CN111677799A - Three-degree-of-freedom electromagnetic vibration isolator based on horizontal pre-pressing spring - Google Patents

Abstract

Three degree of freedom electromagnetism isolator based on horizontal pre-compaction spring belongs to accurate vibration isolation technical field, and the pre-compaction spring that four levels were placed is arranged along circumference array, the inner with the outer end respectively with load connecting piece, fixed frame fixed connection, the magnetic spring by last fixed magnet, middle moving magnet and down fixed magnet along Z axle uniform gap arrange constitute, go up fixed magnet and down fixed magnet respectively with fixed frame, bottom plate fixed connection, middle moving magnet passes through moving magnet connecting piece fixed connection with load connecting piece. The invention has simple and flexible structure design and high utilization rate of magnetic materials, and realizes the low-frequency/ultralow-frequency vibration isolation effect of three degrees of freedom of precision instruments and equipment.

Description

Three-degree-of-freedom electromagnetic vibration isolator based on horizontal pre-pressing spring

Technical Field

The invention belongs to the technical field of precise vibration isolation, and particularly relates to a three-degree-of-freedom electromagnetic vibration isolator based on a horizontal pre-pressing spring.

Background

In the processes of installation, adjustment, test and experiment of precision instruments and equipment, low-frequency micro-amplitude vibration interference in the environment becomes one of the key problems influencing the research effect, and the equipping of a low-frequency vibration isolator for the precision instruments and equipment gradually becomes a main technical means for inhibiting the environmental micro-vibration in the field of precision engineering. The low-frequency vibration isolator mainly adopts a mode of connecting positive and negative rigidity structures in parallel or in series to realize the low-frequency vibration isolation effect, the single-degree-of-freedom and six-degree-of-freedom electromagnetic vibration isolators are researched more at present, and the three-degree-of-freedom electromagnetic vibration isolators are researched less.

Patent No. cn201310187711.x discloses a three-degree-of-freedom ultra-low frequency vibration absorber. In the vertical direction, the technical scheme realizes a low-frequency vibration isolation effect by connecting a magnetic positive stiffness structure and a magnetic negative stiffness structure in parallel, wherein the magnetic positive stiffness structure and the magnetic negative stiffness structure are respectively realized by the action of repulsion between homopolar magnets and the action of attraction between heteropolar magnets; in the horizontal direction, a leaf spring is used as a positive stiffness element and is connected with a horizontal magnetic negative stiffness structure in parallel to achieve a low-frequency vibration isolation effect, and the horizontal magnetic negative stiffness characteristic is generated by a vertical magnetic positive stiffness spring. The technical scheme is characterized in that: the vertical magnetic negative stiffness structure only utilizes the negative stiffness characteristic generated by the attractive force between the magnets in the Z direction, the utilization rate of magnetic materials is low, a motion guide mechanism is needed to realize the constraint of the vertical magnetic negative stiffness structure along the X, Y direction, and the vertical magnetic negative stiffness structure is complex in structure, large in size and high in manufacturing cost.

The patent number CN201811427114.9 discloses a multidimensional magnetic negative stiffness mechanism and a multidimensional magnetic negative stiffness vibration damping system formed by the same, wherein the multidimensional vibration damping system is formed by connecting a positive stiffness mechanism and a multidimensional negative stiffness mechanism in parallel. The positive stiffness mechanism is a traditional elastic element and is used for connecting the damped body and the mounting base and providing support and basic damping functions in the X direction, the Y direction and the Z direction; the multi-dimensional negative stiffness mechanism is formed by connecting a one-dimensional negative stiffness magnetic group and a two-dimensional negative stiffness magnetic group which are formed by homopolar magnets in series. The technical scheme is characterized in that: the one-dimensional negative stiffness magnetic group generates negative stiffness characteristic in the Z direction by utilizing the repulsive force between the magnets, the motion of the one-dimensional negative stiffness magnetic group along the X, Y direction is limited by motion guide mechanisms such as a linear guide rail, and the like, so that the magnetic material has low utilization rate, complex structure, large volume and high manufacturing cost.

