The present invention relates to physical training equipment, and more particularly to a treadmill with an anti-entrapment function.
People nowadays pay more and more attention to health. It is therefore not uncommon to have a treadmill placed in one's house so that physical training can be carried out at home, rain or shine, with the treadmill.
Generally, a treadmill has a setting panel, or control panel, with which a user can adjust the rotation speed of the running belt according to the desired running speed.
While the user can adjust the rotation speed of the running belt with the control panel if the rotation speed is too high, the relatively small sizes of the buttons on the control panel make it difficult to find any button rapidly when the user is nervous or in an urgent situation. Moreover, should the user fall, it will be difficult for the user to press any button on the control panel, which is usually at a relatively great height, and the running belt will therefore keep rotating and may pull and entrap the user's clothes, limbs or foreign objects into a gap on either side of, or under, the running belt, which is dangerous.
One objective of the present invention is to provide a treadmill that has an anti-entrapment function to prevent the entrapment of the user's clothes, limbs or foreign objects.
The treadmill of the present invention has an anti-entrapment function and allows a user to stand on the treadmill. The treadmill with the anti-entrapment function includes a running unit, a driving unit, a control unit, and a sensing unit.
The running unit includes a main base, two lateral bases that extend rearward from the main base and are spaced apart from each other, a driving roller and a driven roller that are pivotally provided between the lateral bases, and a running belt that is provided between the lateral bases, is looped around the driving roller and the driven roller, and allows the user to stand on the running belt. The direction in which each lateral base extends is defined as a direction along or substantially parallel to a front-rear axial direction of the running unit. Each lateral base has a front section adjacent to the main base and a rear section extending away from the front section along the front-rear axial direction. Each rear section has a top end portion higher than the running belt and a bottom end portion lower than the running belt.
The driving unit is provided at the main base and is configured to drive the driving roller into rotation so that the running belt is driven to rotate around the driving roller and the driven roller, thereby allowing the user to run forward on the running belt along the front-rear axial direction.
The control unit is in signal communication with the driving unit.
The sensing unit includes a guard bar and at least one sensing member. The guard bar is pivotally provided at the bottom end portions of the running unit and is at least partially located at the back of the running belt. The at least one sensing member is provided at the running unit. The guard bar is configured to rotate about a rotation axis that is perpendicular to the front-rear axial direction. When the guard bar is subjected to an external force and is thus rotated downward about the rotation axis, the at least one sensing member is driven by the guard bar to send a warning signal to the control unit, in order for the control unit to control the rotation speed of the driving roller accordingly.
The present invention has the following effects: When the user's clothes, limbs or foreign objects are accidentally pulled into the gap between the running belt and one of the lateral bases, the guard bar will be driven to rotate about the rotation axis, causing the at least one sensing member to send out the warning signal. The control unit will receive the warning signal immediately and then control the rotation speed of the driving roller in order to keep the user's clothes, limbs or foreign objects are from being pulled deeper into the gap.
Other features and effects of the present invention can be known by referring to the following detailed description in conjunction with the accompanying drawings, in which:
Referring to
The running unit 1 includes a main base 11, two lateral bases 12 that extend rearward from the main base 11 and are spaced apart from each other, a driving roller 13 and a driven roller 14 that are pivotally provided between the lateral bases 12. A running belt 15 is provided between the lateral bases 12, and is looped around the driving roller 13 and the driven roller 14 to allow the user to stand on the running belt 15. The direction in which each lateral base 12 extends is defined as a front-rear axial direction X of the running unit 1.
Each lateral base 12 has a front section 121 adjacent to the main base 11 and a rear section 122 that extends away from the front section 121 along the front-rear axial direction X. Each rear section 122 has a top end portion 123 higher than the running belt 15 and a bottom end portion 124 lower than the running belt 15.
The driving unit 2 is provided at the main base 11 and is configured to drive the driving roller 13 into rotation, thereby driving the running belt 15 to rotate around the driving roller 13 and the driven roller 14 so that the user can run forward on the running belt 15 in the front-rear axial direction X. In this embodiment, the driving roller 13 is located at the front side, and the driven roller 14 at the rear side; the present invention, however, has no limitation on which of the two rollers is at the front or rear side.
The sensing unit 4 includes a guard bar 41, at least one sensing member 42, and at least one elastic member 43. The guard bar 41 is pivotally provided at the bottom end portions 124 and is at least partially located at the back of the running belt 15. The at least one sensing member 42 is provided at the running unit 1. The at least one elastic member 43 is connected to the guard bar 41.
