Weight-adjustable dumbbell

Abstract

Provided is a weight-adjustable dumbbell, including a grip bar assembly, a dumbbell seat, a plurality of dumbbell discs placed on the dumbbell seat; the grip bar assembly includes a plurality of hanging discs arranged adjacent to each other and are rotated synchronously, and the hanging discs are rotated relative to the dumbbell discs to setting positions to engage with or disengage from the dumbbell discs. The grip bar assembly also includes at least one stopping mechanism, each stopping mechanism includes at least one locking component, and the dumbbell seat is provided with a limiting hole for the locking component to be engaged with. When the hanging discs are rotated to a setting position, the locking component is disengaged from the limiting hole to maintain an unlocked state. When the hanging discs are rotated between two setting positions, the locking component is inserted into the limiting hole to maintain a locked state.

Claims

1. A weight-adjustable dumbbell, comprising: a grip bar assembly, a dumbbell seat, and a plurality of dumbbell discs placed on the dumbbell seat; wherein the grip bar assembly comprises a plurality of hanging discs, the plurality of hanging discs are arranged adjacent to each other and are configured to be rotated synchronously with the grip bar assembly, and the plurality of hanging discs are adapted to be rotated to a plurality of setting positions relative to the plurality of dumbbell discs, wherein each of the plurality of hanging discs is adapted to engage with or disengage with a respective one of the plurality of dumbbell discs at each of the plurality of setting positions; the grip bar assembly further comprises at least one stopping mechanism, the at least one stopping mechanism comprises at least one locking component, and the dumbbell seat is provided with a limiting hole for the at least one locking component to be engaged with, wherein when the plurality of hanging discs are rotated to one of the plurality of setting positions, the at least one locking component is disengaged from the limiting hole to maintain an unlocked state, and when the plurality of hanging discs are rotated between two of the plurality of setting positions, the at least one locking component is inserted into the limiting hole to maintain a locked state; the at least one stopping mechanism further comprises an inner end cap and a stopping plate, wherein the inner end cap is configured to be clamped on the dumbbell seat and is rotated relative to the plurality of hanging discs, the stopping plate is provided in the inner end cap and is rotated synchronously with the plurality of hanging discs, the inner end cap is formed with a guiding hole, the at least one locking component is extended through the guiding hole and slidably abutted against the stopping plate, and the stopping plate rotationally drives the at least one locking component to slide back and forth in the guiding hole to engage with or disengage from the limiting hole of the dumbbell seat; the stopping plate is evenly provided with a plurality of convex blocks along a circumferential direction, and an escape groove is formed between each two adjacent convex blocks; the at least one locking component comprises an abutting portion abutted against the stopping plate, wherein when the abutting portion abuts against one of the plurality of convex blocks, the at least one locking component is inserted into the limiting hole, and when the abutting portion abuts against a bottom wall of one of the escape grooves, the at least one locking component disengages from the limiting hole; the guiding hole is formed along a radial direction of the inner end cap, and the plurality of convex blocks are evenly arranged on a circumferential side wall of the stopping plate along the circumferential direction; the at least one locking component further comprises a locking portion and a resetting portion, wherein the resetting portion is connected to a peripheral side of the locking portion, and the locking portion is extended through the guiding hole and is adapted to slide and engage in the limiting hole, and wherein the resetting portion slides and engages in the guiding hole and drives the locking portion to be reset into the guiding hole; the resetting portion comprises a connecting section and a limiting section, wherein the limiting section and the locking portion are provided at intervals, and the connecting section is connected between the limiting section and the locking portion; and the guiding hole comprises a sliding cavity and a limiting cavity which are connected, wherein the connecting section is slidably extended through the sliding cavity and the limiting section is slidably extended through the limiting cavity for limiting the connecting section to slide out to one side of the sliding cavity away from the limiting cavity.

2. The weight-adjustable dumbbell according to claim 1, wherein the dumbbell seat comprises a chassis and at least one supporting frame protruding on the chassis, the at least one supporting frame is provided with a clamping slot for the inner end cap of the at least one stopping mechanism to be engaged with, and the limiting hole is formed on a slot wall of the clamping slot.

3. The weight-adjustable dumbbell according to claim 1, wherein the grip bar assembly further comprises a handle tube, and the stopping plate of the at least one stopping mechanism is clamped and sleeved outside the handle tube and is rotated synchronously with the handle tube.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is an overall schematic diagram of an embodiment of the present application.

(2) FIG. 2 is an explosion diagram of an embodiment of the present application.

(3) FIG. 3 is a first explosion diagram of a grip bar assembly of an embodiment of the present application.

