The present invention in general relates to a socket insert. More particularly, it relates to a hollow shape socket insert adapter used in conjunction with a socket driver for tightening, loosening, removing various sizes of nuts and bolts; whereby the socket insert adapter may include a rim coplanar to one end of the socket insert adapter that enhances structural integrity, inhibits disengagement with a socket driver, and facilitates manipulation of the socket insert adapter.
Sockets are one of the most commonly used mechanical tools for driving nuts and bolts. Most of the earlier standard socket drivers were designed with specific metric or SAE size for fastening nuts/bolts thus each time a different socket driver was required for driving nuts/bolts of various dimensions and shapes. Some adjustable socket drivers having a movable jaw and a fixed jaw are available in the prior art to engage nuts/bolts of various dimensions and shapes but such socket drivers are not efficient to prevent rotation of nuts/bolts and do not offer grip to operate on different shapes and sizes of fasteners.
One of the common problem with inserts used in socket drivers of the prior art is the sharp corners which cause the spinning and slippage while providing torque to the inserts because of the improper locking between the insert and socket driver. The major drawback with existing split side, gap wall, and similar inserts available in the prior art is that they fail to provide the durability, strength, and efficiency for driving large diameter of nuts and bolts.
Thus, there is a longstanding need to design insert adapters which can be driven by a single socket driver efficiently to operate on a large range of nuts and bolts of different sizes and shapes.
Accordingly, it is a prime objective of the present invention to overcome the above mentioned disadvantages of the prior art by providing a hollow shaped socket insert adapter for tightening, loosening, and removing various sizes of nuts/bolts.
Another object of the present invention is to provide a plurality of hollow shaped socket insert adapters rotatively driven by a single socket driver for tightening, loosing, removing the various sizes of nuts/bolts.
Another objective of the present invention is to provide unique design inserts with rounded outside corners and rounded inside corners to maximize the torque on the flat wall of the insert.
Another objective of the present invention is to provide a relatively inexpensive hollow shaped socket insert adapter for tightening, loosing, removing the various sizes of nuts/bolts.
Another objective of the present invention is to provide a plurality of hollow shaped socket insert adapters of different sizes and different shapes with variable inner diameter specific to the size of the nuts/bolts to be driven.
The present invention has a further objective to hold the hollow shaped socket insert adapter securely inside the socket driver using a spring ball detent.
A further objective of the present invention is to provide an efficient, light weight, compact adjustable socket insert for socket drivers.
Yet another objective of the present invention is to provide a socket insert which can operate on interchangeable metric or SAE sizes using the same socket driver.
A further objective of the present invention is to provide a hollow shape socket insert adapter permitting the use of a wrench to drive a wrench socket.
Embodiments of the present invention provide a hollow shaped socket insert adapter rotatively driven by a single socket driver for tightening, loosing, removing the various sizes of nuts/bolts. A plurality of hollow shaped socket insert adapters with variable inner diameter has been provided to operate on smaller dimensions of nuts/bolts. The nuts/bolts have dimensions smaller with reference to the size of the socket driver cavity. Hollow shaped socket insert adapters of a single shape are capable of driving nuts/bolts of different sizes and shapes. Each of the hollow shaped socket insert adapters is provided with rounded outside corners and rounded inside corners to maximize the torque on the flat wall of the insert adapter when rotatively driven by a socket driver. The hollow shaped socket insert adapter specific to the size of the subject nut/bolt to be driven is chosen and placed inside the socket driver cavity. Force is applied to the socket driver body enabling the hollow shape socket insert adapter to tighten, loosen, and remove the subject nut/bolt. In some embodiments, a mechanical arrangement for electrically, hydraulically, or pneumatically tightening, loosening or removing nuts and bolts of various sizes is provided. The mechanical arrangement includes a socket driver configured to receive and to be rotatively driven by a torque force from at least one of electrical, hydraulic, or pneumatic means, wherein the torque force generated by the electrical, hydraulic or pneumatic means is greater than a torque force that can be applied manually by a human being; a plurality of hollow-shaped socket insert adapters that are configured to be rotatively driven by a the socket driver, and to receive the electrical, hydraulic, or pneumatic torque force via the socket driver, for tightening, loosening, or removing the nuts and bolts of various sizes, a given one hollow-shaped socket insert adapter of the plurality of hollow-shaped socket insert adapters. The hollow-shaped socket insert adapters include an inner configuration that has a shape and size to conform to and to fit on a head portion, having outside corners, of a given nut or bolt to be driven and wherein the shape of the inner configuration is a closed hollow shape. The mechanical arrangement also includes one or more inner flat walls and one or more rounded inner corners, the inner configuration being shaped to allow the one or more flat walls of the inner configuration to contact and engage, and the one or more rounded inner corners to avoid contacting and engaging, the outside corners of the head portion of the given nut or bolt to be driven; and the flat walls and rounded outer and inner corners increase the ability of the plurality of hollow-shaped socket insert adapters to receive the electrical, hydraulic, or pneumatic torque force via the socket driver and to transmit the torque force to the given nut or bolt to be driven.