In this embodiment, the sensing unit 4 includes two sensing members 42 and two elastic members 43. (
As shown in
The guard bar 41 is configured to rotate about a rotation axis L that is perpendicular to the front-rear axial direction X. When the guard bar 41 is subjected to an external force and is thus rotated downward about the rotation axis L (see
To use the treadmill with the anti-entrapment function, the user stands on the running belt 15 and then starts running forward. Should the user's clothes, limbs or a foreign object (not shown) be accidentally pulled into the gap between the running belt 15 and one of the lateral bases 12, the rotating running belt 15 will move the user's clothes, limbs or foreign object to the rear side of the running belt 15 and then pull the user's clothes, limbs or foreign object downward.
As the transverse bar section 411 of the guard bar 41 corresponds to the space between the bottom end portions 124 and is located at the back of the running belt 15, the user's clothing or limbs, or the foreign object, will press down on the transverse bar section 411 when pulled downward by the running belt 15. In consequence, the guard bar 41 is rotated downward about the rotation axis L and thereby drives the sensing members 42. More specifically, while the guard bar 41 is rotated downward about the rotation axis L, the end of each sensing section 413 that faces away from the corresponding pivotal connection section 412 is moved upward from the position shown in
Once triggered, the sensing members 42 send the warning signal to the control unit 3.
When receiving the warning signal, the control unit 3 controls the rotation speed of the driving roller 13 according to instructions written into the control unit 3 in advance. For example, the control unit 3 may control the driving roller 13 by immediately stopping the driving roller 13 from rotating or by gradually reducing the rotation speed of the driving roller 13 until the driving roller 13 stops rotating.
Thus, when the user's clothing or limbs, or the foreign object, is accidentally pulled into the gap between the running belt 15 and one of the lateral bases 12, the guard bar 41 will be driven to rotate about the rotation axis L and thereby cause the sensing members 42 to send out the warning signal. The control unit 3 will receive the warning signal at once and control the driving roller 13 by stopping it from rotating, lest the user or the foreign object be pulled deeper into the gap, the objective being to lower the severity of personal injury or of the damage of the foreign object or the treadmill with the anti-entrapment function.
Once the condition of the user's clothing or limbs, or the foreign object, caught in the gap between the running belt 15 and one of the lateral bases 12 is cleared from the gap, the elastic members 43, which provide the guard bar 41 with potential energy that always tends to rotate the guard bar 41 upward, bring the guard bar 41 back to the position shown in
It is worth mentioning that, as the transverse bar section 411 of the guard bar 41 corresponds to the space between the bottom end portions 124 and is located at the back of the running belt 15, a person other than the user or a foreign object that is moving toward the treadmill with the anti-entrapment function from the back of the treadmill will be kept by the transverse bar section 411 from contact with the running belt 15. This prevents the person or the foreign object approaching the treadmill from the rear from being pulled into the gap under the running belt 15, thereby protecting the person from injury, or the foreign object and the treadmill with the anti-entrapment function from damage.
Moreover, it should be pointed out that while the guard bar 41 in this embodiment is pivotally provided at the bottom end portions 124 and, when subjected to an external force and thus rotated downward about the rotation axis L, can trigger the sensing members 42 by moving upward the end of each sensing section 413 that faces away from the corresponding pivotal connection section 412, it is not required that the guard bar 41 have the configuration described above. In other embodiments, the guard bar 41 may be movably provided at the bottom end portions 124, with one side of the guard bar 41 located at the back of the running belt 15, and the opposite side of the guard bar 41 extending forward, provided at the bottom end portions 124, and adjacent to the sensing members 42 so that when the guard bar 41 is moved (e.g., forward or downward) with respect to the bottom end portions 124 by an external force, each end of the guard bar 41 that is adjacent to one of the sensing members 42 will approach the corresponding sensing member 42 and drive the corresponding sensing member 42 to send out the warning signal. This alternative configuration is equally capable of achieving the objective stated above.
According to the foregoing, the treadmill with the anti-entrapment function as disclosed herein is so designed that when a user's clothing or limbs, or a foreign object, is accidentally pulled into the gap between the running belt 15 and one of the lateral bases 12, the guard bar 41 will be driven to rotate about the rotation axis L, in order for the sensing members 42 to send out the warning signal. The control unit 3 will receive the warning signal at once and control the driving roller 13 by stopping it from rotating, preventing the user's limb, clothing or the foreign object from being pulled deeper into the gap. Thus, the severity of personal injury or of the damage of the foreign object and the treadmill with the anti-entrapment function can be lowered to attain the objective of the invention.
It should be understood that the embodiments described above are only some feasible ones of the present invention and are not intended to be restrictive of the scope of the invention. Any equivalent change or modification that is based on the appended claims and the contents of this specification shall fall within the scope of the invention.
Number | Date | Country | Kind |
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110117806 | May 2021 | TW | national |