CN209921070U

CN209921070U - Suspension frame suitable for low vacuum pipeline hypervelocity magnetic levitation

Info

Publication number: CN209921070U
Application number: CN201920499009.XU
Authority: CN
Inventors: 武震啸; 毛凯; 韩树春; 赵明; 李少伟; 任晓博; 刘德刚; 李萍
Original assignee: China Academy Of Aerospace Science Engineering And Aerospace Technology (china Academy Of Aerospace Seahawk Electromechanical Technology)
Current assignee: China Academy Of Aerospace Science Engineering And Aerospace Technology (china Academy Of Aerospace Seahawk Electromechanical Technology); Casic Feihang Technology Research Institute of Casia Haiying Mechanical and Electronic Research Institute
Priority date: 2019-04-11
Filing date: 2019-04-11
Publication date: 2020-01-10
Anticipated expiration: 2029-04-11

Abstract

The utility model provides a suspension frame suitable for low vacuum pipe hypervelocity magnetism floats, including the dewar, box girder dewar rigid connection device, the framework, a series of linkage, through box girder dewar rigid connection device rigid connection between the dewar, be connected through a series of linkage between dewar and the framework, vertical symmetry sets up the rubber spring who takes cable suspension device between dewar and the framework, the dewar, tip box girder dewar rigid connection device sets up respectively and is a draw bar device that links to each other with the framework side, can effectively transmit each power and guarantee certain degree of freedom between dewar and the framework, suspension when solving current magnetism and floating dewar operation, direction and restraint ability subalternation problem. Simultaneously the utility model discloses still adopted parts such as undercarriage, leading wheel, emergent support guider, vortex arresting gear, improved the mechanical quench protective capacities, the emergency braking ability of suspension frame.

Description

Suspension frame suitable for low vacuum pipeline hypervelocity magnetic levitation

Technical Field

The utility model belongs to magnetic levitation vehicle running gear field, in particular to low vacuum pipeline hypervelocity magnetic levitation vehicle suspension frame.

Background

The low vacuum pipeline magnetic suspension traffic is a traffic mode for running a magnetic suspension train in a low vacuum pipeline, the running speed can reach 1000km/h or higher, and the low vacuum pipeline magnetic suspension traffic comprises a vehicle system, a line system, a vacuum system, a suspension propulsion system and the like. According to related data, after the speed of the existing rail transit vehicle reaches 600km/h, the ratio of air resistance to total resistance reaches more than 90%, vibration is severe, and factors such as mechanical friction and adhesion coefficient severely restrict further improvement of the speed of the rail transit train. The low-vacuum pipeline runs in a low-pressure pipeline in an ultrahigh-speed magnetic levitation way, and the influence of air resistance on the low-vacuum pipeline is small; the superconducting side wall type suspension and guide device is adopted, the limitation of mechanical friction and adhesion coefficient is avoided, the suspension and guide gap is large, and the safety is high; the adopted superconducting long stator linear motor has strong traction capacity, so that the train can reach the running speed of more than 1000km/h, and the superconducting long stator linear motor is an ideal future vehicle.

In the united states, the Vacuum pipe transportation was studied in the fifties of the last century, and the patents "Apparatus for Vacuum pipe transportation" (US2488287A) "Vacuum pipe transportation system" (US2511979A) directly connect a vehicle body and a circular pipe through a suspension device by a mechanical device so as to provide the circular pipe with supporting and guiding capabilities without a suspension frame; the patent "Evacuated tube transport" (US5950543A) uses a capsule type vehicle, and does not mention a specific support guide mechanism; companies such as Hyperopone, HTT and the like firstly adopt pneumatic suspension and then turn to magnetic suspension, wherein the former adopts linear motor drive and permanent magnet suspension, a magnet and a motor are directly arranged on a vehicle body, a suspension frame device is not provided, and the traction and suspension mode of the latter is not disclosed; "Swiss subway" (Swissmerro) adopts a mode similar to a magnetic airplane, a vehicle body runs in a circular pipeline through a suspension frame, and the vehicle body can axially rotate along the pipeline so as to pass through a curve; the Japanese superconducting magnetic levitation adopts a low-temperature superconducting electric system, a left Dewar and a right Dewar are connected through a forked rod, a front-end forked rod is vertically connected with a framework through an air spring, a transverse traction pull rod is installed on the front-end forked rod and connected with the framework, a longitudinal traction pull rod is installed in the middle of the Dewar and connected with a side beam of the framework, a secondary traction device is installed at the front end of the framework, and an active vibration control device is installed on an end beam of the framework and used for mitigating vibration.

