阅读说明：本技术 用于电动工具的系索系统 (Lanyard system for a power tool ) 是由 詹姆斯·格雷戈里·布鲁尔 于 2018-07-20 设计创作，主要内容包括：用于附接至电动工具的多个附接系索系统,每个系索系统包括附接至驱动件固持器的系索,该驱动件固持器固持驱动件并且连接至缩回系统。该多个附接系索系统提供能够通过将每个驱动件拉出其所附接的系索系统来选择的不同驱动件,该多个附接系索系统将该驱动件延伸经过驱动件接纳器并且将该驱动件插入该驱动件接纳器中。(A plurality of attachment lanyard systems for attachment to a power tool, each lanyard system comprising a lanyard attached to a drive member holder that holds a drive member and connects to a retraction system. The multiple attachment lanyard systems provide different drivers that can be selected by pulling each driver out of the lanyard system to which it is attached, extending the driver past and inserting the driver into the driver receiver.)

1. A lanyard system for connecting a drive member to a power tool housing, the lanyard system comprising:

a. a lanyard assembly having a first end and a second end contained within a lanyard assembly housing;

b. said lanyard assembly further comprising a lanyard strap having two end regions, said first end region attached to a drive member holder that holds a drive member outside the lanyard assembly housing and said second end region attached to an internal stop within the lanyard assembly housing;

c. the lanyard strap of the lanyard assembly is disposed in a first guide disk within a lanyard assembly housing that encloses the lanyard assembly;

d. said internal stop within said lanyard assembly housing further attached to a first end of a retraction system that wraps 180 degrees around a pulley at a second end of the lanyard assembly and returns within a second guide disk of the lanyard assembly housing enclosing the lanyard assembly;

e. the second end of the retraction system is attached to the first end of the lanyard assembly contained within the lanyard assembly housing.

2. The lanyard system for connecting the drive member to the power tool housing of claim 1 wherein the retraction system is a flexible cord looped around the pulley and attached to a spring connector which is then attached to a spring which is attached to the first end of the lanyard assembly.

3. The lanyard system for connecting a drive member to a power tool housing of claim 1 wherein the retraction system is a flexible cord wrapped around the pulley and attached to the first end of the lanyard assembly.

4. The lanyard system for connecting a driver to a power tool housing of claim 1 wherein a friction wing is attached to the driver holder that holds the driver external to the lanyard assembly.

5. The lanyard system for connecting a driver to a power tool housing of claim 1 wherein the attachment of the second end of the retraction system to the first end of the lanyard assembly is accomplished on a mounting shaft.

6. A power tool having a plurality of attached lanyard systems wherein each lanyard system is contained within a lanyard system housing, including a lanyard attached to a drive member holder that holds a drive member and connects to a retraction system, and a different drive member is provided that can be selected by pulling each drive member out of its attached lanyard system, extending the drive member through a drive member receiver and inserting the drive member into the drive member receiver.

7. The power tool of claim 6 having multiple attachment lanyard systems wherein each of the drivers can be removed after use by removing the driver from the driver receiver of the power tool and allowing its retraction system to retract the lanyard into the lanyard system housing, thereby returning the driver to a storage position.

8. The power tool having attachment lanyard systems of claim 6 wherein the power tool is initially supplied with pre-installed base housings of the attachment lanyard systems already attached to the power tool housing.

9. The power tool with multiple attached lanyard systems of claim 7 wherein the remaining internal components and the top cover of each lanyard system can be snapped onto each pre-installed base housing by the end user.

10. The tool having multiple attachment lanyard systems of claim 8 wherein the attachment of the pre-mount base housings is accomplished by molding each pre-mount base housing into the top housing of the power tool during manufacture of the power tool.

