Versions of the present invention relate to systems and devices that may be used to provide a barrier to prevent the passage of vehicles and the like. Some barriers may be installed in a fixed configuration, such that the barrier system constantly prevents the passage of vehicles and the like. Other barriers may be selectively deployable, such that vehicles may pass during selected times (e.g., when the barrier is present but not deployed); while vehicles may be prevented from passing during other selected times (e.g., when the barrier is deployed). Some vehicle barriers are shown and described in U.S. Pub. No. 2007/0264080, entitled “Vehicle Barrier Deployment System,” published Nov. 15, 2007, the disclosure of which is incorporated by reference herein. While a variety of systems and methods have been made and used to provide a barrier, it is believed that no one prior to the inventor has made or used the invention described herein.
While the specification concludes with claims which particularly point out and distinctly claim the invention, it is believed the present invention will be better understood from the following description of certain examples taken in conjunction with the accompanying drawings, in which like reference numerals identify the same elements and in which:
The drawings are not intended to be limiting in any way, and it is contemplated that various embodiments of the invention may be carried out in a variety of other ways, including those not necessarily depicted in the drawings. The accompanying drawings incorporated in and forming a part of the specification illustrate several aspects of the present invention, and together with the description serve to explain the principles of the invention; it being understood, however, that this invention is not limited to the precise arrangements shown.
The following description of certain examples of the invention should not be used to limit the scope of the present invention. Other examples, features, aspects, embodiments, and advantages of the invention will become apparent to those skilled in the art from the following description, which is by way of illustration, one of the best modes contemplated for carrying out the invention. As will be realized, the invention is capable of other different and obvious aspects, all without departing from the invention. Accordingly, the drawings and descriptions should be regarded as illustrative in nature and not restrictive.
I. Exemplary Vehicle Barrier with Guardrail
A. Overview
Posts (100, 101) are connected by a plurality of horizontal members (200) (e.g., I-beams, etc.) in the present example, such that posts (100, 101) move vertically substantially simultaneously. In some versions, a single horizontal member (200) spans across all posts (100, 101) (e.g., along the tops of posts (100, 101)), in addition to or in lieu of separate horizontal members (200) spanning between adjacent posts (100, 101). In addition, guardrails (202) are connected to and span across opposing sides of posts (100, 101) in the present example. While barrier system (10) of the present example comprises a pair of guardrails (202), it should be understood that only a single guardrail (202) may be used, if desired (e.g., on just one side of posts (100, 101), etc.). It should also be understood that various structures other than guardrails (202) may be used. Several structures that may be used as an alternative to guardrails (202) will be described in greater detail below, while others will be apparent to those of ordinary skill in the art in view of the teachings herein. It should be understood that one or more additional guardrails (202) may be provided vertically above guardrails (202) that are shown in the depicted version of barrier system (10), such as to increase the height of barrier system (10). It should also be understood that two or more guardrails (202) may be “nested” with each other (e.g., guardrails (202) doubled, with one guardrail (202) placed on the inside of another guardrail (202), etc.), such as to increase the effective thickness and/or strength of guardrails (202).
As will also be described in greater detail below, barrier system (10) is operable to selectively raise and lower posts (100, 101) relative to housing (4). For instance, guardrails (202) may be raised such that their lower edges are at a height of anywhere between approximately 27 inches and approximately 36 inches (e.g., relative to the ground and/or relative to concrete (3), etc.), or at any other suitable height. Furthermore, cover plates (5) are configured to substantially close posts (100, 101), horizontal members (200), and guardrails (202) within housing (4) when posts (100, 101) and guardrails (202) are retracted downward.
In some versions, barrier system (10) may stop a vehicle that is traveling at a high rate of speed, even if the driver of the vehicle is intent on passing through the barrier provided by barrier system (10). For instance, posts (100, 101) and guardrails (202) may be substantially rigid, such that they provide little or no “give” when struck by a vehicle. By way of example only, some versions of barrier system (10) may meet a Department of State “K” certification requiring that the front line of cargo of a 15,000 pound vehicle traveling 50 mph must not go further than 1 meter past the line defined by barrier system (10). In addition or in the alternative, some versions of barrier system (10) may satisfy the American Association of State Highway and Transportation Officials (AASHTO) Manual for Assessing Safety Hardware (MASH) criteria. In some instances with some versions of barrier system (10), posts (100, 101) and/or guardrails (202) may essentially destroy a vehicle that strikes posts (100, 101) and/or guardrails (202), with relatively little damage being done to barrier system (10). For instance, barrier system (10) may be constructed such that no portions of barrier system (10) are released as projectiles when barrier system (10) is struck by a heavy vehicle moving at a high rate of speed.
As shown in
It should be understood that compartment (11) may be provided at either or both ends of housing (4), in addition to or in lieu of being provided at the side of housing (4). Alternatively, compartment (11) may be provided at any other suitable location; or may be omitted altogether (e.g., components separated and located at various positions within housing (4), etc.). In some versions, battery (43) is rechargeable by solar power via a solar panel (not shown). In some other versions, battery (43) is omitted, and an external power line is fed to housing (4). It will be appreciated, therefore, that a variety of alternative components may be used to provide and/or regulate electricity to other components within housing (4). It will also be appreciated that, in some versions, barrier system (10) may be modified such that no external power source is required at all. A sump pump (18) may also be provided within housing (4), below housing (4), or elsewhere, such as to purge water from housing (4). For instance, a perforated drainage pipe or “French drain” may be located at the bottom of housing (4) (e.g., below floor (40)), and may be coupled with sump pump (18). Of course, as with various other components described herein, a sump pump (18) is merely optional.
