JP3239083U - vibration machine - Google Patents

Abstract

An object of the present invention is to provide a vibrating machine that generates a vibration pattern suitable for human movement and has an excellent exercise effect. A vibration mechanism (1), a drive mechanism (2), a direction-changing connecting rod mechanism (3), and a synchronous direction-changing connecting rod mechanism (4) are provided. Rotational motion is converted into laterally reciprocating motion, said laterally reciprocating motion is further converted into longitudinally reciprocating motion, and said synchronous redirecting connecting rod mechanism is connected to said redirecting connecting rod mechanism, thereby said redirecting coupling A vibration machine 100 that outputs synchronous vertical reciprocating motion in synchronization with a rod mechanism, and vibrates in the vertical direction due to the vertical reciprocating motion and the synchronous vertical reciprocating motion. [Selection drawing] Fig. 2

Description

The present invention relates to a vibrating machine, and more particularly to a longitudinally vibrating vibrating machine.

A Vibration Exercise Machine is a type of fitness equipment that can actively generate up and down longitudinal vibrations according to specified frequencies and amplitudes. By riding on the vibrating machine, the user can move the whole body in rhythm and obtain exercise effects.

Generally speaking, the main structure of the vibration machine includes a motor and a connecting rod group, the connecting rod group is driven by the motor so that the connecting rod group further reciprocates longitudinally on the platform on which the user stands. to drive. Therefore, the vibration pattern of the vibrating machine is determined by the design of the connecting rod group. That is, the quality of the longitudinal vertical vibration produced by the vibrating machine and the kinetic effect of the vibrating machine depend on the design of the connecting rod group. Therefore, it is an important task to improve the design of the connecting rod group of the vibrating machine below to provide a vibrating pattern suitable for human movement.

SUMMARY OF THE INVENTION Therefore, it is an object of the present invention to provide a vibrating machine that can solve the problems of the prior art.

In order to solve the technical problems of the prior art, the present invention comprises: a vibrating mechanism including a base and a vibrating plate located on the base; a driving mechanism installed on the base and including a motor and a drive shaft; A vibrating machine comprising: a redirecting connecting rod mechanism including a conducting connecting rod and a redirecting rod; and a synchronous redirecting connecting rod mechanism including a synchronous connecting rod and a synchronous redirecting rod, wherein the drive shaft comprises the connected to a motor, driven by the motor to rotate about a horizontal axis, the inner end of the transmission connecting rod being eccentrically connected to the drive shaft to the drive shaft, and with the rotation of the drive shaft, the The outer ends of the transmission connecting rods perform lateral reciprocating motion to and from the drive shaft, the diverting rods perform rocking oscillations about a fixed axis, and the driving ends of the diverting rods move toward and away from the drive shafts. Connected to the outer ends of the conducting connecting rods, the passive ends of the redirecting rods are connected to the vibrating plate such that the laterally reciprocating motion of the conducting connecting rods is converted into longitudinally reciprocating motion to the vibrating plate. the synchronous connecting rod includes an output end and an input end, the input end of the synchronous connecting rod is synchronized with the input end of the synchronous connecting rod and the output end of the synchronous connecting rod is synchronized with the input end of the synchronous connecting rod; is connected to the outer end of the conducting connecting rod so as to perform the synchronous connecting rod, the synchronous redirecting rod is installed to perform rocking oscillation about a fixed axis, and the driving end of the synchronous redirecting rod is connected to the synchronous coupling; The synchronous lateral reciprocating motion of the synchronous connecting rod is converted into a synchronous longitudinal reciprocating motion by connecting the passive end of the synchronous redirecting rod to the vibrating plate, and the output end of the rod is connected to the vibrating plate. said synchronous longitudinal reciprocating motion to said longitudinal reciprocating motion of said redirecting rod such that said longitudinal reciprocating motion and said synchronous longitudinal reciprocating motion move said vibrating plate to vibrate longitudinally with respect to said base. To provide a vibrating machine characterized by being synchronized with a reciprocating orienting motion.

One embodiment of the present invention provides a vibrating machine, wherein the vibrating plate is a cover, the base is a sink, and the cover covers the top of the sink and the upper part of the outer peripheral wall of the sink.

