CN116999286A - Vertical rhythm device - Google Patents

Abstract

The invention relates to a vertical rhythm device, comprising: the vertical rhythm device comprises a rhythm body, a driving mechanism, a linear moving mechanism and a swinging mechanism, wherein the rhythm body is provided with a supporting seat and a rhythm platform, a moving part of the linear moving mechanism can carry out reciprocating rectilinear motion along a moving track of the linear moving mechanism through the driving mechanism, the swinging mechanism is provided with a swinging rod and a switching component, the swinging rod is connected with the rhythm platform and pivoted with the supporting seat, in addition, the switching component is connected between the swinging rod and the moving part and can convert the reciprocating rectilinear motion of the moving part into reciprocating swinging motion to drive the swinging rod to swing, and the rhythm platform can swing relative to the supporting seat through the swinging rod.

Description

Vertical rhythm device

Technical Field

The invention relates to a vertical rhythm device for exercise and fitness, in particular to a vertical rhythm device capable of supporting a heavy weight, and even the vertical rhythm device can reduce the power loss of swinging a rhythm platform.

Background

Because modern life is nervous and busy, modern people have unbalanced diet due to insufficient vegetable and fruit intake, even modern people do not have too much time to exercise and body-building, and further modern people have a trend of gradual younger of cardiovascular diseases, however, most modern people can choose to exercise (such as walk, jogging, swimming or riding a bicycle) simply and simply without taking time in order to keep healthy.

In order to facilitate the exercise and fitness of modern people in indoor space, a plurality of exercise devices capable of being placed in the indoor are further available in the market, an existing exercise device assisting the modern people in exercise is available in the market, the existing exercise device is provided with an exercise support seat, an exercise platform and an eccentric vibration motor, wherein the exercise platform covers the exercise support seat, the eccentric vibration motor is connected between the exercise support seat and the exercise platform, and the eccentric vibration motor can drive the exercise platform to swing relative to the exercise support seat, when the existing exercise device is applied, a user stands on the exercise platform, and then the user controls the vibration size of the eccentric vibration motor through a controller, so that the eccentric vibration motor drives the body of the user to vibrate through the exercise platform, and the exercise effect is achieved.

However, although the conventional pulsator can achieve the exercise effect on the user, because of the connection relationship between the pulsator platform and the eccentric vibration motor, the eccentric vibration motor can only drive the pulsator platform to swing with a single axis, and thus the conventional pulsator only has a swing mode of up-and-down reciprocating swing, so that the exercise effect achieved by the user using the conventional pulsator is limited, and in addition, the structural aspect of the conventional pulsator does not carry heavy users, and thus not all users are suitable for exercise using the conventional pulsator.

Disclosure of Invention

The invention aims to provide a vertical rhythm device with an improved structure, so that the improved rhythm device can support heavier weight, and users with various postures can use the improved rhythm device to exercise and build body.

A secondary object of the present invention is to provide a vertical rhythm device with improved connection between a driving mechanism and a rhythm platform, so that power loss transmitted from the driving mechanism to the rhythm platform can be minimized in the process of driving the rhythm platform to swing by the driving mechanism.

To achieve the above object, the present invention provides a vertical pulsator, which is mainly composed of a pulsator body, a linear movement mechanism, a driving mechanism, and a swinging mechanism.

The device comprises a support seat body and a rhythm platform capable of moving relative to the support seat body, wherein the support seat body is provided with a seat body connecting part, the rhythm platform is provided with a platform connecting part, and the linear moving mechanism is provided with a moving track connected with the support seat body and a moving piece movably connected with the moving track.

In addition, the driving mechanism can drive the moving part to reciprocate along the moving track, wherein the swinging mechanism is provided with a swinging rod capable of swinging and a switching component connected between the swinging rod and the moving part, the swinging rod is pivoted to the seat body connecting part and assembled to the platform connecting part, and the switching component can convert the reciprocating rectilinear motion of the moving part into reciprocating swinging motion to drive the swinging rod to swing, so that the shaking platform can swing relative to the supporting seat body through the swinging rod.