(4) FIG. 4 is a schematic diagram of a stopping mechanism according to the first embodiment of the present application.

(5) FIG. 5 is a schematic diagram of a dumbbell seat according to the first embodiment of the present application.

(6) FIG. 6 is a schematic diagram of a stopping mechanism according to the second embodiment of the present application.

(7) FIG. 7 is a schematic diagram of a dumbbell seat according to the second embodiment of the present application.

(8) FIG. 8 is a schematic diagram of a locking component of an embodiment of the present application.

(9) FIG. 9 is installation diagram of a locking component of an embodiment of the present application.

(10) FIG. 10 is an enlarged diagram at A in FIG. 9 of an embodiment of the present application.

(11) FIG. 11 is a schematic diagram of a locking component according to a third embodiment of the present application.

(12) FIG. 12 is an installation diagram of a locking component according to the third embodiment of the present application.

(13) FIG. 13 is an enlarged diagram at B in FIG. 12 of an embodiment of the present application.

(14) FIG. 14 is a second explosion diagram of the grip bar assembly of an embodiment of the application.

(15) FIG. 15 is a schematic diagram of a dumbbell disc of an embodiment of the present application.

(16) FIG. 16 is a schematic diagram of the hanging disc and dumbbell disc when they cooperate with each other in an embodiment of the application.

(17) FIG. 17 is a schematic diagram of position adjustment of an embodiment of the present application.

(18) FIG. 18 is an enlarged view at C in FIG. 10 of an embodiment of the present application.

DETAILED DESCRIPTION

(19) The present application is further described in detail below in combination with the accompanying drawings 1-18.

(20) The present application discloses a weight-adjustable dumbbell, referring to FIGS. 1-2, including a grip bar assembly 1, a dumbbell sea 2 and a plurality of dumbbell discs 3 placed on the dumbbell seat 2. The both ends of grip bar assembly 1 is mounted with two groups of hanging disc 11 which are arranged adjacent to each other and are rotated synchronously, and the hanging disc 11 can engage with or disengage from the dumbbell discs 3 by rotating relative to the dumbbell discs 3, thereby adjust to the appropriate position and adapt to different levels of exercise.

(21) Referring to FIG. 2, the grip bar assembly 1 also includes at least one stopping mechanism 4, each stopping mechanism 4 includes at least one locking component 41, and the dumbbell seat 2 is arranged with a limiting hole 222. During the hanging disc 11 is engaged or disengaged from the dumbbell disc 3, when the hanging disc 11 is rotated at the setting position, the locking component 41 can disengage from the limiting hole 222 and is in an unlocked state, and the user can lift the grip bar assembly 1 from the dumbbell seat 2. When the hanging disc 11 is not rotated at the setting position, that is, the hanging disc 11 is rotated between two setting position, the hanging disc 11 is semi-engaged with the dumbbell disc 3, the locking component 41 can be inserted in the limiting hole 222 and is in an locked state, and the user is not easy to lift the grip bar assembly 1 from the dumbbell seat 2.

(22) In particular, the number and position of the stopping mechanism 4 can be adjusted as needed. In this embodiment, one stopping mechanism 4 is arranged corresponding to each group of hanging discs 11, and the two stopping mechanisms 4 are positioned between the two groups of hanging discs 11.

(23) Referring to FIGS. 2-3, the stopping mechanism 4 also includes an inner end cap 43 and a stopping plate 42. In this embodiment, the inner end cap 43, the stopping plate 42 and the hanging discs 11 are coaxially provided. The inner end cap 43 is rotated relative to the hanging discs 11, and the stopping plate 42 is embedded in the inner end cap 43 and is rotated synchronously with hanging discs 11.

(24) The inner end cap 43 is formed with a guiding hole 431 cooperated with the locking component 41. The locking component 41 extends through the guiding hole 431 and one end of the locking member 41 abuts against the stopping plate 42. At the same time, the dumbbell seat 2 is formed with a clamping slot 221 for the inner end cap 43 to be engaged with, and the limiting hole 222 is formed on the slot wall of the clamping slot 221. When the inner end cap 43 is clamped into the clamping slot 221, the guiding hole 431 is aligned and communicates with the limiting hole 222, thereby facilitate the accurate insertion or disengagement of the locking component 41 from the limiting hole 222.

(25) In this application, the dumbbell seat 2 can be a plate, and the clamping slot 222 is directly formed at the top of the plate. In addition, the dumbbell seat 2 also can be a seat including a chassis 21 and a supporting frame 22, and the supporting frame 22 is protruded on the chassis 21 and the clamping slot 221 is formed in the middle of the supporting frame 22. The number of the supporting frame 22 specifically depends on the number of the inner end cap 43. In this embodiment, one supporting frame 22 is arranged corresponding to each of the two inner end caps 43 of the dumbbell seat 2.