In some embodiments, a method of driving nuts and bolts with a socket driver is provided. The method includes: selecting a nut or bolt to be driven; checking the size of the selected nut or bolt to be driven; selecting an appropriate socket insert adapter to fit the nut or bolt to be driven, wherein the socket insert adapter comprises rounded inner corners and rounded outer corners; placing the socket insert adapter inside a cavity of the socket driver; mating the socket insert adapter with the socket driver without contacting the rounded outer corners; mating the selected nut or bolt without contacting the inner rounded corners of the socket insert adapter; and applying torque to the socket driver to drive the selected nut or bolt.
The disclosure will now be made, by way of example, with reference to the accompanying drawings, in which:
Embodiments of the present invention provide a socket insert for tightening, loosening, and removing various nuts/bolts of smaller dimensions used in conjunction with a single socket driver. The following detailed description is merely exemplary in nature and is not intended to limit the described embodiments or the application and uses of the described embodiments. As used herein, the word “exemplary” or “illustrative” means “serving as an example, instance, or illustration.” Any implementation described herein as “exemplary” or “illustrative” is not necessarily to be construed as preferred or advantageous over other implementations. All of the implementations described below are exemplary implementations provided to enable persons skilled in the art to practice the disclosure and are not intended to limit the scope of the claims. Furthermore, there is no intention to be bound by any expressed or implied theory presented in the preceding technical field, background, brief summary or the following detailed description. Further multiple references to “one embodiment,” “an embodiment” or “some embodiments” are often not referring to the same embodiments.
Embodiments of the present invention provide a hollow shaped socket insert adapter rotatively driven by a single socket driver for tightening, loosing, and removing the various sizes of nuts/bolts. A plurality of hollow shaped socket insert adapters with variable inner diameter has been provided to operate on smaller dimensions of nuts/bolts. Hollow shaped socket insert adapters of different shapes to rotatively drive nuts/bolts of different shapes have also been provided. Each of the hollow shaped socket insert adapters is provided with rounded outside corners and rounded inside corners to maximize the torque on the flat wall of the insert adapter when rotatively driven by a socket driver. The hollow shaped socket insert adapter specific to the size of the subject nut/bolt to be driven is chosen and placed inside the socket driver cavity. Force is applied to the socket driver body enabling the hollow shaped socket insert adapter to tighten, loosen, and remove the subject nut/bolt.
Referring now to
Hollow shaped socket insert adapter 100A is a hollow insert that fits into the cavity of a socket driver. In an embodiment of the present invention, socket insert adapter 100A is composed of any metal to absorb heavy impact while being rotatively driven by a socket driver. In some embodiments, adapter 100A is composed of plastic, resin composites and polymers used in the aerospace industry that are very dense, strong, and tough. Examples of metal include, but are not limited to aluminum, steel and its alloys, brass, iron, titanium, and copper. In some embodiments, the adapter 100A is composed of steel or titanium for some high torque applications. In practice, titanium and steel alloys can be used at all torque levels of socket insert usage. Aluminum alloys have worked well at lower to mid-range torque applications, the difference being that some metals will have a longer life in industrial use. Aluminum inserts offer the light weight advantage in those applications where weight savings is critical, they may not last as long as the steel alloy composition inserts, but in some aerospace applications a light weight tool is of prime importance not its longevity. On the other hand, hydraulic wrenches with their very high torque operating ranges (>135,000 ft/lbs.), steel alloy composition inserts would be preferred. Aerospace applications will also be an industry where the composite or polymer socket inserts would be used.
