TWM517627U - Multifunctional vibration exercise machine - Google Patents

Description

Multifunctional vibration exercise machine

This creative department is about the technical field of fitness equipment, especially the multi-function vibrating machine that can provide upper and lower amplitude and left and right yaw amplitude respectively.

According to the conventional vibration exercise machine, in addition to providing active exercise for the user, passive fitness can also be performed, which is very popular among users.

However, the vibration mode and the amplitude of the vibration machine are fixed. If you need to use a different vibration mode or the size of the exercise machine, the user must purchase another different vibration shape and amplitude. The fitness machine causes the user to have problems in purchasing, repairing, and storing. Therefore, there is currently an amplitude fitness machine on the market, which is adjusted by mechanical means, but the fitness machine must be stopped before adjustment, and the amplitude can be adjusted. After the adjustment, the fitness machine is restarted. Exercise and fitness with different amplitudes. However, this method of first stopping the machine and then adjusting the amplitude not only causes inconvenience in operation, but also adjusts the mode after the machine stop, which will make the process of exercise and fitness incoherent, which may easily lead to a decrease in the user's fitness intention.

In addition, the so-called upper and lower vibrations of the upper and lower vibrating exercise machines are not really vertical up and down, but the upper and lower vibrating movements are performed on the track of the runway circle.

In view of the above problems and shortcomings of the prior art, one of the purposes of the present invention is that through the design of the structure, the upper and lower amplitude rhythms and the left and right amplitude rhythms can be generated by a single model.

In order to achieve the above object, the present invention proposes a multifunctional vibration exercise machine comprising a base, a first and second eccentric transmission group, a first and second sensing unit, a first and second power unit, and a lift mechanism. The first and second eccentric transmission groups are pivoted on the base and driven by the first and second power groups to form a preset rhythm of the lifting mechanism of the first and second eccentric transmission groups and the base. The first and second eccentric transmission units are sensed by the first and second sensing units, and the output of the first and second power groups is adjusted in time to change the rhythm shape of the lifting mechanism, which is vertical and upper and lower rhythm, and Or the movement of the left and right swings, in response to the needs of users of different users, and can achieve the purpose of immediate adjustment.

1‧‧‧Base

21‧‧‧First eccentric drive set

211‧‧‧First drive shaft

212‧‧‧First Passive Wheel

213, 214‧‧‧ first eccentric axle

215, 216‧‧‧ first pivot seat

22‧‧‧Second eccentric drive set

221‧‧‧second drive shaft

222‧‧‧second passive wheel

223, 224‧‧‧Second eccentric axle

225, 226‧‧‧ second pivot seat

31‧‧‧First sensing unit

311‧‧‧The first empty plate

312‧‧‧First sensor

32‧‧‧Second sensing unit

321‧‧‧Second empty plate

322‧‧‧Second sensor

41‧‧‧First Power Group

411‧‧‧First motor

412‧‧‧First reduction wheel

413, 414‧‧‧ belt

42‧‧‧Second Power Group

421‧‧‧second motor

422‧‧‧Second reducer

423, 424‧‧‧ belt

5‧‧‧ Lifting institutions

51‧‧‧ platform

52‧‧‧First restraint rod

53‧‧‧second restraint rod

Figure 1 is a schematic diagram of an embodiment of a multi-functional vibrating exercise machine.

Fig. 2 is an exploded perspective view of the embodiment shown in Fig. 1.

Fig. 3 is a schematic exploded view of a portion of the embodiment shown in Fig. 2.

Fig. 4 is a schematic exploded view of a part of the embodiment shown in Fig. 3.

Figure 5 is a schematic diagram of the operation of the multi-functional vibrating exercise machine (1).

Figure 6 is a schematic diagram of the active cross-section of the multi-functional vibrating motion machine (2).

Figure 7 is a schematic diagram of the operation of the multi-functional vibrating exercise machine (3).

Figure 8 is a schematic diagram of the active cross-section of the multi-functional vibrating motion machine (4).

Figure 9 is a schematic diagram of the active cross-section of the multi-functional vibrating motion machine (5).

Figure 10 is a schematic diagram of the active cross-section of the multi-functional vibrating motion machine (6).

Hereinafter, the embodiment of the present multifunctional vibration machine will be further described with reference to the related drawings. In order to facilitate the understanding of the present embodiment, the same parts are denoted by the same symbols.