(26) In particular, the stopping plate 42 is evenly arranged with a plurality of convex blocks 421 along the circumferential direction, and an escape groove 422 is formed between each two adjacent convex blocks 421. The locking component 41 includes an abutting portion 411 abutted against the stopping plate 42. When the stopping plate 42 is rotated, the abutting joint between the abutting portion 411 and the stopping plate 42 fluctuates evenly, so that the locking component 41 can slide back and forth in the guiding hole 431. When the abutting portion 411 abuts against the convex block 421, the locking component 41 is inserted into the limiting hole 222 with the drive of the convex block 421. When the abutting portion 411 abuts against the bottom wall of the escape groove 422, the locking component 41 disengages from the limiting hole 222.

(27) The first embodiment of the present application is:

(28) referring to FIGS. 4-5, the convex blocks 421 are evenly arranged on the circumferential side wall of the stopping plate 42 along the circumferential direction. The guiding holes 431 are formed along the radial direction of the inner end cap 43, then the locking component 41 extended through the guiding holes 431 can slide back and forth along the radial direction of the inner end cap 43 with the drive of the stopping plate 42. The limiting hole 222 is formed on the inner walls of the opposite sides of the clamping slot 221 to be aligned with the guiding hole 431. When the locking component 41 slides back and forth along the radial direction of the inner end cap 43, the locking component 41 can be inserted into or disengaged from the limiting hole 222.

(29) The second embodiment of the present application is:

(30) referring to FIGS. 6-7, the convex blocks 421 are evenly arranged on the plate surface of the stopping plate 42 along the circumferential direction. The guiding holes 431 are formed the vertical direction of the cap surface of the inner end cap 43, then after the locking component 41 extended through the guiding holes 431 abuts against the stopping plate 42, it can slide back and forth along the vertical direction of the inner end cap 43 with drive of the stopping plate 42. The limiting hole 222 is formed on one side of the supporting frame 22 facing the plate surface of the inner end cap 43 and aligning with the guiding hole 431. When the locking component 41 slides back and forth with the drive of the stopping plate 42, the locking component 41 can be inserted into or disengaged from the limiting hole 222.

(31) Referring to FIGS. 8-10, the locking component 41 further includes a locking portion 412 and a resetting portion 413, and the resetting portion 413 is arranged to the peripheral side of the locking portion 412. In this embodiment, the resetting portions 413 are two, the two resetting portions 413 are symmetrically arranged on the peripheral side of the locking portion 412, which can provide a good reset effect for the locking portion 412.

(32) In particular, the resetting portion 413 includes a limiting section 4131 and a connecting section 4132, the limiting section 4131 integrally formed on the peripheral side of the locking portion 412, the limiting section 4131 and the locking portion 412 are provided at intervals. The connecting section 4132 is connected between the limiting section 4131 and the locking portion 412 to facilitate the elastic reset of the reset unit 413. The guiding hole 431 includes a sliding cavity 4311 and a limiting cavity 4312, the sliding cavity 4311 penetrates the outer peripheral surface of the inner end cap 43, and the limiting cavity 4312 is positioned on the side of the sliding cavity 4311 facing the stopping plate 42. The diameter of the limiting cavity 4312 is larger than that of the sliding cavity 4311, and the limiting section 4131 abuts against the inner wall of the limiting cavity 4312.

(33) When the convex block 421 abuts against the abutting portion 411, the locking portion 412 slides into the limiting hole 222 through the sliding cavity 4311, and the limiting section 4131 compresses and contracts to the side close to the locking portion 412 under the limit of the inner wall of the limiting cavity 4312, thereby have rebound elastic potential energy. As the stopping plate 42 is rotated to align the escape groove 422 with the guiding hole 431, the locking portion 412 is reset along the limiting cavity 4312 driven by the limiting section 4131.

(34) The third embodiment of the present application is:

(35) referring to FIGS. 11-13, the resetting portion 413 is a spring sleeved outside the locking portion 412. The outer circumferential direction of the locking component 41 is integrally formed with a convex ring 414, the inner wall of the guide hole 431 is integrally formed or bonded with a stopping block 435, and the spring is positioned between the convex ring 414 and the stopping block 435. If the spring is a tension spring, the stopping block 435 is positioned between the convex ring 414 and the stopping plate 42. One end of the spring is bonded with the stopping block 435, and the other end faced the supporting frame 22 is welded or bonded with the convex ring 414. If the spring is a compression spring, the convex ring 414 is positioned between the stopping block 435 and the stopping plate 42. Both ends of the compression spring are separately abutted against the stopping block 435 and the convex ring 414. This embodiment takes the tension spring as an example. When the locking portion 412 slides and inserts into the limiting hole 222, the spring is stretched, so that the elastic potential energy of the spring is increased. When the convex block 421 is misaligned with the guiding hole 431, the spring can drive the locking portion 412 retract into the guiding hole 431.

