The present invention relates to an apparatus for hand tools, and more particularly to a precision handle for hand tools that can facilitate smooth and efficient operation of the hand tools.
This section provides background information related to the present disclosure which is not necessarily prior art.
With reference to
However, the positioning element 90 is mounted around the mounting protrusion 81 directly, and the mounting protrusion 81 engages the positioning element 90 in a surface-to-surface contact. Thus the friction between the mounting protrusion 81 and the positioning element 90 increases when the body 80 rotates, and makes users unable to operate the precision hand tool smoothly.
To overcome the shortcomings of the conventional precision handle for hand tools, the present invention provides a precision handle for hand tools to mitigate or obviate the aforementioned problems.
This section provides a general summary of the disclosure, and is not a comprehensive disclosure of its full scope or all of its features.
An aspect of the present invention is to provide a precision handle which could be operated smoothly and efficiently.
The precision handle for hand tools has a body, an elastic element, a sheath, a pressing element, and a group of balls. A mounting protrusion protrudes axially from a rear end of the body. The elastic element is mounted in the body. The sheath is mounted around the mounting protrusion. The pressing element is mounted through and engages with the sheath. The group of balls includes a first ball and a second ball. The first ball is mounted in the mounting protrusion and abuts the elastic element. The second ball is mounted between the pressing element and the first ball. The first ball abuts the second ball at one point of contact when the pressing element is pressed, which can decrease the friction between the body and the sheath. So the precision handle for hand tools may be operated smoothly and efficiently.
Other aspects, advantages, and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
The drawings described herein are for illustrative purposes only of a selected embodiment and not all possible implementations, and are not intended to limit the scope of the present disclosure.
An example embodiment will now be described more fully with reference to the accompanying drawings.
With reference to
The body 10 is rod-shaped and has a front end 101, a rear end 102, and a mounting protrusion 11. A tool head may be mounted in the front end 101 of the body 10. The mounting protrusion 11 is axially formed on and protrudes from the rear end 102 of the body 10 and comprises a rear side, a mounting recess 111, a through hole 112, and a limiting circular rib 113. The rear side of the mounting protrusion 11 is opposite to the rear end 102 of the body 10 and has an inner diameter. The mounting recess 111 is formed in the mounting protrusion 11 adjacent to the rear end 102 of the body 10. The through hole 112 is formed through the rear side of the mounting protrusion 11 and has an inner diameter. The inner diameter of the through hole 112 is larger than an inner diameter of the mounting recess 111. The limiting circular rib 113 is formed in the mounting protrusion 11 at a connecting portion between the mounting recess 111 and the through hole 112. The limiting circular rib 113 is tapered from the through hole 112 toward the mounting recess 111.
The elastic element 20 is mounted in the mounting recess 111 via the through hole 112. Preferably, the elastic element 20 is a spring.
The sheath 30 may be a tapered tube, is securely mounted around the mounting protrusion 11 of the body 10, and comprises an inner surface, a proximal end 301, a distal end 302, a positioning circular rib 31, and a connecting hole 32. The proximal end 301 of the sheath 30 abuts the rear end 102 of the body 10. The distal end 302 of the sheath 30 is opposite to the proximal end 301. The positioning circular rib 31 is formed radially inward on the inner surface of the sheath 30 adjacent the distal end 302 of the sheath 30. The connecting hole 32 is formed through the distal end 302 of the sheath 30 and communicates with the through hole 112.
With reference to
The embedded portion 42 has an outer surface, a proximal side 420, an engaging circular rib 421, two constricting recesses 422, and an embedding recess 423. The proximal side 420 is opposite to the proximal face 410 of the pressing element 40. The engaging circular rib 421 is formed radially outward on the embedded portion 42 at the proximal side 420 of the embedded portion 42. The engaging circular rib 421 engages the positioning circular rib 31 of the sheath 30, and this enables the pressing element 40 to be connected to the sheath 30 without separating. The two constricting recesses 422 are formed through the outer surface of the embedded portion 42 and the engaging circular rib 421 radially, thereby making the embedded portion 42 deformable. The two constricting recesses 422 face to each other. The embedding recess 423 is formed in the proximal side 420 of the embedded portion 42 axially and is a circular recess. The embedding recess 423 communicates with the two constricting recesses 422.
The group of balls 50 is mounted in the sheath 30 between the mounting protrusion 11 of the body 10 and the pressing element 40. The group of balls 50 comprises a first ball 51 and a second ball 52. The first ball 51 is mounted in the mounting protrusion 11 via the through hole 112 and has a front side. A diameter of the first ball 51 is smaller than the inner diameter of the through hole 112, while the diameter of the first ball 51 is larger than the inner diameter of the mounting recess 111. The first ball 51 is located in the through hole 112, and the front side of the first ball 51 extends in the mounting recess 111 to enable the first ball 51 to abut the elastic element 20. The second ball 52 is embedded in the embedding recess 423 of the pressing element 40 and abuts the first ball 51 at one point of contact due to the pushing force between the elastic element 20 and the first ball 51. An annular gap is formed between the distal end 302 of the sheath 30 and the pressing disk 41 of the pressing element 40.
In use, with reference to
Compared with the conventional precision handle, wherein the mounting protrusion 81 engages the positioning element 90 in a surface-to-surface contact, the friction between the mounting protrusion 81 and the positioning element 90 is increased, and users are unable to operate the precision hand tool smoothly. The precision handle for hand tools of the present invention has the following advantages.
1. The first ball 51 continually touches the second ball 52 at one point of contact, which may decrease the friction between the body 10 and the pressing element 40. Thus the precision handle can be operated more smoothly and more efficiently.
2. The screw, the body 10 and the pressing element 40 may stay precisely aligned and linear while the precision handle is operated. Thus the precision handle may maintain its precision since the friction between the body 10 and the pressing element 40 decreases.
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 function of the invention, the disclosure is illustrative only, and changes may be made in detail, 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.