阅读说明：本技术 一种基于电磁悬浮滑梭的节点网压的浮置板轨道隔振系统 (Node network pressure floating plate track vibration isolation system based on electromagnetic suspension shuttle ) 是由 王涛 于 2019-09-19 设计创作，主要内容包括：本发明公开了一种基于电磁悬浮滑梭的节点网压的浮置板轨道隔振系统,其结构包括：单片机电板、轨道短柱块、电网平衡磁盘、电缆线、轨道横板、卡销凹槽、橡胶底座,本发明实现了运用轨道短柱块与电网平衡磁盘相配合,形成一个升降调节电势差和电位高低平衡的效果,使电磁悬浮过程中,消耗的线圈值可以通过升降柱槽升降配合节点放射器展开内射牵拉电网得到调节,形成一个加固内电磁场的电磁感线形变抗压平衡效果,保障轨道隔振的平衡压力,避免单侧受力损耗,使贴附浮置板形成一个托台电流,使浮置板在轨道式悬浮滑行时更加稳妥的承重且均匀受力,保障了节点网压使微量变化电力得到控制,让压电材料浮置板得到平衡防护效果。(The invention discloses a node net pressure floating plate track vibration isolation system based on an electromagnetic suspension shuttle, which structurally comprises: the invention discloses a single-chip microcomputer electric plate, a rail short column block, a power grid balance magnetic disc, a cable, a rail transverse plate, a clamping pin groove and a rubber base.)

1. A node net pressure floating plate track vibration isolation system based on an electromagnetic suspension shuttle structurally comprises: singlechip electroplax (1), track stub piece (2), electric wire netting balance disk (3), cable conductor (4), track diaphragm (5), bayonet lock recess (6), rubber base (7), its characterized in that:

the power grid balancing magnetic disc (3) is nested on the top of the rail short column block (2), the single-chip microcomputer electric plate (1) is electrically connected with the power grid balancing magnetic disc (3), the rail short column block (2) and the bayonet groove (6) are of an integral structure, the power grid balancing magnetic disc (3) is electrically connected with the cable (4), the rail transverse plate (5) is buckled with the rail short column block (2), and the rubber base (7) is nested below the bottom of the rail short column block (2);

the power grid balance disk (3) is provided with a pin adapter (3A), a disk shell cover (3B), a mirror ball arc belt (3C), a side open slot (3D), a light-gathering film body (3E), a node emitter (3F), a lifting column slot (3G) and a spring tube (3H);

the lens is characterized in that the pin adapter (3A) is inserted and embedded under the bottoms of the disk shell cover (3B) and the light-gathering film body (3E), the mirror spherical arc belt (3C) is provided with two and is respectively inserted and embedded on the left side and the right side inside the disk shell cover (3B), the side open slots (3D) are buckled with the node radiators (3F), the side open slots (3D) are embedded on the tops of the pin adapter (3A), the lifting column slots (3G) are inserted and embedded under the bottoms of the disk shell cover (3B), the lifting column slots (3G) are mechanically connected with the pin adapter (3A) through spring tubes (3H), the node radiators (3F) are electrically connected with the pin adapter (3A), and the disk shell cover (3B) is embedded on the tops of the track short column blocks (2).

2. The system of claim 1, wherein the system comprises: pin adapter (3A) comprises integrated electroplax (3A1), pin tube (3A2), plug-in section of thick bamboo (3A3), bearing frame (3A4), integrated electroplax (3A1) and pin tube (3A2) electricity are connected, pin tube (3A2) and plug-in section of thick bamboo (3A3) lock together, plug-in section of thick bamboo (3A3) and bearing frame (3A4) mechanical connection.

3. The system of claim 1, wherein the system comprises: mirror ball arc area (3C) comprises three convex mirror ball seats (3C1), transparent arc area (3C2), three convex mirror ball seats (3C1) are equipped with threely and all establish the left side at transparent arc area (3C2), three convex mirror ball seats (3C1) are hugged closely together with transparent arc area (3C 2).

4. The system of claim 3, wherein the system comprises: the three convex lens ball seats (3C1) are composed of an elliptical convex lens block (3C11), a triangular prism plate seat (3C12), a three-way pipe barrel groove (3C13) and a spherical cover seat (3C14), the elliptical convex lens block (3C11) is three and is respectively nested on the left side of the three-way pipe barrel groove (3C13), the triangular prism plate seat (3C12) is arranged in the three-way pipe barrel groove (3C13), and the three-way pipe barrel groove (3C13) is matched with the spherical cover seat (3C14) through the elliptical convex lens block (3C 11).

