Patent Application
20170252888
The present invention relates to a handheld abrader, and more particularly relates to a handheld abrader that may reduce the cost of use and may be adjusted according to the user's need conveniently to increase the applicability of the handheld abrader.
When a surface of metal needs cleaning, decontaminating or descaling, a grinding tray is connected to and rotated with a conventional handheld abrader to grid or polish the surface of metal to provide a cleaning, decontaminating or descaling effect to the metal. The conventional handheld abrader has a body, a driving device and a grinding tray. The body is gun shaped and has a handle and a gun body. The gun body is connected to the handle and has a mounting chamber. The driving device is mounted in the mounting chamber of the gun body and has a driving shaft. The driving shaft is rotatably connected to the body by the driving device and has an end extending out of a front side of the gun body. The grinding tray is connected to the end of the driving shaft and is rotated with the driving shaft relative to the body.
However, the conventional handheld abrader may provide a cleaning, decontaminating or descaling effect to the metal. Since the driving shaft of the conventional handheld abrader has a specific torque, users need to replace or buy handheld abraders with different torques when the metal needs to be grinded or polished by different ways such as rough grinding or fine grinding, and this may increase the cost of use and may limit the applicability of the conventional handheld abrader.
To overcome the shortcomings, the present invention provides a handheld abrader to mitigate or obviate the aforementioned problems.
The main objective of the present invention is to provide a handheld abrader that may reduce the cost of use and may be adjusted according to the user's need conveniently to increase the applicability of the handheld abrader.
The handheld abrader in accordance with the present invention has a body, a driving device, an eccentric device, and a grinding tray. The body has a handle and a gun body. The driving device is mounted in the gun body and has a driving shaft. The eccentric device is connected to the driving device and has a transmitting sheath, a transmitting shaft, and an eccentric sleeve. The transmitting sheath is connected to the driving shaft and has two positioning recesses and a receiving chamber. The transmitting shaft has at least one engaging face. The eccentric sleeve is movably mounted around the transmitting sheath and has at least one positioning slice abutting against the transmitting sheath in one of the positioning recesses and an engaging ring mounted in the eccentric sleeve, mounted around the transmitting shaft, and having at least one pressing arm selectively pressed against the transmitting shaft at the at least one engaging face.
Other objects, advantages and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
With reference to
The body 10 may be in a gun shape and has a handle 11 and a gun body 12. The handle 11 has at least one controlling unit such as a pressing button 13 or a toggle button 14. The at least one controlling unit is conventional and the features and the structures of the at least one controlling unit are not described in detail. The gun body 12 is formed with the handle 11 and has a mounting chamber 121.
The driving device 20 is mounted in the mounting chamber 121 of the gun body 12, and is electrically connected to the at least one controlling unit of the handle 11 to control a rotating direction of the driving device 20. The driving device 20 has a driving shaft 21 rotatably mounted in the gun body 12 of the body 10. The driving shaft 21 has an outer end and a connecting recess 211. The outer end of the driving shaft 21 extends out of a front side of the gun body 12 and has a front side. The connecting recess 211 is formed in the front side of the outer end of the driving shaft 21. In addition, the driving shaft 21 has an inner thread formed in the connecting recess 211.
With reference to
The transmitting sheath 31 is connected to the driving shaft 21 at the front side of the gun body 12, and has a rear side, a front side, an outer surface, a connecting rod 311, two positioning recesses 312, a guiding block 313, and a receiving chamber 314. The rear side of the transmitting sheath 31 faces the outer end of the driving shaft 21. The connecting rod 311 is formed on and protrudes from the rear side of the transmitting sheath 31 and is connected to the connecting recess 211 of the driving shaft 21 to enable the transmitting sheath 31 to rotate with the driving shaft 21 relative to the body 10.
In addition, the connecting rod 311 has an outer thread screwed with the inner thread in the connecting recess 211 of the driving shaft 21 to connect the transmitting sheath 31 securely with the driving shaft 21. The two positioning recesses 312 are annularly formed in the outer surface of the transmitting sheath 31 at a spaced interval. The guiding block 313 is mounted on the outer surface of the transmitting sheath 31. With reference to
The transmitting shaft 32 is mounted in the receiving chamber 314 of the transmitting sheath 31 and has an external surface, a front end, an engaging segment, a bearing 322, and at least one C-ring 323. The front end of the transmitting shaft 32 extends out of the receiving chamber 314 of the transmitting sheath 31. The engaging segment is formed on the external surface of the transmitting shaft 32 that extends out of the transmitting sheath 31. In addition, the engaging segment has at least one engaging face 321 formed on the external surface of the transmitting shaft 32 that extends out of the transmitting sheath 31. Furthermore, the transmitting shaft 32 may have two engaging faces 321 formed on the external surface of the transmitting shaft 32 at the engaging segment of the transmitting shaft 32. The bearing 322 and the at least one C-ring are mounted around the transmitting shaft 32, and are mounted in the receiving chamber 314 of the transmitting sheath 31 to hold the transmitting shaft 32 with the transmitting sheath 31. Additionally, with reference to
The eccentric sleeve 33 is movably mounted around the transmitting sheath 31, and the front end of the transmitting shaft 32 extends out of a front side of the eccentric sleeve 33. In addition, the eccentric sleeve 33 may be formed by two half-casings 331. The eccentric sleeve 33 has an internal surface, a front side, at least one positioning slice 332, a guiding recess 333, and an engaging element. The at least one positioning slice 332 is mounted on the internal surface of the eccentric sleeve 33 and abuts against the transmitting sheath 31 in one of the positioning recesses 312. In addition, the at least one positioning slice 332 may be a V-shaped elastic sheet.
