CN114272553A - Torsion detecting device of body-building equipment - Google Patents
Torsion detecting device of body-building equipment Download PDFInfo
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- CN114272553A CN114272553A CN202011041006.5A CN202011041006A CN114272553A CN 114272553 A CN114272553 A CN 114272553A CN 202011041006 A CN202011041006 A CN 202011041006A CN 114272553 A CN114272553 A CN 114272553A
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- base
- magnet
- load sensor
- flywheel
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Abstract
The invention provides a torsion detecting device of body-building equipment, in particular to a torsion detecting device which utilizes a steel cable to drive a magnet seat to move so as to change the area change of a magnet of the magnet seat covering a flywheel, the area of the magnet covering the flywheel is changed so as to change the magnetic attraction resistance of the magnet seat when the flywheel rotates, and a load sensor detects the reaction force of a magnetic resistance mechanism so as to calculate the torsion value of the flywheel.
Description
Technical Field
The invention relates to a torsion detecting device of body-building equipment, in particular to a torsion detecting device which utilizes a steel cable to drive the displacement of a magnet seat so as to change the area change of a magnet of the magnet seat covering a flywheel, the area of the magnet covering the flywheel is changed so as to change the magnetic attraction resistance of the magnet seat when the flywheel rotates, and a load sensor detects the reaction force of a magnetic resistance mechanism so as to calculate the torsion value of the flywheel.
Background
Although the nature of indoor exercise equipment is different from outdoor exercise, at the present stage, indoor exercise equipment in various fields can train muscles of all parts of a body, so that a consumer can train physical fitness even at home or indoors, and the purpose of fitness training is achieved.
Disclosure of Invention
The present invention is directed to a torsion detecting device for exercise equipment, which overcomes the disadvantage of inaccurate detection of torsion due to wear of the device.
In order to achieve the purpose, the invention adopts the scheme that: a torsion detection device of fitness equipment comprises a frame, wherein a flywheel and a torsion detection device are pivoted on the frame, the torsion detection device comprises a load sensor and a magnetic resistance mechanism, one end of the load sensor is fixed on an upper base, the upper base combined with the load sensor is locked on a fixed base body of the magnetic resistance mechanism, the other end of the load sensor is fixed on a lower base, and the lower base combined with the load sensor is fixed on the frame; one end of a magnet seat is provided with a rotating shaft which can lead the magnet seat to be movably pivoted on the fixed seat body, and the other end of the magnet seat is provided with a plurality of magnets; a steel cable, which can make the magnet seat use the rotating shaft as the rotating axis to change the relative position between the magnet and the flywheel, namely change the area change of the magnet covering the flywheel; by the structure, the area of the magnet covering the flywheel is changed, so that the magnetic attraction resistance of the magnet seat on the flywheel during rotation is changed, and the load sensor can detect the reaction force of the magnetic resistance mechanism so as to calculate the torque force value of the flywheel.
One end of the fixed base of the reluctance mechanism is connected to one end of the pair of connecting rod sets, the other end of the connecting rod sets is connected to the lower side of the magnet base, a rotating shaft is arranged at the rotating shaft between the connecting rod sets, and the fixed base, the magnet base and the pair of connecting rod sets form a four-bar linkage in a combined structure.
Wherein the load sensor is provided with a first end and a second end, the first end of the load sensor is provided with a first positioning hole, the second end of the load sensor is provided with a second positioning hole, the lower base is provided with a positioning groove, a through hole communicated with the positioning groove, a plurality of through holes and a screw hole, the screw hole on the lower base is positioned between the plurality of through holes and is separated from the through hole, the first end of the load sensor is arranged in the positioning groove of the lower base in a penetrating way, a fixing piece is arranged in the through hole communicated with the positioning groove in a penetrating way and is screwed on the first positioning hole of the load sensor, a hexagonal bolt is matched with a nut and is screwed on the screw hole of the lower base, the upper base is provided with a positioning groove, a through hole communicated with the positioning groove and a plurality of positioning screw holes, the second end of the load sensor is arranged in the positioning groove of the upper base in a penetrating way, the other fixing piece is arranged in the through hole communicated with the positioning groove of the upper base and is screwed on the second positioning hole of the load sensor, the first washers are respectively arranged between the fixing piece and the lower base, and between the other fixing piece and the upper base, and can be used for increasing the friction surface and reducing looseness.