The patent of 'a high-temperature superconducting maglev vehicle with strong curve passing capability' (CN205130968U), 'a maglev vehicle self-guiding bogie' (CN205044569U), 'a maglev mechanism and a maglev train' (CB206327183U) designs the maglev train which generates pinning force by utilizing a high-temperature superconducting block material to generate suspension and guiding force by interaction with a permanent magnet track and is driven by a linear motor, wherein the high-temperature superconducting block material is placed in a Dewar and is arranged at two sides of the bottom of the suspension frame, and the linear motor is arranged at the bottom of the suspension frame or other positions; the patent "superconducting maglev bogie" (CN206297425U) designs a large bogie comprising at least one secondary beam and a plurality of suspension units, each suspension unit comprises a connecting beam and two dewars, and the dewars are mounted on the lower surface of the connecting beam.

The Beijing Jiuzhou artery patent 'a passive superconducting maglev train' (CN207449664U) is additionally provided with a suspension guide device and a linear motor driving device on the basis of a traditional railway bogie. The primary linear motor is arranged in the middle of the rail and corresponds to the secondary linear motor at the bottom of the middle of the bogie; the suspension and guide induction plates are arranged on two sides of the steel rail and correspond to the arc-shaped mechanisms which extend out of the suspension frame in the lateral direction, and suspension and guide force is provided.

The Vacuum pipeline transportation suspension-free concept designed by the patents of 'Apparatus for Vacuum tube transportation' (US2488287A), 'Vacuum tube transportation system' (US2511979A) and 'Vacuum tube transportation' (US5950543A) has extremely poor curve passing capacity and is not in line with the design concept of modern high-speed rail transportation, and the suspension system without the suspension frame can not isolate the vibration caused by line excitation due to the limitation of friction in supporting and guiding by a mechanical device, so that the riding comfort can not meet the requirement and an emergency protection device is not provided.

The active vibration control system is installed on the Japanese superconducting maglev for vibration reduction, the system is an active system, and needs a large amount of external energy input for the work of an actuator, so that the structural complexity and the manufacturing cost are increased, and once the system fails, the suspension frame loses part of suspension capacity, so that the reliability is reduced; the Dewar has no safety redundancy and the suspension frame has no emergency supporting and guiding device, and once any Dewar is quenched, the vehicle can be unstably collided with the rail; the suspension device is supplied with air depending on the atmospheric environment and cannot be used in a vacuum pipeline; the left and right Dewar are inserted into the Dewar through a fork-shaped structure for connection, so that the relative positions of the left and right Dewar can not be effectively restrained during vibration, and suspension and guiding are not facilitated; the emergency braking capability is lacked, and once the linear motor fails to brake, the linear motor cannot brake; the two-system traction pull rod is arranged at the end part of the framework, and the suspension frame and the vehicle body can generate larger rotation when moving relatively, so that the transmission of traction force is not facilitated.

The high-temperature superconducting magnetic levitation designed by the southwest intersection utilizes the pinning effect of a non-ideal second-type superconductor to suspend and guide, is limited by the level of high-temperature superconducting bulk materials and magnetic materials of a permanent magnet track, and has weak suspension and guide capabilities, so that the load carrying capacity and curve passing capacity of the high-temperature superconducting magnetic levitation system are limited, the requirements of large-capacity load carrying and high-speed operation cannot be met, and the cost and maintenance of the permanent magnet track are difficult.

