and the less part of lower outer diameter; Two-part internal diameter is identical; The less part of external diameter of stepped cylinder (11) is enclosed within the blowout patche of thrust-bearing (101); The shoulder of stepped cylinder (11) contacts with the upper surface of the blowout patche of thrust-bearing (101); The lower end of the part that the external diameter of stepped cylinder (11) is less does not contact with bottom disc flange (19), and the relation of the less part of the external diameter of stepped cylinder (11) and the blowout patche of thrust-bearing (101) is an axle and the conventional matching relationship of the blowout patche of thrust-bearing; The seat ring of thrust-bearing (101) is positioned at the annular groove (103) of bottom disc flange (19), and the relation of the seat ring of thrust-bearing (101) and annular groove (103) is the seat ring of thrust-bearing and the conventional matching relationship of bearing saddle bore;
This magnetic force rotates with axle streaming current variant damper and also comprises piston (48), first Hollow Cylindrical Shaft (16), second Hollow Cylindrical Shaft (18), rotor blade (20), stator blade (46), second permanent magnetic iron block (14) and first permanent magnetic iron block (4), first dividing plate (8), second partition (79), ring positive plate (78) along oil hydraulic cylinder (17) axial motion, the first circular shaft shape supporting frame (84), first circular shaft (91), second circular shaft (92), the second circular shaft shape supporting frame (95), ring negative plate (96);
Same circumference along second Hollow Cylindrical Shaft ((18)) lower external face is evenly equipped with second round tube hole (81); The orthogonal axe of the axis of second round tube hole (81) and second Hollow Cylindrical Shaft (18); The same circumference on the top of edge second Hollow Cylindrical Shaft (18) outer surface is evenly equipped with the 3rd round tube hole (89); The orthogonal axe of the axis of the 3rd round tube hole (89) and second Hollow Cylindrical Shaft (18); Be with second circular shaft (92) that top is hollow, the bottom is solid in second Hollow Cylindrical Shaft (18); Same circumference along second circular shaft (92) outer surface of upper is evenly equipped with the 4th round tube hole (93); The orthogonal axe of the axis of the 4th round tube hole (93) and second Hollow Cylindrical Shaft (18); The 3rd round tube hole (89) and the 4th round tube hole (93) correspondence and dead in line one by one, the length of second circular shaft (92) are less than the length of second Hollow Cylindrical Shaft (18), and the lower end surface of second circular shaft (92) is higher than the lower end surface of second Hollow Cylindrical Shaft (18); The upper-end surface of second circular shaft (92) flushes with the upper-end surface of second Hollow Cylindrical Shaft (18); Be with first circular shaft (91) in the top hollow shaft of second circular shaft (92), first circular shaft (91) length is less than the length of the top Hollow Cylindrical Shaft of second circular shaft (92), and the top of first circular shaft (91) flushes with the top of second circular shaft (92); Ring positive plate (78) is positioned on the upper surface of bottom disc flange (19); Link to each other with an end of the first circular shaft shape supporting frame (84), the other end of the first circular shaft shape supporting frame (84) passes second round tube hole (81) and links to each other with second circular shaft (92), and ring negative plate (96) is positioned under the lower surface of disk (13); Be connected with an end of the second circular shaft shape supporting frame (95); The other end of the second circular shaft shape supporting frame (95) passes the 3rd round tube hole (89) and links to each other with first circular shaft (91) with the 4th round tube hole (93), and second circular shaft (92) top is passed manhole (97) through second lead (99) and linked to each other with external power supply is anodal, and the top of first circular shaft (91) is passed manhole (97) through first lead (98) and linked to each other with the external power supply negative pole;