Wherein, an adjusting rod which rotates by adopting an axle center is pivoted on the frame; one end of the fixed base of the magnetic resistance mechanism is provided with a rolling shaft, the magnet base is provided with an accommodating space, and two sides of the accommodating space are provided with the plurality of magnets; one end of the steel cable is fixed on the fixed base of the magnetic resistance mechanism, and the other end of the steel cable is sequentially wound around the rotating shaft between the connecting rod sets and the rolling shaft of the fixed base and is fixed on the adjusting rod.
The torsion detecting device is arranged on the frame and the lower base through a plurality of through bolts, and is fixed by combining a second washer and a nut with the through bolts, the accommodating space of the magnet seat can accommodate the periphery of the flywheel, and the magnets on two sides of the accommodating space can be used for generating a magnetic resistance effect on the flywheel.
The hexagonal bolt is arranged between the lower base and the upper base, the top surface of the hexagonal bolt and the upper base have a gap, and the hexagonal bolt can prevent the deformation of the load sensor caused by the pressure exerted by the external gravity of the body-building equipment.
Wherein, an adjusting rod which rotates by adopting an axle center is pivoted on the frame; the magnet seat may be provided with a tail end seat, one end of the steel cable may be pivoted to the tail end seat of the magnet seat, and the other end of the steel cable is fixed to the adjusting rod, when the adjusting rod rotates around the axis as a reference under external force to synchronously pull the steel cable to generate displacement, the steel cable synchronously pulls the magnet seat to make the magnet seat pivot around the rotating shaft as the axis.
After the technical scheme is adopted, the steel cable is utilized to drive the magnet seat to move so as to change the change of the area of the magnet seat covering the flywheel, the area of the magnet covering the flywheel is changed, the size of the magnetic attraction resistance of the magnet seat when the flywheel rotates can be changed, and the load sensor detects the reaction force of the magnetic resistance mechanism so as to calculate the torque force value of the flywheel.
Drawings
Fig. 1 is a partial perspective view of the torsion detecting device of the present invention disposed on a fitness apparatus;
FIG. 2 is an exploded perspective view of the torque detection device of the present invention;
FIG. 3 is a cross-sectional view of the base, load cell, top mount combination of the present invention;
FIG. 4 is a schematic diagram of the magnetic base driven by an adjusting rod pulling a steel cable, the magnetic base adjusting the magnetic attraction resistance relative to the flywheel;
FIG. 5 is a schematic view of the present invention using a steel cable to drive a magnet holder relatively close to a flywheel;
FIG. 6 is a diagram of another embodiment of the present invention.
The reference numbers illustrate:
torsion detecting device
Load cell
A first end
A first locating hole
A second end
120
Lower base
Positioning groove
Perforation
231
Screw hole
A fixture
Hexagon bolt
Screw cap
Go up base
Positioning groove
Perforation
331.. positioning screw hole
Fixing piece
A first washer
Magnetic resistance mechanism
A fixed stand
A fixture
53.. roller
54. magnet holder
541.. tail end seat
55
56.. accommodating space
A magnet
58.. linkage
Rotating shaft
Steel cord
Through bolt
71.. second washer
Screw cap
9
Flywheel 91
92.. adjusting rod
Shaft center
H.
Detailed Description
Referring to fig. 1, the present invention provides a torsion detecting device 10 for exercise equipment, and more particularly, to a torsion detecting device 10 for exercise equipment, which utilizes a steel cable 6 to drive a magnet base 54 to move so as to change a relative position between a magnet 57 of the magnet base 54 and a flywheel 91, i.e., change an area of the magnet 57 covering the flywheel 91, and change an area of the magnet 57 covering the flywheel 91, so as to change a magnitude of a magnetic attraction resistance of the magnet 57 of the magnet base 54 when the flywheel 91 rotates, and a load sensor 1 can detect a reaction force of a reluctance mechanism 5, thereby calculating a torsion value of the flywheel 91.