The switching assembly is provided with a switching connecting rod connected with the moving piece and a switching swinging piece connected with the swinging rod, and the switching connecting rod is movably connected with the switching swinging piece, so that the relative position between the switching connecting rod and the switching swinging piece can be changed at any time when the moving piece moves.

In a preferred embodiment, the switching link is provided with a first link portion and a second link portion at different positions, where the first link portion and the second link portion are respectively pivoted to the moving member and the switching swing member, so that the switching link is driven by the moving member to swing relative to the moving member, and further the height difference between the first link portion and the second link portion can be increased or decreased.

In another preferred embodiment, a guide rail and a guide projection penetrating into the guide rail are provided between the switching link and the switching ornament, and the guide projection can move inside the guide rail when the relative position relationship between the switching link and the switching ornament is changed.

In the foregoing two embodiments, the linear movement mechanism further has an auxiliary moving member capable of moving along the movement track by the driving mechanism, and the vertical metro further has an auxiliary swinging mechanism arranged at intervals on the swinging mechanism, the auxiliary swinging mechanism has an auxiliary swinging rod pivoted to the supporting base and an auxiliary switching assembly connected between the auxiliary swinging rod and the auxiliary moving member, the auxiliary swinging rod is connected to the metro platform, and the auxiliary switching assembly can convert the reciprocating linear motion of the auxiliary moving member into a reciprocating swinging motion to drive the auxiliary swinging rod to swing, so that the metro platform can swing relative to the supporting base by the swinging rod and the auxiliary swinging rod.

The linear moving mechanism is further provided with a synchronizing rod which is connected with the moving piece and the auxiliary moving piece at the same time, so that the moving piece and the auxiliary moving piece can synchronously move along the moving track, wherein the swinging rods are arranged in parallel on the auxiliary swinging rods, and the swinging rods and the auxiliary swinging rods are vertically arranged on the moving track.

Furthermore, the platform connecting part is provided with a first platform base arranged on the rhythm platform and a second platform base arranged on the swinging rod, the first platform base is pivoted with the second platform base, wherein the base connecting part is provided with a base connecting hole for the swinging rod to pass through, the platform connecting part is provided with a platform connecting hole for the swinging rod to pass through, and the base connecting holes are coaxially arranged in the platform connecting hole.

The invention is characterized in that the vertical rhythm device mainly comprises a rhythm body, a linear moving mechanism, a driving mechanism and a swinging mechanism, so that the vertical rhythm device can support heavier weight, and users in various states can use the vertical rhythm device to exercise and build body.

In addition, a linear moving mechanism and a swinging mechanism are arranged between the rhythm body and the driving mechanism, wherein a moving part of the linear moving mechanism can carry out reciprocating linear motion along a moving track of the linear moving mechanism, and a switching component of the swinging mechanism can convert the reciprocating linear motion of the moving part into reciprocating swinging motion to drive a rhythm platform of the rhythm body to swing, so that in the process that the driving mechanism drives the rhythm platform to swing, the power loss transmitted to the rhythm platform by the driving mechanism can be minimized.

Drawings

FIG. 1 is a schematic diagram of a vertical rhythm device according to a first preferred embodiment of the present invention;

FIG. 2 is an exploded view of the drive mechanism, the linear motion mechanism, the swing mechanism, and the auxiliary swing mechanism;

FIG. 3 is an exploded view of the rhythm body;

FIG. 4 is an exploded view of the drive mechanism;

FIG. 5 is a schematic view of a linear movement mechanism;

FIG. 6 is an exploded view of the swing mechanism;

FIG. 7 is an exploded view of the auxiliary swing mechanism;

FIG. 8A is a schematic view of the moving member and the auxiliary moving member moving backward simultaneously;

FIG. 8B is a schematic view of the swing lever swinging counterclockwise;

FIG. 8C is a schematic view of the auxiliary swing lever swinging counterclockwise;

FIG. 9A is a schematic view of the moving member and the auxiliary moving member moving forward simultaneously;

fig. 9B is a schematic view of the swing lever swinging clockwise;

FIG. 9C is a schematic view of the auxiliary swing lever swinging clockwise;

fig. 10 is a schematic diagram of a vertical rhythm device according to a second preferred embodiment of the present invention.

