Devices and methods for locking handles are disclosed.
In many devices it can be useful to have a handle that can either deployed or stowed as the user selects, and it can be particularly useful to have the handle lock in either or both positions. A handle and a body can be attached in such a way that the handle is biased toward a locked position with a locking portion of the handle sized and shaped to be mated with a locking portion of the base. The locking portion of the handle can be complementary to the locking portion of the base. The bias can be achieved by means of a spring. The handle may be lockable in more than one position. For example, the base may have two different locking portions, both of which are complementary to the same locking portion of the handle. The base and handle can be attached in such a way that the locking portion of the handle can be disengaged from a locking portion of the base with out entirely detaching the base and handle. In that disengaged state, the handle can be moved between multiple positions, for example between a deployed position and a stowed position.
In use with an air gun, the assembly shown in
As shown the roll pin 6 is free to rotate in the gudgeon 4 and also in the folding handle 5. In other embodiments, the roll pin 6 may be either fixedly attached to or an integral part of either the gudgeon 4 or the folding handle 5. But the roll pin 6 may not be fixed with respect to both the gudgeon 4 and the folding handle 5. If it were, then the folding handle 5 would also be fixed with respect to the gudgeon 4. As shown the gudgeon 4 is integrally formed with the main body of the assembly, but could alternatively be a separate part fixedly attached.
The folding handle 5 is not entirely unconstrained. The piston 9 includes a guiding pin 18 that rides in an elongated guiding groove 19 defined by the folding handle 5. The guiding groove 19 does not extend the full length of the blind bore 12. When a user pulls the folding handle 5 away from the gudgeon 4 along the piston axis 10, eventually the folding handle 5 can hit a stop. The stop may be due to contact between the guiding pin 18 and the end of the guiding groove 19. This limits the possible excursion of the folding handle 5 along the piston axis 10. Or the excursion may simply be limited by the compressibility of the spring 11. The primary (although not the only) function of the guiding pin 18 and guiding groove 19 is to prevent the folding handle 5 from rotating about the piston axis 10. In some embodiments, the folding handle 5 can be free to rotate about the piston axis 10. As shown, the folding handle 5 has a roughly trapezoidal profile. If the folding handle 5 had, for example, a circular cross-sectional profile, rotation about the piston axis 10 would not be undesirable.
At the end near the gudgeon 4, the folding handle 5 has a chamfered end 14. The gudgeon 4 defines two divots 15, 16. Each divot is sized and shaped to match the chamfered end 14. The first divot 15 is visible in
With the chamfered end 14 fully seated in the second divot 16, the folding handle 5 is in a locked state and is not free to rotate about the roll pin 6. To transition the folding handle 5 to an unlocked state, the user pulls the folding handle 5 along the piston axis 10 until the chamfered end 14 is clear of the second divot 16. In order to pull the folding handle 5 clear of the second divot 16, the user must compress the spring 11, which normally urges the folding handle 5 in the locked position. Once pulled clear, the folding handle 5 is then free to rotate about the roll pin 6. The folding handle 5, the piston 9 and the spring 11 rotate as a single unit about the roll pin 6.
The folding handle 5, once in the unlocked state, can be rotated so that the chamfered end 14 is above the first divot 15. The folding handle 5 can then be released so that the spring 11 urges the chamfered end 14 into the first divot 15. This transitions the folding handle 5 back into a locked state, this time locked in the first divot 15 rather than the second divot 16. When locked into the first divot 15 the folding handle 5 is generally parallel to the static handle 8.
Although the folding handle 5 is shown with a chamfered end 14 and the gudgeon 4 is shown with conical divots 15, 16 a wide variety of mating shapes could suffice. A cylindrical end could mate with a generally cylindrical bore in the gudgeon 4. Or any other pair of mating, locking shapes could be used.
The exhaust port 7 is the mouth of an air channel inside the assembly. When an elongated air-gun shaft is affixed to the exhaust port 7, the elongated shaft can be generally aligned with longitudinal axis 17 shown as a dashed line in
One feature of the depicted assembly is the type of motion necessary to transition the folding handle 5 from the state of being locked in the first divot 15 to the unlocked state. When air is expelled through the exhaust port 7, for example into and then through and out of an elongated shaft of an air gun aligned with the longitudinal axis 17, the recoil on the assembly will tend to be along the longitudinal axis 17. When the folding handle is locked in the first divot 15, the piston axis 10 is perpendicular to the longitudinal axis 17. So the recoil on the assembly will tend to push on the folding handle 5 perpendicular to the only direction it is allowed to move, namely along the piston axis 10. Conversely, the folding handle 5 cannot be unlocked by the recoil, since to unlock the folding handle 5 it must be moved along the piston axis 10, which has no or essentially no component along the longitudinal axis 17.
