The present invention relates to the field of hand held tools. More specifically, the present invention relates to the field of folding multi-tool and related tools and safety, comfort, and convenience of accessories and tools.
Hexagonal wrenches or tool drivers, also referred to as allen wrenches or L-wrenches, have a hexagonal L-shaped body, including a long leg member and a short leg member. The end of either leg member is able to be inserted into a head of a screw or tool designed to accept a hexagonal wrench. Once inserted, rotational pressure is applied to the hexagonal wrench in order to tighten or loosen the screw. The leg members of the hexagonal wrench are designed to be of different lengths in order to allow a user flexibility when using the wrench in different environments and situations. For example, in a narrow, confined environment, the long leg of the hexagonal wrench is inserted into the head of the screw and the user will apply rotational pressure to the short leg. Or, if the environment is not so confined, the user is able to insert the short leg of the hexagonal wrench into the head of the screw and apply rotational pressure to the long leg.
Hexagonal wrenches are manufactured and distributed in multiple English (e.g., standard) and metric sizes in order to facilitate their use with screw heads of multiple sizes. Such wrenches are usually sold in a set which includes wrenches of multiple sizes but are also distributed individually.
When using a hexagonal wrench, a user will insert an end of the hexagonal wrench into the head of a workpiece such as a screw, and will then exert rotational pressure on the opposite end of the wrench in order to tighten or loosen the screw. Because of the size and dimensions of the hexagonal wrench it is particularly difficult to exert a great amount of rotational pressure on the hexagonal wrench when the long leg of the hexagonal wrench is inserted into the head of the screw. Because the hexagonal wrench is typically turned with the user's fingers, the user is able to also experience scrapes and cuts from the use of hexagonal wrenches in this manner. Ingenuitive users have also used other tools, including vice grips, pliers and the like, to turn hexagonal wrenches. However, this method is disadvantageous because such tools are able to lose their hold on the hexagonal wrench when rotational pressure is applied or are able to even bend or otherwise disfigure the hexagonal wrench.
Socket wrenches, also referred to as ratchets, have a ratcheting mechanism and use interchangeable sockets to tighten or loosen nuts and bolts. The sockets are sized to fit different sized nuts and bolts. The ratcheting mechanism allows the nuts and bolts to be tightened or loosened with an alternating backward and forward motion. The sockets are manufactured and distributed in multiple English (e.g., standard) and metric sizes in order to facilitate their use with nuts and bolts of multiple sizes. Socket wrenches are usually sold in a set which includes sockets of different sizes but are also distributed individually.
Hexagonal wrenches and socket wrenches, among other tools, are commonly used. Yet, hexagonal wrenches and socket wrenches are separate tools. The user needs to gather these separate tools to work, for example, on a construction project. Multi-purpose devices allow the user to access different tools. Some multi-purpose devices have a blade, a corkscrew, scissors, and other tools for outdoor use but do not have tools for use during construction, carpentry, car repair, and the like. Other multi-purpose devices have tools, such as pliers, wire cutters, and drivers, but require the user to transform the multi-purpose device into a different configuration in order to access a particular tool. This method is disadvantageous because such a multi-purpose device does not provide easy access to any of the tools. In addition, once transformed into the right configuration, the multi-purpose device loses its convenient handle and, therefore, is awkward to grip onto.
A radial foldout tool includes a body with opposing ends and one or more sets of tool drivers. A first set of tool drivers are positioned on/near a first end and a second set of tool drivers are positioned on/near a second end. The tool drivers are contained within channels of the body when in a closed position. The tool drivers are also contained in a plurality of planes. The tool drivers open by rotating/moving in a direction at least perpendicular to a neighboring tool driver. When they are in an open position, each of the tool drivers are in/near the center of the end of the body. By being positioned in/near the center of the end, the radial foldout tool is able to be gripped and turned in a fashion similar to a standard screwdriver.