The suspension and guide device of the bogie designed by the Beijing Jiuzhou artery patent, namely 'a passive superconducting maglev train' (CN207449664U), is positioned outside the track, so that the diameter of the pipeline is greatly increased, the engineering cost is greatly increased, the curve passing capacity of the guide mode is relatively weak due to geometric limitation, the suspension clearance is relatively small during high-speed operation, the precision requirement on the track is high, and the engineering and the cost saving are not facilitated.

Disclosure of Invention

In order to guarantee safe comfortable hypervelocity operation of vehicle in low vacuum pipe, the utility model provides a pipeline train suspension frame that adapts to low vacuum, high vibration and strong magnetic field environment solves vibration big, the speed that current low vacuum pipe hypervelocity magnetism floats that suspension frame exists, the reliability is low, hang and rely on the outside air, suspend the problem that guiding ability is weak.

The utility model provides a technical scheme as follows that above-mentioned technical problem adopted:

a suspension frame suitable for ultrahigh-speed magnetic levitation of a low-vacuum pipeline comprises a Dewar, a box-shaped beam Dewar rigid connecting device, a framework and a primary suspension device; the dewars are at least 2 sets, and the symmetrically arranged dewars are rigidly connected through at least 4 sets of box girder dewar rigid connecting devices; the framework comprises 2 framework end beams, 2 framework longitudinal beams and at least 1 framework cross beam, wherein the framework end beams and the framework cross beams are perpendicular to the framework longitudinal beams and are respectively arranged at the two ends and the middle of the framework longitudinal beams; the framework is connected with the Dewar through a suspension device, the suspension device includes rubber spring and a tie rod device of taking cable suspension device, and vertical symmetry is provided with 4 set at least rubber spring of taking cable suspension device between Dewar and the framework, sets up 2 set at least one tie rod devices between Dewar and the framework longeron, sets up 1 set at least one tie rod device between framework end beam and the tip box roof beam Dewar rigid connection device.

Furthermore, the framework end beam is of a U-shaped structure with stand columns at two ends of the cross beam, outward supporting seats are arranged at the top ends of the two stand columns, and rubber springs with hanging devices are mounted on the lower surfaces of the supporting seats.

Furthermore, the suspension frame also comprises a landing gear, a guide wheel and an emergency support guide device; the undercarriage is at least 4 sets and is symmetrically arranged on the opposite side surfaces of the upright columns at the two ends of the front and rear frame end beams, the guide wheels are at least 4 sets and are symmetrically arranged on the front and rear side surfaces of the top supporting seats of the front and rear frame end beams, and the undercarriage and the guide wheels have the retraction function; emergent guider that supports contains 4 sets at least emergent supporting wheels and 4 sets at least emergent leading wheels, emergent supporting wheel is installed at framework end beam or framework longeron lower surface, and the lateral surface at framework end beam top sprag seat is installed to emergent leading wheel. The undercarriage and the guide wheel are matched with the emergency supporting and guiding device to solve the problem of no mechanical quench protection of the magnetic levitation of the existing vacuum pipeline.

Further, the suspension frame still includes the secondary suspension system with car connection, secondary suspension device includes closed air spring, secondary draw gear, damping device, framework end beam both ends supporting seat sets up 2 at least sets of closed air springs, vertical symmetry is provided with 2 at least sets of damping device on the crossbeam of framework end beam middle part, transversely is provided with 1 at least sets of damping device, framework crossbeam middle part is provided with 1 at least sets of secondary draw gear.

Furthermore, the first tie rod device and the second tie rod device are tie rods with elastic nodes and/or joint bearings; the vibration damper is an oil-gas vibration damper with elastic nodes.

Furthermore, the suspension frame also comprises 2 or 4 sets of eddy current braking devices which are symmetrically arranged at two sides of the lower parts of the front and rear frame end beams and the frame cross beam, and the eddy current braking devices arranged at the same side correspond to the reaction plate on the track. The eddy current brake device is used for solving the problem that the conventional vacuum pipeline magnetic levitation linear motor has no vehicle-mounted emergency brake when the brake fails or the vehicle-ground communication is interrupted.