Reference numerals illustrate: 1-vertical rhythmic device; 10-rhythm body; 11-a supporting seat body; 111-a housing receptacle; 111 a-accommodating bottom plate; 111 b-receiving sidewalls; 111 c-an accommodating space; 112-a housing connection; 112 a-a base; 112 b-a housing connection hole; 113-a seat auxiliary connection; 113 a-a base auxiliary base; 113 b-a housing auxiliary connection hole; 12-rhythm platform; 121-a platform pedal; 121 a-platform foot pedal; 122-a platform connection; 122 a-a first platform base; 122 b-a second platform base; 122 c-platform connection holes; 123-a platform auxiliary connection; 123 a-a first platform auxiliary base; 123 b-a second platform auxiliary base; 123 c-auxiliary connection holes of the platform; 20-a driving mechanism; 21-a driving source; 22-a transmission assembly; 221-a drive pulley; 222-a driven pulley; 223-drive belt; a 23-conversion assembly; 231-a switch lever; 232-switching handle; 232 a-a first tang; 232 b-a second tang; 233-eccentric; 234-bearings; 30-a linear movement mechanism; 31-moving the track; 32-a moving member; 321-moving blocks; 322-moving a rod; 33-auxiliary moving parts; 331-auxiliary moving block; 332-auxiliary moving rod; 34-a synchronizing bar; 40-swinging mechanism; 41-swinging rod; 42-a switching component; 421-switching links; 421 a-a first link portion; 421 b-a second link portion; 421 c-guide tab; 422-switching the ornament; 422 a-a first swing portion; 422 b-a second swing portion; 422 c-guide tracks; 50-an auxiliary swing mechanism; 51-auxiliary swing lever; 52-an auxiliary switching component; 521-auxiliary switching links; 521 a-a first auxiliary link portion; 521 b-a second auxiliary link portion; 522-auxiliary switching ornament; 522 a-a first auxiliary oscillating piece portion; 522 b-a second auxiliary oscillating piece portion.

Detailed Description

The advantages and features of the present invention will become more apparent from the following description when taken in conjunction with the accompanying drawings and detailed description.

Referring to fig. 1, in a first preferred embodiment, a vertical rhythm device 1 of the present invention comprises: a uniform body 10, a driving mechanism 20, a linear movement mechanism 30, a swinging mechanism 40 and an auxiliary swinging mechanism 50.

Referring to fig. 1, 2 and 3, the rhythm body 10 has a supporting base 11 and a rhythm platform 12, the supporting base 11 has a base receiving portion 111 presenting a hollow shape, a base connecting portion 112 located in the base receiving portion 111 and a base auxiliary connecting portion 113 located in the base receiving portion 111, as shown in the figure, the base receiving portion 111 has a receiving bottom plate 111a connected to the base connecting portion 112 and the base auxiliary connecting portion 113 and a receiving side wall 111b extending along the Z-axis from the periphery of the receiving bottom plate 111a, the receiving bottom plate 111a and the receiving side wall 111b together form a receiving space 111c for receiving the base connecting portion 112 and the base auxiliary connecting portion 113, in addition, the base connecting portion 112 is composed of two base bases 112a arranged at intervals, and each base 112a is formed with a base connecting hole 112b parallel to the X-axis, wherein the base auxiliary connecting portion 113 is composed of two base bases 113a arranged at intervals, and each base 113a base 113b is arranged at intervals, and each base 113a base is formed at intervals.