One embodiment of the present invention provides a vibration machine, wherein the output shaft of the motor and the drive shaft are arranged parallel to each other.

An embodiment of the present invention provides a vibrating machine in which the outer end of the transmission connecting rod, the driving end of the turning rod and the input end of the synchronizing connecting rod are connected side by side on the same rotation axis.

In one embodiment of the present invention, the vibrating machine includes two direction-changing connecting rod mechanisms and two synchronous direction-changing connecting rod mechanisms; A vibrating machine arranged in parallel before and after the synchronous direction-changing connecting rod mechanism, and in which the vertical reciprocating motion of the two synchronous direction-changing connecting rod mechanisms is synchronized with the vertical reciprocating motion of the two synchronous direction-changing connecting rod mechanisms. offer.

In one embodiment of the present invention, the synchronous turning connecting rod mechanism further comprises a synchronous floating lever, one end of the synchronous floating lever is connected to the passive end of the synchronous turning rod, and the other end of the synchronous floating lever is By being connected to the vibrating plate, a vibrating machine is provided in which the synchronous redirecting rods are connected to the vibrating plate via the synchronous floating levers.

In one embodiment of the present invention, the redirecting connecting rod mechanism further comprises a mount, the mount is removably fastened to the vibrating plate, and the passive end of the redirecting rod is connected to the mount. connecting to the vibration plate through the mount, and the synchronous redirecting connecting rod mechanism further comprising another mount, the another mount releasably clipped to the vibration plate; A vibrating machine is provided in which the other end of the synchronous floating lever is connected to the another mounting base so as to be connected to the vibrating plate through the another mounting base.

In one embodiment of the present invention, the direction-changing rod is an L-shaped connecting rod, the fixed axis of the direction-changing rod is located at the bending corner of the L-shaped connecting rod, and the synchronous direction-changing rod is another two L-shaped connecting rods, wherein the fixed axis of the synchronous redirecting rod is located at the bend of the other L-shaped connecting rod.

In one embodiment of the invention, the drive mechanism includes a rotational speed control electrically connected to the motor and arranged to control the rotational speed of the motor, thereby controlling the vibration speed of the vibrating plate. To provide a vibrating machine further comprising a unit.

According to the technical means of the present invention, the vibration machine of the present invention is such that the transmission connecting rod converts the rotary motion of the motor into lateral reciprocating motion through eccentric connection to the drive shaft, and the transmission Lateral reciprocating motion of the connecting rod is further converted into vertical reciprocating motion and transmitted to the vibrating plate. In addition, the vibration machine of the present invention synchronously performs synchronous lateral reciprocating motion by the synchronous connecting rod connected to the transmission connecting rod, and synchronously performs the synchronous lateral reciprocating motion by the synchronous direction changing rod. and conduct to the vibrating plate synchronously with the vertical reciprocating motion. As a result, the vibration plate is simultaneously driven by the vertical reciprocating motion and the synchronous vertical reciprocating motion and moves vertically with respect to the base, so that the vibration plate provides the user with vertical vibrations for movement. achieve the effect.

1 is a three-dimensional view of a vibrating machine according to one embodiment of the present invention; FIG. 1 is an exploded view of a vibrating machine according to one embodiment of the present invention; FIG. 1 is a bird's-eye view showing the internal structure of a vibrating machine according to one embodiment of the present invention; FIG. 1 is a cross-sectional view of the vibrating machine of one embodiment of the present invention in operation; FIG. 1 is a cross-sectional view of the vibrating machine of one embodiment of the present invention in operation; FIG.

An embodiment of the present invention will be described below with reference to FIGS. 1 to 5. FIG. The description is merely an example of embodiments of the present invention, and is not intended to limit the embodiments of the present invention.

As shown in FIGS. 1 to 12316, a vibrating machine 100 according to one embodiment of the present invention includes a vibrating mechanism 1, a driving mechanism 2, a redirecting connecting rod mechanism 3 and a synchronous redirecting connecting rod mechanism 4. .