5. The system of claim 1, wherein the system comprises: spotlight film body (3E) comprises film area (3E1), trapezoidal pedestal (3E2), narrow light mirror groove (3E3), bleeder vent (3E4) of falling, fall narrow light mirror groove (3E3) and nest on the top of trapezoidal pedestal (3E2), bleeder vent (3E4) and film area (3E1) structure as an organic whole, film area (3E1) cooperate with narrow light mirror groove (3E3) of falling.

6. The system of claim 5, wherein the system comprises: the node radiator (3F) is composed of a gourd top groove seat (3F1), a vertical optical fiber tube (3F2), a top discharge tube (3F3) and a node spotlight tube (3F4), the vertical optical fiber tube (3F2) is nested on the right sides of the top discharge tube (3F3) and the node spotlight tube (3F4), and the vertical optical fiber tube (3F2) is inserted and embedded in the gourd top groove seat (3F 1).

7. The system of claim 6, wherein the system comprises: the calabash top groove seat (3F1) comprises top bulb utricule (3F11), flat dish pad (3F12), oblique burr barrel (3F13), round platform groove seat (3F14), flat dish pad (3F12) nestification is on the top of oblique burr barrel (3F13), top bulb utricule (3F11) welding is on the top surface of round platform groove seat (3F14), the inside at round platform groove seat (3F14) is inserted and inlays to oblique burr barrel (3F 13).

8. The system of claim 6, wherein the system comprises: the node spotlight pipe (3F4) is composed of an angle clamping cap pipe body (3F41), a trapezoidal prism sheet (3F42), a contact three-section frame (3F43) and a radiation electric tube (3F44), the trapezoidal prism sheet (3F42) is tightly attached to the angle clamping cap pipe body (3F41), the contact three-section frame (3F43) is nested on the left side of the radiation electric tube (3F44), and the trapezoidal prism sheet (3F42) is electrically connected with the contact three-section frame (3F 43).

Technical Field

The invention discloses a node network pressure floating plate track vibration isolation system based on an electromagnetic suspension shuttle, and belongs to the field of piezoelectric materials.

Background

The maglev train is the vehicle that generally utilizes electricity structure to realize building, and because the current velocity of flow is high, and the sliding pressure of cooperation coil resistance is huge, makes the train travel speed fly fast, has ensured among the electromagnetic field power that the stationarity and the vibration isolation effect of floating slab on the magnetic levitation track are splendid, and the public shortcoming of treating the optimization of prior art has:

the balance force of magnetic suspension is very important, the floating plate on the balance track is balanced under the condition of poor coil potential difference and abrasion ring number, the micro-tilt phenomenon can be caused, thereby leading to the slide pressure of the whole upper carrier to be heavier, leading to the poor vibration isolation balance effect of the floating plate, leading to uneven stress of nodes, influencing the shear force effect of the whole plate surface, leading to the floating plate to be easily broken because the load of a single side exceeds the rated bearing capacity in the process of track suspension sliding, and an electromagnetic force line field can be subjected to abnormal torsional pressure, leading to the accumulation of free electrons on the single side to generate the phenomenon of electric spark friction easily, and leading to the insufficient protection and adjustment of the potential safety hazard of the track.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a floating plate track vibration isolation system based on node net pressure of an electromagnetic suspension shuttle, which is used for solving the problems that the balance force of magnetic suspension is very important, and the floating plate on a track is balanced under the condition of poor coil potential difference and abrasion ring number, so that the micro-tilting phenomenon can be caused, the sliding pressure of the whole upper carrier is heavy, the vibration isolation balance effect of the floating plate is poor, the node stress is uneven, the shearing force effect of the whole plate surface is influenced, the plate block is easily broken due to the fact that the load of a single side exceeds the rated bearing force in the track suspension sliding process of the floating plate, and an electromagnetic force line field can be deformed and twisted, so that the phenomenon of electric spark friction is easily generated due to the accumulation of the free electrons on the single side, and the protection and adjustment on the potential safety hazard of the track are.

