CN205592284U - Vertical axial suspension support structure - Google Patents

Abstract

The utility model discloses a vertical axial suspension support structure, including the stand that the vertical set up, be equipped with on the stand can horizontal rotation the carousel be equipped with the mount pad on the stand outer wall the magnetic suspension rotary supporting device that the level that is equipped with between mount pad and the carousel set up, the device include with under mount pad fixed connection's the horizontal annular circle and with carousel fixed connection's horizontal annular on enclose lower ring of horizontal annular and horizontal annular on be provided with the magnetic levitation device of messenger's formation magnetic suspension effort between them between the circle lower ring of horizontal annular and horizontal annular on still be equipped with between the circle and prevent that horizontal annular from upward enclosing the radical location device of radial deflection, the radical location device is provided with a plurality of spacing balls including set up the horizontal annular guide rail who circles in lower ring of horizontal annular and/or horizontal annular in horizontal annular guide rail, the utility model discloses simple structure, maintain that convenience, permanent magnetism suspension, consumption are little.

Description

A kind of vertical axial suspension bearing structure

[technical field]

The present invention relates to a kind of recreation facility, particularly relate to a kind of vertical axial suspension bearing structure.

[background technology]

At present slew gear is widely used that common pivoting support or bearing.The problems such as common pivoting support or bearing generally exist: outdoor use, and wet by the rain and burnt by the sun, dust is many, and natural environment is relatively more severe, the impact that is rigidly connected is big, maintenance difficulty (work high above the ground), and frictional resistance is bigger.The magnetic bearing of mechanical contact has the advantages such as noncontact, bearing damp little without lubricant, power consumption and rigidity be adjustable, can meet the Special use occasion of game equipment.But magnetic bearing technical sophistication, active type magnetic bearing also relates to feedback control system, with high costs, there is no application at game device at present.

[summary of the invention]

Instant invention overcomes the deficiency of above-mentioned technology, it is provided that a kind of simple in construction, vertical easy to maintenance, that permanent magnet suspension, power consumption are little axial suspension bearing structure.

For achieving the above object, present invention employs following technical proposal:

nullA kind of vertical axial suspension bearing structure，The column 1 arranged including vertical，Equipped with the rotating disk 2 of energy column 1 horizontal rotation relatively on column 1，It is characterized in that being provided with mounting seat 5 on described column 1 outer wall，Horizontally disposed magnetic suspension rotary supporting device 6 it is provided with between described mounting seat 5 and rotating disk 2，Described magnetic suspension rotary supporting device 6 includes and encloses 61 under the described fixing transverse annular being connected of mounting seat 5 and fix circle 62 in the transverse annular being connected with rotating disk 2，Enclose under described transverse annular 61 and with transverse annular on enclose 62 separately positioned，Enclose 61 under described transverse annular and be all enclosed within outside column 1 with circle 62 in transverse annular，Enclose under described transverse annular 61 and and transverse annular on enclose and be provided with the magnetic levitation system 7 making to form magnetic suspension active force between them between 62，Enclose under described transverse annular 61 and and transverse annular on enclose between 62 and be additionally provided with the radial positioning device 8 preventing from enclosing 62 radial deflections in transverse annular，Described radial positioning device 8 includes being arranged under transverse annular the transverse annular guide rail 9 on circle 62 in circle 61 and/or transverse annular，Some spacing balls 10 it are provided with in transverse annular guide rail 9，The radial width of described transverse annular guide rail 9 is identical with the cross-sectional width of spacing ball 10.

Described magnetic levitation system 7 includes the upper circle toroidal magnet 71 being arranged in described transverse annular the horizontally set bottom circle 62 and is arranged under transverse annular the lower ring shape magnet 72 of the horizontally set enclosed on 61, separates and formed magnetic suspension active force between bottom and the top of lower ring shape magnet 72 of described upper circle toroidal magnet 71.

The cross section of described upper circle toroidal magnet 71 is matrix, and the cross section of described lower ring shape magnet 72 is T-shaped, is provided with the annular groove of the contactless insertion in top for T-shaped lower ring shape magnet 72 bottom described upper circle toroidal magnet 71.