Further, the suspension rack also comprises a driving device and a refrigerating device; the driving device is 2 sets and is respectively arranged between the front frame end beam and the rear frame end beam and between the adjacent frame cross beams, and the driving device comprises at least 1 set of hydraulic driving mechanism and pneumatic driving mechanism which are mutually independent; the refrigerating device is at least 1 set and is arranged on the framework cross beam or between the two framework cross beams.

Furthermore, the rubber spring with the hanging device is provided with a hanging rod in the center of the rubber spring, one end of the hanging rod is connected with the end beam of the framework, and the other end of the hanging rod vertically extends into the Dewar.

Furthermore, a supporting structure and 4 superconducting coils made of superconducting wires are installed in the dewar, and the superconducting coils correspond to the track side wall reaction plate.

Furthermore, the rigid box-beam Dewar connecting device comprises an upper box-beam and a lower box-beam.

The utility model has the advantages that:

the utility model discloses a box girder dewar rigid connection device rigid connection's dewar is the biggest vertical displacement when passing through the curve and is no longer than 8mm, and the biggest lateral displacement is no longer than 12mm, and the dewar is not more than 3mm with the biggest relative displacement of framework curb girder, has good operating performance, and suspension, the direction and the relatively weak problem of restraint ability and overcome between dewar and the dewar or the influence of mutual electromagnetic force between dewar and the framework when solving current magnetism and floating the dewar operation.

The problem of adaptability of a vacuum environment of a suspension device is solved by adopting a closed air spring and a rubber spring device with the suspension device, and dynamics calculation shows that when low-vacuum ultrahigh-speed magnetic levitation with the total weight of 37t in the suspension mode passes through a 20000m curve at a high speed of 1000km/h, the maximum transverse and vertical comfort indexes are 2.12 and 2.27 respectively, the excellent evaluation standard specified in GB5599-95 is met, and the problems of poor comfort and weak bearing capacity of the existing magnetic levitation are solved.

The maximum transverse acceleration of the vehicle body is not more than 0.35m/s²The maximum vertical acceleration is not more than 0.8m/s²Far less than a maximum acceleration of not more than 2.5m/s²The standard requirement shows the utility model discloses a linkage and overall arrangement mode can guarantee that magnetism floats and possess outstanding vibration isolation performance when the hypervelocity operation, have solved the big, the low problem of speed of original low vacuum hypervelocity pipeline magnetism float vibration.

The landing gear, the guide wheel, the emergency support wheel and the emergency guide wheel are arranged comprehensively, so that the magnetic levitation vehicle has enough mechanical support and guide capacity when the Dewar quench occurs, and the problem of no mechanical quench protection of the existing magnetic levitation is solved.

By adopting the eddy current brake device, the existing magnetic suspension has emergency brake capability when the conditions of quench, vehicle-ground communication interruption, electric brake failure and the like occur when the existing magnetic suspension runs in a low-pressure pipeline at a high speed, and the problem that the existing vacuum pipeline magnetic suspension has no vehicle-mounted reliable emergency brake is solved.

The central secondary traction device has transverse and vertical maximum force smaller than 300N and maximum rotation angle smaller than 2 degrees except longitudinal direction, has good traction performance, and solves the problem that the conventional magnetic suspension traction device is unreasonable in arrangement.

Drawings

The accompanying drawings, which are included to provide a further understanding of the embodiments of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention. It is obvious that the drawings in the following description are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.

Fig. 1 shows an isometric view provided in accordance with a particular embodiment of the present invention;

fig. 2 shows a front view provided according to a specific embodiment of the present invention;

wherein the figures include the following reference numerals:

1. the device comprises an end box-type beam Dewar rigid connecting device, 2 a closed air spring, 3a refrigerant tank, 4 a framework longitudinal beam, 5 a middle box-type beam Dewar rigid connecting device, 6 a secondary traction pull rod, 7a refrigerating device, 8 a Dewar, 9a framework cross beam, 10 a primary longitudinal pull rod, 11 an undercarriage, 12 a vertical shock absorber, 13 a driving device, 14 a transverse shock absorber, 15 a framework end beam, 16 a rubber spring with a hanging device, 17 an emergency guide wheel, 18 a guide wheel, 19 an emergency support wheel, 20 an eddy current braking device and 21 a primary transverse pull rod.