In order to achieve the purpose, the invention is realized by the following technical scheme: a node net pressure floating plate track vibration isolation system based on an electromagnetic suspension shuttle structurally comprises: the single-chip microcomputer electric plate, the track short column block, the power grid balance magnetic disc, the cable conductor, the track transverse plate, the bayonet lock groove and the rubber base, wherein the power grid balance magnetic disc is nested on the top of the track short column block and is positioned on the same vertical line, the single-chip microcomputer electric plate is electrically connected with the power grid balance magnetic disc, the track short column block and the bayonet lock groove are of an integral structure, the power grid balance magnetic disc is electrically connected with the cable conductor, the track transverse plate and the track short column block are buckled together and are mutually vertical, the rubber base is nested under the bottom of the track short column block, the power grid balance magnetic disc is provided with a pin adapter, a magnetic disc shell, a mirror ball arc belt, a side open slot, a light-gathering film body, a node radiator, a lifting column groove and a spring tube, the pin adapter is inserted and embedded under the bottoms of the magnetic disc shell and the light-gathering film body, the mirror ball arc, the lifting column groove is inserted and embedded under the bottom of the disk shell and is positioned on the same vertical surface, the lifting column groove is mechanically connected with the pin adapter through a spring tube, the node radiator is electrically connected with the pin adapter, and the disk shell is embedded and embedded on the top of the track short column block.

In order to optimize the technical scheme, the method further comprises the following steps:

as a further improvement of the present invention, the pin adapter is composed of an integrated electric board, pin tubes, an insertion tube, and a bearing seat, wherein the integrated electric board is electrically connected with the pin tubes and is perpendicular to each other, the pin tubes and the insertion tube are buckled together and are located on the same vertical plane, and the insertion tube is mechanically connected with the bearing seat and has a collinear axis.

As a further improvement of the invention, the mirror ball arc belt consists of three convex mirror ball seats and a transparent arc belt, wherein the three convex mirror ball seats are three and are all arranged at the left side of the transparent arc belt, and the three convex mirror ball seats are tightly attached to the transparent arc belt and are positioned on the same arc surface.

As a further improvement of the invention, the three-convex-mirror ball seat consists of three elliptical convex-mirror blocks, three prism plate seats, three Y-shaped pipe barrel grooves and a ball cover seat, the three elliptical convex-mirror blocks are respectively nested on the left side of the three Y-shaped pipe barrel grooves, the three prism plate seats are arranged inside the three Y-shaped pipe barrel grooves, and the three Y-shaped pipe barrel grooves are in clearance fit with the ball cover seat through the elliptical convex-mirror blocks.

As a further improvement of the invention, the light-gathering film body consists of a film belt, a trapezoidal pedestal, a reversed narrow light mirror groove and a vent hole, wherein the reversed narrow light mirror groove is nested on the top of the trapezoidal pedestal, the vent hole and the film belt are in an integral structure, and the film belt and the reversed narrow light mirror groove are in interference fit.

As a further improvement of the invention, the node radiator comprises a gourd top groove seat, a vertical optical fiber tube, a top discharge tube and a node spotlight tube, wherein the vertical optical fiber tube is nested on the right sides of the top discharge tube and the node spotlight tube and is vertical to each other, the vertical optical fiber tube is nested inside the gourd top groove seat, and the axes of the vertical optical fiber tube are collinear.

As a further improvement of the invention, the gourd top groove seat consists of a top ball bag body, a flat disc pad, an oblique convex line barrel body and a circular table groove seat, wherein the flat disc pad is nested on the top of the oblique convex line barrel body, the axes of the flat disc pad and the oblique convex line barrel body are collinear, the top ball bag body is welded on the top surface of the circular table groove seat and communicated with each other, and the oblique convex line barrel body is nested in the circular table groove seat.

As a further improvement of the invention, the nodal point spotlight tube consists of an included angle cap tube body, two trapezoidal prism sheets, a contact three-section frame and a radiation tube, wherein the trapezoidal prism sheets are tightly attached to the left end inside the included angle cap tube body, the contact three-section frame is nested on the left side of the radiation tube and is positioned on the same vertical plane, and the trapezoidal prism sheets are electrically connected with the contact three-section frame.

As a further improvement of the invention, the Y-shaped tube groove is a composite Y-shaped tube structure with branch tube grooves with inclined included angles of forty-five degrees at the upper part and the lower part of a transverse tube body, so that lens radiation current direct connection effect is conveniently formed by three nodes at the side, and the end angle wrapping effect during the tie forming of a power grid is guaranteed.