Described transverse annular guide rail 9 includes being arranged under transverse annular the lower annular guide rail groove 91 of the horizontally set enclosed on 61 end faces and being arranged in transverse annular the upper annular guide rail groove 92 of the horizontally set enclosed on 62, described lower annular guide rail groove 91 separates with upper annular guide rail groove 92 and is oppositely arranged, described spacing ball 10 one end is supported by lower annular guide rail groove 91, described spacing ball 10 other end extend in annular guide rail groove 92, the groove width of described upper annular guide rail groove 92 is identical with the cross-sectional width of spacing ball 10, the axial direction of described transverse annular guide rail 9 is provided with spacing ball 10 levitation gap in axial sliding of permission.

Described ball 10 is spherosome, and the cross section of described lower annular guide rail groove 91 is semicircle close-fitting with spherosome, and described upper annular guide rail groove 92 bottom land is provided with described levitation gap.

Described ball 10 is run-track shaped column for cross section, the cross section of described lower annular guide rail groove 91 is close-fitting with ball 10 lower end half run-track shaped, described upper annular guide rail groove 92 is also half run-track shaped, and described upper annular guide rail groove 92 bottom land is provided with described levitation gap.

Described radial positioning device 8 includes the circular orientation cylinder 81 being arranged in described transverse annular on circle 62, it is outside that described circular orientation cylinder 81 is enclosed within transverse annular circle 61, enclose under described circular orientation cylinder 81 inwall and transverse annular and form annular gap 100 between the outer wall of 61, described transverse annular guide rail 9 includes the outer ring guide rail groove 93 being arranged on the horizontally set on described circular orientation cylinder 81 inwall, described outer ring guide rail groove 93 is built with described spacing ball 10, described outer ring guide rail groove 93 closely cooperates with the outer end of spacing ball 10, described spacing ball 10 closely cooperates with the outer wall of circle 61 under transverse annular.

Described upper circle toroidal magnet 71 includes the upper circle magnet mounting ring 711 being fixed in transverse annular on circle 62, described upper circle magnet mounting ring 711 is provided with the annular mounting groove of horizontally set, the inner magnet group 712,713 being spaced apart it is fixed with in annular mounting groove, the radius of described inner magnet group 712, less than the radius of outer magnet group 713, forms the first annular groove 200 inserted for described T-shaped lower ring shape magnet 72 between described inner magnet group 712,713；Described magnet group includes the upper circle internal magnetic ring 7121 being fixed together from top to bottom, upper circle magnetism-isolating loop 7122 and upper circle outer magnetic ring 7123, and described upper circle internal magnetic ring 7121 is fixedly installed in magnet mounting ring 711；Described upper circle internal magnetic ring 7121, upper circle outer magnetic ring 7123 are all permanent magnets, and their magnetic is the most contrary；The magnetic of two upper circle outer magnetic rings 7123 is the most identical, and the magnetic of two upper circle internal magnetic rings 7121 is the most identical.

Described lower ring shape magnet 72 includes be fixedly connected sequentially from top to bottom lower circle magnet mounting ring 721 together, lower circle internal magnetic ring 722, lower circle magnetism-isolating loop 723 and lower circle outer magnetic ring 724；Described lower circle magnet mounting ring 721 is fixed under described transverse annular on circle 61, and lower circle magnet mounting ring 721 is as the horizontal edge of lower ring shape magnet 72, and described lower circle magnet mounting ring 721 and lower circle magnetism-isolating loop 723 are non-magnetizers；Described lower circle internal magnetic ring 722, lower circle magnetism-isolating loop 723 are permanent magnets, and their magnetic is the most contrary；Described lower circle internal magnetic ring 722, lower circle magnetism-isolating loop 723 and lower circle outer magnetic ring 724 constitute the vertical edge of lower ring shape magnet 72, and the lower circle internal magnetic ring 722 of described lower ring shape magnet 72 is the most contrary with the magnetic of the upper circle outer magnetic ring 7123 of described upper circle toroidal magnet 71；The lower circle outer magnetic ring 724 of described lower ring shape magnet 72 is the most identical with the magnetic of the lower circle outer magnetic ring 7123 of described upper circle toroidal magnet 71.

Described magnetic levitation system 7 is multiple, and the radius of multiple magnetic levitation systems 7 is different, and they concentrics are arranged.