Detailed Description

The utility model provides a suspension frame suitable for low vacuum hypervelocity pipeline magnetic levitation mainly includes: the frame, the Dewar 8, the box girder Dewar rigid connection device, the landing gear 11, the guide wheels 18, the emergency support guide device, the primary suspension device, the secondary suspension device, the eddy current brake device 20, the driving device 13, the refrigerating device 7 and the like.

The framework includes 2 framework end beams 15, 2 framework longerons 4 and 1 at least framework crossbeam 9, and framework longeron 1 is along the track direction, and framework end beam 15, framework crossbeam 9 all are perpendicular to framework longeron 1 and set up respectively at framework longeron 1 both ends and centre, constitute similar "mesh" style of calligraphy structure through the welded mode, framework end beam 15 is "U" type structure of crossbeam both ends area stand, and two stand tops set up outside supporting seat.

The Dewar 8 is at least 2 sets, each set of Dewar is internally provided with a support structure and superconducting coils made of 4 superconducting wires, and the superconducting wires comprise but are not limited to a high-temperature superconducting magnet or a low-temperature superconducting magnet and correspond to the track side wall reaction plate to provide traction, braking, suspension and guiding capabilities; the side surfaces of the 2 sets of the Dewar relative to each other are rigidly connected through at least four sets of box-type beam Dewar rigid connecting devices, and each set of the box-type beam Dewar rigid connecting device comprises an upper box-type beam and a lower box-type beam.

The undercarriage 11 and the guide wheel 18 are at least 4 sets respectively, the undercarriage 11 is symmetrically arranged on the opposite side surfaces of the upright columns at the two ends of the front and rear framework end beams, and the guide wheel 18 is symmetrically arranged on the front and rear side surfaces of the supporting seat at the top of the front and rear framework end beams and has the retraction function; the emergency supporting and guiding device comprises at least 4 sets of emergency supporting wheels 19 and 4 sets of emergency guiding wheels 17, the emergency supporting wheels 19 are arranged on the lower surface of the framework end beam 15 or the lower surface of the framework longitudinal beam 4, and the emergency guiding wheels 17 are arranged on the outer side surfaces of supporting seats at two ends of the framework end beam; the guide wheels and the landing gear are in contact with the concave track when extending out, and are flush with the emergency support wheels 19 and the emergency guide wheels 17 when retracting, so that the guide wheels and the landing gear play a role in protection when the Dewar quench or other emergency situations occur.

The frame is connected on the dewar through a linkage suspension device, and a linkage suspension device is including taking cable suspension device's rubber spring and a tie rod device, and vertical symmetry is provided with 4 at least sets of rubber spring of taking cable suspension device between dewar and the frame, transversely is provided with 2 at least sets of tie rod devices, connects frame end beam and tip box beam dewar rigid connection device, vertically is provided with 2 sets or 4 sets of tie rod devices, connects frame longeron and dewar, and a linkage suspension device is used for transmitting each power and guarantees certain degree of freedom.

The frame is connected with the vehicle body through a secondary suspension device, the secondary suspension device comprises closed air springs, a secondary traction device and a vibration damping device, at least 2 sets of closed air springs are arranged on the upper portion of each frame end beam, at least 2 sets of vibration damping devices are vertically and symmetrically arranged on a beam in the middle of each frame end beam, at least 1 set of vibration damping device is transversely arranged on the beam in the middle of each frame end beam, at least 1 set of secondary traction device is arranged in the middle of each frame beam, and the secondary suspension device is used for transmitting all directions of force and ensuring certain degree of freedom.