(36) Because of the existence of the convex ring 414, it is difficult for the locking component 41 to directly slide and clamp in the guiding hole 431. Therefore, a mounting hole communicating with the guiding hole 431 can be formed on the inner end cap 43 near the guiding hole 431. After mounting the locking component 41 and the spring into the guiding hole 431, the mounting hole can be closed with a cover plate. Alternatively, the locking component 41 and the spring can be put into the guiding hole 431 from the opening which from guiding hole 431 towards the on the side of the stopping plate 42, and then the stopping block 435 can be bonded to the hole wall of the guiding hole 431. In addition, the locking component 41 and the spring can be installed in the guiding hole 431 in other appropriate ways.

(37) Referring to FIG. 14, the grip bar assembly 1 also includes a handle tube 12, the handle tube 12 is positioned between two groups of the hanging discs 11, and the stopping plate 42 and the inner end cap 43 are sleeved outside the handle tube 12. In particular, the stopping plate 42 is clamped with the handle tube 12, so that the stopping plate 42 can rotate synchronously with the handle tube 12. At the same time, the handle tube 12 is clamped with the hanging discs 11 at the corresponding both ends, so that the handle tube 12, the stopping plate 42 and the hanging discs 11 can rotate synchronously. Turning the handle tube 12 can drive the hanging disc 11 to rotate and engage with or disengage from the dumbbell disc 3, and drive the stopping plate 42 to rotate synchronously, thereby drive the locking component 41 to slide back and forth.

(38) Referring to FIGS. 14-16, the hanging disc 11 and the dumbbell disc 3 are engaged through the following solution: each group of hanging discs 11 are integrally provided with an arc hanging strip 111 with gradually increasing or decreasing length. Each dumbbell disc 3 is provided with a U-shaped slot 31 for sliding and clamping of the hanging disc 11, and the inner wall of the U-shaped slot 31 is integrated with the dumbbell disc 3 to integrally form a waist-shaped positioning block 32. Rotating the hanging disc 11, the hanging strip 111 is rotated and clamped between the positioning block 32 and the bottom wall of the U-shaped slot 31, so that the hanging disc 11 is engaged with the dumbbell disc 3. When the end of the hanging strip 111 is clamped into the U-shaped slot 31 to be tangent to the arc surface of the positioning block 32, the hanging disc 11 is half-engaged with the dumbbell disc 3.

(39) Combining with FIG. 17, when the hanging disc 11 is rotated to engage with or disengage from the dumbbell disc 3, the working state of the locking component 41 will be described in detail.

(40) Each group of hanging discs 11 are centered on the handle tube 12 and are respectively a first disc 11a, a second disc 11b, a third disc 11c and a fourth disc 11d from inside to outside. Two hanging strips 111 are symmetrically mounted on each hanging disc 11, in particular, the central angle of the hanging strip 111 of the first disc 11a is 144°, the central angle of the hanging strip 111 of the second disc 11b is 108°, the central angle of the hanging strip 111 of the third disc 11C is 72°, and the central angle of the hanging strip 111 on the fourth disc 11d is 36°. The dumbbell disc 3 corresponds to a first dumbbell single-disc 3a, a second dumbbell single-disc 3b, a third dumbbell single-disc 3c and a fourth dumbbell single-disc 3d from the inside to the outside. The corresponding central angle between the top of two adjacent convex blocks 421 or the bottom walls of two adjacent escape grooves 422 is 36°. The dumbbell has the following five positions in total, and the five positions can be adjusted cyclically.

(41) Neutral position (no hanging disc): the grip bar assembly 1 is unloaded and placed on the dumbbell seat 2. At the same time, the hanging disc 11 does not engage with any dumbbell disc 3.

(42) First position (engaging two dumbbell discs): the handle tube 12 is counterclockwise rotated by 36°, and the first disc 11a is engaged with two first dumbbell single-disc 3a.

(43) Second position (engaging four dumbbell discs): the handle tube 12 is continued to be counterclockwise rotated by 36°, the first disc 11a is engaged with two first dumbbell single-discs 3a, and the second disc 11b is engaged with two second dumbbell single-discs 3b.