Compared with prior art, present invention have the advantage that 1, owing to being provided with magnetic levitation system on the revolving support between the main shaft of rotating disk and column, described magnetic levitation system includes the lower ring shape magnet being fixed on the upper circle toroidal magnet enclosed in transverse annular and being fixed under transverse annular on circle, upper and lower two magnets separate and form magnetic suspension active force, so that arriving at rotating disk during the horizontal rotation of 360 degree, upper circle toroidal magnet and lower ring shape magnet will not produce frictional force, which reduces resistance and power consumption, and reduce noise.

2, comparing the levitation device of active type, The present invention reduces feedback control system, decrease integral installation and safeguard link, therefore the structure of the present invention is simpler and reasonable, produce and use cost is lower, easy to maintenance.

3, it is additionally provided with and prevents from enclosing in transverse annular the transverse annular guide rail of radial deflection and spacing ball between circle under circle and transverse annular in transverse annular, limit the diametrically play enclosing relatively transverse lower ring in transverse annular, it is ensured that its smooth rotation.

[accompanying drawing explanation]

Fig. 1 is the front view that the present invention applies on horizontal rotation recreational machine；

Fig. 2 is the enlarged drawing of the local J of Fig. 1；

Fig. 3 is the structural representation of the embodiment of the present invention one；

Fig. 4 is the enlarged drawing of the local H of Fig. 3；

Fig. 5 is one of partial enlarged drawing of the transverse annular guide rail of Fig. 3 and ball；

Fig. 6 is the two of the partial enlarged drawing of the transverse annular guide rail of Fig. 3 and ball；

Fig. 7 is the structural representation of the embodiment of the present invention two；

Fig. 8 is the enlarged drawing of the local I of Fig. 7；

Fig. 9 is the structural representation of the radial positioning device in Fig. 8；

[detailed description of the invention]

It is described in further detail with embodiments of the present invention below in conjunction with the accompanying drawings:

nullSuch as Fig. 1-9，The open a kind of vertical axial suspension bearing structure of the present invention，The column 1 arranged including vertical，Equipped with the rotating disk 2 of energy column 1 horizontal rotation relatively on column 1，Described column 1 outer wall is provided with mounting seat 5，Horizontally disposed magnetic suspension slewing supporting device 6 it is provided with between described mounting seat 5 and rotating disk 2，Described magnetic suspension slewing supporting device 6 includes and encloses 61 under the described fixing transverse annular being connected of installation 5 and fix circle 62 in the transverse annular being connected with rotating disk 2，Enclose under described transverse annular 61 and with transverse annular on enclose 62 separately positioned,Enclose 61 under described transverse annular and be all enclosed within outside column 1 with circle 62 in transverse annular，During work，The motor being arranged on column rotates by enclosing 62 in driving gear drives transverse annular，Enclose 62 relatively transverse lower rings 61 in transverse annular to rotate.Enclose under described transverse annular 61 and and transverse annular on enclose the magnetic levitation system 7 making to form magnetic suspension active force between them be set between 62, enclose under described transverse annular 61 and and transverse annular on enclose between 62 and be additionally provided with the radial positioning device 8 preventing from enclosing 62 radial deflections in transverse annular, described radial positioning device 8 includes being arranged under transverse annular the transverse annular guide rail 9 on circle 62 in circle 61 and/or transverse annular, some spacing balls 10 it are provided with in transverse annular guide rail 9, the radial width of described transverse annular guide rail 9 is identical with the cross-sectional width of spacing ball 10, by vertical annular guide rail 9 and the setting of spacing ball 10, limit the diametrically play enclosing relatively transverse lower ring in transverse annular, ensure its smooth rotation.

Described magnetic levitation system 7 includes the upper circle toroidal magnet 71 being arranged in described transverse annular the horizontally set bottom circle 62 and is arranged under transverse annular the lower ring shape magnet 72 of the horizontally set enclosed on 61, separating and formed magnetic suspension active force between bottom and the top of lower ring shape magnet 72 of described upper circle toroidal magnet 71, this active force makes circle toroidal magnet 71 relative lower ring shape magnet 72 friction-free rotary.