Technical Field

The present disclosure relates generally to power tools. More particularly, the present disclosure relates to supporting and retaining a removable piece for use with a power tool (such as an impact driver, drill, hammer drill, power nut wrench, impact wrench, reciprocating saw, paint sprayer, sand blaster, or water sprayer). A retraction lanyard for a drill bit, a helical bit, a sleeve driver, a chisel, a saw blade, or a nozzle is described herein. Briefly, this lanyard system stores, tethers, retains, extends and retracts a driver that is secured to and removed from the tool. The drive is designed to perform tasks such as, but not limited to, screwing, unscrewing, drilling, chiseling, cutting, painting, or a combination thereof.

Background

Power tools with removable parts can perform a wider range of tasks than those with fixed parts. For example, a nut driver with a removable sleeve or a screw driver with a removable screw bit can tighten or loosen a wider variety of nuts, bolts, or screws than a wrench or screw driver with a fixed working end. Indeed, a driver adapted to manipulate both the socket and the screw bit may perform the task of tightening and loosening nuts, bolts and screws without the use of a wrench and a tool box for the screw driver. The same applies to power tools and injectors equipped with a piece receiver, such as a chuck or quick change coupling. However, challenges are encountered in tracking pieces placed in a piece receiver (chuck or quick change coupling). Another challenge is quick and easy access to the pieces.

Described herein are low cost lanyard systems that store and manage one or more pieces for use with a tool through the use of a retractable tether. The lanyard system described herein may be incorporated into a power tool by a modest change to the top of the housing of the tool. The described tether system is a low profile system that allows for easy location and selection of a desired tether from a storage location and movement of the tether into a tether receiver (like a chuck or quick change coupling) with little or no need to guide the tether into or around the working area of the tool. There is still further provided a tether system wherein one or more pieces can be kept safely tethered to a tool even when they are installed in a piece receiver (like a chuck or quick change coupling). And to provide a lanyard system having a retraction system that is capable of retrieving and storing a tether with little or no user intervention once the tether is released from the tether receiver or work area.

Disclosure of Invention

A lanyard system for connecting a driver to a power tool housing, the lanyard system comprising at least: a lanyard assembly having a first end and a second end contained within a lanyard assembly housing; the lanyard assembly further includes at least a lanyard strap having two end regions, the first end region attached to a drive member holder that holds a drive member outside of the lanyard assembly housing and the second end region attached to an internal stop within the lanyard assembly housing; the lanyard strap of the lanyard assembly is disposed in a first guide disk within a lanyard assembly housing that encloses the lanyard assembly; the internal stop within the lanyard assembly housing is attached to a first end of a retraction system that wraps 180 degrees around a pulley at a second end of the lanyard assembly and returns within a second guide disk of the lanyard assembly housing that encloses the lanyard assembly; the second end of the retraction system is attached to a first end of the lanyard assembly contained within the lanyard assembly housing.

Drawings

FIG. 1 is an exploded perspective view of a separate lanyard system utilizing a flexible cord and spring design that can be mounted to a power tool.

FIG. 2 is a perspective view of the individual lanyard system of FIG. 1 with the top cover.

FIG. 3 is a top view of the individual lanyard system of FIG. 1 without the top cover.

FIG. 4 is a top view of the individual lanyard system of FIG. 1 with the top cover.

FIG. 5 is a side view of the individual lanyard system of FIG. 1 with the top cover.

FIG. 6 is a top view of the individual lanyard system of FIG. 1 with a transparent top cover.

FIG. 7 is a perspective view of a separate lanyard system that can be mounted to a power tool, shown without the top cover, utilizing an internal elastic cord to eliminate the need for a spring.

FIG. 8 is a top view of the individual lanyard system of FIG. 7

FIG. 9 is a perspective view of a typical power tool equipped with multiple individual lanyard systems that surround the top housing of the power tool.

Fig. 10 is a front view of the assembled power tool of fig. 9.

Fig. 11 is a side view of the assembled power tool of fig. 9.

Fig. 12 is a perspective view of an alternate embodiment of the power tool of fig. 9.