Referring to fig. 1 and 4, the exercise apparatus shown in the embodiment of the present invention includes a frame 9, a flywheel 91, a torque detecting device 10 and an adjusting rod 92 rotating around an axis C are pivotally disposed on the frame 9.
Referring to fig. 2, the torque force detecting device 10 includes a load sensor 1 and a magnetic resistance mechanism 5, the load sensor 1 has a first end 11 and a second end 12, the first end 11 of the load sensor 1 has a first positioning hole 110, the second end 12 of the load sensor 1 has a second positioning hole 120, the lower base 2 has a positioning slot 21, a through hole 22 communicating with the positioning slot 21, a plurality of through holes 231 and a screw hole 24, the screw hole 24 of the lower base 2 is located between the through holes 231, the first end 11 of the load sensor 1 is inserted into the positioning slot 21 of the lower base 2, and a fixing member 25 is inserted into the through hole 22 communicating with the positioning slot 21 and screwed into the first positioning hole 110 of the load sensor 1, a hexagonal bolt 26 is screwed into the screw hole 24 of the lower base 2 in cooperation with a nut 27, the upper base 3 has a positioning slot 31, a second end 12, and a positioning hole 31, A through hole 32 communicated with the positioning groove 31 and a plurality of positioning screw holes 331, wherein the second end 12 of the load sensor 1 is inserted into the positioning groove 31 of the upper base 3, and is extended to the through hole 32 communicated with the positioning groove 31 of the upper base 3 by another fixing member 34 and is screwed in the second positioning hole 120 of the load sensor 1, and a plurality of first washers 41 can be respectively arranged between the fixing member 25 and the lower base 2, and between the other fixing member 34 and the upper base 3, which can be used for increasing friction surfaces and reducing looseness; the magnetic resistance mechanism 5 is provided with a fixed base body 51, which can combine the upper base 3 on the lower side of the fixed base body 51 by a plurality of fixing pieces 52, one end of the fixed base body 51 is provided with a roller 53, a magnet base 54 is movably pivoted on the fixed base body 51 by a rotating shaft 55, the magnet base 54 is provided with a containing space 56, two sides of the containing space 56 are provided with a plurality of magnets 57, the other end of the fixed base body 51 is connected with one end of a pair of connecting rod groups 58, the other end of the connecting rod group 58 is connected to the lower side of the magnet base 54, a rotating shaft 59 is arranged at the rotating shaft between the connecting rod groups 58, and the fixed base body 51, the magnet base 54 and the pair of connecting rod groups 58 form a four-bar mechanism together; one end of the steel cable 6 is fixed to the fixed base 51, and the other end of the steel cable is sequentially wound around the rotating shaft 59 between the connecting rod sets 58 and the roller 53 of the fixed base 51 and fixed to the adjusting rod 92, as shown in fig. 4.
Referring to fig. 1 and 4, the torque detecting device 10 is disposed through the plurality of through-bolts 7 passing through the plurality of through-holes 231 of the frame 9 and the lower base 2 and fixed by the second washers 71 and the nuts 72 being combined with the through-bolts 7, the accommodating space 56 of the magnet base 54 can accommodate the periphery of the flywheel 91, and the magnets 57 at two sides of the accommodating space 56 can generate magnetic resistance effect on the flywheel 91.
Referring to fig. 1 and 4, when the adjusting rod 92 rotates around the axis C under external force to synchronously pull the steel cable 6 to generate displacement, the steel cable 6 synchronously pulls the rotating shafts 59 of the pair of linkage assemblies 58, the magnet base 54 pivots around the rotating shaft 55, and the pair of linkage assemblies 58 pushes the magnet base 54 upwards during pivoting, so that the magnitude of the magnetic attraction resistance of the magnet 57 of the magnet base 54 when the flywheel 91 rotates can be changed by changing the relative position between the magnet 57 and the flywheel 91 (refer to fig. 5 at the same time), and the load sensor 1 can detect the reaction force of the reluctance mechanism 5, thereby calculating the torque force of the flywheel 91.