As shown in FIGS. 1 and 2, the vibrating mechanism 1 includes a base 11 and a vibrating plate 12 positioned on the base 11 . In this embodiment, the base 11 is a sink, said sink includes a bottom plate and an outer peripheral wall surrounding the bottom plate, the outer peripheral wall mainly consists of four wall panels, and the upper end of said sink forms an opening. Said vibration plate 12 is a cover, said cover comprising four side panels surrounding a top panel. The top panel of the cover covers the top of the sink, ie covers the opening of the sink. The four side panels of the cover laterally cover the top of the outer peripheral wall of the sink, ie cover the top of the four wall panels of the sink. Of course, the present invention is not limited to this, and the base 11 and the vibrating plate 12 can be changed to any structure other than a sink and a cover. Furthermore, in this embodiment, the vibrating plate 12 covers the base 11, but there is no direct contact between said vibrating plate 12 and the base 11, thereby causing friction between the vibrating plate 12 and the base 11 during movement. Note that no

Additionally, in this embodiment, the vibration plate 12 includes an outer cover 121 , a connection plate 122 and a foot pad 123 . The outer cover 121 is the main part of the vibrating plate 12 and includes the top panel and four side panels surrounding the top panel. A connection plate 122 is disposed under the top panel, and the connection plate 122 has a plurality of connection structures (e.g., keyholes) for connecting the redirecting connecting rod mechanism 3 and the synchronous redirecting connecting rod mechanism 4. have A foot pad 123 is installed on the outer cover 121 for the user to step on. The foot pad 123 is preferably made of non-slip material or forms a non-slip pattern on the upper surface so that the user can stand stably without slipping when using the vibrating mechanism 1 . Also, the foot pads 123 can preferably be of a removable design so that they can be easily removed from or attached to the outer cover 121, thereby facilitating cleaning of the foot pads 123, Maintenance and replacement become easier.

As Figures 2 and 3 show, the drive mechanism 2 is disposed on the base 11, the drive mechanism 2 includes a motor 21 and a drive shaft 22, the drive shaft 22 is connected to the motor. , and driven by the motor 21 to rotate about the horizontal axis. In this embodiment, the motor 21 is an electric motor, capable of receiving external power (eg, utility power, batteries) and outputting rotary motion from an output shaft 211 . Of course, the present invention is not limited to this, and the motor 21 can be a pneumatic motor, a hydraulic motor, etc., as long as it can output rotary motion. The drive shaft 22 is fixed to the base 11 by bearings, and the horizontal axis about which the drive shaft 22 rotates refers to an axis substantially parallel to the vibration plate 12 (top surface).

Preferably, the output shaft 211 of the motor 21 and the drive shaft 22 are arranged parallel to each other. Specifically, in this embodiment, the drive shaft 22 is provided with a pulley 23 , and a conductive belt 231 is wound around the pulley 23 and the output shaft 211 of the motor 21 . Thereby, the rotational motion of the output shaft 211 of the motor 21 is transmitted to the drive shaft 22 via the transmission belt 231 and the pulley 23 . Preferably, in this embodiment, the diameter of the pulley 23 is larger than the diameter of the output shaft 211 of the motor 21, so that the rotary motion transmitted from the motor 21 to the drive shaft 22 is reduced in rotational speed. and the torque increases. Of course, the present invention is not limited to this, and the transmission between the drive shaft 22 and the motor 21 can use gears, or the drive shaft 22 can be the output of the motor 21 as the case may be. A direct connection with the shaft 211 is also possible.

As shown in FIGS. 3-5, the diverting connecting rod mechanism 3 includes a conducting connecting rod 31 and a diverting rod 32, and the inner end 311 of the conducting connecting rod 31 is eccentrically connected to the drive shaft 22. When the driving shaft 22 rotates, the outer end 312 of the transmission connecting rod 31 is caused to perform a lateral reciprocating motion M1 to separate from the driving shaft 22, and the direction changing rod 32 is fixed. The driving end 321 of the redirecting rod 32 is connected to the outer end 312 of the conducting connecting rod 31, and the passive end 322 of the redirecting rod 32 is configured to perform rocking vibration about the axis 32a. is connected to the vibrating plate 12 to convert the horizontal reciprocating motion M1 of the transmission connecting rod 31 into vertical reciprocating motion M2 and transmit it to the vibrating plate 12;