In conclusion, through the structural and principle innovation of the electromagnetic device, the three-degree-of-freedom electromagnetic vibration isolator with high magnetic material utilization rate and without the motion guide mechanism has great significance for reducing low-frequency micro-amplitude vibration interference in the environment, ensuring the optimal working environment of the precision instrument and equipment and further improving the precision of the precision instrument and equipment.

Disclosure of Invention

The invention provides a three-degree-of-freedom electromagnetic vibration isolator based on horizontal prepressing springs, aiming at the problems that the utilization rate of magnetic materials of the existing three-degree-of-freedom electromagnetic vibration isolator is low and a motion guide mechanism is needed to realize the rigidity characteristic in a specific direction; the magnetization direction of this outer magnetic spring is various, and structural design flexibility is high.

The technical solution of the invention is as follows:

a three-degree-of-freedom electromagnetic vibration isolator based on a horizontally pre-pressed spring comprises a connecting structure, a fixing structure and a spring structure, wherein the connecting structure, the fixing structure and the spring structure are integrally formed into axial symmetry; the fixing structure comprises a fixed spring seat, an adjustable spring seat, a nut, a fixed frame and a bottom plate, and the bottom of the fixed frame is fixedly connected with the bottom plate; the adjustable spring seats are provided with external threads, the spring structure comprises a magnetic spring and four horizontally arranged pre-pressing springs, the ratio of the pre-compression amount of the pre-pressing springs to the original length is less than 0.75, the four pre-pressing springs are arranged along the circumference in an array mode, the inner ends of the four pre-pressing springs are fixedly connected with the side wall of the load connecting piece through the four fixed spring seats, and the outer ends of the four pre-pressing springs are fixedly connected with the side wall of the fixed frame through the four adjustable; the magnetic spring is positioned right below the load connecting piece and is formed by arranging an upper fixed magnet, a middle movable magnet and a lower fixed magnet with holes in the center at equal intervals along a Z axis, the upper fixed magnet, the middle movable magnet and the lower fixed magnet are magnetized along the Z axis, the magnetization direction of the upper fixed magnet is the same as that of the lower fixed magnet and is opposite to that of the middle movable magnet, the upper fixed magnet is fixedly connected with the fixed frame, the lower fixed magnet is fixedly connected with the bottom plate, the bottom of the movable magnet connecting piece is fixedly installed in a hole in the center of the middle movable magnet in an axis coinciding mode, and the top end of the movable magnet connecting piece penetrates through the hole in the center of the upper fixed magnet and is fixedly installed at the bottom of the load connecting.

Preferably, the upper fixed magnet, the middle movable magnet and the lower fixed magnet are in the shape of a cube or a cylinder.

Preferably, the pre-pressing spring is an air spring, a rubber spring, a spiral spring or a magnetic spring.

Preferably, the upper fixed magnet, the middle moving magnet and the lower fixed magnet are permanent magnets or electromagnets.

The technical innovation and the good effect of the invention are as follows:

according to the technical scheme, the magnetic spring is connected with four horizontal pre-pressing springs which are uniformly distributed along the circumference in parallel, so that three-degree-of-freedom electromagnetic vibration isolation is realized, and meanwhile, the utilization rate of high-magnetic materials and the structural design without a guide mechanism are realized. The positive stiffness characteristic generated by the magnetic spring in the Z direction, the negative stiffness characteristic generated in the X, Y direction and the negative stiffness characteristic generated by the four horizontal pre-pressing springs uniformly distributed along the circumference in the Z direction are utilized, the positive stiffness characteristic generated in the X, Y direction is connected in parallel to realize the low-frequency vibration isolation effect of three degrees of freedom, and the stiffness characteristics of the magnetic spring and the horizontal pre-pressing springs in three degrees of freedom are utilized, so that the utilization rate of magnetic materials is obviously improved; in the actual use process, the motion guide mechanism is not needed to restrict the motion of the magnetic spring, and the structural design of the non-guide mechanism reduces the complexity and the manufacturing cost of the vibration isolation device. This is the innovation of the present invention from the prior art.