The hollow shaped socket insert adapter may be of any shape formed of edges. Examples of shapes include a square, hexagonal, octagonal, decagonal, and dodecagonal, any polygonal or any special shape. Most industrial heavy use of nuts/bolt heads will be of the hexagonal design. This is because of the common design of heavy duty socket drivers are of the hexagonal variety. Simply a matter of economics that a standard was used globally to settle on hexagonal design for heavy duty use. Tools, wrenches, sockets were found to attach easier and more efficiently with the hex design. Also, hexagonal designs limit the damage to nut/bolt head corners upon torque applications because of the 120 degree angle of the corner faces them. Access to the hex design only requires 60 degrees of spatial area, whereas the square shape requires 90 degrees or triangle shapes required 120 degrees. In early industrial years square designs of nut/bolt heads were used, but when torque engaged at the four corners damage resulted at the corners resulting in rounded off nuts/bolts. More or less, a global standard was adopted for economic and design ease for hexagonal design. The common design of most impact sockets are of the hexagonal configuration, for example the very large 9½″ SAE and 255 mm impact sockets are both of the hexagonal variety.
The socket insert adapter 100A is of varied sizes to accommodate the nuts/bolts of smaller dimensions with reference to the size of the socket driver. In an embodiment of the present invention, the sizes of the hollow shaped socket insert adapters are designed with different sizes, the sizes varying with a difference of at-least 1/16 inches (or about 1 mm). Most effective dimensions for the hollow shaped socket insert adapters vary from one inch (or 25 mm) to 12⅞ inch (or 327 mm). In an embodiment of the present invention, the socket insert adapter 100A has SAE (Society of Automotive Engineers) sizes. In another embodiment of the present invention, metric sizes corresponding to the SAE sizes are available. Further, hollow shaped socket insert adapters have interchangeable SAE to metric sizes or vice versa.
In an embodiment of the present invention, socket insert adapter 100A has an outer wall 102 and an inner wall 104 indicating that socket insert adapter 100A has a thickness 106. The thickness of the hollow shaped socket insert adapter is governed by the size of nuts/bolts to be driven. The outer wall of socket insert adapter 100A is structured to mechanically co-operate with the socket driver enabling it to conform to the cavity of the socket driver allowing it to tighten, loosen, and remove various smaller dimensions of nuts/bolts. The inner wall is configured to engage nuts/bolts of smaller dimensions and fits on the head portion of nuts/bolts.
Moving forward with reference to
The inner configuration 110 interacts with the head portion of nuts/bolts (e.g., 199,
Depending on the particular embodiment, the construction of the outer configuration may or may not be similar to the construction of the inner configuration. For example, the outer configuration of the hollow shaped socket insert adapter may be selected from, but not limited to, a circle, square, pentagonal, hexagonal, decagonal, dodecagonal, and any polygonal and the inner configuration of the hollow shape socket insert adapter may be selected from, but not limited to, a circle, square, pentagonal, hexagonal, decagonal, dodecagonal, and any polygonal, indicating that the hollow shape socket insert adapter that are 6 pt. (hexagonal) on the outside can be 4 pt, 5 pt, 6 pt, 7 pt, 8 pt., 10 pt, 12 pt., SAE or metric dimension on the “inside” of the hollow shaped socket insert adapter. This enables the single socket driver to operate on nuts/bolts of different shapes and smaller dimensions effectively. In an embodiment of the present invention, various SAE to SAE; SAE to metric; metric to metric; metric to SAE; 6 pt. to 6 pt.; 6 pt. to 8 pt.; 6 pt. to 12 pt.; 12 pt. to 12 pt.; 12 pt. to 8 pt.; 12 pt. to 6 pt. combinations are possible. The exercise of different hollow shaped socket insert adapters enables a great variety of socket driver dimensions and configurations. For example: if one has a 3″ SAE hexagonal (6 pt.) socket driver, this socket driver can now become a platform for tightening, loosening, and removing nuts/bolts of different configurations having dimensions smaller than 3″. The combination of outer configurations 108 and inner configurations 110 vary in great variety.
In an embodiment of the present invention, the outer configuration 108 of the hollow shaped socket insert adapter is similar to the cavity of socket driver to fit well to the cavity of the socket driver. In another embodiment of the present invention, outer configuration 108 of the hollow shaped socket insert adapter is not similar to the cavity of socket driver.