(44) Third position (engaging six dumbbell discs): the handle tube 12 is continued to be counterclockwise rotated by 36°, the first disc 11a is engaged with two first dumbbell single-discs 3a, the second disc 11b is engaged with two second dumbbell single-discs 3b, and the third disc 11c is engaged with two third dumbbell single-discs 3c;

(45) Fourth position (engaging eight dumbbell discs): the handle tube 12 is continued to be counterclockwise rotated by 36°, the first disc 11a is engaged with two first dumbbell single-discs 3a, the second disc 11b is engaged with two second dumbbell single-discs 3b, the third disc 11c is engaged with two third dumbbell single-discs 3c, and the fourth disc 11d is engaged with two fourth dumbbell single-discs 3d.

(46) After the fourth position, the handle tube 12 is continued to be counterclockwise rotated, and it will automatically jump to the neutral position. The position is adjusted according to the cycle sequence of “neutral position-one-two-three-four”. If the handle tube 12 is turned clockwise, the position will be adjusted according to the cycle sequence of “four-three-two-one-neutral position”.

(47) When the dumbbell is in the above five positions, the locking component 41 abuts against the bottom wall of the escape groove 422, and the grip bar assembly 1 is unlocked and can be lifted. If the dumbbell is between the above two adjacent positions, the locking component 41 abuts against the convex block 421, and the grip bar assembly 1 is locked and cannot be lifted.

(48) Referring to FIGS. 17-18, the stopping mechanism 4 also includes an anti-rotating component 434 sliding radially along the radial direction of the inner end cap 43. The inner wall of the stopping plate 42 is evenly formed with an anti-rotating slot 423 corresponding to the convex block 421 in the circumferential direction. When the anti-rotating component 434 is clamped into the anti-rotating slot 423, the stopping plate 42 is fixed relative to the inner end cap 43. When the anti-rotating component 434 is disengaged from the anti-rotating slot 423, the stopping plate 42 can rotate relative to the inner end cap 43.

(49) Specifically, a mounting slot 432 is formed on the inner end cap 43 along the radial direction, and the anti-rotating component 434 is slidably installed in the mounting slot 432. A compressing spring 433 is also mounted in the mounting slot 432. One end of the compressing spring 433 is abutted against the groove wall of the mounting slot 432, and the other end of the compressing spring 433 is abutted against the anti-rotating component 434. An anti-rotating block 4341 is integrally arranged on the anti-rotating component 434. Under the action of the compressing spring 433, the anti-rotating component 434 always has a movement trend away from the axis of the inner end cap 43, so that the anti-rotating block 4341 can be clamped into the anti-rotating slot 423.

(50) Meanwhile, the dumbbell seat 2 is integrally arranged with a top block 223, which is positioned on the bottom wall of the clamping groove 221 and corresponds to the mounting slot 432. When the grip bar assembly 1 is positioned on the dumbbell seat 2, the top block 223 is inserted into the mounting slot 432 and abuts against the anti-rotating component 434, the compressing spring 433 is compressed, and the anti-rotating block 4341 slides out of the anti-rotating slot 423, so that the stopping plate 42 can synchronously rotate with the inner end cap 43. When the grip bar assembly 1 is removed from the dumbbell seat 2, the top block 223 is disengaged from the mounting slot 432, the anti-rotating component 434 slides radially along the radial direction of the inner end cap 43 driven by the compressing spring 433, and the anti-rotating block 4341 is clamped into the anti-rotating slot 423, so that the stopping plate 42 is fixed the inner end cap 43.

(51) The implementation principle of a weight-adjustable dumbbell in the embodiment of the application is:

(52) When the grip bar assembly 1 is positioned on the dumbbell seat 2 to adjust the position, the guiding hole 431 is aligned with the limit hole 222. The user drives the hanging disc 11 to rotate synchronously by rotating the handle tube 12, thereby hang or disengage the dumbbell disc 3. At the same time, the stopping plate 42 is rotated synchronously with the handle tube 12. During the rotation of the stopping plate 42, when the hanging disc 11 is half-hung with the dumbbell disc 3, the convex block 421 is aligned with the guiding hole 431, and the locking component 41 abuts against the convex block 421 and slides into the limiting hole 222 in a locked state. When the hanging disc 11 is engaged with the dumbbell disc 3, the escape groove 422 is aligned with the guiding hole 431, and the locking component 41 abuts against the bottom wall of the escape groove 422 and slides out of the limiting hole 222 driven by the resetting portion 413, then it is in the unlocked state.

(53) The above are the preferred embodiments of the present application, which are not intend to limit the protection scope of the present application. Therefore, all equivalent changes made according to the structure, shape and principle of the present application should be covered within the protection scope of the present application.