Drawings

FIG. 1 is a three-dimensional model of a three-degree-of-freedom electromagnetic vibration isolator based on a horizontal pre-pressing spring;

FIG. 2 is a schematic three-dimensional cross-sectional view of the three-degree-of-freedom electromagnetic vibration isolator based on the horizontal pre-pressing spring;

FIG. 3 is a top view of FIG. 1;

FIG. 4 is a cross-sectional view of FIG. 3A-A;

FIG. 5 is a schematic diagram of four horizontally disposed compression springs in a balanced position;

FIG. 6 is a schematic view of four horizontally disposed compression springs with vibration isolation in the X direction;

FIG. 7 is a schematic view of the vibration isolation of four horizontally disposed compression springs in the Y direction;

fig. 8 is a schematic view of vibration isolation of four horizontally disposed compression springs in the Z direction.

Description of part numbers in the figures: the magnetic spring type magnetic suspension device comprises a magnetic spring 1, an upper fixed magnet 1a, a lower fixed magnet 1b, a middle movable magnet 1c, a movable magnet connecting piece 2, a fixed spring seat 3, a pre-pressing spring 4, an adjustable spring seat 5, a load connecting piece 6, a nut 7, a fixed frame 8 and a bottom plate 9.

Detailed Description

A three-degree-of-freedom electromagnetic vibration isolator based on a horizontally pre-pressed spring comprises a connecting structure, a fixing structure and a spring structure, wherein the connecting structure is axially symmetrical and comprises a moving magnet connecting piece 2 and a load connecting piece 6, and the top end of the load connecting piece 6 is fixedly connected with a vibration isolation load; the fixing structure comprises a fixed spring seat 3, an adjustable spring seat 5, a nut 7, a fixed frame 8 and a bottom plate 9, wherein the bottom of the fixed frame 8 is fixedly connected with the bottom plate 9; the adjustable spring seats 5 are provided with external threads, the spring structure comprises a magnetic spring 1 and four horizontally-arranged pre-pressing springs 4, the ratio of the pre-compression amount of the pre-pressing springs 4 to the original length is less than 0.75, the four pre-pressing springs 4 are arranged in a circumferential array mode, the inner ends of the four pre-pressing springs are fixedly connected with the side wall of the load connecting piece 6 through the four fixed spring seats 3, and the outer ends of the four pre-pressing springs are fixedly connected with the side wall of the fixed frame 8 through the four adjustable spring seats 5; the magnetic spring 1 is positioned right below the load connecting piece 6 and is formed by arranging an upper fixed magnet 1a, a middle movable magnet 1c and a lower fixed magnet 1b with holes in the center at equal intervals along a Z axis, the upper fixed magnet 1a, the middle movable magnet 1c and the lower fixed magnet 1b are magnetized along the Z axis, the magnetization direction of the upper fixed magnet 1a is the same as that of the lower fixed magnet 1b and is opposite to that of the middle movable magnet 1c, the upper fixed magnet 1a is fixedly connected with the fixed frame 8, the lower fixed magnet 1b is fixedly connected with the bottom plate 9, the bottom of the movable magnet connecting piece 2 is fixedly installed in a hole in the center of the middle movable magnet 1c in an axis coinciding mode, and the top end of the movable magnet connecting piece penetrates through the hole in the center of the upper fixed magnet 1a and is fixedly installed at the bottom of the load connecting.

In a specific embodiment, the upper fixed magnet 1a, the middle moving magnet 1c, and the lower fixed magnet 1b are in the shape of a cube or a cylinder.

As a specific embodiment, the pre-pressing spring 4 is an air spring, a rubber spring, a coil spring or a magnetic spring.

In a specific embodiment, the upper fixed magnet 1a, the middle moving magnet 1c, and the lower fixed magnet 1b are permanent magnets or electromagnets.

An embodiment of the present invention is given below with reference to fig. 1 to 4.