In the embodiment of
In an embodiment of the present invention, socket insert adapter 100A has an outer diameter 112 to fit inside the socket driver cavity and a variable inner diameter 114 to operate on large range of smaller sizes of nuts/bolts. The variable inner diameter 114 of the hollow shaped socket insert adapter conforms to the head portion of nuts/bolts of different sizes. The hollow shaped socket insert adapter has rounded corners. Details corresponding to the rounded corners have been provided in conjunction with
The socket insert adapter 100A is designed to have rounded “outside” corners 116A and rounded “inside” corners 118A which enables concentrating more torque upon the flat walls 102, 104 of the hollow shape insert rather than at corners. This helps to reduce the possibility of “rounded” corners upon the nut or bolt head portion being tightened or loosen. The rounded “outside” corners 116A and rounded “inside” corners 118A of the hollow shape socket insert adapter 100A securely holds socket insert adapter 100A inside the socket driver cavity (e.g., 604C) and prevents it from spinning and slippage.
In the embodiment shown in
Referring now to
Referring now to
The hollow shaped socket insert adapter has outer wall 102 concentric about longitudinal axis 120 configured to conform to the cavity of the socket driver. Socket insert adapter 100A is configured to slidably and non-rotatably engage a nut/bolt to be driven.
Both
Socket drivers 600A (6 point) and 600C (hex) have socket driver bodies 602A and 602C, respectively enclosing a socket driver cavities 604A and 604C. Outer walls 606A and 606C of the socket drivers and inner walls 608A and 608C of the socket drivers define the structure of the socket drivers. Socket driver cavities 604A and 604C accommodate the hollow shaped socket insert adapters. Outer walls 602A and 602C of socket insert adapter 100A interacts with inner walls 608A and 608C of the socket drivers for rotatively driving nuts/bolts of smaller dimensions. Inner wall 104 of socket insert adapter 100A is configured to engage nuts/bolts of smaller dimensions and fits on the head portion of nuts/bolts. In some embodiments, adapters 100A, 100B, and 100C remain below the rim of inner walls 608A and 608C, most preferably about 1/16″ below the rim. This ensures that the inner wall rim will not interfere with the application of maximum torque for tightening and loosening actions.
The Type 2 design has the advantage of enabling a socket insert to fit into socket drivers that have only straight wall interiors, that is, it will fit into the sockets that have only flat walls (without the inner corner concave radii at the inner face intersections) as well as the newer type of socket drivers that have the inner corner concave radii (
The hollow shaped socket insert adapters 702A(i), 702A(ii), 702A(iii), 702A(iv), 702A(v), and 702A(vi) have a fixed outer diameter 112 and a different inner diameter 114. The sizes of the hollow shape socket insert adapters vary with a difference of at-least 1/16 inches (or about 1 mm). The varying inner diameter 114 enables the hollow shape socket insert adapters to fit on different smaller dimensions of nuts/bolts. Thus, one socket driver is enabled to be used to tighten, loosen, and remove nuts/bolts of different sizes and shapes.
In an embodiment of the present invention, the hollow shaped socket insert adapter has a fixed outer diameter 112 and a variable inner diameter 114. The variable inner diameter 114 of the hollow shape socket insert adapter conforms to the head portion of nuts/bolts of different sizes. Inserts 802a, 802b, 802c are examples of inserts having a fixed outer diameter and a variable inner diameter.
In another embodiment of the present invention, the hollow shaped socket insert adapter has an outer configuration 108 and an inner configuration 110. The construction of the outer configuration may or may not be similar to the construction of the inner configuration. For example: the outer configuration of the hollow shaped socket insert adapter may be selected from, but not limited to, a circle, square, pentagonal, hexagonal, decagonal, dodecagonal, and any polygonal and the inner configuration of the hollow shape socket insert adapter may be selected from, but not limited to, a circle, square, pentagonal, hexagonal, decagonal, dodecagonal, and any polygonal. The combination of outer configurations 108 and inner configurations 110 vary in great variety. Thus, by means of a series of hollow shaped socket insert adapters, single socket driver is employed to operate upon a large number of nuts/bolts of different size and shapes. Inserts 804a, 804b, 804c are examples of inserts with different inner and outer configuration.
In another embodiment of the present invention, the hollow shaped socket insert adapters are adapted to be used with spring ball detent. Details corresponding to inserts for spring ball detent have been provided in conjunction with
Spring ball detent 902 is a simple mechanical arrangement used to hold hollow shape socket insert 904 securely within socket driver 910 while operating upon nuts/bolts. The spring ball is a single, usually metal sphere, sliding within a bored cylinder, against the pressure of a spring, which pushes the ball against the hollow shaped socket insert adapter, which carries hole 906. Spring ball detent 902 passes through hole 911 (in the socket driver body) and hole 906 (in the hollow socket insert) to hold the hollow socket insert in place while rotatively driving the nuts/bolts of different shapes and sizes. Preferably, spring ball detent 902 is affixed permanently to the socket driver cavity wall.