In one aspect, a device comprises a body having a center, a first end and a second end, wherein the first end and the second end are positioned on opposite ends of the body and a first set of tool drivers positioned within the body in a plurality of planes, wherein each tool driver of the first set of tool drivers is configured to be positioned generally in the center out of the first end in an open position. The device further comprises a second set of tool drivers positioned within the body in the plurality of planes, wherein the second set of tool drivers are configured to be positioned out of the second end. The first set of tool drivers and the second set of tool drivers are positioned within the body in a closed position. Each tool driver of the second set of tool drivers is positioned out of the second end in an open position. Each tool driver of the second set of tool drivers is positioned generally in the center of the second end in an open position. In some embodiments, a first tool driver of the first set of tool drivers is in the same plane as a second tool driver of the second set of tool drivers. The body includes a set of channels for the first set of tool drivers and the second set of tool drivers to be positioned in the closed position. In some embodiments, each tool driver of the first set of tool drivers is positioned at least 90° around the circumference of the first end away from a neighboring tool driver and each tool driver of the second set of tool drivers is positioned at least 90° around the circumference of the second end away from a neighboring tool driver. The body is generally cylindrical. In some embodiments, the first set of tool drivers and the second set of tool drivers are selected from the group consisting of hexagonal wrenches, screwdrivers, socket wrenches and star-shaped drivers. In some embodiments, the first set of tool drivers are hexagonal wrenches and the second set of tool drivers are screwdrivers. The device further comprises a stop within the body for preventing each of the first set of tool drivers from opening further. In some embodiments, each of the first set of tool drivers do not open further than 180°.
In another aspect, a device comprises a body having a center, the body including a plurality of faces, a first end and a second end, wherein the first end and the second end are positioned on opposite ends of the body, a first set of tool drivers, each tool driver of the first set of tool drivers positioned within the body on a face of the plurality of faces, wherein the first set of tool drivers are configured to be positioned generally in the center out of the first end in an open position and a second set of tool drivers, each tool driver of the second set of tool drivers positioned on a face of the plurality of faces within the body, wherein the first set of tool drivers are configured to be positioned generally in the center out of the second end in an open position. The first set of tool drivers and the second set of tool drivers are positioned within the body in a closed position. In some embodiments, a first tool driver of the first set of tool drivers is in the same plane as a second tool driver of the second set of tool drivers. The body includes a set of channels for the first set of tool drivers and the second set of tool drivers to be positioned in the closed position. Each tool driver of the first set of tool drivers and the second set of tool drivers is positioned in the open position by rotation in a substantially perpendicular direction away from the face. The body is generally cylindrical. In some embodiments, the first set of tool drivers and the second set of tool drivers are selected from the group consisting of hexagonal wrenches, screwdrivers, socket wrenches and star-shaped drivers. In some embodiments, the first set of tool drivers are hexagonal wrenches and the second set of tool drivers are screwdrivers. The device further comprises a stop within the body for preventing each of the first set of tool drivers and the second set of tool drivers from opening further.
In yet another aspect, a generally cylindrical tool handle having a body with a center, a first end and a second end and a generally cylindrical surface, the handle including a plurality of tool drivers each of a differing size in a plurality of planes, wherein each of the plurality of tool drivers includes an elongated rod coupled with the tool handle having a bend through a predetermined angle and including a proximal end for engaging an object, and a mounting end between the bend and a distal end, further wherein each tool driver of the set of tool drivers is positioned generally in the center of one of the first end and the second end in an open position. The set of tool drivers are positioned within the body in a closed position. In some embodiments, each tool driver of the set of tool drivers is positioned at least 90° around the circumference of one of the first end and the second end away from a neighboring tool driver. The tool handle further comprises a stop within the body for preventing each tool driver of the set of tool drivers from opening further.