The cross section of described upper circle toroidal magnet 71 is matrix, and the cross section of described lower ring shape magnet 72 is T-shaped, is provided with the annular groove of the contactless insertion in top for T-shaped lower ring shape magnet 72 bottom described upper circle toroidal magnet 71.

Described radial positioning device 8 can use numerous embodiments, and the present invention, in order to illustrate only to enumerate two kinds of embodiments, does not carry out exhaustive at this.

Such as Fig. 3-6, embodiment one:

Described transverse annular guide rail 9 includes being arranged under transverse annular the lower annular guide rail groove 91 of the horizontally set enclosed on 61 end faces and being arranged in transverse annular the upper annular guide rail groove 92 of the horizontally set enclosed on 62, described lower annular guide rail groove 91 separates with upper annular guide rail groove 92 and is oppositely arranged, described spacing ball 10 one end is supported by lower annular guide rail groove 91, described spacing ball 10 other end extend in annular guide rail groove 92, the groove width of described upper annular guide rail groove 92 is identical with the cross-sectional width of spacing ball 10, the axial direction of described transverse annular guide rail 9 is provided with spacing ball 10 levitation gap in axial sliding of permission.

So that it is more stable during the work of spacing ball, such as Fig. 5, described ball 10 is spherosome, the cross section of described lower annular guide rail groove 91 is semicircle close-fitting with spherosome, described upper annular guide rail groove 92 bottom land is provided with described levitation gap, and the groove width of described upper annular guide rail groove 92 is identical with the cross-sectional width of spacing ball 10.

Such as Fig. 6, described ball 10 is run-track shaped column for cross section, the cross section of described lower annular guide rail groove 91 is close-fitting with ball 10 lower end half run-track shaped, described upper annular guide rail groove 92 is also half run-track shaped, described upper annular guide rail groove 92 bottom land is provided with described levitation gap, and the groove width of described upper annular guide rail groove 92 is identical with the cross-sectional width of spacing ball 10.

Such as Fig. 7-9, embodiment two:

Described radial positioning device 8 includes the circular orientation cylinder 81 being arranged in described transverse annular on circle 62, it is outside that described circular orientation cylinder 81 is enclosed within transverse annular circle 61, enclose under described circular orientation cylinder 81 inwall and transverse annular and form annular gap 100 between the outer wall of 61, described transverse annular guide rail 9 includes the outer ring guide rail groove 93 being arranged on the horizontally set on described circular orientation cylinder 81 inwall, described outer ring guide rail groove 93 is built with described spacing ball 10, described outer ring guide rail groove 93 closely cooperates with the outer end of spacing ball 10, described spacing ball 10 closely cooperates with the outer wall of circle 61 under transverse annular.

Such as Fig. 3-9, described upper circle toroidal magnet 71 includes the upper circle magnet mounting ring 711 being fixed under transverse annular bottom circle 61, described upper circle magnet mounting ring 711 is provided with the annular mounting groove of horizontally set, the inner magnet group 712,713 being spaced apart it is fixed with in annular mounting groove, the radius of described inner magnet group 712, less than the radius of outer magnet group 713, forms the first annular groove 200 inserted for described T-shaped lower ring shape magnet 72 between described inner magnet group 712,713；Described magnet group includes the upper circle internal magnetic ring 7121 being fixed together from top to bottom, upper circle magnetism-isolating loop 7122 and upper circle outer magnetic ring 7123, and described upper circle internal magnetic ring 7121 is fixedly installed in magnet mounting ring 711；Described upper circle internal magnetic ring 7121, upper circle outer magnetic ring 7123 are all permanent magnets, and their magnetic is the most contrary；The magnetic of two upper circle outer magnetic rings 7123 is the most identical, and the magnetic of two upper circle internal magnetic rings 7121 is the most identical.