In another embodiment of the present invention, the hollow socket insert is held securely in place using a magnetic metal for production of hollow socket insert. In another embodiment of the present invention, the hollow socket insert is held in place using pins.
Further referencing
In some embodiments, hollow socket insert 904 includes outer flat walls. At intersections of the flat outer walls, hollow socket insert 904 defines one or more outer rounded corners. The outer flat walls and the outer rounded corners of hollow socket insert 904 define an outer configuration having a shape and size to conform to and to fit into the cavity of socket driver 910. The outer configuration of socket insert 904 is shaped to allow the plurality of outer flat walls of the outer configuration to contact and to engage, and the one or more outer corners to avoid engaging, the chamber of socket driver 910. That is, the plurality of flat outer walls of the socket insert contact and engage the plurality of flat inner walls of the chamber of socket driver 910. Further, the rounded outer corners of socket adapter 904 do not contact or engage the rounded inner corners of the chamber of socket driver 910.
Socket wrench 1002 is a type of tightening tool used to tighten, loosen, and remove nuts/bolts. In an embodiment of the present invention, socket wrench is an open end socket wrench 1004. In another embodiment of the present invention, socket wrench is a closed box end wrench 1006. The socket wrench is enabled to use socket insert adapter 100A, 100B, or 100C for tightening, loosening, and removing nuts/bolts of different dimensions by receiving socket insert adapters 100A, 100B, or 100C in the cavity at its end.
Referring now to
At step 202, the dimension and shape of the nut/bolt to be driven, are checked. At step 204 an appropriate hollow shaped socket insert adapter specific to the size of subject nut or bolt head dimension is selected. At step 206, the hollow shaped socket insert adapter is placed inside the socket driver cavity. Further referencing step 206, in some embodiments, an insert is placed inside a socket driver cavity and adapter is mated with driver without contacting outer rounded corners. As discussed above, not all embodiments have outer rounded corners. In another embodiment of the present invention, hollow socket insert having a spring ball detent provision is placed within the socket driver/socket wrench cavity at step 208. Socket driver/socket wrench with hollow shaped socket insert adapter is now ready for application of torque to tighten, loosen, or remove the subject nut or bolt. In another embodiment, at step 209 the socket driver may be optionally attached to a power source, preferably including electrical, hydraulic, and pneumatic impact wrenches. At step 210, torque force is applied on the socket driver/socket wrench. The torque force may be applied by manual, electric, hydraulic, or pneumatic means. Further referencing step 210, in some embodiments, adapter is mated with nuts/bolts without contacting inner rounded corners of the adapter.
Referring now to
Referring now to
Powered impact wrenches operate in torque ranges well above any wrench that is only manually operated. While an electrical, hydraulic, or pneumatically driven versions could apply a range of torque forces, one skilled in the art would easily recognize, after reading the above, that at least some of the torque ranges for the above electrical, hydraulic, or pneumatically driven drivers would be beyond what could typically be applied by manual or human force on a manually driven driver. That is, at least some of the above-discussed electrically, hydraulically, or pneumatically driven drivers would apply a torque beyond the torque that could be applied by manual or human force on a manually driven driver. For example, a very strong human applying legs, arms and back optimally placed and braced against a wall, could generate a force of around 500 ft./lbs. for a short period of time. In some embodiments, a socket insert adapter can absorb more than 500 ft./lbs. of torque, more than what could typically be applied manually, from a powered impact wrench. In some embodiments, a socket insert adapter can absorb more than 4000 ft./lbs. of torque from a powered impact wrench. In some embodiments using a pneumatic powered impact wrench, a socket insert adapter can absorb up to 80,000 ft./lbs. and hydraulic wrenches, acting on the socket insert adapter of the present invention, can exert a force of over 138,000 ft./lbs.
The socket insert adapter of the present invention with its two sided (interior and exterior) precision tolerance sizing itself to the high torque, is particularly suited for industrial classification as to scope and purpose. Optimally, both interior as well as the exterior surfaces are in contact with the socket to be acted on for action or optimal operation. Type 1 socket insert adapters, with outer convex radii at face intersections and Type 2 socket insert adapters, with all flat intersecting planes on the exterior faces, both accommodate high torque (greater than 1000 ft./lbs.) socket wrench designs having similar arrangement of faces at their interiors. All Type 1, Type 2, and Type 3 designs have concave radii at interior corner intersections.