Fig. 1 to 3 are a three-dimensional model, a three-dimensional cross-sectional schematic view and a top view of the three-dimensional degree-of-freedom electromagnetic vibration isolator based on the horizontal pre-pressing spring, respectively. The front section of the fixed frame 8 is H-shaped, the section of the fixed frame is square, the three-degree-of-freedom electromagnetic vibration isolator is divided into an upper layer and a lower layer, a round hole is formed between the upper layer and the lower layer, and the three-degree-of-freedom electromagnetic vibration isolator is made of aluminum alloy. The horizontal pre-pressing spring 4 is a cylindrical linear spiral spring with the rigidity of k₁The original length is L, the precompression amount is delta L, and delta L is less than 0.75L, the inner ends of four precompression springs 4 evenly arranged along the circumference are fixedly connected with the side wall of a load connecting piece 6 through four fixed spring seats 3, the outer ends of the precompression springs are fixedly connected with the side wall of a fixed frame 8 through four adjustable spring seats 5 and nuts 7, and the external threads arranged on the adjustable spring seats 5 are matched with the nuts 7 to adjust the precompression amount of the horizontal precompression springs 4 so as to change the rigidity value of the three-degree-of-freedom vibration isolator. The magnetic spring 1 is positioned at the lower layer of the fixed frame 8 and is composed of an upper fixed magnet 1a, a middle movable magnet 1c and a lower fixed magnet 1b which are arranged at equal intervals along the Z axis, the upper fixed magnet 1a, the middle movable magnet 1c and the lower fixed magnet 1b are cylindrical permanent magnets with round holes arranged at the centers, the permanent magnet is N44H brand neodymium iron boron, the residual magnetic induction Br is 1.34T, and the relative magnetic conductivity mu is_r1.03. The diameters of central openings of the upper fixed magnet 1a and the lower fixed magnet 1b are far larger than the diameter of the movable magnet connecting piece 2, and the diameter of the central opening of the middle movable magnet 1c is equal to the diameter of the movable magnet connecting piece 2. The upper fixed magnet 1a and the lower fixed magnet 1b are respectively fixedly connected with the top end of the lower layer structure of the fixed frame 8 and the upper surface of the bottom plate 9, the bottom of the movable magnet connecting piece 2 is fixedly arranged in a circular hole at the center of the middle movable magnet 1c in a mode of coinciding axes, and the top end of the movable magnet connecting piece penetrates through the circular holes on the upper fixed magnet 1a and the fixed frame 8 and is the same as the circular hole on the bottom plate 9The shaft is fixedly mounted in a circular hole in the bottom of the load connection member 6.

The upper fixed magnet 1a and the lower fixed magnet 1b are magnetized in the negative direction of the Z axis, and the middle moving magnet 1c is magnetized in the positive direction of the Z axis, as shown by the arrow direction in fig. 4. The repulsive force of the upper fixed magnet 1a and the lower fixed magnet 1b acts to make the middle moving magnet 1c in a stable equilibrium state in the Z direction, exhibiting a positive stiffness characteristic, and in an unstable equilibrium state in the X, Y direction, exhibiting a negative stiffness characteristic. The moving magnet connecting piece 2 and the load connecting piece 6 connect the magnetic spring 1 and four pre-pressing springs 4 which are uniformly distributed along the circumference in parallel, namely in the direction of X, Y, the positive stiffness generated by the horizontal pre-pressing spring 4 is connected with the negative stiffness generated by the magnetic spring 1 in parallel; in the Z direction, the negative stiffness generated by the horizontal pre-pressing spring 4 is connected with the positive stiffness generated by the magnetic spring 1 in parallel; the three-degree-of-freedom low-frequency vibration isolation effect is achieved by optimizing the structural parameters of the pre-pressing spring 4 and the magnetic spring 1.