In yet another aspect, a folding multi-tool comprises a body comprising one or more faces, a top end and a bottom end of the body, wherein the top end and the bottom end are positioned on opposite ends of the body, a plurality of tools stored against the one or more faces in a closed position, a first socket holder configured to secure a first set of sockets against the body, and a second socket holder configured to secure a second set of sockets against the body. In some embodiments, the first socket holder is configured to rotate about a first hinge coupled to the bottom end of the body, and the second socket holder is configured to rotate about a second hinge coupled to the bottom end of the body. Alternatively, the first socket holder and the second socket holder are press fit socket holders that are able to press into cavities of the body. The first socket holder and the second socket holder comprise a plurality of beds, wherein each bed is sized and configured to hold in place a socket. The socket is a metric size socket, a standard size socket, or other types of sockets. In some embodiments, the plurality of tools includes a set of tool drivers, wherein each tool driver of the set is configured to rotate about a rotatable mechanism coupled to the bottom end of the body. Each tool driver is arranged according to size, wherein a biggest tool driver is positioned generally near a middle of the body. In some embodiments, the plurality of tools includes a set of tool drivers, wherein each tool driver of the set is configured to rotate about a rotatable mechanism coupled to the top end of the body. Each tool driver is arranged according to size, wherein a biggest tool driver is positioned generally near a middle of the body. In some embodiments, the plurality of tools includes a drive, wherein the drive is configured to rotate about a rotatable mechanism coupled to the bottom end of the body, and wherein the drive is adapted to fit a socket. The drive is positioned generally near a middle of the body. In some embodiments, the plurality of tools includes a can opener, wherein the can opener is configured to rotate about a rotatable mechanism coupled to the bottom end of the body. The can opener is positioned generally near a middle of the body. In some embodiments, the plurality of tools includes a blade, wherein the blade is configured to rotate about an insert coupled to the top end of the body. In some embodiments, the folding multi-tool further comprises a bent loop coupled to top end of the body, wherein the bent loop is configured to attach the folding multi-tool to objects. In some embodiments, the folding multi-tool is configured to stand upright on the bottom end.
In yet another aspect, a foldout tool comprises a body comprising a plurality of faces, a top end of the body, and a bottom end of the body, wherein the top end and the bottom end are positioned on opposite ends of the body. The foldout tool further comprises a first socket storage coupled to a first face of the plurality of faces, wherein the first socket storage rotates about a first rotatable mechanism coupled to the bottom end of the body, a second socket storage coupled to a second face of the plurality of faces, wherein the second socket storage rotates about a second rotatable mechanism coupled to the bottom end of the body, and a drive coupled to a third face of the plurality of faces, wherein the drive rotates about a third rotatable mechanism coupled to the bottom end of the body, and wherein the drive is adapted to fit a socket. The first socket storage and the second socket storage comprise a plurality of chambers sized and configured to hold in place a plurality of sockets. The socket is a metric size socket or a standard size socket. In some embodiments, the foldout tool further comprises a can opener coupled to the third face, wherein the can opener rotates about the third rotatable mechanism. In some embodiments, the foldout tool further comprises a first set of tool drivers and a second set of tool drivers coupled to a fourth face, wherein each tool driver of the first set rotates about a fourth rotatable mechanism coupled to the bottom end of the body, and wherein each tool driver of the second set rotates about a fifth rotatable mechanism coupled to the top end of the body. In some embodiments, the foldout tool further comprises a blade, wherein the blade is configured to rotate about an insert coupled to the top end of the body. In some embodiments, the foldout tool further comprises a bent loop coupled to top end of the body, wherein the bent loop is configured to attach the foldout tool to objects. In some embodiments, the foldout tool is configured to stand upright on the bottom end of the foldout tool.
In yet another aspect, an apparatus comprises a body with a generally cylindrical surface, the body comprises a first end, a second end, and four faces, wherein each face has a plurality of tools, wherein each of the plurality of tools is positioned generally near a middle of the body, and wherein the apparatus is configured to stand upright on the second end. The four faces include a first face, wherein the first face comprises a bit storage and a hinge, wherein the bit storage holds at least one socket and rotates about the hinge, wherein the hinge is coupled to the second end of the body. The four faces includes a second face, wherein the second face comprises a bit storage and a hinge, wherein the bit storage holds at least one socket and rotates about the hinge coupled to the second end of the body. The four faces includes a third face, wherein the third face comprises a drive, a can opener, and a blade, wherein the drive and the can opener rotate about a rotatable mechanism coupled to the second end of the body, and the blade rotates about an insert coupled to the first end of the body. The four faces includes a fourth face, wherein the fourth face comprises a first set of tool drivers and a second set of tool drivers, wherein each tool driver of the first set rotates about a first pivotable mechanism coupled to the second end of the body, and wherein each tool driver of the second set rotates about a second pivotable mechanism coupled to the first end of the body.