As a further improvement of the invention, the inverted narrow light mirror groove is of a composite trapezoid groove structure with wide top and narrow bottom, and narrow top and narrow bottom is arranged in the mirror groove, so that the film surface can be conveniently expanded and contracted, and radiated power can form a through direct current effect when the glass surface is not conductive through the mirror groove, so that the cambered mirror groove has an outward star-ray emission effect.

As a further improvement of the invention, the oblique-ridge cylinder body is of a groove cylinder structure with a sealing cover at the top and a square convex block clamped at the side, and the lifting and pushing effect of the whole capsule shell can be formed through the twisting of the convex block.

As a further improvement of the invention, the contact three-section frame is a current frame structure with the left upper end and the lower end and the middle section provided with three ball line tubes for insertion, so that the open positions of the three contacts can conveniently form a concentration effect at the round end when the three contacts are simultaneously discharged.

Advantageous effects

The invention relates to a floating plate track vibration isolation system based on node net pressure of an electromagnetic suspension shuttle, which is characterized in that after a worker powers on a singlechip electric plate to stably erect a clamping pin groove and a rubber base in a track short column block to form a plug-in base, the bottom of a track transverse plate supports a floating plate, then the side of a cable is conducted to a pin adapter in a balanced magnetic disk one by one through a power grid, so that a bearing block drives a plug-in cylinder to link an integrated electric plate and a pin tube to rotate and push up current and is led into a node radiator in a magnetic disk shell, a three-convex-lens ball seat of a mirror spherical arc belt is attached to the side of a transparent arc belt to form a light interweaving effect of an elliptical convex-lens block and a three-fork-tube groove in a three-lens plate seat, light penetrates through a ball cover seat to be matched with a thin film belt of a light-condensation thin film body to form a light-transmitting pre-mapping effect, light transmittance is formed for forming, and the current of later, avoiding deviation operation, ensuring the stability of an electromagnetic field and the fine adjustment prefabrication space of potential difference, forming an up-and-down drawing effect through the side-opening groove clamping lifting column groove and the spring tube, and leading a section of potential difference which is excessively worn and lacked by the coil to be weak, the inclined convex-line cylinder and the circular truncated cone groove seat can be pressurized by a top ball bag body and a flat disc pad in the gourd top groove seat to form an electric tube bearing effect, then the high-level power grid is lifted through interweaving the vertical optical fiber tube and the top discharge tube to achieve the effect of adjusting balance, otherwise, when the low-level power grid is lifted, when the radiation tube enters the current generating process of the contact three-section frame through the included angle cap tube body of the node spotlight tube and the trapezoidal prism sheet, the effect of refraction adjustment on the current line pipe is achieved, the traction density of the power grid is reduced, the balance degree of the floating plate on the track is guaranteed, the node grid voltage of the electromagnetic suspension shuttle is improved, and the simple density independent fine adjustment operation of the floating plate track vibration isolation system is achieved.

The invention has the following advantages after operation:

the rail short column block is matched with a power grid balance magnetic disc, and a lifting column groove at the top of the rail short column block is used to form an effect of lifting and adjusting potential difference and potential height balance, so that in the electromagnetic suspension process, the consumed coil value can be adjusted by matching the lifting of the lifting column groove with the expansion of the node radiator to spread the internal-emission traction power grid, so that the multi-node magnetic disk shells can be oppositely interwoven to form an electromagnetic induction line deformation compression-resistant balance effect for reinforcing an internal electromagnetic field, the balance pressure of track vibration isolation is ensured, and the single-side stress loss is avoided, and the mirror ball arc belt prefabricated optical network diagram covers the power grid to form the track guidance of the radiation current, so that the attached floating plate forms a saddle current, the floating plate is more stably supported and uniformly stressed when in rail type suspension sliding, the node network voltage is ensured to control the micro-change power, and the piezoelectric material floating plate obtains a balance protection effect.

Drawings

Other features, objects, and advantages of the present invention will become more apparent from the following detailed description of the embodiments of the invention when taken in conjunction with the accompanying drawings, in which:

fig. 1 is a schematic structural diagram of a floating plate track vibration isolation system based on node net pressure of an electromagnetic suspension shuttle in the invention.

FIG. 2 is a schematic cross-sectional view of a power-grid balancing disk according to the present invention.

Fig. 3 is a schematic cross-sectional structural view of the working states of the pin adapter, the mirror ball arc belt and the node radiator according to the present invention.