The upper surface of ring negative plate (96) does not contact with the lower surface of disk (13); The lower surface of ring positive plate (78) does not contact with the upper surface of bottom disc flange (19); Ring positive plate (78) does not all contact with oil hydraulic cylinder (14), second Hollow Cylindrical Shaft (18) with ring negative plate (96); Ring positive plate (78) only contacts with electro rheological fluids (55) with the first circular shaft shape supporting frame (69), and ring negative plate (96) only contacts with electro rheological fluids (55) with the second circular shaft shape supporting frame (95); The first circular shaft shape supporting frame (69) does not contact with second Hollow Cylindrical Shaft (18); The first circular shaft shape supporting frame (69) does not contact with bottom disc flange (19); The second circular shaft shape supporting frame (95) does not contact with second Hollow Cylindrical Shaft (18), and packing material (83) insulated enclosure is used in the space between space, second circular shaft (92) and first circular shaft (91) between space, second circular shaft (92) and second Hollow Cylindrical Shaft (18) between the space between the space between the first circular shaft shape supporting frame (69) and second Hollow Cylindrical Shaft (18), the second circular shaft shape supporting frame (95) and second Hollow Cylindrical Shaft (18), the second circular shaft shape supporting frame (95) and second circular shaft (92) respectively;
Piston (48) is positioned at the below of ring negative plate (96); Piston (48) circle centre position is provided with first round tube hole (33); Have the second little round tube hole (28) on the piston (48); When electro rheological fluids (55) passes through the second little round tube hole (28), the line of action of making a concerted effort of the suffered damping force of piston (48) and the dead in line of second Hollow Cylindrical Shaft (18), first permanent magnetic iron block (4) is arranged on piston (48) inside; First dividing plate (8) is positioned at the below of piston (48), and the inner ring surface of first dividing plate (8) links to each other with the outer peripheral surface of second Hollow Cylindrical Shaft (18), and the outer ring surface of first dividing plate (8) links to each other with the inner peripheral surface of oil hydraulic cylinder (17); Second partition (79) is positioned at the top of ring positive plate (78), the inner ring surface of second partition (79) and smooth contact of second Hollow Cylindrical Shaft (18), the outer ring surface of second partition (79) and smooth contact of oil hydraulic cylinder (17); Second Hollow Cylindrical Shaft (18) is passed first round tube hole (33), first dividing plate (8) and second partition (79); Second Hollow Cylindrical Shaft (18) lower end surface does not have leakage with bottom disc flange (19) and is connected, and the upper-end surface of second Hollow Cylindrical Shaft (18) flushes with the upper-end surface of first disk (1) and do not have to leak and is connected;
Rotor blade (20) is positioned between first dividing plate (8) and the second partition (79); And the height of rotor blade (20) is consistent with the height of first Hollow Cylindrical Shaft (16); First Hollow Cylindrical Shaft (16) is enclosed within on second Hollow Cylindrical Shaft (18); Rotor blade (20) links to each other with first Hollow Cylindrical Shaft (16) near an end in the center of circle, and rotor blade (20) is away from an end and smooth contact of oil hydraulic cylinder (17) in the center of circle, the upper end of rotor blade (20) and smooth contact of first dividing plate (8); The lower end of rotor blade (20) and smooth contact of second partition (79); Rotor blade (20) is along highly having the first little round tube hole (15), and the orthogonal axe of the axis of the first little round tube hole (15) and second Hollow Cylindrical Shaft (18) is when electro rheological fluids (55) passes through the first little round tube hole (15); The master vows to be zero during the suffered damping force reduction of force system of rotor blade (20) some to second Hollow Cylindrical Shaft (18) axis, the axis normal of the acting surface of main square and second Hollow Cylindrical Shaft (18); Stator blade (46) links to each other with oil hydraulic cylinder (17) away from an end in the center of circle; Stator blade (46) is near an end and smooth contact of first Hollow Cylindrical Shaft (16) in the center of circle; Second permanent magnetic iron block (14) is arranged on rotor blade (20) inside; Rotor blade (20) evenly distributes along first Hollow Cylindrical Shaft (16) cylindrical contour, and stator blade (46) evenly distributes along oil hydraulic cylinder (17) inner circumference line, and is provided with a rotor blade (20) in the middle of per two stator blades (46).