Detailed Description

In the following detailed description, reference is made to the accompanying drawings that show embodiments of the invention. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention without undue experimentation. It should be understood, however, that the embodiments and examples described herein are presented by way of illustration only and not limitation. Various substitutions, modifications, additions and rearrangements may be made without departing from the spirit of the invention. The following description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims.

Referring to FIG. 1, an exploded perspective view of an independent lanyard system 100 is shown. By independent, it is meant that multiple of these lanyard systems can be attached to the power tool, but not dependent on each other. Each independent lanyard system is self-sufficient. The lanyard system is comprised of a lanyard assembly having a first end and a second end contained within the overlying lanyard assembly housings 128, 102, 104. The assembly includes a lanyard strap 140 having two end regions, wherein a first end region is attached to the drive member 114 outside of the lanyard assembly housing via a drive retainer 116. The lanyard strap 140 is located inside the lanyard assembly housing 128, 102, 104. An undeployed view of the covered housing in place is shown in fig. 2. Returning to fig. 1, the lanyard strap 140 is positioned in a first guide disk within the lanyard assembly housing. At a first end of the lanyard strap 140, which is outside of the lanyard assembly housing, the lanyard strap is attached to a drive member holder 116 that holds a drive member 114, which may be the various drive members discussed. Attached to the driver holder 116 is a friction wing 118 that can be used to pull out the lanyard strap and the driver 114 to attach the driver to the power tool housing (not shown). The friction wing 118 also serves to protect the drive holder 116 from impact by a power tool in use. When not in use in a power tool (not shown), the driver 114 is pulled back to the driver stop 146 and rests in the parking recess 112, which is part of the independent lanyard system 100. At its second end, the lanyard is attached to an internal stop 141 which is then attached to a retraction system made of flexible cord 134 wrapped around pulley 130. The flexible cord 134 of the retraction system then extends into the second guide disk and the end of the flexible cord 134 is attached to a spring connector 136. The spring connector is then attached to a spring 108, which is secured to a spring mounting shaft 110 at a first end of the lanyard assembly. The combination of the flexible cord 134 wound around the pulley 130 to the mounted spring 108 constitutes a retraction system. The spring is used to pull the lanyard system back into the housing after the lanyard system is released from the power tool. The connection systems 120, 122, 124 designed into the power tool housing are configured to snap into the receiver 126 when the lanyard system 100 is attached to the power tool (not shown). An additional attachment between the lanyard system and the power tool will be shown in fig. 5.

The complete independent lanyard system can be seen in fig. 2 when the housing covers 102, 104 are attached to the housing 128.

FIG. 3 is a top view of the individual lanyard system of FIG. 1 without the top cover. Below the rear end of the drive member 114 are the ends 142, 144 of a magnet that holds the drive member in place during periods when the lanyard strap 140 is at rest and not in use in the power tool.

FIG. 4 is a top view of the individual lanyard system of FIG. 1 with the top cover.

FIG. 5 is a side view of the individual lanyard system of FIG. 1 with the top cover. In an additional aspect shown in this view, the first power tool connection module includes an engagement member 150 for insertion into a hole provided in the power tool housing when each independent lanyard system 100 is installed on the power tool housing. The engagement member 150 may be a pin inserted into a hole, or a plurality of pins in a plurality of holes, provided in the top of the power tool housing, or may be a blade for sliding into a blade receptacle provided in the top of the power tool housing. A second power tool connection module to the power tool housing is provided by a connection system 120, 122, 124 (see fig. 1) designed into the power tool housing. The connection system is configured to snap into a receiver 126 (part of the separate lanyard system 100). The combination of the two power tool connection modules enables the individual lanyard systems to be reliably connected to the power tool.

FIG. 6 is a top view of the individual lanyard system of FIG. 1 with a transparent top cover.