Described lower ring shape magnet 72 includes be fixedly connected sequentially from top to bottom lower circle magnet mounting ring 721 together, lower circle internal magnetic ring 722, lower circle magnetism-isolating loop 723 and lower circle outer magnetic ring 724；Described lower circle magnet mounting ring 721 is fixed under described transverse annular on circle 61, and lower circle magnet mounting ring 721 is as the horizontal edge of lower ring shape magnet 72, and described lower circle magnet mounting ring 721 and lower circle magnetism-isolating loop 723 are non-magnetizers；Described lower circle internal magnetic ring 722, lower circle magnetism-isolating loop 723 are permanent magnets, and their magnetic is the most contrary；Described lower circle internal magnetic ring 722, lower circle magnetism-isolating loop 723 and lower circle outer magnetic ring 724 constitute the vertical edge of lower ring shape magnet 72, and the lower circle internal magnetic ring 722 of described lower ring shape magnet 72 is the most contrary with the magnetic of the upper circle outer magnetic ring 7123 of described upper circle toroidal magnet 71；The lower circle outer magnetic ring 724 of described lower ring shape magnet 72 is the most identical with the magnetic of the lower circle outer magnetic ring 7123 of described upper circle toroidal magnet 71.

Described magnetic levitation system 7 is multiple, and the radius of multiple magnetic levitation systems 7 is different, and they concentrics are arranged.

Such as Fig. 1, it is that the present invention applies on the recreational machine of horizontal rotation, bottom rotating disk 2, by suspension rod 3, multiple seat 4 is installed.

Although the present invention being described in detail with reference to above example, but it will be apparent to one skilled in the art that in the case of the principle of the present invention limited without departing from described claim by the disclosure, can the present invention is made a variety of changes or revises.Therefore, the detailed description of disclosure embodiment is only used for explaining rather than for limiting the present invention.

Claims (10)

1. a vertical axial suspension bearing structure, the column (1) arranged including vertical, Equipped with the energy rotating disk (2) that column (1) horizontally rotates relatively on column (1), its feature exists In being provided with mounting seat (5) on described column (1) outer wall, described mounting seat (5) with turn Horizontally disposed magnetic suspension rotary supporting device (6), described magnetic suspension it is provided with between dish (2) Rotary supporting device (6) includes enclosing under the transverse annular being connected fixing with described mounting seat (5) (61) and (62) are enclosed in the transverse annular being connected fixing with rotating disk (2), described transverse annular Lower circle (61) and with transverse annular on enclose (62) separately positioned, under described transverse annular enclose (61) And all it is enclosed within column (1) outward with circle (62) in transverse annular, enclose under described transverse annular (61) and and transverse annular on enclose to be provided with between (62) and make between them, to form magnetic suspension and make Magnetic levitation system (7) firmly, enclose under described transverse annular (61) and with in transverse annular The radial direction location dress preventing from enclosing (62) radial deflection in transverse annular it is additionally provided with between circle (62) Put (8), described radial positioning device (8) include being arranged under transverse annular enclose (61) and/ Or in transverse annular, enclose the transverse annular guide rail (9) on (62), guide in transverse annular Some spacing balls (10), described transverse annular guide rail (9) it is provided with in track (9) Radial width identical with the cross-sectional width of spacing ball (10).

A kind of vertical axial suspension bearing structure the most according to claim 1, it is special Levy and be that described magnetic levitation system (7) includes being arranged on circle (62) end in described transverse annular The upper circle toroidal magnet (71) of the horizontally set in portion and being arranged under transverse annular on circle (61) Lower ring shape magnet (72) of horizontally set, the bottom of described upper circle toroidal magnet (71) And separate and formed magnetic suspension active force between the top of lower ring shape magnet (72).

A kind of vertical axial suspension bearing structure the most according to claim 2, it is special Levy and be that the cross section of described upper circle toroidal magnet (71) is matrix, described lower ring shape magnet (72) Cross section be T-shaped, described upper circle toroidal magnet (71) bottom is provided with for T-shaped lower ring shape The annular groove of the contactless insertion in top of magnet (72).

A kind of vertical axial suspension bearing structure the most according to claim 1 and 2, It is characterized in that described transverse annular guide rail (9) includes being arranged on circle (61) under transverse annular Lower annular guide rail groove (91) and be arranged in transverse annular circle of the horizontally set on end face (62) upper annular guide rail groove (92) of the horizontally set on, described lower annular guided way Road groove (91) separates with upper annular guide rail groove (92) and is oppositely arranged, described spacing rolling Pearl (10) one end is supported by lower annular guide rail groove (91), described spacing ball (10) The other end extend in annular guide rail groove (92), described upper annular guide rail groove (92) Groove width identical with the cross-sectional width of spacing ball (10), described transverse annular guide rail (9) Axial direction be provided with permission spacing ball (10) levitation gap in axial sliding.