2. magnetic force according to claim 1 rotates and axle streaming current variant damper; It is characterized in that: said the 4th permanent magnetic iron block (30) attracts each other through magnetic force with first permanent magnetic iron block (4); The 4th permanent magnetic iron block (30) is identical with first permanent magnetic iron block (4) quantity; The position is corresponding one by one, and the component of making a concerted effort in the horizontal direction of the suffered magnetic force of all first permanent magnetic iron blocks (4) is zero; The 3rd permanent magnetic iron block (26) is identical with second permanent magnetic iron block (14) quantity; The position is corresponding one by one; And the master vowed to be zero, the axis normal of the acting surface of main square and second Hollow Cylindrical Shaft (18) when the suffered magnetic force of the 3rd permanent magnetic iron block (26) system was simplified to some on second Hollow Cylindrical Shaft (18) axis; The master vowed to be zero, the axis normal of the acting surface of main square and second Hollow Cylindrical Shaft (18) when the suffered magnetic force of second permanent magnetic iron block (14) system was simplified to some on second Hollow Cylindrical Shaft (18) axis.
3. magnetic force according to claim 1 rotates and axle streaming current variant damper; It is characterized in that: the upper end has the axis of the cylinder (35) of disc flange, the axis of cylinder (11), the axis of first disk (1), the axis of oil hydraulic cylinder (17), the axis of bottom disc flange (19), the axis of second Hollow Cylindrical Shaft (18), the axis of piston (48), the axis of the axis of the axis of the axis of the axis of first dividing plate (8), second partition (79), the axis of first Hollow Cylindrical Shaft (16), rotor blade (20), the axis of stator blade (46), ring negative plate (96), the axis of ring positive plate (78), first circular shaft (91), the axis of second circular shaft (92), the axis of the first circular shaft shape supporting frame (84), the axis of second disk (104), the axis of the second circular shaft shape supporting frame (95) and the dead in line of first round tube hole (33).
4. nothing according to claim 1 is leaked the rotating fluid damper, it is characterized in that: the distribution of the first little round tube hole (15) also has following dual mode: a, the first little round tube hole (15) to change to be located on the stator blade (46); Have the first little round tube hole (15) on b, stator blade (46) and the rotor blade (20) simultaneously.
5. rotate and axle streaming current variant damper according to claim 1,2,3 or 4 described magnetic force; It is characterized in that: in this magnetic force rotation and axle streaming current variant damper, also comprise first spring (27); Obtaining magnetic force rotates and an another kind of style of streaming current variant damper; Wherein: the upper end of first spring (27) is connected with piston (48) lower surface; The lower end of first spring (27) is connected with second Hollow Cylindrical Shaft (18), and first spring (27) is positioned at the top of the upper surface of first dividing plate (8), and first spring (27) is to the line of action of making a concerted effort of the active force of piston (48) and the dead in line of second Hollow Cylindrical Shaft (18).
6. rotate and axle streaming current variant damper according to claim 1,2,3 or 4 described magnetic force; It is characterized in that: in this magnetic force rotation and axle streaming current variant damper, also comprise second spring (34); Obtaining magnetic force rotates and an another kind of style of streaming current variant damper; Wherein: the lower end of second spring (34) is connected with the upper surface of piston (48); The upper end of second spring (34) is connected with the top of second Hollow Cylindrical Shaft (18); And the upper end of second spring (34) is positioned at the below of second circular shaft shape supporting frame (95) lower surface, and second spring (34) is to the line of action of making a concerted effort of the active force of piston (48) and the dead in line of second Hollow Cylindrical Shaft (18).