The rhythm platform 12 of the rhythm body 10 has a platform pedal 121, a platform connection part 122 formed at the platform pedal 121 and a platform auxiliary connection part 123 formed at the platform pedal 121, as shown in the figure, the platform pedal 121 is composed of only a single platform foot pedal 121a, and the platform foot pedal 121a is arranged above the seat body accommodation part 111 of the support seat body 11 along the Z axis direction, such that the platform foot pedal 121a is located outside the accommodation space 111c of the seat body accommodation part 111, and the platform connection part 122 has two first platform bases 122a and two second platform bases 122b, each first platform base 122a is pivotally connected to one of the second platform bases 122b in one-to-one, wherein each first platform base 122a is mounted at the platform foot pedal 121a, and the second platform bases 122b are connected to the swinging mechanism 40, and each second platform base 122b is provided with a platform connection hole 122c whose axis is parallel to the X axis, wherein the platform connection hole 122c is coaxially arranged at the seat body accommodation space 111c of the seat body accommodation part 121, and each second platform base 123b is arranged at the two second platform bases 123a, and each second platform base 123b is pivotally connected to one of the two platform bases 123b, wherein each second platform base 123a is mounted at the second platform base 123a, and each second platform base 123b is connected to the swinging mechanism.

Referring to fig. 1, 2 and 4, the driving mechanism 20 is located in the accommodating space 111c of the supporting seat 11, and the driving mechanism 20 has a driving source 21, a transmission assembly 22 and a conversion assembly 23, wherein the driving source 21 can generate rotation power, and the transmission assembly 22 has a driving pulley 221 connected to the driving source 21 and a driven pulley 222 connected to the conversion assembly 23, and the driving pulley 221 is connected to the driven pulley 222 via a driving belt 223, so that the driving source 21 can drive the driving pulley 221 to rotate, and the driving pulley 221 to rotate can drive the driven pulley 222 via the driving belt 223, in addition, the conversion assembly 23 is used for converting the rotation motion rotating about the X-axis into the linear motion reciprocating along the Y-axis, in this embodiment, the conversion assembly 23 is used for converting the rotation motion of the driven pulley 222 into the reciprocating linear motion, wherein the conversion assembly 23 has a conversion lever 231 connected to the driven pulley 222 and a conversion handle 232 intersecting the conversion assembly 23, a conversion handle 232 is disposed between the conversion lever 231 and the conversion handle 232, so that the driving pulley 221 can drive the driving pulley 221 to rotate via the driving belt 223, and the driving pulley 221 can drive the driven pulley 222 to rotate via the driving belt 223, in addition, the conversion assembly 23 is used for converting the rotation motion about the X-axis into the linear motion reciprocating motion along the Y-axis, the conversion assembly 23 is used for converting the rotation motion of the driven pulley 222, and the linear motion of the reciprocating motion of the driven pulley 231, wherein the conversion lever is converted by the conversion lever 23 has a conversion lever 231 connected to the conversion lever 231 and a conversion lever 23, and a conversion handle 232 is connected to the conversion lever 231 and a conversion lever 232 are connected to the conversion lever 231 and a conversion lever 23, and a conversion handle which is connected to the conversion lever 234, and a conversion lever. While the second handle end 232b is capable of reciprocating rectilinear motion.

Referring to fig. 1, 2 and 5, the linear moving mechanism 30 is disposed in the accommodating space 111c of the supporting base 11, and the linear moving mechanism 30 has a moving track 31, a moving member 32 and an auxiliary moving member 33, wherein the moving track 31 is connected to the accommodating bottom 111a of the supporting base 11, the moving track 31 is parallel to the Y axis, the moving member 32 has a moving block 321 movably connected to the moving track 31 and a moving rod 322 connected to the moving block 321, the moving block 321 is connected to the second end 232b of the switching handle 232, such that the moving member 32 can perform a linear movement along the Y axis direction along the moving track 31 by the driving mechanism 20, the moving rod 322 is parallel to the X axis, such that the moving rod 322 is vertically aligned with the moving track 31, and the auxiliary moving member 33 has an auxiliary moving block 331 movably connected to the moving track 31 and an auxiliary moving rod 332 connected to the moving block 321, and the auxiliary moving block 331 is connected to the moving block 321 via a synchronizing rod 34, such that the moving member 32 and the auxiliary moving member 33 can perform a linear movement along the Y axis direction along the moving track 31, and the auxiliary moving rod 322 is parallel to the linear moving rod 322.