In the depicted embodiment, the folding handle 5 rotates in only one sense, about the axis of the roll pin 6. But in other embodiments, a different sort of pivot could be used to allow the handle to rotate in more than one sense, for example a ball and socket. Likewise, the folding handle could lock in more than two positions, for example, three, or four, or more. The locked positions could be separated by 90 degrees as shown, 180 degrees, 60 degrees, 45 degrees, 30 degrees, or any other angle, for example an angle that proves convenient or otherwise ergonomic for a user's grip on the device.
As shown, the assembly includes a pressure gauge 20 located so as to be clearly visible to a user who is gripping the air gun as if it were a jackhammer.
As an alternative to the particular example shown in the figures, the handle could move from stowed to deployed, not by rotating relative to the assembly, but by translating. For example, as shown in
In some embodiments, the handle can be both slidable and rotatable. For example, as shown in
A locking handle assembly can include a gudgeon, a roll pin, a piston defining a piston axis, a spring, and a handle. The roll pin can be operably attached to the gudgeon so that the roll pin cannot translate relative to the gudgeon. The piston can be operably attached to the roll pin so that the piston can rotate about the roll pin but cannot otherwise translate relative to the roll pin or the gudgeon. The handle can define a blind bore substantially aligned with the piston axis. The spring and a portion of the piston can be arranged within the blind bore so that the spring biases the handle relative to the piston toward the gudgeon along the piston axis. The handle can be configured to transition between a first locked state and an unlocked state by translating relative to the piston along the piston axis. When the handle is in the first locked state, (a) a chamfered end of the handle can be held in contact with a first divot, the first divot being defined by the gudgeon and being sized and shaped to mate with the chamfered end, and (b) the chamfered end can be held in contact with the first divot by the bias of the spring acting along the piston axis such that interference of the chamfered end with the first divot substantially prevents the handle, the piston and the spring from rotating relative to the gudgeon. When the handle is in the unlocked state, (a) the handle can be farther from the gudgeon along the piston axis than in the locked state so that the chamfered end of the handle is clear of the first divot, thereby allowing the handle, the piston and the spring to rotate relative to the gudgeon, (b) the handle can be urged along the piston axis by the bias of the spring, and (c) the spring can be more compressed along the piston axis in the unlocked state than in the locked state.
In such assemblies, the gudgeon can further define a second divot sized and shaped to mate with the chamfered end, the handle can be further configured to transition between the unlocked state and a second locked state by translating relative to the piston axis, when the handle is in the second locked state, (a) the chamfered end of the handle can be held in contact with the second divot, and (b) the chamfered end can be held in contact with the second divot by the bias of the spring acting along the piston axis such that interference of the chamfered end with the second divot substantially prevents the handle, the piston and the spring from rotating relative to the gudgeon, and the first and second divots can be spaced apart on the gudgeon so that in the first locked state the handle assumes a first orientation relative to the gudgeon and in the second locked state the handle assumes a second orientation relative to the gudgeon. In the first orientation the piston axis can be rotated 90 degrees about the roll pin relative to the second orientation of the piston axis.
An air gun can include such a locking handle assembly and an elongated shaft defining a longitudinal axis. The elongated shaft can include a user end configured to be supplied with pressurized air, and a working end configured to discharge pressurized air, the shaft can define a channel substantially aligned with the longitudinal axis, the user end can be in fluid communication with the working end through the channel, the gudgeon can be fixedly attached to the elongated shaft adjacent to the user end such that the gudgeon can neither rotate nor translate relative to the elongated shaft, the piston axis in the first orientation can be substantially perpendicular to the longitudinal axis, and the piston axis in the second orientation can be substantially parallel to the longitudinal axis.
In some embodiments, a locking handle assembly can include a base, a locking handle operably attached to the base, and a means for disposing the handle relative to the base so that the handle either (a) cannot translate relative to the base in at least a first position and a second position relative to the base, or (b) can transition between the first and second positions. The means for disposing the handle can, for example, include the roll-pin-and-gudgeon-type assembly shown in
This application is a continuation of U.S. patent application Ser. No. 14/215,674 filed on Mar. 17, 2014 entitled LOCKING HANDLE, which claims priority to U.S. Provisional Patent Application 61/792,234, filed on Mar. 15, 2013 entitled LOCKING HANDLE, both of which applications are hereby incorporated by reference.
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Number | Date | Country |
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10138065 | Feb 2003 | DE |
1166972 | Jan 2002 | EP |
Entry |
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Machine Translation of DE 10138065, obtained Oct. 31, 2016. |
Number | Date | Country | |
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20180149446 A1 | May 2018 | US |
Number | Date | Country | |
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61792234 | Mar 2013 | US |
Number | Date | Country | |
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Parent | 14215674 | Mar 2014 | US |
Child | 15884547 | US |