The eddy current brake device 20 is 2 sets or 4 sets, and is respectively arranged on the two sides of the lower parts of the front and rear frame end beams 15 and the frame cross beam 9, the eddy current brake device arranged on the same side corresponds to the reaction plate on the track, and the eddy current brake device is lowered to react with the reaction plate to play an emergency braking role when the feedback braking of the linear motor fails or the vehicle-ground communication is lost.

The driving device 13 is 2 sets and is respectively arranged between the front frame end beam 15, the rear frame end beam 15 and the frame cross beam 9, the driving device comprises at least 1 set of hydraulic driving mechanism and 1 set of pneumatic driving mechanism and is mutually independent, and power is provided for the undercarriage, the guide wheel and the eddy current brake actuator under normal conditions and emergency conditions respectively.

The refrigerating device 7 is fixedly arranged on the frame beam or between the two frame beams and has the function of maintaining the temperature of the superconducting wire in the Dewar.

The rubber spring with the hanging device can transmit compression force and tensile force.

The vibration damper is an oil-gas vibration damper with elastic nodes.

The first tie rod device and the second tie rod device are tie rods with elastic nodes and/or joint bearings.

In order to make the objects, technical solutions and advantages of the present invention clearer, the following will combine the detailed embodiments and drawings of the present invention to perform clear and complete descriptions on the technical solutions of the present invention.

As shown in figures 1 and 2, the suspension frame suitable for the superconducting fast magnetic levitation of the low vacuum pipeline can be divided into two layers in the vertical direction. The first layer is composed of 2 sets of Dewar 8, 2 sets of end box-type beam Dewar rigid connection devices 1, 2 sets of middle box-type beam Dewar rigid connection devices 5 and 2 refrigerant tanks 3, the Dewar 8 is arranged along the track direction, the refrigerant tanks 3 are fixedly connected to the upper surface of the Dewar 8, 4 sets of box-type beam Dewar rigid connection devices rigidly connect the side surfaces of the left Dewar 8 and the right Dewar 8 together through bolts to form a structure shaped like a Chinese character 'mu', the distance between the upper box-type beam and the lower box-type beam of the end box-type beam Dewar rigid connection device 1 is smaller than the distance between the upper box-type beam and the lower box-type beam of the middle box-type beam Dewar rigid connection device 5, and matching installation of a framework and other.

The upper surfaces of the front end parts and the rear end parts of the two sets of Dewar 8 are connected with the lower surfaces of rubber springs 16 with hanging devices, the framework end beams 15 are of U-shaped structures, supporting seats are arranged outwards at the tops of the framework end beams 15, and the lower surfaces of the supporting seats at the tops of the framework end beams 15 are connected with the upper surfaces of the rubber springs 16 with the hanging devices. The rubber spring 16 with the hanging device is characterized in that a hanging rod is arranged in the center of the rubber spring, one end of the hanging rod is connected with the end beam 1 of the framework, and the other end of the hanging rod can vertically extend into the Dewar 8. The dewar 8 supports the frame end beam 15 through the rubber spring 16 with the hanger at the time of high-speed operation, and the rubber spring 16 with the hanger at the time of low-speed operation hangs the dewar 8 on the frame end beam 15 by the hanger rod extending into the inside of the dewar 8.

The end box beam Dewar rigid connecting device 1 is connected with a middle cross beam of a framework end beam 15 through a series of transverse pull rods 21 to transmit transverse force; the side of the Dewar 8 is connected with the framework longitudinal beam 4 through 2 sets of a series of longitudinal pull rods 10 to transmit longitudinal force. The elastic joint and/or the knuckle bearing of the series of longitudinal tie rods 10 and of the series of transverse tie rods 21 allow a rotational freedom of not less than 10 ° with the connected parts, preventing a rigid connection between the connected parts. A gap is arranged between the side surface of the Dewar 8 and the framework longitudinal beam 4, and an elastic stop catch is arranged between the Dewar and the framework longitudinal beam, so that the Dewar and the framework longitudinal beam cannot be contacted in normal work.

