HANDLE DEVICE FOR A HAMMER GUN

Abstract

A handle device for a hammer gun includes a tubular sleeve and a handle body. The tubular sleeve is adapted to connect threadedly with a barrel of the hammer gun, and includes front and rear end faces, a peripheral wall interconnecting the front and rear end faces, an installing cavity extending from the front end face toward the rear end face and adapted to receive therein the barrel of the hammer gun, and a retaining portion provided on the peripheral wall. The handle body has a grip portion, and a casing portion molded directly over the tubular sleeve and engaging the retaining portion so that the tubular sleeve is connected immovably to the handle body.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

Other features and advantages of the present invention will become apparent in the following detailed description of the preferred embodiment of the invention, with reference to the accompanying drawings, in which:

FIG. 1 is a sectional view of a hammer gun incorporating a currently available handle device;

FIG. 2 is a sectional view of a hammer gun incorporating a handle device according to the preferred embodiment of the present invention;

FIG. 3 is a perspective view of a tubular sleeve of the preferred embodiment;

FIG. 4 is a perspective view of an alternative form of the tubular sleeve of the preferred embodiment;

FIG. 5 is a sectional view of another alternative form of the tubular sleeve of the preferred embodiment;

FIG. 6 is a perspective view of still another alternative form of the tubular sleeve of the preferred embodiment; and

FIG. 7 is a perspective view of yet another alternative form of the tubular sleeve of the preferred embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to FIGS. 2 and 3, the preferred embodiment of a handle device 2 for a hammer gun according to the present invention is adapted to connect threadedly with a barrel 9 of the hammer gun, and is shown to comprise a tubular sleeve 3 and a handle body 4.

The tubular sleeve 3 is made of metal, defines an axis (II), and includes front and rear end faces 31, 32, a peripheral wall 33 interconnecting the front and rear end faces 31, 32, an installing cavity 34 extending from the front end face 31 toward the rear end face 32 and adapted to receive therein the barrel 9, and a retaining portion 35 provided on the peripheral wall 33. The peripheral wall 33 includes an internally threaded section 341 proximate to the front end face 31 and adapted to engage threadedly the barrel 9 of the hammer gun, a fixing section 342 proximate to the rear end face 32, and an air inlet section 343 connected between the internally threaded section 341 and the fixing section 342. The fixing section 342 has the retaining portion 35, and an open end (not visible in FIG. 3) at the rear end face 32 of the tubular sleeve 3. The retaining portion 35 includes a plurality of angularly spaced-apart through holes 351 extending radially through the fixing section 342. The air inlet section 343 has an air inlet port 331 extending radially through the air inlet section 343 and communicating fluidly with the installing cavity 34.

Preferably, the peripheral wall 33 of the tubular sleeve 3 is further provided with at least one auxiliary positioning recess 361 extending annularly in an outer surface of the internally threaded section 341. In this embodiment, the peripheral wall 33 is provided with three spaced-apart auxiliary positioning recesses 361.

The handle body 4 is made of plastic, and has a grip portion 401 and a casing portion 402 molded directly over the tubular sleeve 3. The grip portion 401 has an air passage 41 communicating fluidly with the air inlet port 331 of the tubular sleeve 3, a mounting hole 42 for mounting of a switch 8 therein and communicating fluidly with the air passage 41, and an air inlet channel 43 extending from the mounting hole 42 to a bottom wall face 44 of the handle body 4. The casing portion 402 has a part 4021 filling and engaging the open end of the fixing section 342 and the through holes 351 in the retaining portion 35. The bottom wall face 44 of the handle body 4 is provided with a hole 431 that communicates fluidly with the air inlet channel 43. A tube (not shown) may be connected to the air inlet channel 43 via the hole 431 for supply of highly compressed air. By pressing the switch 8, highly compressed air can flow from the air inlet channel 43 through the mounting hole 42, the air passage 41, the air inlet port 331, and in to the installing cavity 34, so that the barrel 9 is activated to produce a hammering action.