In this embodiment, the inner end 311 of the conducting connecting rod 31 is formed with a ring, the driving shaft 22 is provided with an eccentric ring 24 , and the eccentric ring 24 is attached to the ring of the inner end 311 of the conducting connecting rod 31 . be done. Thus, when the driving shaft 22 rotates, the eccentric ring 24 causes the driving connecting rod 31 to be driven by the ring to perform a reciprocating upward and downward motion with respect to the driving shaft 22 . Specifically, in this embodiment, when the conducting connecting rod 31 rises, the outer end of the conducting connecting rod 31 moves away from the axis of the drive shaft 22, and the conducting connecting rod 31 descends. , the outer end of the transmission connecting rod 31 moves toward the axis of the driving shaft 22 . Thus, with the continued rotation of the driving shaft 22 , the conducting connecting rod 31 alternately ascends and descends so that the outer end of the conducting connecting rod 31 moves towards or away from the driving shaft 22 . The lateral reciprocating motion M1 is performed. Of course, the present invention is not limited to this, and the transmission connecting rod 31 can be connected to the driving shaft 22 by a mechanism other than an eccentric ring to achieve the same effect as the lateral reciprocating motion M1.

A redirecting rod is a connecting rod mechanism used to convert motion from the driving end into motion in the other direction and output to the passive end. Specifically, as shown in FIGS. 4 and 5, in this embodiment, the direction-changing connecting rod 32 is an L-shaped connecting rod, and the fixed axis 32a of the direction-changing rod 32 is an L-shaped connecting rod. Placed at the bend of the rod. Thus, as shown in FIG. 5, when the drive shaft 22 rotates to move the outer end 312 of the transmission connecting rod 31 away from the drive shaft 22, the main drive end 321 of the diverting rod 32 can Along with the outer end 312 of the connecting rod 31, it moves in the lateral direction (to the left in the figure), rocking vibration is performed around the axis 32a (clockwise in the figure) to which the direction changing rod 32 is fixed, and the direction changing rod 32 is fixed. The driven ends 322 of the deflection rods 32 move together with the movement of the deflection rod 32 . As shown in FIG. 4, when the drive shaft 22 rotates and the outer end 312 of the transmission connecting rod 31 moves closer to the drive shaft 22, the driving end 321 of the diverting rod 32 moves toward the transmission It moves laterally along with the outer end 312 of the connecting rod 31 (moves to the right in the figure), rocking-vibrates the direction changing rod 32 about the fixed axis 32a (counterclockwise in the figure). swing), thus the passive end 322 of the deflection rod 32 moves downward as the deflection rod 32 moves. In this way, the lateral reciprocating motion M1 of the outer end 312 of the conducting connecting rod 31 is transformed by the redirecting rod 32 into a longitudinal reciprocating motion M2.

As shown in FIGS. 3 to 5 , the synchronous direction-changing connecting rod mechanism 4 includes a synchronous connecting rod 41 and a synchronous direction-changing rod 42 , and the synchronous connecting rod 41 has an input end 411 and an output end 412 . the input end 411 of the synchronous connecting rod 41 is connected to the outer end 312 of the transmission connecting rod 31, and the output end 412 of the synchronous connecting rod 41 is synchronized with the input end 411 of the synchronous connecting rod 41; Synchronous lateral reciprocating motion M1' is performed. The synchronous direction changing rod 42 is configured to swing around the fixed axis 42a, the driving end 421 of the synchronous direction changing rod 42 is connected to the output end 412 of the synchronous connecting rod 41, The driven end 422 of the synchronous direction changing rod 42 is connected to the vibrating plate 12 to convert the synchronous lateral reciprocating motion M1' of the synchronous connecting rod 41 into a synchronous vertical reciprocating motion M2' to the vibrating plate. 12. The synchronous vertical reciprocating motion M2' is synchronized with the vertical reciprocating motion M2 of the direction changing rod 32, so that the vibrating plate 12 is moved by the vertical reciprocating motion M2 and the synchronous vertical reciprocating motion M2'. It vibrates vertically with respect to the base 11 .