FIG. 4 is a schematic cross-sectional view of the three-convex mirror ball seat of the present invention.

Fig. 5 is an enlarged structural diagram of the cross section of the light-gathering thin film body in the working state.

Fig. 6 is a schematic perspective structural view of the operating state of the gourd vertex slot base of the present invention.

FIG. 7 is an enlarged cross-sectional view of the nodal spotlight tube of the present invention in operation.

Description of reference numerals: a singlechip electric plate-1, a track short column block-2, a power grid balance disk-3, a cable-4, a track transverse plate-5, a bayonet groove-6, a rubber base-7, a pin adapter-3A, a disk shell-3B, a mirror spherical arc belt-3C, a side open slot-3D, a light-gathering film body-3E, a node radiator-3F, a lifting column groove-3G, a spring tube-3H, an integrated electric plate-3A 1, a pin tube-3A 2, a plug-in tube-3A 3, a bearing seat-3A 4, a three-convex mirror ball seat-3C 1, a transparent arc belt-3C 2, an elliptical convex mirror block-3C 11, a three-convex mirror plate seat-3C 12, a three-fork tube groove-3C 13, a ball cover seat-3C 14, a film belt-3E 1, a power grid balance disk-3, a cable-4, a track transverse, The device comprises a trapezoid pedestal-3E 2, an inverted narrow light mirror groove-3E 3, an air vent-3E 4, a gourd top groove seat-3F 1, a vertical optical fiber tube-3F 2, a top discharge tube-3F 3, a nodal spotlight tube-3F 4, a top balloon-3F 11, a flat disc pad-3F 12, an oblique ridge cylinder-3F 13, a circular truncated cone groove seat-3F 14, an included angle cap tube-3F 41, a trapezoid prism sheet-3F 42, a contact three-section frame-3F 43 and a radioactive electrode tube-3F 44.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1 to 7, the present invention provides a floating plate track vibration isolation system based on node net pressure of an electromagnetic levitation shuttle, which comprises: the single-chip microcomputer electric plate 1, the rail short column block 2, the power grid balance disk 3, the cable 4, the rail transverse plate 5, the bayonet socket groove 6 and the rubber base 7, wherein the power grid balance disk 3 is nested on the top of the rail short column block 2 and is positioned on the same vertical line, the single-chip microcomputer electric plate 1 is electrically connected with the power grid balance disk 3, the rail short column block 2 and the bayonet socket groove 6 are of an integral structure, the power grid balance disk 3 is electrically connected with the cable 4, the rail transverse plate 5 and the rail short column block 2 are buckled together and are mutually vertical, the rubber base 7 is nested under the bottom of the rail short column block 2, the power grid balance disk 3 is provided with a pin adapter 3A, a disk shell 3B, a mirror ball arc belt 3C, a side opening groove 3D, a light-gathering film body 3E, a node radiator 3F, a lifting column groove 3G and a spring tube 3H, the pin adapter 3A is inserted and nested under the bottoms of the disk shell 3B and the light-gathering film body, the mirror spherical arc belt 3C is provided with two mirror spherical arc belts and is respectively inserted and embedded in the left side and the right side of the inner part of the magnetic disc housing cover 3B, the side open slot 3D is buckled with the node radiator 3F together, the side open slot 3D is embedded and embedded on the top of the pin adapter 3A, the lifting column slot 3G is inserted and embedded under the bottom of the magnetic disc housing cover 3B and is positioned on the same vertical surface, the lifting column slot 3G is mechanically connected with the pin adapter 3A through the spring tube 3H, the node radiator 3F is electrically connected with the pin adapter 3A, and the magnetic disc housing cover 3B is embedded and embedded on the top of the track short column block 2.

Referring to fig. 3, the pin adapter 3A is composed of an integrator plate 3A1, a pin tube 3A2, a socket tube 3A3 and a bearing seat 3A4, the integrator plate 3A1 is electrically connected with the pin tube 3A2 and perpendicular to each other, the pin tube 3A2 is fastened with the socket tube 3A3 and is located on the same vertical plane, the socket tube 3A3 is mechanically connected with the bearing seat 3A4 and has a collinear axis, the mirror ball arc strip 3C is composed of a three-convex-mirror ball seat 3C1 and a transparent arc strip 3C2, the three-convex-mirror ball seat 3C1 is provided with three and is all provided on the left side of the transparent arc strip 3C2, the three-convex-mirror ball seat 3C1 is provided with the transparent arc strip 3C2 and is located on the same arc surface, the gourd node collector 3F is composed of a top groove seat 3F1, a vertical optical fiber tube 3F2, a top discharge tube 6863F 3, a radiation tube 593F is nested on the right side of the vertical optical fiber tube 593F 593, the vertical optical fiber tube 3F2 is inserted and embedded in the gourd top groove seat 3F1, the axes of the vertical optical fiber tube are collinear, the gourd top groove seat 3F1 is rotationally drawn through the bearing seat 3A4 to move to form a traction covering effect of power grid rotation interweaving, electrode rays can be mutually supported to form a power grid support cushion floating plate, and the stability of suspension balance force of a track is guaranteed.