Fig. 7 is a perspective view of an alternative embodiment of a separate lanyard system 101 that can be installed on a power tool with the top cover removed. One significant change in this embodiment is a retraction system that utilizes an internal elastic cord 135 in this embodiment, thereby eliminating the need for the spring 108 shown in FIG. 1. Referring to fig. 7, a perspective view of the independent lanyard system 101 with the cover removed is shown. By independent, it is meant that multiple of these lanyard systems can be attached to the power tool, but not dependent on each other. Each independent lanyard system is self-sufficient. The lanyard system is comprised of a lanyard assembly having a first end and a second end contained within a covered lanyard assembly housing 128 (top cover not shown). The assembly includes a lanyard strap 140 having two end regions, with a first end region attached to a drive retainer 116 that retains the drive member 114 outside of the lanyard assembly housing. The lanyard strap 140 is positioned inside the lanyard assembly housing 128 and is positioned in a first guide disk within the lanyard assembly housing. At a first end of the lanyard strap 140, which is outside of the lanyard assembly housing, the lanyard strap is attached to a drive member holder 116 that holds a drive member 114, which may be the various drive members discussed. Attached to the driver holder 116 is a friction wing 118, which may be used to pull the lanyard strap and the driver 114 to attach the driver to the power tool housing (not shown). The friction wing 118 also serves to protect the drive holder 116 from impact by a power tool in use. When not in use in a power tool (not shown), the driver 114 is pulled back to the driver stop 146 and rests in the parking recess 112, which is part of the independent lanyard system 101. At the second end of the lanyard strap, the lanyard strap 140 is attached to an internal stop 141 which is then attached to a retraction system made of elastic cord 135 wrapped around pulley 130. The elastic cord 135 then extends into the second guide plate and is attached at its end to an elastic cord connector 137 mounted on the mounting shaft 110. The elastic cord is used to pull the lanyard system back into the housing after the lanyard system is released from the power tool. The connection systems 120, 124 designed into the power tool housing are configured to snap into the receptacle 126 when the lanyard system 101 is attached to the power tool (not shown). An additional attachment between the lanyard system and the power tool is shown in fig. 5.

FIG. 8 is a top view of an alternative embodiment of the individual lanyard system of FIG. 7 without the top cover.

Fig. 9 is a perspective view of a typical power tool 160 equipped with a plurality of individual lanyard systems 170 that surround the top housing of the tool. For clarity, a separate lanyard system 170 is shown with the top cover removed. The particular power tool shown may be of any type, such as a hammer driver, drill, hammer drill, power nut runner, impact wrench, reciprocating saw, paint sprayer, sand blaster, or water sprayer. These separate lanyard systems may be the embodiment shown in fig. 1-6 that utilizes a flexible cord attached to a spring, or the alternative embodiment of fig. 7-8 that utilizes an elastic cord. The manner in which the separate lanyard system is assembled to the power tool is with design options that make minor modifications to the top housing of the power tool. An example manner of doing this is illustrated in fig. 5, where the engagement member 150 is used to be inserted into a hole provided in the power tool housing when each independent lanyard system 100 or 101 is mounted on the power tool housing. The engagement member 150 may be a pin inserted into a hole, or a plurality of pins in a plurality of holes, provided in the top of the power tool housing, or may be a blade for sliding into a blade receptacle provided in the top of the power tool housing. A second power tool connection module to the power tool housing is provided by a connection system 120, 122, 124 (see fig. 1) designed into the power tool housing. The connection system is configured to snap into a receiver 126 (part of the individual lanyard system 100 or 101). The combination of the two power tool connection modules enables the individual lanyard systems to be reliably connected to the power tool.