Referring to Figures 1 to 4, the multifunctional vibration exercise machine includes a base 1, a first and second eccentric transmission sets 21, 22, a first and second sensing units 31, 32, and a first First and second power groups 41, 42 and one lift mechanism 5. The first and second eccentric transmission groups 21 and 22 are pivotally mounted on the base 1 and are driven by the first and second power groups 41 and 42 to cause the lifting mechanism 5 to form a predetermined rhythm to match the first and second senses. The measuring units 31, 32 sense the first and second eccentric transmission groups 21, 22 to adjust the first and second power groups 41, 42 to change the rhythmic motion of the lifting mechanism 5 to the upper and lower amplitudes or the left and right yaws. In response to the needs of users of different users.

The base 1 is disposed on a support surface (for example, the ground).

The first and second eccentric transmission sets 21, 22 include a first and second transmission shafts 211, 221, a first and second passive wheels 212, 222, a plurality of first, (b) eccentric axles 213, 214, (223 224), plural first, (b) pivot seats 215, 216, (225, 226).

The first and second pivotal seats 215, 216, and (225, 226) are respectively fixed on the two sides of the base 1, and the two ends of the first and second transmission shafts 211 and 221 are pivotally connected.

The first and second eccentric axles 213, 214, (223, 224) and the first and second passive wheels 212, 222 are coaxially connected in series with the first and second transmission shafts 211 and 221, respectively.

The first and second sensing units 31 and 32 include a first and second stencils 311 and 321 and a first and second sensors 312 and 322.

The first and second hollow disks 311 and 321 have a slightly half-shaped circular shape and are respectively fixed on one side of the corresponding first and second passive wheels 212 and 222, and are coupled to the first and second passive wheels 212 and 222, respectively. The same move.

The first and second sensors 312 and 322 are respectively arranged corresponding to the rotation paths of the first and second open disks 311 and 321; and are triggered by the first and second open disks 311 and 321 respectively, and output the first and second senses respectively. Test signal. The first and second sensing signals may include time and number of times, thereby converting the rotational speeds of the first and second passive wheels 212, 222 and the current phase angle.

The first and second power groups 41 and 42 include a first and second motors 411 and 412, a first and second reduction wheels 412 and 422, and a plurality of belts 413 and 414. 423, 424.

The first and second motors 411 and 421 are selected from (including but not limited to) induction motors, servo motors, and the like.

The first and second reduction wheels 412 and 422 are pivotally disposed on the base 1 , and the belts 413 , 414 , 423 , and 424 are respectively coupled to the first and second motors 411 and 421 and the first and second passive wheels 412 and 422 . connection. The first and second eccentric transmission groups 21, 22 are driven by transmitting the power of the first and second motors 411, 421, respectively. In the implementation, the first and second sensing units 31, 32 and the first and second power groups 41, 42 can be electrically connected to a controller (not shown), and the first and second sensing signals are adjusted first, The rotational speeds of the two motors 411, 421 form a synchronization or a phase difference.

The lifting mechanism 5 includes a platform 51 and a first and second restraining rods 52 and 53.

The platform 51 is pivotally connected to the left and right ends of the lower end surface, and is respectively connected to the top ends of the first and second eccentric axles 213, 214 and (223, 224).

The first ends of the first and second restraining rods 52, 53 are pivotally connected to the top end surface of the same side of the base 1, and the other end is pivotally connected to the lower end surface of the platform 51, and is restrained by the first and second restraining rods 52, 53. The range of motion of the platform 51.

Therefore, the above is a description of the components and assembly methods of the multi-functional vibrating exercise machine according to a preferred embodiment of the present invention. The actuation characteristics of the embodiment of the present invention are described below.

First, when the first and second motors 411, 421 drive the first and second eccentric transmission groups 21, 22, the first and second passive wheels 412, 422, 1. (2) The eccentric axles 213, 214, (223, 224) rotate synchronously.

When the first and (2) eccentric axles 213, 214, (223, 224) rotate, the vertical pivoting platform 51 is synchronously pulled to generate vertical upper and lower rhythms (limited by the first and second restraining rods 52, 53). The constraint is such that it cannot move horizontally to the left and right. The user is provided to sit on the platform 51, selectively perform vertical and up-and-down rhythmic movements, or move left and right.