The first end 11 and the second end 12 of the load sensor 1 are combined with the lower base 2 and the upper base 3, the hexagon bolt 26 screwed on the screw hole 24 of the lower base 2 by the matching nut 27 is arranged between the lower base 2 and the upper base 3, a gap H is formed between the top surface of the hexagon bolt 26 and the upper base 3, and the hexagon bolt 26 can prevent the load sensor 1 from deforming due to the pressure exerted by the external gravity of the fitness equipment, as shown in fig. 3.
Referring to another embodiment shown in fig. 6, the magnet holder 54 may be provided with a tail end seat 541, one end of the steel cable 6 may be pivoted to the tail end seat 541 of the magnet holder 54, and the other end is fixed to the adjusting rod 92, when the adjusting rod 92 is rotated by an external force based on the axis C to synchronously pull the steel cable 6 to generate displacement (refer to fig. 4 at the same time), the steel cable 6 synchronously pulls the magnet holder 54, so that the magnet holder 54 pivots about the rotating shaft 55.
In summary, the torsion detecting device 10 of the exercise apparatus of the present invention utilizes a steel cable 6 to drive the magnet base 54 to move, so as to change the relative position between the magnet 57 of the magnet base 54 and the flywheel 91, i.e. change the area of the magnet 57 covering the flywheel 91, and the area of the magnet 57 covering the flywheel 91 changes, so as to change the magnetic attraction resistance of the magnet 57 of the magnet base 54 on the rotation of the flywheel 91, and a load sensor 1 can detect the reaction force of the reluctance mechanism 5, and further calculate the torsion value of the flywheel 91.
Claims (7)
1. A torsion force detection device of fitness equipment is characterized in that the fitness equipment comprises a frame, a flywheel and a torsion force detection device are pivoted on the frame, the torsion force detection device comprises a load sensor and a magnetic resistance mechanism, one end of the load sensor is fixed on an upper base, the upper base combined with the load sensor is locked on a fixed base body of the magnetic resistance mechanism, the other end of the load sensor is fixed on a lower base, and the lower base combined with the load sensor is fixed on the frame; one end of a magnet seat is provided with a rotating shaft which can lead the magnet seat to be movably pivoted on the fixed seat body, and the other end of the magnet seat is provided with a plurality of magnets; a steel cable, which can make the magnet seat use the rotating shaft as the rotating axis to change the relative position between the magnet and the flywheel, namely change the area change of the magnet covering the flywheel; by the structure, the area of the magnet covering the flywheel is changed, so that the magnetic attraction resistance of the magnet seat on the flywheel during rotation is changed, and the load sensor can detect the reaction force of the magnetic resistance mechanism so as to calculate the torque force value of the flywheel.
2. The torque force detecting device of exercise equipment according to claim 1, wherein one end of the fixed base of the magnetic resistance mechanism is connected to one end of a pair of linkage, and the other end of the linkage is connected to the lower side of the magnet base, the rotation shaft between the linkage has a rotation shaft, and the fixed base, the magnet base and the pair of linkage form a four-bar linkage.
3. The torsion detecting device according to claim 1, wherein the load sensor has a first end and a second end, the first end of the load sensor has a first positioning hole, the second end of the load sensor has a second positioning hole, the lower base has a positioning groove, a through hole communicating with the positioning groove, a plurality of through holes and a screw hole, the screw hole of the lower base is located between the through holes, the first end of the load sensor is inserted into the positioning groove of the lower base, and is inserted into the through hole communicating with the positioning groove by a fixing member and screwed into the first positioning hole of the load sensor, a hexagonal bolt is screwed into the screw hole of the lower base, the upper base has a positioning groove, a through hole communicating with the positioning groove and a plurality of positioning screw holes, the second end of the load sensor is inserted into the positioning groove of the upper base, and the other fixing piece is used for penetrating to the through hole communicated with the positioning groove of the upper base and is screwed in the second positioning hole of the load sensor, and the plurality of first gaskets are respectively arranged between the fixing piece and the lower base and between the other fixing piece and the upper base and can be used for increasing the friction surface and reducing the looseness.