Said synchronous redirecting rod 42 is also a redirecting rod and is used to convert motion from the driving end into motion in the other direction for output by the passive end. Specifically, as shown in FIGS. 4 and 5, in this embodiment, the synchronous direction-changing rod 42 is another L-shaped connecting rod, and the fixed axis 42a of the synchronous direction-changing rod 42 is is placed at the bend of said another L-shaped connecting rod. Thus, as shown in FIG. 5, when the drive shaft 22 rotates to move the outer end 312 of the transmission connecting rod 31 away from the drive shaft 22, the main drive end 421 of the synchronous redirecting rod 42 is laterally moved (moved to the left in the figure) by the synchronous connecting rod 41 along with the outer end 312 of the conducting connecting rod 31, causing rocking oscillation about the axis 42a to which the synchronous redirecting rod 42 is fixed. (clockwise in the figure) thereby causing the passive end 422 of the synchronizing redirecting rod 42 to move upward as the synchronizing redirecting rod 42 swings. As shown in FIG. 4, when the drive shaft 22 rotates to move the outer end 312 of the transmission connecting rod 31 away from the drive shaft 22, the driving end 421 of the synchronous redirecting rod 42 is pushed toward the By means of the synchronous connecting rod 41, the outer end 312 of the conducting connecting rod 31 is moved laterally (to the right in the figure), and rockingly oscillates about the axis 42a to which the synchronous redirecting rod 42 is fixed ( counterclockwise in the figure) causes the passive end 422 of the synchronizing redirecting rod 42 to move downward as the synchronizing redirecting rod 42 swings. Thus, the output end 412 of the synchronous connecting rod 41 synchronously carries out the synchronous lateral reciprocating motion M1' with the lateral reciprocating motion M1 of the outer end 312 of the transmission connecting rod 31, and the synchronous lateral reciprocating motion M1' is converted by the synchronous redirection rod 42 into the synchronous longitudinal reciprocating motion M2'. In addition, since the synchronous lateral reciprocating motion M1′ of the output end 412 of the synchronous connecting rod 41 and the lateral reciprocating motion M1 of the outer end 312 of the transmission connecting rod 31 are synchronous, the synchronous direction changing rod 42 The synchronous longitudinal reciprocating motion M2′ translated by is also synchronized with the longitudinal reciprocating motion M2 translated by the redirecting rod 32 . Thus, the vertical reciprocating motion M2 and the synchronous vertical reciprocating motion M2' can synchronously drive the vibrating plate 12 to alternately move up and down, that is, move it in the vertical direction.

Preferably, as FIGS. 4 and 5 show, in this embodiment the outer end 312 of said conducting connecting rod 31, the driving end 321 of said redirecting rod 32 and the input end 411 of said synchronizing connecting rod are the same. Connected along the axis of rotation. Specifically, in this embodiment, the synchronous connecting rod 41 is a horizontal horizontal rod, and the distance between the input end 411 and the output end 412 is equal to the fixed axis 32a of the redirecting rod 32. and the fixed axis 42a of the synchronous direction changing rod 42, and the distance between the output end 411 of the synchronous connecting rod 41 and the fixed axis 32a of the direction changing rod 32 is equal to the synchronous equal to the distance between the output end 412 of the connecting rod 41 and the fixed axial center 42a of the synchronous redirecting rod 42; Thus, a parallel four-bar rotation mechanism is formed to move the synchronous connecting rod 41 horizontally, and the diverting rod 32 and the synchronous diverting rod 42 swing at the same angle to synchronize with each other.

Preferably, in this embodiment, said vibrating machine 100 includes two redirecting connecting rod mechanisms 3 and two said synchronized redirecting connecting rod mechanisms 4, as shown in FIGS. Two said reorienting connecting rod mechanisms 3 are juxtaposed one behind the other, two said synchronous reorienting connecting rod mechanisms 4 are juxtaposed one behind the other, and the longitudinal reciprocating movements M2 and M2 of the two said reorienting connecting rod mechanisms 3 The synchronous longitudinal reciprocating motions M2' of the two synchronous redirecting connecting rod mechanisms 4 are synchronized with each other. By arranging two said reorienting connecting rod mechanisms 3 and two said synchronous reorienting connecting rod mechanisms 4, said vibrating plate 12 can be supported from a plurality of points, and said vibrating plate 12 can be synchronously driven. can make the vibration of the vibrating plate 12 more stable.