During manufacture of the handle device 2, the tubular sleeve 3 is first positioned inside a mold cavity of a mold assembly (not shown), after which a plurality of auxiliary forming blocks (not shown), which can be removed after molding, are placed respectively at predetermined positions within the mold cavity. Molten plastic material is then injected into the mold cavity. After the plastic material is molded over the tubular sleeve 3 and is formed into the handle body 4, the auxiliary forming blocks are removed from the handle body 4. The handle device 2 formed in this manner has the tubular sleeve 3 integral with the handle body 4. The handle body 4 has an air-discharge groove 45 (see FIG. 2) in communication with the external environment. The function of the air-discharge groove 45 is to permit discharging of air during the injection molding process. The presence of the air-discharge groove 45 does not affect the strength of the connection between the handle body 4 and the tubular sleeve 3 nor does it affect the function of the handle device 2.

In the injection molding process, the plastic material is filled into the open end of the fixing section 342 and the through holes 351 of the retaining portion 35, so that the tubular sleeve 3 is connected immovably to the handle body 4. Through the temporary placement of the auxiliary forming blocks in the internally threaded section 341 and the air inlet section 343 of the tubular sleeve 3 during the molding of the handle body 4, the internally threaded and air inlet sections 341, 343 are prevented from being filled with the plastic material. Moreover, the plastic material also fills and covers the auxiliary positioning recesses 361, so that the tubular sleeve 3 and the handle body 4 interengage further to prevent relative movement therebetween. Hence, the connection between the tubular sleeve 3 and the handle body 4 is strong and stable.

In an alternative embodiment, referring to FIG. 4, the open end 345 of the fixing section 342 of the tubular sleeve 3 is of polygonal cross section, and the peripheral wall 33 is indented to form the retaining portion 35. The retaining portion 35 includes an annular groove 352 formed in an outer surface of the fixing section 342. The part 4021 of the casing portion 402 of the handle body 4 (see FIG. 2) also fills and engages the open end 345 and the annular groove 352. Because of the polygonal open end 345 of the fixing section 342 and the presence of the annular groove 352, the tubular sleeve 3 cannot rotate nor axially move relative to the handle body 4. Hence, the handle body 4 and the tubular sleeve 3 are connected stably to each other. Although the fixing section 342 is shown to have a hexagonal cross section, the shape of the fixing section 342 is not limited thereto. As long as the fixing section 342 is not circular in cross section which can permit rotation, the fixing section 342 may have a cross section of any geometrical or irregular shape, such as a tetragonal, pentagonal, octagonal, heart-shaped or star-shaped cross section, which can restrict rotation of the tubular sleeve 3 relative to the handle body 4.

In another alternative embodiment, referring to FIG. 5, the fixing section 342 of the peripheral wall 33 of the tubular sleeve 3 has a closed end wall 37 forming the rear end face 32, and the retaining portion 35 of the tubular sleeve 3 includes a plurality of angularly spaced-apart blind bores 353 extending radially in the closed end wall 37. The retaining portion 35 may also be as shown in FIG. 6, i.e., the retaining portion 35 may include a polygonal section 350 that surrounds the outer surface of the fixing section 342 and that has a plurality of corners 354 and flat sides 355 between adjacent ones of the corners 354. The part 4021 of the casing portion 402 of the handle body 4 (see FIG. 2) also fills and engages the blind bores 353 or the polygonal section 350, so that the stable connection between the tubular sleeve 3 and the handle body 4 can be similarly attained.

In still another alternative embodiment, referring to FIG. 7, the peripheral wall 33 of the tubular sleeve 3 is directly formed with a polygonal outer surface 332 in the internally threaded section 341, the air inlet section 343, and the fixing section 342, and the retaining portion 35 has an annular groove 356 extending in the polygonal outer surface 332. The retaining portion 35 may have a plurality of angularly spaced-apart retaining holes (not shown) extending radially in the outer polygonal surface 332 instead of the annular groove 356. Similarly, the handle body 4 and the tubular sleeve 3 are prevented from moving axially relative to each other through the retaining portion 35, and are prevented from rotating relative to each other through the polygonal outer surface 332 of the peripheral wall 33.