In use, once the independent lanyard system is assembled to the top housing of the power tool, the user can select either driver (such as driver 172) and simply pull out the lanyard, which allows the driver 172 to extend well past the driver receiver 178 to enable the driver 172 to be placed in the driver receiver 178. When a different type of drive is required, the user simply removes the drive 172 from the drive receiver 178 and allows the retraction system of the spring (or elastic cord) to retract the lanyard into the lanyard housing, pulling the drive 172 back to the drive stop 146 to rest in the parking recess 112 that is part of the independent lanyard system 100 or 101. The user may then select an alternative driver (e.g., 174) and simply pull out the lanyard, which extends the driver 174 well past the driver receiver 178 to place the driver 174 in the driver receiver 178. When the driver is pulled back onto the driver stop 146 (of fig. 1 or 7), it encounters a magnet before and below the driver stop 146, which further ensures that the driver is inactive during power tool operation.

Fig. 10 is a front view of the assembled power tool of fig. 9.

Fig. 11 is a side view of the assembled power tool of fig. 9.

Fig. 12 is a perspective view of an alternate embodiment of the power tool 160 of fig. 9. In this embodiment, the power tool manufacturer can install the multiple mounts of the bottom housing 128 (fig. 1, 2, and 7) around the top housing of the power tool using any functional attachment method, and then the end user can purchase and snap over any remaining lanyard system (all internal components plus a top cover) as desired. The functional attachment method may be any number of attachment devices, such as those previously described in fig. 1, 5, and 7. Alternatively, the bottom housing 128 of fig. 1, 2, and 7 may be molded into the top housing of the power tool during manufacture of the tool.

It is contemplated that the power tool 160 may be powered manually, electrically, pneumatically, hydraulically, or a combination thereof. By way of illustrative example, the tool 160 may be an impact driver, drill, hammer drill, power nut wrench, impact wrench, reciprocating saw, paint sprayer, sand blaster, or water sprayer. The drives 172, 174 may be drill bits, auger bits, sleeve drivers, chisels, saw blades, or nozzles. Briefly, a driver is an object that is removably secured in a tool to perform a task such as, but not limited to, tightening, loosening, drilling, chiseling, cutting, or a combination thereof. In one embodiment, the driver is an object having radial symmetry that can be positioned in the driver receiver 178 and used in combination with the tool 160 to accomplish a task such as described above. Driving members having radial symmetry include, but are not limited to, phillips heads, robertson heads, hex heads, 12-point flange heads, hex sleeve heads, safety hex sleeve heads, quincunx heads, safety quincunx heads, trilobal heads, torq-set heads, wrench head heads, clutch heads, one-way heads, bi-square heads, tri-square heads, multi-drive heads, spline drive heads, bi-hex heads, Bristol heads (Bristol bits), pentagonal heads, sleeve heads, drill bits, helical cutting heads, cutting disc heads, barrel polishing heads, and/or combinations thereof. In other embodiments, however, the drive may be a chisel, a saw blade, or other object used in conjunction with the tool 160 to accomplish tasks such as removing or cutting material. In yet another embodiment, the drive is a nozzle used in conjunction with the tool 160 to accomplish a task such as sandblasting or spraying.

Lanyard strap 140 may be a rope, belt line, cable, or combination thereof, constructed of a durable material. Such wear resistant materials include, but are not limited to, plastics, metals, elastomeric materials, or combinations thereof. It is contemplated that the cross-section of the lanyard strap 140 can be circular, arcuate, polygonal, or a combination thereof. In one embodiment, the lanyard strap 140 has a rectangular cross-section and is constructed of a hard plastic with minimal flexing and stretching. In another embodiment, the lanyard strap 140 has a circular cross-section and is constructed of metal with sufficient flexibility to form a loop without kinking the metal.

Although particular embodiments and their advantages have been described in detail herein, it should be understood that various changes, substitutions and alterations can be made herein without departing from the scope of the invention as defined by the appended claims. Moreover, the potential applications of the disclosed techniques are not intended to be limited to the particular embodiments of the process, machine, manufacture, means, methods and steps described herein. As one of ordinary skill in the art will readily appreciate from the disclosure, other processes, machines, manufacture, means, methods, or steps, presently existing or later to be developed that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized. Accordingly, the appended claims are intended to include within their scope such processes, machines, manufacture, means, methods, or steps.