4 and 5 , in this embodiment, the synchronous direction changing connecting rod mechanism 4 further includes a synchronous floating lever 43 , one end of the synchronous floating lever 43 is connected to the synchronous direction changing rod 42 . , and the other end of the synchronous floating lever 43 is connected to the vibrating plate 12 , so that the synchronous direction changing rod 42 is connected to the vibrating plate 12 via the synchronous floating lever 43 . .

Also, as FIGS. 4 and 5 show, in this embodiment, the redirecting connecting rod mechanism 3 further comprises a mount 34, which is removably clipped to the vibrating plate 12 to allow the direction change. The driven end 322 of the change rod 32 is connected to the vibration plate 12 through the mount 34 by being connected to the mount 34 . The synchronous reorienting connecting rod mechanism 4 further includes another mount 44 . The another mounting base 44 is detachably fixed to the vibrating plate 12 , and the other end of the synchronous floating lever 43 is connected to the another mounting base 44 so that the another mounting base 44 is connected to the vibrating plate 12 via the . By installing the mounting base 34 and the another mounting base 44, the vibration plate 12 can be easily removed, and maintenance and replacement of internal parts can be easily performed.

In addition, as shown in FIGS. 2 and 3, in the vibration machine 100 of the embodiment of the present invention, the drive mechanism 2 further includes a rotation speed control unit 25 electrically connected to the motor 21 to adjust the rotation speed. A unit is arranged to control the speed of rotation, thereby varying the speed of vibration of the vibrating plate 12 . Of course, there are many ways to control the rotation speed of the motor 21 , the present invention is not limited, and conventional methods can be applied to the rotation speed control unit 25 .

With the above structure, the vibration machine 100 of the present invention converts the rotary motion of the motor 21 into lateral reciprocating motion M1 by eccentrically connecting the transmission connecting rod 31 to the driving shaft 22, and by installing the direction-changing rod 32 The horizontal reciprocating motion M1 of the transmission connecting rod 31 is further converted into a vertical reciprocating motion M2 and transmitted to the vibrating plate. In addition, the vibration machine 100 of the present invention synchronously performs the synchronous lateral reciprocating motion M1' by the synchronous connecting rod 41 connected to the transmission connecting rod 31, and synchronously performs the synchronous lateral reciprocating motion M1' by the synchronous direction changing rod 42. The motion M1' is further converted into the synchronous vertical reciprocating motion M2' and transmitted to the vibrating plate 12 synchronously with the vertical reciprocating motion M2. In this way, the vibrating plate 12 is simultaneously driven by said longitudinal reciprocating motion M2 and said synchronous longitudinal reciprocating motion M2' to vibrate longitudinally with respect to the base 11 to achieve the effect of movement.

Although preferred embodiments of the invention have been disclosed above, they are not intended to limit the invention in any way. Various changes and modifications may be made without departing from the spirit and scope of the invention. It is therefore the scope of the claims of the present invention to include such changes and modifications.

100 vibrating machine
1 Vibration mechanism
11 Base 12 Vibration plate 121 Cover 122 Connection plate 123 Foot pad 2 Drive mechanism 21 Motor 211 Output shaft 22 Drive shaft 23 Pulley 231 Conductive belt 24 Eccentric ring 25 Rotational speed control unit 3 Direction changing connecting rod mechanism 31 Conductive connecting rod 311 Inside 3
312 outer end 32 direction changing rod 321, 421 driving end 322, 422 passive end 32a, 42a fixed axis 34 mount 4 synchronous direction changing connecting rod mechanism 41 synchronous connecting rod 411 input end 412 output end 42 synchronous direction changing rod 43 Synchronous floating lever 44 Another mount M1 Horizontal reciprocating motion M1' Synchronous horizontal reciprocating motion M2 Vertical reciprocating motion M2' Synchronous vertical reciprocating motion