<The platform is synchronized with the upper and lower rhythm>

As shown in FIGS. 5 to 7, when the first and second power groups 41, 42 drive the first and second eccentric transmission groups 21, 22 and the first and second stencils 311, 321 are rotated, the first and second sensing are performed. The 312, 322 are triggered by the first and second open disks 311, 321; if the time and phase angle are the same, the first and second eccentric axles 213, 214, (223, 224) of the coaxial pivoting are synchronized. The platform 51 is pushed down to allow the platform 51 to form an up and down rhythm. Further, by adjusting the rotational speeds of the outputs of the first and second motors 411 and 421, the frequency of the upper and lower rhythms of the platform 51 can be adjusted.

<The two ends of the platform are not synchronized, the lower rhythm>

As shown in FIGS. 8 to 10, when the first and second power groups 41, 42 drive the first and second eccentric transmission groups 21, 22 and the first and second stencils 311, 321 are rotated, the first and second sensing are performed. The 312, 322 are triggered by the first and second open disks 311, 321; if one of the time or phase angles is different, the first and second eccentric axles 213, 214, (223, 224) are coaxially pivoted, It is impossible to synchronize the up and down push platform 51, so that the platform 51 presents the upper and lower rhythms of the left and right ends that are not synchronized. Cheng (or the movement of the left and right pendulum). Further, by adjusting the rotational speeds of the first and second motors 411 and 421 and the relative phase angle difference, the magnitude and speed of the amplitude of the left and right ends of the platform 51 and the upper and lower rhythm (overpass) can be adjusted.

The above description is only for the preferred embodiment of the present invention, and is intended to clarify the features of the present invention, and is not intended to limit the scope of the present embodiment, and the average variation made by those skilled in the art according to the present creation. Changes that are well known to those skilled in the art, and still fall within the scope of this creation.

1‧‧‧Base

21‧‧‧First eccentric drive set

22‧‧‧Second eccentric drive set

41‧‧‧First Power Group

42‧‧‧Second Power Group

5‧‧‧ Lifting institutions

51‧‧‧ platform

52‧‧‧First restraint rod

53‧‧‧second restraint rod

Claims (2)

A multi-functional vibrating exercise machine comprising: a base; a first power unit comprising at least one first motor disposed on the base; and a second power unit having at least one disposed on the base a first eccentric transmission set includes a first transmission shaft, a first driven wheel, and a plurality of first eccentric shafts; the first transmission shaft is pivotally disposed at the base, and the first The moving wheel and each of the first eccentric axles are fixed to the outer periphery of the first transmission shaft, and the first driven wheel is further connected to the first power group by the driving; a second eccentric transmission group is matched with the first An eccentric transmission set symmetrically disposed on the base, including a second transmission shaft, a second driven wheel, and a plurality of second eccentric shafts; the second transmission shaft is pivotally disposed at the base and the second The movable wheel and each of the second eccentric axles are fixed to the outer periphery of the second transmission shaft, and the second passive wheel is further connected to the second power unit by the driving; a first sensing unit includes a first a hollow disk and a first sensor; the first hollow disk is fixed to the first passive wheel; The first sensor is disposed corresponding to the first hollow disk rotation path and is triggered by the first hollow disk; a second sensing unit includes a second hollow disk and a second sensor; the second hollow The disk is fixed to the second passive wheel; the second sensor is disposed corresponding to the second hollow disk rotation path, and is triggered by the second hollow disk; The lifting mechanism includes a platform, a first restraining rod, and a second restraining rod; the left and right ends of the platform facing the lower end surface are respectively pivotally connected to the first and each of the second eccentric shaft ends; The first end and the second end of the second restraining rod are pivotally connected to the top end surface of the same side of the base, and the other end is pivotally connected to the lower end surface of the platform; wherein the first and the second motor drive the first end The second passive wheel adjusts the phase angles of the first and second passive wheels to be synchronized or different, so that the platform generates synchronous upper and lower amplitudes or different left and right ends. Lower amplitude. The multi-functional vibrating exercise machine of claim 1, wherein the first eccentric transmission group further comprises a plurality of first pivot seats, each of the first pivot seats being symmetrically fixed to the base The second eccentric transmission group further includes a plurality of second pivot seats, each of the second pivot seats being symmetrically fixed to the base, respectively. Providing a corresponding pivotal connection at both ends of the second transmission shaft.