In yet another aspect, a tool handle comprises a body and a plurality of tools. The body comprises a first face of the body, a second face of the body, a third face of the body, wherein the third face is opposite the first face, a fourth face of the body, wherein the fourth face is opposite the second face, a top end of the body, and a bottom end of the body, wherein the top end and the bottom end are positioned on opposite ends of the body. The plurality of tools comprises a bent loop coupled to top end of the body, wherein the bent wire loop is configured to attach the tool handle to objects, a first depository comprising a first plurality of chambers sized and configured to hold in place metric size sockets, wherein the first depository is coupled to the first face, and wherein the first depository rotates about a first rotatable mechanism coupled to the bottom end of the body, a second depository comprising a second plurality of chambers sized and configured to hold in place standard size sockets, wherein the second depository is coupled to the third face, and wherein the second depository rotates about a second rotatable mechanism coupled to the bottom end of the body, a drive coupled to the second face, wherein the drive rotates about a third rotatable mechanism coupled to the bottom end of the body, and wherein the drive is adapted to fit ends of the metric size sockets and ends of the standard size sockets, a can opener coupled to the second face, wherein the can opener rotates about the third rotatable mechanism, a blade coupled to the second face, wherein the blade is configured to rotate about a fourth rotatable mechanism coupled to the top end of the body, a first set of tool drivers coupled to the fourth face, wherein each tool driver of the first set rotates about a fifth rotatable mechanism coupled to the bottom end of the body, and a second set of tool drivers coupled to the fourth face, wherein each tool driver of the second set rotates about a sixth rotatable mechanism coupled to the top end of the body. The tool handle is configured to stand upright on the bottom end of the body. In some embodiments, each face of the body is rounded.
In the following description, numerous details are set forth for purposes of explanation. However, one of ordinary skill in the art will realize that the invention may be practiced without the use of these specific details or with equivalent alternatives. Thus, the present invention is not intended to be limited to the embodiments shown but is to be accorded the widest scope consistent with the principles and features described herein.
Reference will now be made in detail to implementations of the present invention as illustrated in the accompanying drawings. The same reference indicators will be used throughout the drawings and the following detailed description to refer to the same or like parts.
Embodiments of the present invention are directed to a radial foldout tool.
In some embodiments, a radial foldout tool stores tool drivers in a compact configuration. The tool drivers are able to be positioned for use to tighten or loosen an object such as a screw or bolt.
In some embodiments, each of the tool drivers 112 of the first set of tool drivers 108 is positioned in the body 102 in a different plane from the other tool drivers of the first set of tool drivers 108. Similarly, in some embodiments, each of the tool drivers 112 of the second set of tool drivers 110 is positioned in the body 102 in a different plane from the other tool drivers of the second set of tool drivers 110. For example, in a radial foldout tool 100 which has a body 102 that is generally cylindrical in shape and surface, a first tool driver is positioned at 0° along the circumference of a round first end of the tool, a second tool driver is positioned at 120° along the circumference and a third tool driver is positioned at 240° along the circumference. Tool drivers are similarly positioned on the opposite end as well.
In some embodiments, each tool driver of the first set of tool drivers 108 is positioned in the same plane as a correspondingly positioned tool driver of the second set of tool drivers 110.
In some embodiments, each of the tool drivers of the radial foldout tool 100 is configured to open at least perpendicularly to its neighboring tool driver. For example, with a radial foldout tool 100 containing three tool drivers at each end, a first tool driver opens at 0°, a second tool driver opens at 90° and a third tool driver opens at 270°. This configuration enables each of the tool drivers to open into/near the middle/center of the end, so that a user has better and easier turning power instead of the awkward turning capabilities when the tool drivers are not positioned near the middle of the end. In other words, each of the tool drivers fold out to a position as close as possible to a central axis of the radial foldout tool 100.
