The present exemplary embodiment relates to masts. It finds particular application in conjunction with tilting of telescoping masts for antennas, lights and other payloads, and will be described with particular reference thereto. However, it is to be appreciated that the present exemplary embodiment is also amenable to other like applications.
Telescoping masts generally include multiple tube or lattice structure sections that are configured to telescope or nest within each other. A drive system is typically configured to deploy and/or retract the tubes between extended and retracted configurations. Locks or latches may be used to lock each tube to its adjacent tube or tubes when in the extended configuration.
Military and commercial mast users often have a need to transport a telescoping mast to the location where it will be deployed. It is often desired to have these masts deployed and ready for use immediately upon arriving on location. In addition, some mast systems would be unable to fit in aircraft or trucks, or clear bridges and other overhead encumbrances without bringing the mast to a horizontal position for transport. One means to bring the mast to a horizontal position is by using a tilting mechanism. A tilting mechanism can be manual or automated. In cases where the masts and payloads are large or where time to readiness is critical an automated version is desired.
One version of an automated tilting mechanism uses an actuator to provide a rotational moment to tilt the mast which is mounted in a pivoting cradle. This rotational moment can be provided by an electromechanical, pneumatic or a hydraulic actuator, or through other mechanical means using a motor and gears, etc. An automated tilting mechanism also generally includes a locking mechanism to “lock” the pivoting cradle with the mast in the horizontal and vertical positions. When the mast carrying cradle is in the horizontal position it needs to be secured to avoid damage to the mast or payload during transportation. When the mast carrying cradle is in the vertical position it needs to be secured to provide a stable platform for the payload to function properly.
One approach to lock the tilting cradle carrying a mast in either position is by moving a large pin into a bushing that is securely fastened to the automated tilt mechanism base. To prevent rotational movement of the cradle and mast due to mast payload induced pivoting and torsional loads on the mast, four locking actuators have generally been needed, each actuator configured to a locking pin into and out of engagement with a lock hole.
In the present disclosure, a single locking actuator is configured to shuttle oppositely extending pins in and out locking engagement with respective bushings. By utilizing a single actuator to move at least two pins, it is possible to reduce the number of actuators needed for a given application, thereby reducing complexity and cost.
In accordance with one aspect, a mast assembly comprises a base member, a mast, a cradle supporting an end of the mast and being pivotally mounted to the base member for movement between first and second positions for changing an orientation of the mast, and at least one locking actuator for locking the cradle in at least one of the first or second positions, the locking actuator including a housing having a first lock pin extending in a first direction and a movable member supported by the housing having a second lock pin extending in a second direction opposite the first, the locking actuator being slideably mounted to the cradle for sliding movement along an axis parallel to an axis of extension/retraction of the locking actuator. When the locking actuator is extended the first and second lock pins are inserted into respective openings in the base member thereby locking the cradle against pivoting movement relative to the base member, whereby when the locking actuator is retracted the first and second lock pins are withdrawn from the openings in the base member thereby permitting pivoting movement of the cradle relative to the base member.
The cradle can be pivotable about a cradle axis, and the at least one locking actuator can extend/retract along an axis parallel to the cradle axis. The at least one locking actuator can be at least one of an electric actuator, a hydraulic actuator, or a pneumatic actuator. The mast can include a telescoping mast having a plurality of nesting sections. The first and second lock pins can be aligned along a common axis.
A center stop can be supported on at least one of the locking actuator or the cradle for limiting an extent to which terminal ends of the first and second lock pins can be drawn towards each other during retraction of the locking actuator either by limiting movement of one of the lock pins or by limiting movement of the housing of the locking actuator. The center stop can be positioned between the first and second lock pins. The assembly can also include at least one outer stop surface against which a lock pin impinges when fully inserted into the opening in the base member, the outer stop surface limiting an extent to which the first and second lock pins can be separated from each other during extension of the locking actuator.
The base member can include a bottom wall and spaced apart side walls extending in a common direction from the bottom wall, each side wall including at least one opening into which a respective lock pin can be inserted when the lock actuator is in the extended position. The cradle can be mounted between the side walls and each side wall can include a stowed lock hole and a deployed lock hole spaced from the stowed lock hole, each stowed lock hole receiving one of the first or second lock pins of the locking actuator when the mast is in a stowed position, and each deployed lock hole receiving one of the first or second lock pins of the locking actuator when the mast is in the deployed position.