Furthermore, the eccentric sleeve 33 has at least one embedded slot 335 formed in the internal surface of the eccentric sleeve 33, and the at least one positioning slice 332 is securely mounted in the at least one embedded slot 335 to hold the at least one positioning slice 332 in the eccentric sleeve 33. Additionally, the eccentric sleeve 33 has two embedded slots 335 formed in the internal surface of the eccentric sleeve 33 and two positioning slices 332 respectively mounted in the two embedded slots 335. Furthermore, the two positioning slices 332 are mounted on the internal surface of the eccentric sleeve 33 at a spaced interval and abut against the outer surface of the transmitting sheath 31 in the same positioning recess 312.
The guiding recess 333 is axially formed in the internal surface of the eccentric sleeve 33 and is disposed around the guiding block 313 of the transmitting sheath 31. In addition, the guiding recess 333 has a length along an axis direction of the transmitting shaft 32 longer than a length of the guiding block 313. Then, the eccentric sleeve 33 may be moved relative to the transmitting sheath 31 by the length difference between the eccentric sleeve 33 and the transmitting sheath 31, and the eccentric sleeve 33 may be rotated with the transmitting sheath 31 by the guiding recess 333 disposed around the guiding block 313.
Furthermore, the eccentric sleeve 33 has a fixing slot 336 and at least one engaging groove 337. The fixing slot 336 is formed in the internal surface of the eccentric sleeve 33 adjacent to the front side of the eccentric sleeve 33. The at least one engaging groove 337 is formed in the internal surface of the eccentric sleeve 33 and communicates with the fixing slot 336. Additionally, the eccentric sleeve 33 has two engaging grooves 337 formed in the internal surface of the eccentric sleeve 33 at a spaced interval and communicating with the fixing slot 336.
The engaging element is securely mounted in the eccentric sleeve 33 and selectively engages the engaging segment of the transmitting shaft 32 to enable the eccentric sleeve 33 to rotate with the transmitting shaft 32. Furthermore, the engaging element has an engaging ring 334 securely mounted in the fixing slot 336 of the eccentric sleeve 33, mounted around the transmitting shaft 32, and having a through hole, an outer periphery, at least one pressing arm 338, and at least one holding segment 339. The through hole is formed through the engaging ring 334 and is disposed around the transmitting shaft 32. The at least one pressing arm 338 is formed on and protrudes from the engaging ring 334 adjacent to the through hole, extends into the through hole, and selectively presses against the transmitting shaft 32 at the at least one engaging face 321 to enable the eccentric sleeve 33 to rotate with the transmitting shaft 32. Furthermore, the engaging ring 334 has two pressing arms 338 formed on the engaging ring 334 adjacent to the through hole and selectively pressed against the transmitting shaft 32 respectively at the engaging faces 321 of the transmitting shaft 32.
The at least one holding segment 339 is formed on and protrudes from the outer periphery of the engaging ring 334 and is mounted in the at least one engaging groove 337 to hold the engaging ring 334 securely on the internal surface of the eccentric sleeve 33. In addition, the engaging ring 334 has two holding segments 339 formed on and protruding from the outer periphery of the engaging ring 334 at a spaced interval and respectively mounted in the two engaging grooves 337 of the eccentric sleeve 33.
The grinding tray 40 is connected to the transmitting shaft 32 of the eccentric device 30 at the front side of the eccentric sleeve 33 to rotate relative to the body 10 by the driving device 20.
With reference to
With reference to
When the grinding tray 40 abuts against an object to grind or polish a surface of the object, a rotating force of the driving shaft 21 is transmitted to the grinding tray 40 via the transmitting sheath 31 and the transmitting shaft 32. Then, the grinding tray 40 is rotated relative to the object to grind or polish the surface of the object. During the above-mentioned grinding process, since the at least one pressing arm 338 presses against the transmitting shaft 32 at the at least one engaging face 321 to hold the transmitting shaft 32 with the eccentric sleeve 33, this enables an eccentric rotating force of the eccentric sleeve 33 to transmit to the transmitting shaft 32. Then, the transmitting shaft 32 has a larger torque to transmit to the grinding tray 40 and this enables the object to be grinded or polished in a rough grinding way.
With reference to
When the pressing button 13 is pressed to operate the driving device 20, the rotating force of the driving shaft 21 is transmitted to the transmitting shaft 32 via the transmitting sheath 31. Since the at least one pressing arm 338 is not pressed against the transmitting shaft 32 at the at least one engaging face 321, the transmitting shaft 32 is not held with the eccentric sleeve 33. Then, the eccentric rotating force of the eccentric sleeve 33 may not transmit to the transmitting shaft 32, and this enables the transmitting shaft 32 to rotate with the transmitting sheath 31 without the eccentric sleeve 33. Therefore, the object is grinded or polished by the grinding tray 40 with a smaller torque in a fine grinding way.
According to the above-mentioned features and structural relationship of the handheld abrader, the torque of the handheld abrader may be adjusted according to the user's need by changing the position of the eccentric sleeve 33 relative to the transmitting sheath 31. Then, the at least one pressing arm 338 of the eccentric sleeve 33 presses against or separates from the at least one engaging face of the transmitting shaft 32 to change the conditions between the transmitting sheath 31 and the eccentric sleeve 33 in an engaging condition (larger torque) or a separating condition (smaller torque). Consequently, the single handheld abrader can be used with different torques to grind or polish the object by different grinding ways according to the user's need without replacing or buying other handheld abraders with different torques, and this may decrease the cost of use and may improve the applicability of the handheld abrader.
Even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and features of the invention, the disclosure is illustrative only. Changes may be made in the details, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