In some embodiments, a hard stop such as an internal wall prevents the tool drivers from opening past a certain angle such as 180° so that the tool extends perpendicular to the corresponding end.
In some embodiments, the radial foldout tool 100 is designed to include some hexagonal wrenches of English (e.g., standard) sizes including a ¼ inch hexagonal wrench, a 7/32 inch hexagonal wrench, a 3/16 inch hexagonal wrench, a 5/32 inch hexagonal wrench, a 9/64 inch hexagonal wrench, a ⅛ inch hexagonal wrench, a 7/64 inch hexagonal wrench, a 3/32 inch hexagonal wrench and a 5/64 inch hexagonal wrench.
In some embodiments, the radial foldout tool 100 is designed to include some hexagonal wrenches of metric sizes including an 8 mm hexagonal wrench, a 6 mm hexagonal wrench, a 5 mm hexagonal wrench, a 4 mm hexagonal wrench, a 3 mm hexagonal wrench, a 2.5 mm hexagonal wrench, a 2 mm hexagonal wrench and a 1.5 mm hexagonal wrench. It should be apparent to one skilled in the art that a radial foldout tool 100 is able to be formed to hold fewer, additional or different sizes of hexagonal wrenches.
In some embodiments, the radial foldout tool 100 is designed to be of a round shape. In some embodiments, the radial foldout tool 100 is designed to be of a triangular shape including three faces, a square or rectangle shape including four faces, a hexagonal shape including six faces or any other appropriate shape. In some embodiments, a single tool driver is positioned on each face of the radial foldout tool 100. In some embodiments, each face is approximately 1 inch across its width and the body 102 of the radial foldout tool 100 is approximately 4.5 inches in length. The body 102 is designed to provide a comfortable, user-friendly interface to a user's hand, in order to enhance a user's ability to exert rotational pressure on the tool driver 112 without subjecting the user to personal injury or requiring the use of additional tools. As should be apparent to one skilled in the art, the body 102 of the present invention may be designed to be of any convenient shape, including any number of faces.
As described in this section, the tool drivers in some embodiments are configured to rotate to an open position which is generally in the middle/center of each end of the body of the radial foldout tool. In other words, the tool drivers each folds out to a position as close as possible to a central axis of the radial foldout tool. By being near the middle of each end, turning the radial foldout tool is more stable for a user when the radial foldout tool is in use and each of the tool drivers is in use. The tool drivers are also stored in a plurality of planes in the body which help ensure the tool drivers open to the middle of each end. Since the tool drivers are stored in a plurality of planes, the tool drivers open in a direction at least perpendicular to their neighboring tool driver to further ensure they open to the middle of each end of the radial foldout tool. Previously existing foldout tools suffer from an awkward grasping implementation where the awkwardness is due to the fact that, in the worst case, for example, the previously existing tools allow for the smallest of wrenches to place the part of the tool that is grasped and turned, as far off-axis as possible (and without the benefit of a hard stop in the fully extended position as the present radial foldout tool does). In addition to that, since the previously existing tools are rectangular cubes, the user's hand is required to either fully disengage the tool between turns, or to use rather involved spider-like, alternating stepping actions with the fingers to crawl the hand around the tool into position for the next twist, all the while, keeping the tool stabilized in multiple axes due to the fact that the grasp is compromised and that the wrench, when fully extended, is able to rotate at least 270°. Whereas, with the present radial foldout tool design, the user's hand is able to simply loosen the grasp and slide the palm around within the circumference of the tool while maintaining a steady and sure grasp on the tool, wrench and fastener.
In operation, a radial foldout tool contains multiple tool drivers to consolidate the space needed for a set of tool drivers. Furthermore, the body of the radial foldout tool contains channels for storing the tool drivers in a closed position, so that more tools are able to be stored. To utilize the radial foldout tool, a user moves a desired tool driver from a closed position to an open position. The user moves the desired tool driver using a finger or two to simply pull or push the tool driver in the appropriate direction. In some embodiments, the tool driver locks into place in the open position. The user then grasps the body of the radial foldout tool similarly to grasping a handle of a screwdriver. The user turns the body of the radial foldout tool to either tighten or loosen an object such as a screw or bolt. This turning action is also similar to the use of a screwdriver. Once the user has performed the tightening or loosening actions on the desired object or objects, the tool driver is moved to a closed position by pushing or pulling the tool driver with the user's fingers. In some embodiments, the tool drivers lock in the closed position. When in the closed position, the tools are safely stored within channels in the body to prevent injuries. Unlike a standard screwdriver which has a sharp point jutting out of the handle, the radial foldout tool is able to be compacted and stored safely.
