This invention is to introduce a screwdriver bit holder structure, which can prevent driver bits from springing out unexpectedly while being unloaded.
A prior art was proposed as Taiwan Patent No. M293121 “Screwdriver Bit Holder Structure (1)”, which comprises a screwdriver bit holder that has a polygon hole allowing load or unload of a driver bit, and at least a shaft-axis hole on top of it allowing balls to fit in; a ring clipped on the holder body externally, pushed by a spring component that is set between the ring and the holder body, and its inner part has a pressing wall used to push balls to fix bits. Its features include: at least one shaft-axis hole at the lower part of the holder body for balls to fit in, and a cylinder cavity at the inner part of the polygon hole. A spring component and fixing plate are set inside the cylinder cavity, and the fixing plate has a triangle recess facing the shaft-axis hole. The ring has a concave and a pushing surface facing the shaft-axis hole, and the pressing wall of it is gradient-curved surfaced. Based on aforementioned structure, the pushing surface of the ring can push balls into the triangle recess so as to position the ring and fixing plate, and then utilize the gradient-curved surfaced pressing wall to push balls fit into the concaves of driver bits for tightening.
Although driver bits can be fixed in the polygon hole tightly based on aforementioned structure, it may cause safety concern because the spring component fixed in the fixing plate will suddenly and fully release accumulated power, then pushes fixing plate move outwards rapidly, which further forces the magnetized bits to spring out of the bit holder too powerfully to a dangerous extent when the bits are released by pushing down the ring until the top and bottom balls can leave the concaves of the bits and the triangle recess of fixing plate.
Throughout rigorous tests and researches, the inventor finally devised such an improved structure that enables a driver bit to be unloaded from polygon hole more gently to prevent dangers from powerful ejection of the bit occurring in prior arts. Therefore, a patent application is hereby being filed based on the absolute novelty and capability of industrial application of the invention.
The screwdriver bit holder structure proposed in this invention is mainly intended to reach following two purposes. First, it can be assembled from the front end of the holder body, simplifying the installation complexity. Second, it enables driver bits to be fixed smoothly and tightly into the holder body, and to be unloaded safely by avoiding powerful ejection occurring in prior arts.
To reach aforementioned purposes, the invention proposes a screwdriver bit holder structure, which comprises: a holder body that sets a polygon hole in one end for loading bits, and at the end of the polygon hole sets a cylinder cavity that houses a inner spring and a sliding tube; a c-clamp clips the holder body externally, and ahead of which are front balls that fit in or unfit from the concaves positioned in the middle of the bits to fix or loose bits; behind the c-clamp are symmetric middle and back balls and holes that can fit with front and back grooves to confine the movements of the sliding tube; A fixing cap is capped on the holder body around polygon hole. A limiting ring is set at the back of the fixing cap, and a front recess and a back recess are set in front of the fixing cap that is designed, by sliding the cap forward and backward along the holder body, to push front balls to fit into the fitting concaves of the bits so as to fix them tightly with the holder body or loose front balls from fitting concaves to release the bits. An outer spring is also installed between the back recess and c-clamp. As a solid improvement, above components enables the proposed screwdriver bit holder easily assembled, and makes sure the bits be loaded tightly or unloaded easily and safely.
FIG. 1—A breakdown view of the structure of exemplary embodiment
FIG. 2—A put-up view of the structure of exemplary embodiment
FIG. 3—A sectional view based on
FIG. 4—A view of
FIG. 5—A sectional view based on
FIG. 6—A view of
Please read the description of an exemplary embodiment as follows with references to
For more supplements: about the front ball holes 13 on the polygon hole 11 of the holder body 10, their radius decrease from outside towards inside of the polygon hole 11 to limit the length the front balls 131 can beetle into the polygon hole 11; further, the axis (not shown in the FIG.) of the front ball holes 13 should fall right on either included angle of the polygon hole 11 to make sure front balls 131 can fit perfectly into the fitting concaves 61 located on the included angle of driver bits 60.
The sliding tube 30 is cylinder shaped. Besides front groove 31 and back groove 32, it also sets a magnet 33 in its front end in order to magnetize the driver bits 60 to prevent its dropping when it is not firmly fixed in the right position. Moreover, please read descriptions of movements before and after the bits are firmly positioned; First,
When no bit is loaded, the inner spring 20 will be stretching out naturally, pushing sliding tube 30 outwards and making the convex ring 34 positioned between front groove 31 and back groove 32 moves forward to simultaneously force two middle balls 141 outwards. Then, because the middle balls 141 beetle out of the holder body 10, the fixing cap 50 will be prevented from falling off holder body 10 due to middle balls' blockage against the limiting ring 54 of holder body 10; And the back balls 151 just touch the inner wall of the limiting ring 54, so the back balls 151 are forced to beetle into the cylinder cavity 12 to nest into the back groove 32, which provides a blockage against stopping ring 321 and thus prevents sliding tube 30 from further forward moving. The outer spring 40 set between holder body 10 and the inner hole 51 of fixing cap 50 is actually against both c-clamp 16 and the side wall of back recess 53 on both ends. Also in natural stretch condition as inner spring, it pushes fixing cap 50 outwards c-clamp 16, which not just forces limiting ring 54 to firmly against middle balls 141, but also makes the front recess 52, whose radius is greater than back recess 53, in line with front ball holes 13. As a result, the front balls 131 nested in the front ball holes 13 could have more moving rooms to stay away from polygon hole 11; Aforementioned describe the status of all the components in natural condition without bits being loaded. When a bit is inserted into the polygon hole, it will be immediately attracted by the magnet 33 of the sliding tube 30, but not yet fixed.
Provided a bit 60 is firmly fixed inside the polygon hole 11. To unload the bit 60, the fixing cap 50 needs to be pushed backwards until the front recess 52 meets with front ball holes 13, and the front balls 131 can have rooms to unfit from the fitting concave and fully nest inside the front ball holes 13. Thus, all components will be in same status as shown in
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95220643 U | Nov 2006 | TW | national |
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