The second layer comprises 2 framework end beams 15, 2 framework longitudinal beams 4, 2 framework cross beams 9, 4 sets of closed air springs 2, 4 sets of vertical shock absorbers 12, 2 sets of transverse shock absorbers 14, 4 sets of landing gears 11, 4 sets of guide wheels 18, 1 secondary traction pull rod 6, 2 sets of driving devices 13, 2 sets of refrigerating devices 7, 4 sets of emergency support wheels 19, 4 sets of emergency guide wheels 17 and 4 sets of eddy current braking devices 20.

The 2 framework end beams 15 and the 2 framework cross beams 9 are vertically arranged between the 2 framework longitudinal beams 4.

4 sets of closed air springs 2 are arranged on the upper surface of a supporting seat of a framework end beam 15, 2 sets of vertical shock absorbers 12 are arranged on the upper surface of a middle cross beam of the framework end beam 15 and close to the inner side of the closed air springs 2, a transverse shock absorber 14 is arranged on the upper surface of the middle cross beam of the framework end beam 15, elastic nodes are connected with the vertical shock absorbers and the transverse shock absorbers, a certain degree of freedom in rotation is ensured to exist between the elastic nodes and the framework end beam 15, and the other ends of the vertical shock absorbers and.

The refrigerating device 7 is arranged between the 2 framework beams 9 and is used for maintaining the temperature of the superconducting coils in the Dewar 8 to be constant; the two-system traction pull rod 6 is arranged on the 1 framework cross beam 9, the other end of the two-system traction pull rod is connected with the vehicle body, the two-system traction pull rod 6 is provided with an elastic node and a joint bearing, and the rotation freedom degree of the two-system traction pull rod and the framework cross beam 9 is not less than 15 degrees.

The side surfaces of the upright columns at the two ends of each framework end beam 15, which are close to the center of the suspension frame, are respectively provided with a set of undercarriage 11, and the side surfaces of the supporting seat at the top of each framework end beam 15, which faces forwards or backwards, are respectively provided with a set of guide wheels 18. The whole landing gear 11 adopts a rocker arm type structure, and the buffer and the actuator cylinder adopt an integrated structure form and are provided with built-in locks; the guide wheel 18 adopts a telescopic structure with a built-in lock, wherein the wheel adopts a non-magnetic material, and the bearing adopts a ceramic bearing. Two sides of the bottom surface of each framework end beam 15 are respectively provided with 1 set of emergency supporting wheels 19, and the outer side surface of the top supporting seat is respectively provided with 1 set of emergency guide wheels 17. 2 sets of eddy current brake set 20 install the both sides between preceding framework end beam 15 and framework crossbeam 9, 2 sets of eddy current brake set 20 install the both sides between back framework end beam 15 and framework crossbeam 9, 2 sets of eddy current brake 20 of homonymy installation correspond with same reaction plate on the track, eddy current brake set 20 transfer when linear electric motor feedback braking became invalid and the reaction of induction plate plays emergency braking effect. The driving device 13 comprises a normal hydraulic driving mechanism and an emergency pneumatic driving mechanism, the two mechanisms are arranged in the same magnetic shielding box body but are independent, and the driving device 13 provides power for the landing gear 11, the guide wheel 18 and the eddy current braking device 20 to work under normal conditions and emergency conditions; before floating, the undercarriage 11 extends downwards and the guide wheels 18 extend towards two sides to be in contact with the track, support and guide force are provided for the suspension frame, and after floating, the undercarriage 11 and the guide wheels 18 are retracted to be flush with the emergency support wheels 19 and the emergency guide wheels 17, so that the vehicle posture is maintained when Dewar quench or other emergency situations occur, and a protection effect is achieved.

Features that are described and/or illustrated above with respect to one embodiment may be used in the same way or in a similar way in one or more other embodiments and/or in combination with or instead of the features of the other embodiments.

It should be emphasized that the term "comprises/comprising" when used herein, is taken to specify the presence of stated features, integers, steps or components but does not preclude the presence or addition of one or more other features, integers, steps, components or groups thereof.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

The detailed description of the present invention is the technology known to those skilled in the art.