Radial Foldout Tool with Multiple Types of Tools and Bit Storage
In some embodiments, a radial foldout tool has multiple types of tools and bit storage. As such, the radial foldout tool is a general purpose folding multi-tool.
In some embodiments, the radial foldout tool 300 has two bit holders. A first bit holder holds hex sockets of English (e.g., standard) sizes including a ⅜ inch hex socket, a 5/16 inch hex socket, a ¼ inch hex socket and a 3/16 inch hex socket. A second bit holder holds hex sockets of metric sizes including a 10 mm hex socket, a 8 mm hex socket, a 6 mm hex socket and a 5 mm hex socket.
Also illustrated in
Alternatively, the bit holders 312, 322 are press fit socket holders that are able to completely separate from the body 302. The press fit socket holders are removably coupled to the body 302 without a rotatable or pivotable mechanism. Instead, the press fit socket holders press into cavities of the body 302.
In some embodiments, the radial foldout tool 300 typically has a drive configured to be used with the hex sockets. In some embodiments, the drive is a ¼ inch square drive, which fits within ends of the hex sockets. Alternatively, the drive can be of any size and shape, configured to fit within ends of different sockets.
In some embodiments, the drive 316 and the bottle opener 314 are positioned next to each other in a middle or center of the second face such that the drive 316 and the bottle opener 314 fold out to a position as close as possible to a central axis of the radial foldout tool 300. This configuration enables a user to have a better and easier handle of the radial foldout tool 300 during use. For example, the drive 316 positioned near the middle of the bottom end allows the user to have a better turning power instead of the awkward turning capabilities when the drive 316 is not positioned near the middle of the bottom. The bottle opener 314 positioned near the middle of the bottom end allows the user to have a better grip of the radial foldout tool 300 when opening a bottle, a can and the like.
In some embodiments, the radial foldout tool 300 also has a blade 320 protected behind a protective covering 318, in a closed position, coupled to the second face of the radial foldout tool 300. The protective covering 318 is typically positioned behind the drive 316 and the bottle opener 314. In some embodiments, the blade 320 is three inches long and fans open to a side, rotating about a rotatable mechanism, such as a pin or a threaded insert 326d, coupled to the top end of the radial foldout tool 300, as illustrated in
In some embodiments, the blade 320 is stainless or a plated steel. In some embodiments, the blade 320 is rust-proof. In other embodiments, the blade 320 is coupled to a spring mechanism (not illustrated) to facilitate the opening and closing of the blade 320. In other embodiments, the radial foldout tool 300 has a locking mechanism (not illustrated) such that the blade 320 locks in place in a closed and/or open position to prevent injuries during use and/or non-use.
In some embodiments, the radial foldout tool 300 typically has at least one set of tool drivers.
In some embodiments, the first set of tool drivers 308 rotates about a rotatable mechanism, such as a screw 326a, within the bottom end of the radial foldout tool 300 to an open position. In some embodiments, the second set of tool drivers 306 rotates about a rotatable mechanism, such as a screw 326c, within the top end of the radial foldout tool 300 to an open position. In some embodiments, a hard stop prevents the tool driver from opening past a certain angle such as 180° so that when the tool driver stops rotating, the tool driver is pointing in a parallel direction to the body 302. To position the tool driver in a closed position, the user rotates the tool driver in an opposite direction from the opening direction.