The hollow shaped socket insert adapters described in the invention fulfill the objects set forth at the beginning of the description and provide means whereby a single socket driver/socket wrench may be employed to operate on a large range of nuts/bolts of different size and shapes at a substantial saving in weight, space, and cost.
As illustrated in
Socket insert adapter 1400 is designed to have smooth “outside” corners 1402a-f and rounded “inside” corners 1404a-f which enables concentrating more torque upon the flat walls 1412, 1414 of the hollow shape insert rather than at corners 1402a-f, 1404a-f. Outside corners 1402a-f may be sloped at an angle between 30° to 75° to optimize the torque application. Inside corners are sized and dimensioned to mate with nuts/bolts.
Socket insert adapter 1400 is defined by a mount end 1406 and a rim end 1408. Mount end 1406 enters cavity of a socket driver. Mount end 1406 is defined by a mount edge 1418 that abuts a rear wall in socket driver when fully engaged. The insert adapter 1400 does not necessarily, however, have to abut the rear wall 1702 of socket driver 1700. The socket insert adapter 1400 is still operational even with a gap between the rear wall 1702 of socket driver 1700. This is because numerous manufacturers of socket drivers. In one embodiment insertion of the socket insert adapter 1400 two-thirds of the way inside socket driver 1700 allows socket insert adapter 1400 to be operational.
Rim end comprises a rim edge 1416. In some embodiments, a rim 1410 circumambulates rim end 1408, disposed generally coplanar with rim edge 1416 of rim end 1408. Rim 1410 forms an integrated unitary piece with outer flat walls 1414. This unitary configuration enhances the structural integrity of socket insert adapter 1400. This enables socket insert adapter 1400 to withstand substantial torque forces.
In one exemplary embodiment, rim 1410 extends between 2 to 50 millimeters from edge 1416 of rim end 1408. Though various lengths and thicknesses of rims may be used. In yet another alternative embodiment, rim 1410 comprises a plurality of spaced-apart ridges that enhance adherence to rim edge 1416 of rim end 1408.
When socket insert adapter 1400 is fully entered into socket driver, rim 1410 rests substantially flush with edge of socket driver. In this disposition, rim 1410 provides a surface for rotatably manipulating socket insert adapter 1400 with the hands. Rim further enables facilitated removal of socket insert adapter 1400 from cavity of socket driver. For example, a flat instrument can pry socket insert adapter 1400 from cavity of socket driver by positioning beneath rim 1410 and using rim edge 1416 as a fulcrum.
Another advantage provided by socket insert adapter 1400 is that rim 1410 holds an insert in a wrench, as the insert will not fall out, move laterally, or move axially when being handled and moved by an operator. This stationary effect results because rim 1410 provides extra surface area to engage the rim edge 1416 of rim end 1408. In one alternative embodiment, an oil may coat rim 1410 to create additional adherence with rim edge 1416 of rim end 1418. Rim is also useful for repositioning socket insert adapter 1400 in cavity of socket driver.
The hollow shaped socket insert adapters described in the invention fulfill the objects set forth at the beginning of the description and provide means whereby a single socket driver/socket wrench may be employed to operate on a large range of nuts/bolts of different size and shapes at a substantial saving in weight, space, and cost.
While the illustrative embodiments of the disclosure have been described above, it will be recognized and understood that various modifications can be made in the disclosure and the appended claims are intended to cover all such modifications which may fall within the spirit and scope of the disclosure.
This application is a continuation-in-part application of U.S. Ser. No. 14/287,261, entitled “Socket Insert Adapter and Method of Use”, filed May 27, 2014, which in turn is a continuation application of U.S. Ser. No. 13/283,499, entitled “Socket Insert Adapter and Method of Use”, filed Oct. 27, 2011 (now U.S. Pat. No. 8,752,455, issued Jun. 17, 2014), which in turn is a continuation-in-part of U.S. Ser. No. 12/434,609, entitled “Socket Insert Adapter”, filed May 1, 2009, which applications are incorporated herein for all purposes.
Number | Date | Country | |
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Parent | 13283499 | Oct 2011 | US |
Child | 14287261 | US |
Number | Date | Country | |
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Parent | 14287261 | May 2014 | US |
Child | 15332889 | US | |
Parent | 12434609 | May 2009 | US |
Child | 13283499 | US |