Hence, by varying the configurations of the retaining portion 35 and the peripheral wall 33 of the tubular sleeve 3, the tubular sleeve 3 and the handle body 4 respectively made of metal and plastic can be immovably and stably connected to each other to form the handle device 2 of the present invention.

From the aforementioned description of the present invention, the advantages of the handle device 2 of the present invention can be summarized as follows:

1. Since the handle body 4 is made by injection molding using a plastic material, and through the use of the auxiliary forming blocks and the mold assembly, the handle body 4 can be formed into a predetermined shape without the need to undergo additional processing steps, so that the process time and the labor time needed in the making of the handle device 2 are minimized. Further, since the handle body 4 is made of plastic, the material cost of the handle device 2 is also minimized.

2. Although the tubular sleeve 3 is made of metal so as to resist the striking force of the hammering action, the handle body 4 which occupies a larger part of the handle device 2 is made of plastic, so that the weight of the entire handle device 2 is reduced. Hence, fatigue of the operator's hands following a long period of use can be minimized, and injuries to the operator's hands can be reduced as well.

While the present invention has been described in connection with what is considered the most practical and preferred embodiment, it is understood that this invention is not limited to the disclosed embodiment but is intended to cover various arrangements included within the spirit and scope of the broadest interpretations and equivalent arrangements.

Claims

1. A handle device for a hammer gun, comprising: a tubular sleeve adapted to connect threadedly with a barrel of the hammer gun and including front and rear end faces, a peripheral wall interconnecting said front and rear end faces, an installing cavity extending from said front end face toward said rear end face and adapted to receive therein the barrel of the hammer gun, and a retaining portion provided on said peripheral wall; anda handle body having a grip portion, and a casing portion molded directly over said tubular sleeve and engaging said retaining portion so that said tubular sleeve is connected immovably to said handle body.

2. The handle device of claim 1, wherein said tubular sleeve is made of metal, and said handle body is made of plastic.

3. The handle device of claim 1, wherein said peripheral wall of said tubular sleeve includes an internally threaded section proximate to said front end face and adapted to engage threadedly the barrel of the hammer gun, and a fixing section proximate to said rear end face and having said retaining portion, said peripheral wall being indented to form said retaining portion.

4. The handle device of claim 3, wherein said fixing section has an open end at said rear end face, said casing portion of said handle body having a part filling and engaging said open end.

5. The handle device of claim 3, wherein said retaining portion includes a plurality of angularly spaced-apart through holes extending radially through said fixing section.

6. The handle device of claim 3, wherein said peripheral wall further includes an air inlet section connected between said internally threaded and fixing sections and having an air inlet port extending radially through said air inlet section.

7. The handle device of claim 3, wherein said retaining portion includes an annular groove formed in an outer surface of said fixing section.

8. The handle device of claim 7, wherein said fixing section has an open end of polygonal cross section at said rear end face, said casing portion of said handle body having a part filling and engaging said open end.

9. The handle device of claim 3, wherein said fixing section has a closed end wall forming said rear end face, said retaining portion including a plurality of angularly spaced-apart blind bores extending radially in said closed end wall.

10. The handle device of claim 3, wherein said retaining portion includes a polygonal section that is provided in said fixing section and that has a plurality of corners and flat sides between adjacent ones of said corners.

11. The handle device of claim 3, wherein said peripheral wall has a polygonal outer surface in said internally threaded section, said air inlet section, and said fixing section, said retaining portion having an annular groove extending in said polygonal outer surface.

12. The handle device of claim 3, wherein said peripheral wall further includes at least one auxiliary positioning recess extending annularly in an outer surface of said internally threaded section.