Referring to fig. 1, 2 and 6, the swinging mechanism 40 is located in the accommodating space 111c of the supporting base 11, and the swinging mechanism 40 has a swinging rod 41 and a switching component 42, wherein the swinging rod 41 is simultaneously inserted into the base connecting hole 112b of the base 112a and the platform connecting hole 122c of the second platform base 122b, so that the swinging rod 41 is parallel to the X axis, and further the swinging rod 41 is vertically arranged on the moving track 31 of the linear moving mechanism 30, and in this embodiment, the swinging rod 41 is pivoted to the base 112a of the base connecting portion 112, so that the swinging rod 41 can swing relative to the supporting base 11 of the oscillating body 10, and the swinging rod 41 is also assembled to the second platform base 122b of the platform connecting portion 122, so that the swinging rod 41 and the second platform base 122b can swing synchronously, in addition, the switching component 42 is connected between the swinging rod 41 and the moving element 32 of the linear moving mechanism 30, and the switching component 42 is used for converting the linear motion reciprocating along the Y axis into the linear motion reciprocating along the X axis into the linear motion of the reciprocating motion along the reciprocating axis, which is the axis, and the reciprocating motion of the reciprocating body 10 can reciprocate relative to the oscillating body 12, so that the swinging rod 41 can reciprocate relative to the oscillating body 10, and the oscillating body can reciprocate through the switching component 12.

In this embodiment, the switching assembly 42 of the swinging mechanism 40 has two switching links 421 and two switching pendulums 422, each switching link 421 is provided with a first link portion 421a and a second link portion 421b at different positions, as shown in the drawing, the first link portion 421a of one switching link 421 is pivotally connected to the right end of the moving rod 322 of the moving member 32, and the first link portion 421a of the other switching link 421 is pivotally connected to the left end of the moving rod 322 of the moving member 32, however, the second link portion 421b of each switching link 421 is pivotally connected to one of the switching pendulums 422 one by one, so that the switching links 421 are movably connected to the switching pendulums 422, and in addition, each switching pendulums 422 is respectively provided with a first swinging member portion 422a and a second swinging member portion 422b with a height lower than that of the first swinging member portion 422a, the first swinging member 422a is fixedly connected to the swinging rod 41 of the swinging mechanism 40, so that each switching pendulums 422 can synchronously swing with the first link portion 421b of the corresponding switching link portion 422 b.

Referring to fig. 1, 2 and 7, the auxiliary swinging mechanism 50 is located in the accommodating space 111c of the supporting seat 11, and the auxiliary swinging mechanism 50 is arranged at intervals in the Y-axis direction of the swinging mechanism 40, wherein the auxiliary swinging mechanism 50 has an auxiliary swinging rod 51 and an auxiliary switching component 52, the auxiliary swinging rod 51 is simultaneously penetrating through the seat auxiliary connecting hole 113b of the seat auxiliary base 113a and the platform auxiliary connecting hole 123c of the second platform auxiliary base 123b, so that the auxiliary swinging rod 51 is parallel to the X-axis, and further the auxiliary swinging rod 51 is parallel to the swinging rod 41 of the swinging mechanism 40, so that the auxiliary swinging rod 51 is also vertically arranged on the moving track 31 of the linear moving mechanism 30 like the swinging rod 41, in this embodiment, the auxiliary swinging rod 51 is pivoted to the seat auxiliary base 113a of the seat auxiliary connecting part 113, so that the auxiliary swinging rod 51 can swing relative to the supporting seat 11 of the oscillating body 10, and the auxiliary swinging rod 51 is assembled to the second platform auxiliary base 123b of the platform auxiliary connecting part 123, so that the auxiliary swinging rod 51 and the second platform auxiliary base 123b can move synchronously with the second platform auxiliary base 123b, and the auxiliary swinging component 33 can move linearly along the reciprocating body 12, so that the auxiliary swinging rod 51 can move linearly along the auxiliary swinging rod 33 and the auxiliary swinging component 33 can move relatively to the auxiliary swinging rod 33, and the auxiliary swinging component can move linearly along the reciprocating body 12, and the auxiliary swinging rod can move relatively to the auxiliary swinging rod 33.