The tool drivers are configured to tighten or loosen an object such as a screw or bolt. As illustrated in
In some embodiments, each tool driver of the first set of tool drivers 308 is coupled to the bottom end of the radial foldout tool 300 in a predetermined order such as size. Similarly, in some embodiments, each tool driver of the second set of tool drivers 306 is coupled to the top end of the radial foldout tool 300 in a predetermined order such as size. For example, a largest tool driver is positioned nearest to a middle or center of the radial foldout tool 300. As such, in an open position, the largest tool driver is generally in the middle of the body 302. In other words, the largest tool folds out to a position as close as possible to the central axis of the radial foldout tool 300. Having the largest tool driver generally in the middle of the body 302 advantageously provides a more even torque during usage. Alternatively, the smallest tool driver of the first set of tool drivers 308 is positioned towards the middle of the radial foldout tool 300. Alternatively, the smallest tool driver of the second set of tool drivers 306 is positioned towards the middle of the radial foldout tool 300.
As illustrated in
As illustrated in
In some embodiments, the body 302 is widest at each end when the radial foldout tool 300 is in an open or partially open position.
In operation, the radial foldout tool 300 contains multiple tools to consolidate the space needed for multiple tools. Furthermore, the body 302 of the radial foldout tool 300 has a plurality of faces for storing the tools in a closed position. To utilize a socket, a user removes the socket from the first bit holder 312 or the second bit holder 322 by rotating the holder away from the body 302 of the radial foldout tool 300 in an open position. After removing the socket, the user rotates the holder back towards the body 302 of the radial foldout tool 300 into a closed position. Next, the user rotates the drive 316 into an open position and couples the selected socket to an end of the drive 316. The user then grasps the body 302 of the radial foldout tool 300 similarly to grasping a handle of a screwdriver. The user turns the body 302 of the radial foldout tool 300 to either tighten or loosen an object.
To utilize the bottle opener 314, the user rotates the bottle opener 314 from a closed position to an open position parallel to the body 302 of the radial foldout tool 300. Similarly, to utilize a tool driver, the user rotates the tool driver from a closed position to an open position parallel to the body 302 of the radial foldout tool 300. To utilize the blade 320, the user rotates the blade 320 to a side until the blade 320 is pointing in a parallel direction to the body 302 of the radial foldout tool 300.
In some embodiments, the tools are locked in the closed position. When in the closed position, the tools are safely stored against the body 302 of the radial foldout tool 300 to prevent injuries. Unlike a standard screwdriver which has a sharp point jutting out of the handle, the radial foldout tool 300 is able to be compacted and stored safely. In some embodiments, with the tools locked in the closed position, the radial foldout tool 300 is able to stand upright on the bottom end of the radial foldout tool 300. In other embodiments, the radial foldout tool 300 is also able to stand upright on the top end of the radial foldout tool 300.
A body of a radial foldout tool is able to be composed of any appropriate material, which is of maximum strength and includes properties which resist materials that the handle will likely be exposed to, e.g., oil, grease, gasoline and the like. In some embodiments, the body is materially composed of 30% glass-filled polypropylene or nylon. In some embodiments, the body is materially composed of any suitable composition including, but not limited to aluminum or steel or thermoplastic rubber. In some embodiments, the radial foldout tool has a re-enforced polypropylene body. In some embodiments, tools are materially composed of aluminum, steel or any other appropriate material. In some embodiments, the body is constructed using an injection molded, core/cavity process as is well known in the art. Alternatively, the body may be constructed in any known manner.
The present invention has been described in terms of specific embodiments incorporating details to facilitate the understanding of principles of construction and operation of the invention. Such reference herein to specific embodiments and details thereof is not intended to limit the scope of the claims appended hereto. It will be readily apparent to one skilled in the art that other various modifications may be made in the embodiment chosen for illustration without departing from the spirit and scope of the invention as defined by the appended claims.
This patent application is a continuation-in-part of the co-pending U.S. patent application Ser. No. 12/009,461, filed Jan. 17, 2008, entitled “RADIAL FOLDOUT TOOL,” which is hereby incorporated by reference.
Number | Date | Country | |
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Parent | 13722235 | Dec 2012 | US |
Child | 14135413 | US | |
Parent | 12567569 | Sep 2009 | US |
Child | 13722235 | US |
Number | Date | Country | |
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Parent | 12009461 | Jan 2008 | US |
Child | 12567569 | US |