Referring to fig. 4, the triangular prism ball holder 3C1 is composed of three elliptical prism blocks 3C11, triangular prism plate holders 3C12, triangular prism barrel grooves 3C13, and spherical cap holders 3C14, the elliptical prism blocks 3C11 are three and are respectively nested on the left side of the triangular prism barrel grooves 3C13, the triangular prism plate holders 3C12 are installed inside the triangular prism barrel grooves 3C13, the triangular prism barrel grooves 3C13 are in clearance fit with the spherical cap holders 3C14 through the elliptical prism blocks 3C11, the triangular prism barrel grooves 3C13 are a composite three-prong barrel structure with upper and lower oblique clip angle forty-five degree branch barrel grooves of the transverse barrel, so that lens radiation current straight-through effect is formed by three nodes on the side, end angle wrapping effect when the power grid is formed is ensured, light beam crossing current can be conveniently arranged along the light beam trajectory in advance under the guide of the triangular prism plate holders 3C12 through the elliptical prism blocks 3C11, avoiding ray deviation interference.

Referring to fig. 5, the light-gathering film body 3E is composed of a film strip 3E1, a trapezoid pedestal 3E2, an inverted narrow mirror groove 3E3, and a vent hole 3E4, the inverted narrow mirror groove 3E3 is nested on the top of the trapezoid pedestal 3E2, the vent hole 3E4 and the film strip 3E1 are integrated, the film strip 3E1 and the inverted narrow mirror groove 3E3 are in interference fit, the inverted narrow mirror groove 3E3 is a composite trapezoid groove structure with a wide top and a narrow bottom, so as to facilitate adjustment of expansion and contraction of the film surface, and the radiated power can form a through direct current effect when the glass surface is not conductive through the mirror groove, so that the arc mirror groove has a star ray outward-spreading effect, and the light-gathering transmission current of the inverted narrow mirror groove 3E3 can be spread efficiently through the rotary expansion of the film strip 3E1, thereby forming a sea urchin-shaped electrode ray interleaving and expanding effect.

Referring to fig. 6, the gourd top groove seat 3F1 is composed of a top ball bag body 3F11, a flat disc pad 3F12, an oblique ridge tube body 3F13 and a circular truncated cone groove seat 3F14, the flat disc pad 3F12 is nested on the top of the oblique ridge tube body 3F13, the axes of the flat disc pad and the oblique ridge tube body are collinear, the top ball bag body 3F11 is welded on the top surface of the circular truncated cone groove seat 3F14 and is communicated with each other, the oblique ridge tube body 3F13 is inserted into the circular truncated cone groove seat 3F14, the oblique ridge tube body 3F13 is a groove tube structure with a sealing cover at the top and a square protruding strip block at the side, the lifting and pushing effect of the whole bag shell can be formed by the twisting of the protruding strip block, the flat disc pad 3F12 bears the floating plate pressure on the top of the oblique ridge tube body 3F13 and enables the oblique ridge tube body 3F13 to be in rotary engagement friction, so that a static electric.

Referring to fig. 7, the nodal focusing tube 3F4 is composed of an angle cap tube 3F41, a trapezoidal prism sheet 3F42, a contact three-segment frame 3F43, and a radiation tube 3F44, the trapezoidal prism sheet 3F42 is provided with two and is tightly attached to the left end of the inside of the angle cap tube body 3F41, the contact three-node holder 3F43 is nested on the left side of the radiation tube 3F44 and is on the same vertical plane, the trapezoidal prism sheet 3F42 is electrically connected with the contact three-section frame 3F43, the contact three-section frame 3F43 is a current frame structure with the upper end and the lower end on the left side and the middle section provided with three ball line tubes for splicing, the open positions of the three contacts can conveniently form a concentration effect at the round end when the three contacts discharge simultaneously, the impact current forms the adjusting and releasing effects of three nodes along with the potential difference of the high and low positions of the coil by connecting the contact three-node frame 3F43 with the radiation tube 3F44 through current, so that the deviation node can be lifted or lowered to correct the balance degree.