Fig. 5 is a schematic diagram of four horizontally disposed compression springs in a balanced position. The four horizontal pre-pressing springs 4 are uniformly arranged on the same horizontal plane along the circumference, and the restoring force borne by the load connecting piece 6 is 0 due to the structural symmetry. Fig. 6 to 8 are schematic diagrams of the vibration isolation of the four horizontally disposed compression springs 4 in the X direction, the Y direction, and the Z direction, respectively. Under the external vibration interference effect, when the vibration isolation load drives four horizontally placed pre-pressed springs 4 to move through the load connecting piece 6, the restoring force and the rigidity received by the load connecting piece 6 can be obtained through calculation:

calculated from equation (2): when Δ L is 0.75L, the four horizontal preload springs 4 uniformly arranged along the circumference exhibit zero stiffness characteristics in the X and Y directions, when Δ L is less than 0.75L, the four horizontal preload springs 4 uniformly distributed along the circumference exhibit positive stiffness characteristics in the X, Y direction, and when Δ L is greater than 0.75L, the four horizontal preload springs 4 uniformly arranged along the circumference exhibit negative stiffness characteristics in the X, Y direction. In the present embodiment, four horizontal preload springs 4 are used to produce a positive stiffness characteristic in the direction X, Y.

Claims (4)

1. A three-degree-of-freedom electromagnetic vibration isolator based on a horizontally pre-pressed spring comprises a connecting structure, a fixing structure and a spring structure, wherein the connecting structure, the fixing structure and the spring structure are integrally formed into axial symmetry, the connecting structure comprises a moving magnet connecting piece (2) and a load connecting piece (6), and the top end of the load connecting piece (6) is fixedly connected with a vibration isolation load; the fixing structure comprises a fixed spring seat (3), an adjustable spring seat (5), a nut (7), a fixing frame (8) and a bottom plate (9), wherein the bottom of the fixing frame (8) is fixedly connected with the bottom plate (9); the method is characterized in that: the adjustable spring seat (5) is provided with external threads, the spring structure comprises a magnetic spring (1) and four horizontally-arranged pre-pressing springs (4), the ratio of the pre-compression amount of the pre-pressing springs (4) to the original length is less than 0.75, the four pre-pressing springs (4) are arranged in a circumferential array mode, the inner ends of the four pre-pressing springs are fixedly connected with the side wall of the load connecting piece (6) through four fixed spring seats (3), and the outer ends of the four pre-pressing springs are fixedly connected with the side wall of the fixed frame (8) through four adjustable spring seats (5) and nuts (7; the magnetic spring (1) is positioned right below the load connecting piece (6) and is formed by arranging an upper fixed magnet (1a), a middle movable magnet (1c) and a lower fixed magnet (1b) with holes at equal intervals along the Z axis, the upper fixed magnet (1a), the middle movable magnet (1c) and the lower fixed magnet (1b) are magnetized along the Z axis, and the magnetization direction of the upper fixed magnet (1a) is the same as the magnetization direction of the lower fixed magnet (1b), opposite to the magnetization direction of the middle moving magnet (1c), the upper fixed magnet (1a) is fixedly connected with the fixed frame (8), the lower fixed magnet (1b) is fixedly connected with the bottom plate (9), the bottom of the moving magnet connecting piece (2) is fixedly arranged in a hole at the center of the middle moving magnet (1c) in an axis superposition mode, the top end of the upper fixed magnet (1a) passes through a hole at the center of the upper fixed magnet (1a) and is fixedly arranged at the bottom of the load connecting piece (6).

2. The three-degree-of-freedom electromagnetic vibration isolator based on the horizontal pre-pressing spring as claimed in claim 1, is characterized in that: the upper fixed magnet (1a), the middle movable magnet (1c) and the lower fixed magnet (1b) are cubic or cylindrical.

3. The three-degree-of-freedom electromagnetic vibration isolator based on the horizontal pre-pressing spring as claimed in claim 1, is characterized in that: the pre-pressing spring (4) is an air spring, a rubber spring, a spiral spring or a magnetic spring.

4. The three-degree-of-freedom electromagnetic vibration isolator based on the horizontal pre-pressing spring as claimed in claims 1 and 2 is characterized in that: the upper fixed magnet (1a), the middle movable magnet (1c) and the lower fixed magnet (1b) are permanent magnets or electromagnets.

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