In accordance with another aspect, a tilt mechanism for an associated mast comprises a mountable base member, a cradle for supporting the associated mast, the cradle pivotally mounted to the base member for movement between first and second positions for changing an orientation of the associated mast, and at least one locking actuator for locking the cradle in at least one of the first or second positions, the locking actuator including a housing having a first lock pin extending in a first direction and a movable member supported by the housing having a second lock pin extending in a second direction opposite the first, the locking actuator being slideably mounted to the cradle for sliding movement along an axis parallel to an axis of extension/retraction of the locking actuator. When the locking actuator is extended the first and second lock pins are inserted into respective openings in the base member thereby locking the cradle against pivoting movement relative to the base member, and whereby when the locking actuator is retracted the first and second lock pins are withdrawn from the openings in the base member thereby permitting pivoting movement of the cradle relative to the base member.
The cradle can be pivotable about a cradle axis, and the at least one locking actuator can extend/retract along an axis parallel to the cradle axis. The at least one locking actuator can be at least one of an electric actuator, a hydraulic actuator, or a pneumatic actuator. The first and second lock pins can be aligned along a common axis.
A center stop can be supported on at least one of the locking actuator or the cradle for limiting an extent to which terminal ends of the first and second lock pins can be drawn towards each other during retraction of the locking actuator either by limiting movement of one of the lock pins or by limiting movement of the housing of the locking actuator. The center stop can be positioned between the first and second lock pins. The mechanism can further include at least one outer stop surface against which a lock pin impinges when fully inserted into the opening in the base member, the outer stop surface limiting an extent to which the first and second lock pins can be separate from each other during extension of the locking actuator.
The base member can include a bottom wall and spaced apart side walls extending in a common direction from the bottom wall, each side wall including at least one opening into which a respective lock pin can be inserted when the lock actuator is in the extended position. The cradle can be mounted between the side walls and each side wall includes a stowed lock hole and a deployed lock hole spaced from the stowed lock hole, each stowed lock hole one of the first or second lock pins of the locking actuator when the mast is in a stowed position, and each deployed lock hole receiving one of the first or second lock pins of the locking actuator when the mast is in the deployed position.
In accordance with another aspect, an automatic tilting mechanism for a mast includes locking pins mounted on a rotating cradle so only one set of moving pins is used to secure the cradle in a given position. The two locking pins are attached to opposite ends of an actuator that is mounted on a sliding mechanism that is attached to the tilting cradle. When the cradle reaches the horizontal or vertical position, for example, a signal is given to extend the actuator. The actuator extends until one locking pin is fully inserted into its associated base bushing (e.g., lock hole in an adjacent flange) and then the actuator slides on the sliding mechanism in the opposite direction until the other locking pin is fully inserted into its associated bushing and thus the pins lock the cradle in position. When the cradle needs to be rotated (e.g., moved again to the horizontal or vertical position) the process is reversed. The actuator is retracted which extracts the locking pins from their associated bushings. The order in which the pins are inserted or extracted from their associated bushings does not matter as the actuator slides from side to side.
Through the use of a sliding locking actuator in accordance with the disclosure only one actuator is needed to engage two opposed locking pins. This eliminates the cost and complexity of multiple actuators and associated limit switches and control functions. It also eliminates two additional locking pins and bushings and their associated cost. The reduction in components and their related electrical connections increases the reliability, lowers the life cycle cost, and improves the overall quality of the automated tilting mechanism. The sliding locking actuator concept could be applied to other apparatus or mechanisms where opposing pins or other devices need to be engaged at the same time.
With reference to
The base member 14 includes a bottom wall 24 and spaced apart side walls 26 that extend in a common direction from the bottom wall 24. The cradle 22 is mounted to the base member 24 for pivoting movement by a pair of bearings 30 or the like that are secured to each of the side walls 26. The cradle 22 and, thus, the mast 18 is pivotable about a cradle axis A that extends through bearings 30.