In this embodiment, the auxiliary switching assembly 52 of the auxiliary swinging mechanism 50 has two auxiliary switching links 521 and two auxiliary switching pendulums 522, each auxiliary switching link 521 is provided with a first auxiliary link 521a and a second auxiliary link 521b at different positions, as shown in the drawing, the first auxiliary link 521a of one auxiliary switching link 521 is pivoted to the right end of the auxiliary moving rod 332 of the auxiliary moving member 33, and the first auxiliary link 521a of the other auxiliary switching link 521 is pivoted to the left end of the auxiliary moving rod 332 of the moving member 32, however, the second auxiliary link 521b of each auxiliary switching link 521 is pivoted to one auxiliary switching pendulum 522 one by one, so that the auxiliary switching links 521 are movably connected to the auxiliary switching pendulums 522, and in addition, each auxiliary switching pendulum 522 is provided with a first auxiliary pendulum 522a and a second auxiliary pendulum 522b with a height lower than that of the first auxiliary pendulum 522a, and each auxiliary switching link 522a first auxiliary pendulum 522a is pivoted to the other auxiliary link 522b of the auxiliary switching links 50, so that each auxiliary switching link 521b can be pivoted to each auxiliary switching link 522b of the auxiliary switching links 51.

Referring to fig. 8A, when the exercise platform 12 of the exercise body 10 is about to oscillate relative to the exercise platform 12 of the exercise body 10, the driving source 21 of the driving mechanism 20 drives the driving pulley 221 of the driving assembly 22 to rotate, and the driving pulley 221 rotates synchronously with the driven pulley 222 of the driving assembly 22 and the switching lever 231 of the switching assembly 23 via the driving belt 223 of the driving assembly 22, wherein when the switching lever 231 rotates, the axis center of the eccentric wheel 233 of the switching assembly 23 is eccentric to the switching lever 231, so that the axis center of the bearing 234 continuously rotates around the switching lever 231, and the first end 232a of the switching lever 232 reciprocates through the bearing 234, and meanwhile, the second end 232b of the switching lever 232 reciprocates in the Y-axis direction, so that the switching lever 232 can simultaneously drive the moving member 32 of the linear moving mechanism 30 and the auxiliary moving member 33 to reciprocate back and forth in the Y-axis direction along the moving track 31 of the linear moving mechanism 30.

As shown in fig. 8B, when the moving member 32 and the auxiliary moving member 33 of the moving mechanism move backward along the Y-axis direction, the second link portion 421B of the switching link 421 moves to the rear side of the swinging rod 41 of the swinging device, because the switching link 421 is pivotally connected to the switching swinging member 422 of the switching assembly 42, and during the movement of the second link portion 421B to the rear side of the swinging rod 41, the second swinging member 422B of the switching swinging member 422 swings counterclockwise around the axis of the swinging rod 41, so that the height position of the second swinging member 422B in the Z-axis direction gradually increases, and further the height difference between the first link portion 421a and the second link portion 421B gradually decreases, whereby the relative positional relationship between the switching link 421 and the switching swinging member 422 can be changed at any time by the moving member 32, wherein when the second swinging member 422B of the switching member 422 swings counterclockwise around the axis of the swinging rod 41, the swinging rod 41 of the swinging mechanism 40 swings counterclockwise around the axis of the X-axis.