4. The torque force detecting device of exercise apparatus according to claim 2, wherein the frame further comprises an adjusting rod pivoted to the frame; one end of the fixed base of the magnetic resistance mechanism is provided with a rolling shaft, the magnet base is provided with an accommodating space, and two sides of the accommodating space are provided with the plurality of magnets; one end of the steel cable is fixed on the fixed base of the magnetic resistance mechanism, and the other end of the steel cable is sequentially wound around the rotating shaft between the connecting rod sets and the rolling shaft of the fixed base and is fixed on the adjusting rod.
5. The torque detecting device according to claim 4, wherein the torque detecting device is fixed to the through holes of the frame and the bottom base by a plurality of through bolts and a second washer and a nut, and the magnet seat is configured to receive the periphery of the flywheel, and the magnets at two sides of the receiving space are configured to generate a magnetic resistance effect on the flywheel.
6. The torsion detecting device according to claim 1, wherein the hexagonal bolt screwed into the screw hole of the lower base is disposed between the lower base and the upper base, and a gap is formed between the top surface of the hexagonal bolt and the upper base, and the hexagonal bolt prevents the deformation of the load sensor caused by the external gravity.
7. The torque force detecting device of exercise apparatus according to claim 2, wherein the frame further comprises an adjusting rod pivoted to the frame; the magnet seat may be provided with a tail end seat, one end of the steel cable may be pivoted to the tail end seat of the magnet seat, and the other end of the steel cable is fixed to the adjusting rod, when the adjusting rod rotates around the axis as a reference under external force to synchronously pull the steel cable to generate displacement, the steel cable synchronously pulls the magnet seat to make the magnet seat pivot around the rotating shaft as the axis.
Priority Applications (1)
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CN202011041006.5A CN114272553B (en) | 2020-09-28 | 2020-09-28 | Torsion detecting device of fitness equipment |
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CN202011041006.5A CN114272553B (en) | 2020-09-28 | 2020-09-28 | Torsion detecting device of fitness equipment |
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CN114272553A true CN114272553A (en) | 2022-04-05 |
CN114272553B CN114272553B (en) | 2023-03-14 |
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Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
GB1017361A (en) * | 1962-02-23 | 1966-01-19 | Atlas Bolt And Screw Company | Load cell mounting and alignment for weighing means |
TWM503914U (en) * | 2015-03-17 | 2015-07-01 | Haouse Sports Cycle Co Ltd | Load perception structure of magnetic control exercise bike |
CN109701215A (en) * | 2018-12-29 | 2019-05-03 | 中国科学院合肥物质科学研究院 | A kind of Power Vehicle power regulation mechanism |
CN209630522U (en) * | 2018-11-14 | 2019-11-15 | 祺骅股份有限公司 | Flywheel fitness equipment with variable reluctance |
CN211513283U (en) * | 2019-11-27 | 2020-09-18 | 乔山健身器材(上海)有限公司 | Flywheel body-building vehicle |
-
2020
- 2020-09-28 CN CN202011041006.5A patent/CN114272553B/en active Active
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
GB1017361A (en) * | 1962-02-23 | 1966-01-19 | Atlas Bolt And Screw Company | Load cell mounting and alignment for weighing means |
TWM503914U (en) * | 2015-03-17 | 2015-07-01 | Haouse Sports Cycle Co Ltd | Load perception structure of magnetic control exercise bike |
CN209630522U (en) * | 2018-11-14 | 2019-11-15 | 祺骅股份有限公司 | Flywheel fitness equipment with variable reluctance |
CN109701215A (en) * | 2018-12-29 | 2019-05-03 | 中国科学院合肥物质科学研究院 | A kind of Power Vehicle power regulation mechanism |
CN211513283U (en) * | 2019-11-27 | 2020-09-18 | 乔山健身器材(上海)有限公司 | Flywheel body-building vehicle |
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