The working process is as follows: after a worker powers on a singlechip electric plate 1 to stably erect a bayonet socket formed by a bayonet groove 6 and a rubber base 7 in a track short column block 2, a floating plate is supported at the bottom of a track transverse plate 5, then the side of a cable 4 is conducted to balance a pin adapter 3A in a magnetic disk 3 one by one through a power grid, a bearing seat 3A4 is made to drive an insertion tube 3A3 to link an integrated electric plate 3A1 and a pin tube 3A2 to rotate and push up current and lead the current into a node radiator 3F in a magnetic disk shell cover 3B, a light interlacing effect is formed by attaching a three-convex-lens ball seat 3C1 on the side of a lens arc 3C to a transparent arc band 3C2, an elliptical-convex-lens block 3C11 and a three-fork-tube groove 3C13 in a three-prism-plate seat 3C12 are formed, light penetrates through the spherical cover seat 3C14 and a light-transmission thin film strip 3E1 of a light-focusing thin film body 3E to form a light-transmission-shaped pre-mapping effect, a riser hole 3E 637 is formed, and a later-stage light transmission-shaped light The effect of the method is to avoid deviation operation, guarantee the stable electromagnetic field and the fine adjustment prefabricated space of potential difference, form up-and-down pulling effect through the 3D clip lifting column groove 3G with the spring tube 3H with the side open groove, when the section of potential difference that is excessively worn and lacked by the coil is weak, the inclined wale cylinder 3F13 and the circular table groove seat 3F14 can be pressurized through the top ball bag body 3F11 and the flat disc pad 3F12 in the calabash top groove seat 3F1 to form the electric tube bearing effect, then the high-level electric network is lifted through the interweaving of the vertical optical fiber tube 3F2 and the top discharge tube 3F3 to achieve the balance adjustment effect, otherwise, when the low-level electric network is lifted, the refraction adjustment effect to the current tube is formed through the angle clamping cap tube body 3F41 of the node convergent tube 3F4 and the trapezoidal prism sheet 3F42 in the process that the radiation electric tube 3F44 sends current to the contact three-level bracket 3F43, the electric wire tube, the node net pressure of the electromagnetic suspension shuttle is improved, so that the floating plate track vibration isolation system obtains simple density independent fine adjustment operation.

The invention achieves the effect of using the track short column block 2 to match with the power grid balance disk 3 and using the lifting column groove 3G at the top of the track short column block 2 to form a lifting regulation potential difference and potential height balance by combining the above components, so that the consumed coil value can be expanded by the lifting column groove 3G lifting matching node emitter 3F to draw the power grid to be regulated in the electromagnetic suspension process, the multi-node disk shell 3B can be oppositely interwoven to form an electromagnetic induction line deformation compression resistance balance effect for reinforcing an internal electromagnetic field, the balance pressure of track vibration isolation is ensured, the unilateral stress loss is avoided, and the mirror ball arc belt 3C prefabricated optical network pattern covers the power grid to form the track guidance of the radiated current, so that the floating attachment plate forms a pallet current, and the floating plate can bear more stably and bear force uniformly when sliding in the track type suspension, the node network pressure is guaranteed to control micro-change electric power, the piezoelectric material floating plate is enabled to obtain a balance protection effect, the problem that the balance force of magnetic suspension is very important to solve is solved, the floating plate on a track is balanced under the condition of poor coil potential difference and abrasion loop number, a micro-tilting phenomenon can be caused, sliding pressure bias of the whole upper carrier is caused, the vibration isolation balance effect of the floating plate is poor, node stress is uneven, the shearing force effect of the whole plate surface is influenced, the floating plate is easy to break a plate block due to the fact that a single-side load exceeds a rated bearing force in the track suspension sliding process, an electromagnetic force line field can be deformed and twisted, free electrons are accumulated on the single side, an electric spark friction phenomenon is easy to generate, and the problem that the potential safety hazard protection adjustment of the track is insufficient.

The specific embodiments described herein are merely illustrative of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the scope of the invention or exceeding the scope of the claims appended hereto.