7. rotate and axle streaming current variant damper according to claim 1,2,3 or 4 described magnetic force; It is characterized in that: in this magnetic force rotation and axle streaming current variant damper, also comprise second spring (34) and first spring (27); Obtaining magnetic force rotates and an another kind of style of streaming current variant damper; Wherein: the lower end of second spring (34) is connected with piston (48) upper surface; The upper end of second spring (34) is connected with the top of second Hollow Cylindrical Shaft (18), and the upper end of second spring (34) is positioned at the below of second circular shaft shape supporting frame (95) lower surface; The upper end of first spring (27) is connected with the lower surface of piston (48), and the lower end of first spring (27) is connected with second Hollow Cylindrical Shaft (18), and first spring (27) is positioned at the top of the upper surface of first dividing plate (8); This second spring (34) is to the line of action of making a concerted effort of the active force of piston (48) and the dead in line of second Hollow Cylindrical Shaft (18); First spring (27) is to the line of action of making a concerted effort of the active force of piston (48) and the dead in line of second Hollow Cylindrical Shaft (18).
8. magnetic force according to claim 5 rotates and axle streaming current variant damper; It is characterized in that: in this magnetic force rotation and axle streaming current variant damper, also comprise the 3rd spring (37), obtain magnetic force and rotate and an another kind of style of streaming current variant damper; The upper end of the 3rd spring (37) is connected the upper end and has on the lower end surface of upper end disc flange (47) of cylinder (35) of disc flange, and the lower end of the 3rd spring (37) is connected on the upper surface of first disk (1).
9. magnetic force according to claim 6 rotates and axle streaming current variant damper; It is characterized in that: in this magnetic force rotation and axle streaming current variant damper, also comprise the 3rd spring (37), obtain magnetic force and rotate and an another kind of style of streaming current variant damper; The upper end of the 3rd spring (37) is connected the upper end and has on the lower end surface of upper end disc flange (47) of cylinder (35) of disc flange, and the lower end of the 3rd spring (37) is connected on the upper surface of first disk (1).
10. magnetic force according to claim 7 rotates and axle streaming current variant damper; It is characterized in that: in this magnetic force rotation and axle streaming current variant damper, also comprise the 3rd spring (37), obtain magnetic force and rotate and an another kind of style of streaming current variant damper; The upper end of the 3rd spring (37) is connected the upper end and has on the lower end surface of upper end disc flange (47) of cylinder (35) of disc flange, and the lower end of the 3rd spring (37) is connected on the upper surface of first disk (1).
CN2012200557257U 2012-02-20 2012-02-20 Magnetic rotation and shaft driving electro-rheological fluid damper Withdrawn - After Issue CN202484184U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2012200557257U CN202484184U (en) 2012-02-20 2012-02-20 Magnetic rotation and shaft driving electro-rheological fluid damper

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Application Number Priority Date Filing Date Title
CN2012200557257U CN202484184U (en) 2012-02-20 2012-02-20 Magnetic rotation and shaft driving electro-rheological fluid damper

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102562926A (en) * 2012-02-20 2012-07-11 东南大学 Electrorheological fluid damper with magnetic rotation and axial movement
CN105546023A (en) * 2016-02-25 2016-05-04 西安电子科技大学 Novel combined shock absorber based on magnetorheological damper
WO2021093221A1 (en) * 2019-11-15 2021-05-20 北京控制工程研究所 Ultrasonic motor-based regulated magnetorheological vibration isolator

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102562926A (en) * 2012-02-20 2012-07-11 东南大学 Electrorheological fluid damper with magnetic rotation and axial movement
CN105546023A (en) * 2016-02-25 2016-05-04 西安电子科技大学 Novel combined shock absorber based on magnetorheological damper
WO2021093221A1 (en) * 2019-11-15 2021-05-20 北京控制工程研究所 Ultrasonic motor-based regulated magnetorheological vibration isolator
US12110946B2 (en) 2019-11-15 2024-10-08 Beijing Institute Of Control Engineering Ultrasonic motor-based regulated magnetorheological vibration isolator

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