In operation, the mast assembly 10 is generally maintained in the stowed position as shown in
In accordance with the present disclosure, the mast assembly 10 further includes at least one sliding locking actuator 40 for locking the cradle 22 in the horizontal and vertical orientations. The locking actuator 40 is supported for movement on a surface of the cradle 22 and is configured to extend and retract first and second lock pins into and out of respective down or stowed lock holes 42 and up or deployed lock holes 44.
With reference to
The locking actuator 62 is supported on a sliding base assembly 72 that includes a base member 74 that is mountable to a surface, such as the cradle 22 of
It will be appreciated that the locking actuator 62 in
Beginning with
In
Turning now to
Retraction of the actuator mechanism is the opposite of extension. As will be appreciated, as the actuator is retracted, sliding platforms 88 and 90 are drawn together thereby retracting locking pins 66 and 68 until both platforms 88 and 90 engage center stop block 90. Locking pins 66 and 68 may be withdrawn simultaneously or sequentially depending on frictional forces and/or other influences, but the order of withdrawal is generally not significant. It should now be appreciated that the present disclosure sets forth a locking mechanism having a single actuator that has the ability to lock/unlock the cradle on two opposing sides while harnessing the force of one actuator that extends from one end. This feature is achieved by the actuator free sliding in either locking pin receptacle direction across the cradle against hard stop thus allowing random initiation of either locking pin insertion/extraction. The locking mechanism is mounted to the cradle and travels therewith thus allowing the locking mechanism to lock/unlock the cradle in two (2) cradle positions (e.g., vertical/horizontal, stowed/deployed, etc.).
As described, thrusting of two (2) locking pins in opposing directions with one (1) actuator that thrusts in only one direction is possible by guiding the pins using sliding platforms and limiting the travel distance of each pin slide with hard stops, thus also limiting the distance the actuator travels (floats) in any one direction while extending.
The locking order (i.e., which pin engages its respective receptacle bushing or lock hole) is typically random. Initially and prior to the collision of moving slides with hard stops, friction “stimulates” the direction of motion. Once any one pin slide reaches its hard stop and thus the pin it carries is inserted into its respective lock hole, that slide stops moving and therefore the actuator stops moving in that direction. The actuator continued extension then thrusts the opposite pin slide to insert the opposite pin into its receptacle bushings. Both locking pins are in the locked position (fully inserted into their respective receptacle bushings) when the actuator is in the fully extended position as limited by an integral electromechanical limit switch.
To unlock, the actuator is retracted. The retracting force of the actuator slides the pin carrying sliding platforms away from the hard stops to extract the pins from their respective receptacle bushings. Initially and prior to the collision of any one moving sliding platform with a center stop block, the unlocking order (i.e., which pin begins to disengage from its respective receptacle bushing) is generally random and is also “stimulated” by friction. While the actuator is retracting one of the locking pin sliding platforms will be first to collide with a stop block (hard stop) in the center of the mechanism which will stop its motion. At this position its pin is fully extracted. The continued retraction of the actuator then moves the opposing (other) locking pin sliding platform towards the center of the mechanism thus extracting the opposite pin. Both locking pins are in the unlocked position (fully extracted into their respective receptacle lock hole bushings) when the actuator is in the fully retracted position as limited by the integral electromechanical limit switch of the actuator.
It will now be appreciated that the present disclosure sets forth a single actuator that floats (e.g., slides) with hard stops limiting the sliding travel to enable both actuator ends to move a pin at each end in/out of receiving holes. This is in contrast to a traditional use of actuators where one end of the actuator is “anchored” to a non-moving structure). The single floating actuator is supported by the pivoting cradle for movement in space to different locking/unlocking locations, and is thus able to perform the same locking/unlocking function of in two different cradle positions (e.g., horizontal mast position and vertical mast position). Accordingly, the single actuator of the present disclosure makes possible locking/unlocking a pivoting cradle in two orientations using four (4) engagements, two per cradle position.
The exemplary embodiment has been described with reference to the preferred embodiments. Obviously, modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the exemplary embodiment be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.
Number | Date | Country | |
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61792314 | Mar 2013 | US |