Claims (9)

a vibrating mechanism including a base and a vibrating plate overlying the base;
a drive mechanism mounted on the base and including a motor and a drive shaft;
a redirecting tie rod mechanism including a conducting tie rod and a redirecting rod;
a synchronous connecting rod and a synchronous redirecting connecting rod mechanism including a synchronous redirecting rod, the vibration machine comprising:
the drive shaft is connected to the motor and driven by the motor to rotate about a horizontal axis;
The inner end of the conducting connecting rod is eccentrically connected to the drive shaft, and the outer end of the conducting connecting rod is laterally oriented away from and away from the drive shaft as the drive shaft rotates. perform reciprocating motion,
The deflecting rod performs rocking vibration about a fixed axis, the driving end of the deflecting rod is connected to the outer end of the conducting connecting rod, and the passive end of the deflecting rod is connected to the vibrating plate. by converting the lateral reciprocating motion of the conductive connecting rod into a vertical reciprocating motion and transmitting it to the vibrating plate;
The synchronous connecting rod includes an output end and an input end, and the input end of the synchronous connecting rod is configured such that the output end of the synchronous connecting rod performs synchronous lateral reciprocating motion synchronously with the input end of the synchronous connecting rod. connected to the outer end of the conducting connecting rod to
The synchronous redirecting rod is installed to perform rocking oscillation around a fixed axis, the driving end of the synchronous redirecting rod is connected to the output end of the synchronous connecting rod, and the passive end of the synchronous redirecting rod is is connected to the vibrating plate, the synchronous lateral reciprocating motion of the synchronous connecting rod is converted into synchronous vertical reciprocating motion and transmitted to the vibrating plate, and the vertical reciprocating motion and the synchronous vertical reciprocating motion wherein said synchronous vertical reciprocation is synchronized with said vertical reciprocation of said redirecting rod so as to move said vibration plate to vibrate longitudinally with respect to said base. 2. The vibrating machine of claim 1, wherein the vibrating plate is a cover, the base is a sink, and the cover covers the top of the sink and the upper portion of the outer peripheral wall of the sink. 2. The vibration machine of claim 1, wherein the output shaft of the motor and the drive shaft are arranged parallel to each other. 2. The vibration machine as claimed in claim 1, wherein the outer end of said conducting connecting rod, the driving end of said diverting rod and the input end of said synchronizing connecting rod are connected side by side on the same axis of rotation. The vibrating machine includes two of the direction-changing connecting rod mechanisms and two of the synchronous direction-changing connecting rod mechanisms, the two of the direction-changing connecting-rod mechanisms are arranged in front and behind, and the two of the synchronous direction-changing connecting rod mechanisms are front and rear. and wherein the longitudinal reciprocating motion of the two redirecting connecting rod mechanisms and the longitudinal reciprocating motion of the two synchronous redirecting connecting rod mechanisms are synchronized. The synchronous turning connecting rod mechanism further includes a synchronous floating lever, one end of the synchronous floating lever is connected to the passive end of the synchronous turning rod, and the other end of the synchronous floating lever is connected to the vibrating plate. 2. The vibrating machine of claim 1, wherein said synchronous redirecting rods are connected to said vibrating plate via said synchronous floating levers. The redirecting tie rod mechanism further includes a mount, the mount is removably clipped to the vibrating plate, and the passive end of the redirecting rod is connected to the mount such that to the vibrating plate, and
The synchronous reorienting connecting rod mechanism further includes another mounting base, wherein said another mounting base is detachably fastened to said vibrating plate, and the other end of said synchronous floating lever connects to said another mounting base. 7. A vibration machine according to claim 6, wherein the vibration plate is connected to the vibration plate through the another mount by means of. The direction-changing rod is an L-shaped connecting rod, the fixed axis of the direction-changing rod is located at the bending corner of the L-shaped connecting rod, and the synchronous direction-changing rod is another L-shaped connecting rod. 8. A vibrating machine according to claim 1, 6 or 7, wherein the fixed axis of said synchronous redirecting rod is located at the bend of said another L-shaped connecting rod. 2. The drive mechanism further comprises a rotational speed control unit electrically connected to the motor and arranged to control the rotational speed of the motor, thereby controlling the vibration speed of the vibrating plate. The vibrating machine described in .

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