As shown in fig. 9C, during the backward movement of the auxiliary moving member 33 of the moving mechanism along the Y-axis direction, the second auxiliary link portion 521b of the auxiliary switching link 521 moves to the rear side of the auxiliary swinging rod 51 of the auxiliary swinging device, however, because the auxiliary switching link 521 is pivoted to the auxiliary switching swinging member 522 of the auxiliary switching assembly 52, the second auxiliary swinging member 522b of the auxiliary switching swinging member 522 swings counterclockwise around the axis of the auxiliary swinging rod 41, so that the height position of the second auxiliary swinging member 522b in the Z-axis direction gradually increases, and the height difference between the first auxiliary link portion 521a and the second auxiliary link portion 521b gradually decreases, so that the relative position relationship between the auxiliary switching link 521 and the auxiliary switching swinging member 522 can be changed at any time by the auxiliary moving member 33, wherein when the second auxiliary swinging member 522b of the auxiliary switching member 522 swings counterclockwise around the axis of the auxiliary swinging member 41, the auxiliary swinging rod 51 of the auxiliary swinging mechanism 50 swings counterclockwise around the axis of the auxiliary swinging member 41, so that the body 10 swings counterclockwise through the switching member 40 and the support body 10 swings around the axis of the auxiliary swinging member 41 by means of the switching member 40, and the body 10 swings counterclockwise, and the body 10 swings around the axis of the body 10 b, and the body 10 swings around the axis of the auxiliary swinging member 41.

Referring to fig. 9A, 9B and 9C, when both the moving member 32 and the auxiliary moving member 33 of the moving mechanism move forward from the rear side of the swing lever 41 in the Y-axis direction, the second swing part 422b of the switching swing piece 422 swings clockwise around the axis of the swing lever 41, so that the height position of the second swing part 422b in the Z-axis direction gradually decreases, further, the difference in height between the first and second link portions 421a and 421b gradually increases, wherein, when the second swinging part 422b of the switching swinging part 422 swings clockwise around the axis of the swinging rod 41, the swing lever 41 of the swing mechanism 40 swings clockwise around the X-axis, at the same time, the second auxiliary swing piece portion 522b of the auxiliary switching swing piece 522 swings clockwise around the axis of the auxiliary swing lever 41, so that the auxiliary swing lever 51 of the auxiliary swing mechanism 50 swings clockwise around the X-axis in synchronization with the swing lever 41, and in this embodiment, during the clockwise swinging of the second auxiliary swinging member 522b around the axis of the auxiliary swinging rod 41, the height position of the second auxiliary swinging member 522b in the Z-axis direction is also gradually reduced, further, the difference in height between the first auxiliary link portion 521a and the second auxiliary link portion 521b is gradually increased, whereby, when the moving member 32 can drive the swing lever 41 of the swing mechanism 40 to swing clockwise about the X-axis through the switching unit 42 and the auxiliary moving member 33 can drive the auxiliary swing lever 51 of the auxiliary swing mechanism 50 to swing clockwise about the X-axis through the auxiliary switching unit 52, so that the rhythm platform 12 of the rhythm body 10 can swing upward relative to the support base 11 of the rhythm body 10 through the swing lever 41.

Referring to fig. 10, in the second preferred embodiment, the difference is that the switching member 42 of the oscillating mechanism 40 has the same structure as that of the first preferred embodiment, and further, in this embodiment, the structure of the oscillating body 10, the linear motion mechanism 30, the driving mechanism 20 and the auxiliary oscillating mechanism 50 will not be repeated, the switching link 421 of the switching member 42 is provided with a guiding protrusion 421c, and the switching member 422 of the switching member 42 is provided with a guiding track 422c penetrating into the guiding protrusion 421 c.

As shown in fig. 10, when the driving mechanism 20 drives the moving piece 32 of the linear moving mechanism 30 to reciprocate linearly along the Y-axis direction, the relative positional relationship between the switching link 421 and the switching piece 422 can be changed by the moving piece 32 reciprocating linearly, so that the guide projection 421c can move inside the guide rail 422c.