Claims

1. A suspension frame suitable for ultrahigh-speed magnetic levitation of a low-vacuum pipeline is characterized by comprising a Dewar, a box-shaped beam Dewar rigid connecting device, a framework and a primary suspension device;

the dewars are at least 2 sets, and the symmetrically arranged dewars are rigidly connected through at least 4 sets of box girder dewar rigid connecting devices;

the framework comprises 2 framework end beams, 2 framework longitudinal beams and at least 1 framework cross beam, wherein the framework end beams and the framework cross beams are perpendicular to the framework longitudinal beams and are respectively arranged at the two ends and the middle of the framework longitudinal beams;

the framework is connected with the Dewar through a suspension device, the suspension device includes rubber spring and a tie rod device of taking cable suspension device, and vertical symmetry is provided with 4 set at least rubber spring of taking cable suspension device between Dewar and the framework, sets up 2 set at least one tie rod devices between Dewar and the framework longeron, sets up 1 set at least one tie rod device between framework end beam and the tip box roof beam Dewar rigid connection device.

2. The suspension frame of claim 1, wherein the end beams of the frame are U-shaped with vertical columns at two ends of the cross beam, and outward supporting seats are arranged at the top ends of the two vertical columns, and rubber springs with hanging devices are arranged on the lower surfaces of the supporting seats.

3. The suspension of claim 2 further comprising a landing gear, a guide wheel, an emergency support guide; the undercarriage is at least 4 sets and is symmetrically arranged on the opposite side surfaces of the upright columns at the two ends of the front and rear frame end beams, the guide wheels are at least 4 sets and are symmetrically arranged on the front and rear side surfaces of the top supporting seats of the front and rear frame end beams, and the undercarriage and the guide wheels have the retraction function; emergent guider that supports contains 4 sets at least emergent supporting wheels and 4 sets at least emergent leading wheels, emergent supporting wheel is installed at framework end beam or framework longeron lower surface, and the lateral surface at framework end beam top sprag seat is installed to emergent leading wheel.

4. The suspension frame according to claim 2, further comprising a secondary suspension system connected with the vehicle body, wherein the secondary suspension system comprises closed air springs, secondary traction devices and damping devices, the supporting seats at the two ends of the end beam of the framework are provided with at least 2 sets of closed air springs, the beam in the middle of the end beam of the framework is provided with at least 2 sets of damping devices in vertical symmetry and at least 1 set of damping devices in transverse direction, and the beam in the middle of the framework is provided with at least 1 set of secondary traction devices.

5. The suspension of claim 4 wherein the primary and secondary tie bar devices are tie bars with resilient joints and/or knuckle bearings; the vibration damper is an oil-gas vibration damper with elastic nodes.

6. A suspension as defined in claim 1, further including 2 or 4 sets of eddy current brake assemblies symmetrically mounted on opposite sides of the lower portions of the front and rear frame end beams and frame cross-members, the same side mounted eddy current brake assemblies corresponding to the reaction plates on the rails.

7. A suspension as defined in claim 1, further comprising a drive device and a refrigeration device; the driving device is 2 sets and is respectively arranged between the front frame end beam and the rear frame end beam and between the adjacent frame cross beams, and the driving device comprises at least 1 set of hydraulic driving mechanism and pneumatic driving mechanism which are mutually independent; the refrigerating device is at least 1 set and is arranged on the framework cross beam or between the two framework cross beams.

8. The suspension according to claim 1, wherein the rubber spring with hanging device is a suspension rod arranged at the center of the rubber spring, one end of the suspension rod is connected with the end beam of the framework, and the other end of the suspension rod vertically extends into the interior of the Dewar.

9. The suspension of claim 1 wherein the dewar houses a support structure and 4 superconducting coils of superconducting wire, the superconducting coils corresponding to the track sidewall reaction plate.

10. A suspension as defined in claim 1 wherein the box beam dewar rigid connection means comprises two upper and lower box beams.