A kind of vertical axial suspension bearing structure the most according to claim 4, its feature It is that described ball (10) is spherosome, the cross section of described lower annular guide rail groove (91) For semicircle close-fitting with spherosome, described upper annular guide rail groove (92) bottom land sets There is described levitation gap.

A kind of vertical axial suspension bearing structure the most according to claim 4, its feature Be described ball (10) be cross section be run-track shaped column, described lower annular guided way The cross section of road groove (91) is close-fitting with ball (10) lower end half run-track shaped, described Upper annular guide rail groove (92) is also half run-track shaped, described upper annular guide rail groove (92) Bottom land is provided with described levitation gap.

A kind of vertical axial suspension bearing structure the most according to claim 1 and 2, its It is characterised by that described radial positioning device (8) includes being arranged on circle (62) in described transverse annular On circular orientation cylinder (81), described circular orientation cylinder (81) is enclosed within transverse annular circle (61) Outside, encloses under described circular orientation cylinder (81) inwall and transverse annular between the outer wall of (61) Forming annular gap (100), described transverse annular guide rail (9) includes being arranged on described Outer ring guide rail groove (93) of the horizontally set on circular orientation cylinder (81) inwall, institute State outer ring guide rail groove (93) built with described spacing ball (10), described outer ring Guide rail groove (93) closely cooperates with the outer end of spacing ball (10), described spacing ball (10) closely cooperate with the outer wall of circle (61) under transverse annular.

A kind of vertical axial suspension bearing structure the most according to claim 2, its feature It is that described upper circle toroidal magnet (71) includes to be fixed in transverse annular on circle (62) Upper circle magnet mounting ring (711), described upper circle magnet mounting ring (711) is provided with and laterally sets The annular mounting groove put, be fixed with in annular mounting groove be spaced apart inner magnet group (712, 713), the radius of described inner magnet group (712) is less than the radius of outer magnet group (713), institute State and formed for described T-shaped lower ring shape magnet (72) between inner magnet group (712,713) The first annular groove (200) inserted；Described magnet group includes and is fixedly connected on one from top to bottom Upper circle internal magnetic ring (7121), upper circle magnetism-isolating loop (7122) and the upper circle outer magnetic ring (7123) risen, Described upper circle internal magnetic ring (7121) is fixedly installed in magnet mounting ring (711)；On described Circle internal magnetic ring (7121), upper circle outer magnetic ring (7123) are all permanent magnets, and their magnetic exists The most contrary；The magnetic enclosing outer magnetic ring (7123) on two is the most identical, on two The magnetic of circle internal magnetic ring (7121) is the most identical.

A kind of vertical axial suspension bearing structure the most according to claim 2, its feature It is that described lower ring shape magnet (72) includes and is fixedly connected sequentially together from top to bottom Lower circle magnet mounting ring (721), lower circle internal magnetic ring (722), lower circle magnetism-isolating loop (723) and Lower circle outer magnetic ring (724)；Described lower circle magnet mounting ring (721) is fixed on described lateral loops Enclosing on (61) under shape, lower circle magnet mounting ring (721) is as lower ring shape magnet (72) Horizontal edge, described lower circle magnet mounting ring (721) and lower circle magnetism-isolating loop (723) are non-magnetic Body；Described lower circle internal magnetic ring (722), lower circle magnetism-isolating loop (723) they are permanent magnets, they Magnetic is the most contrary；Described lower circle internal magnetic ring (722), lower circle magnetism-isolating loop (723) and Lower circle outer magnetic ring (724) constitutes the vertical edge of lower ring shape magnet (72), described lower ring The lower circle internal magnetic ring (722) of shape magnet (72) is upper with described upper circle toroidal magnet (71) The magnetic of circle outer magnetic ring (7123) is the most contrary；Described lower ring shape magnet (72) Lower circle outer magnetic ring (724) and the lower circle outer magnetic ring (7123) of described upper circle toroidal magnet (71) Magnetic the most identical.

A kind of vertical axial suspension bearing structure the most according to claim 3, its feature Being that described magnetic levitation system (7) is multiple, the radius of multiple magnetic levitation systems (7) is different, They concentrics are arranged.