The above description is illustrative of the invention and is not to be construed as limiting, and it will be understood by those skilled in the art that many modifications, variations or equivalents may be made without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (10)

1. A vertical rhythm device, characterized by comprising,

the device comprises a rhythm body, a support base and a control device, wherein the rhythm body is provided with a support base and a rhythm platform capable of moving relative to the support base, the support base is provided with a base connecting part, and the rhythm platform is provided with a platform connecting part;

the linear moving mechanism is provided with a moving track connected with the supporting seat body and a moving piece movably connected with the moving track;

the driving mechanism can drive the moving piece to perform reciprocating linear motion along the moving track; and

the swinging mechanism is provided with a swinging rod capable of swinging and a switching component connected between the swinging rod and the moving part, the swinging rod is pivoted to the seat body connecting part and assembled to the platform connecting part, and the switching component can convert the reciprocating linear motion of the moving part into reciprocating swinging motion to drive the swinging rod to swing, so that the rhythm platform can swing relative to the supporting seat body through the swinging rod.

2. The vertical rhythm of claim 1 wherein: the switching component is provided with a switching connecting rod connected with the moving part and a switching swinging part connected with the swinging rod, and the switching connecting rod is movably connected with the switching swinging part, so that the relative position between the switching connecting rod and the switching swinging part can be changed at any time when the moving part moves.

3. The vertical rhythm of claim 2 wherein: the switching connecting rod is provided with a first connecting rod part and a second connecting rod part at different positions, and the first connecting rod part and the second connecting rod part are respectively pivoted with the moving part and the switching swinging part, so that the switching rod piece is driven by the moving part to swing relative to the moving part, and the height difference between the first connecting rod part and the second connecting rod part can be increased or decreased.

4. The vertical rhythm of claim 2 wherein: the switching ornament is provided with a first ornament part fixed on the swinging rod and a second ornament part movably connected with the switching connecting rod, and the height position of the first ornament part is different from that of the second ornament part.

5. The vertical rhythm of claim 2 wherein: a guide track and a guide lug penetrating into the guide track are arranged between the switching connecting rod and the switching ornament, and the guide lug can move in the guide rail when the relative position relationship between the switching connecting rod and the switching ornament is changed.

6. The vertical rhythm of claim 1 wherein: the platform connecting part is provided with a first platform base arranged on the rhythm platform and a second platform base arranged on the swinging rod, and the first platform base is pivoted with the second platform base.

7. The vertical rhythm of claim 1 wherein: the seat body connecting part is provided with a seat body connecting hole for the swing rod to pass through, the platform connecting part is provided with a platform connecting hole for the swing rod to pass through, and the seat body connecting holes are coaxially arranged in the platform connecting hole.

8. The vertical rhythm of claim 1 wherein: the linear moving mechanism is also provided with an auxiliary moving part which can move along the moving track through the driving mechanism, the vertical rhythm device is also provided with an auxiliary swinging mechanism which is arranged at intervals on the swinging mechanism, the auxiliary swinging mechanism is provided with an auxiliary swinging rod which is pivoted on the supporting seat body and an auxiliary switching component which is connected between the auxiliary swinging rod and the auxiliary moving part, the auxiliary swinging rod is connected with the rhythm platform, and the auxiliary switching component can convert the reciprocating linear motion of the auxiliary moving part into reciprocating swinging motion to drive the auxiliary swinging rod to swing, so that the rhythm platform can swing relative to the supporting seat body through the swinging rod and the auxiliary swinging rod.

9. The vertical rhythm of claim 8 wherein: the linear moving mechanism is also provided with a synchronizing rod which is simultaneously connected with the moving piece and the auxiliary moving piece, so that the moving piece and the auxiliary moving piece can synchronously move along the moving track.

10. The vertical rhythm of claim 8 wherein: the swing bars are arranged in parallel to the auxiliary swing bars, and both the swing bars and the auxiliary swing bars are arranged vertically to the moving track.