As shown in
B. Exemplary Deployment and Retraction System
As shown in
Post guides (120, 121) may have a height that is greater than the height of sidewalls (20), though post guides (120, 121) do not extend above sidewalls (20) in this example. For instance, while the upper rims of post guides (120, 121) may be positioned below the upper rims of sidewalls (20), the lower portions of post guides (120, 121) may extend below floor (40) of housing (4). In particular, the lower portions of post guides (120, 121) may be embedded in concrete (3) or in the ground, below floor (40). Alternatively, post guides (120, 121) may have any other desired length and position relative to housing (4). In addition, as shown in
As shown in
Static guides (130) do not move in this example. Static guides (130) each define a bore (132) and a longitudinal slot (134) in communication with bore (132). Each post (101) has a unitary, outwardly extending extension (103); while each extension has a pipe (105) unitarily secured thereto. In particular, each bore (132) is positioned and configured to receive a corresponding pipe (105); while each slot (134) is positioned and configured to receive a corresponding extension (103). Bores (132), pipes (105), slots (134), and extensions (103) are all positioned and configured such that posts (101) may travel vertically upwardly and downwardly relative to static guides (130), without static guides (130) restricting such vertical movement.
As shown in
As shown in
In some versions, cables (140, 141) are simply opposing ends of a single, unitary cable. In other versions, cables (140, 141) are two separate cables that are coupled with the same winch (17). In some other versions, cables (140, 141) are two separate cables that are each coupled with their own corresponding winch (17), such that two winches (17) are provided. Of course, any other suitable number of cables (140, 141) and winches (17) may be used; and cables (140, 141) and winches (17) may have any other suitable relationships. Furthermore, any suitable alternative, substitute, or supplement for cables (140, 141) and/or winch (17) may be used.
1. Exemplary Deployment Components
As shown in
A pair of additional deployment cables (144, 146) are also secured to clevis (142), such that pulling on cable (140) is communicated to cables (144, 146) via clevis (142) to effect deployment of posts (100, 101). Similarly, pulling on cables (144, 146) is communicated to cable (140) via clevis (142) during retraction of posts (100, 101) as will be described in greater detail below. In the present example, clevis (142) will move in a first direction (to the right in the view of
The following part of the description will describe deployment components that are employed to raise the deployment post (101) that would be at the left-hand side of
Pulley (166) is mounted to a support post (112), and rotates about a horizontal axis that extends parallel to a longitudinal axis defined by housing (4). Pulley (166) redirects deployment cable (144) vertically upwardly to reach pulley (168), as shown in
Pulley (168) is mounted to post guide (121), and rotates about a horizontal axis that extends laterally transversely to a longitudinal axis defined by housing (4) (e.g., pulley (168) rotates about an axis that intersects both long sidewalls (20)). Pulley (168) redirects deployment cable (144) vertically downwardly toward the bottom of deployment post (101).
As shown in
It will therefore be understood that, with deployment post (101) starting at a vertically down position, retracted within post guide (121), deployment post (101) may be raised within post guide (121) by pulling from cable (144). Pulley (169) raises upwardly and unitarily with deployment post (101) in this example. It will also therefore be appreciated that deployment post (101) may be raised within post guide (121) by pulling on deployment cable (140), with such pulling being powered by winch (17) and communicated via pulley (160), clevis (142), cable (144), and pulleys (164, 166, 168, 169).
The following part of the description will describe deployment components that are employed to raise the deployment post (101) that would be at the right-hand side of
Pulley (172) is mounted to sidewall (20), and rotates about a vertical axis that intersects floor (40). Like pulley (164) described above, pulley (172) redirects deployment cable (146), in a direction laterally transverse to housing (4), to reach pulley (174).
Pulley (174) is mounted to a support post (112), and rotates about a horizontal axis that extends parallel to a longitudinal axis defined by housing (4). Like pulley (166) described above, pulley (174) redirects deployment cable (146) vertically upwardly to reach pulley (176).
Pulley (176) is mounted to post guide (121), and rotates about a horizontal axis that extends laterally transversely to a longitudinal axis defined by housing (4) (e.g., an axis that intersects both long sidewalls (20)). Like pulley (168) described above, pulley (176) redirects deployment cable (146) vertically downwardly to reach the bottom of deployment post (101) (i.e., the deployment post (101) on the right-hand side in
It will therefore be understood that, with deployment post (101) starting at a vertically down position, retracted within post guide (121), deployment post (101) may be raised within post guide (121) by vertically upward pulling from cable (146). It will also therefore be appreciated that deployment post (101) may be raised within post guide (121) by pulling on deployment cable (140), with such pulling being communicated via pulley (160), clevis (142), cable (146), and pulleys (170, 172, 174, 176).
In the present example, cables (144, 146) each have a length selected to provide simultaneous raising of both deployment posts (101) when deployment cable (140) is pulled by winch (17). Such length may be selectively adjustable in a variety of ways. By way of example only, a turnbuckle (not shown) may be provided between clevis (142) and any of cables (140, 144, 146) (or elsewhere) to adjust the effective length of such cable(s) (140, 144, 146). In addition or in the alternative, and as shown in
In addition, as noted above, posts (100, 101) are all connected by both a set of horizontal members (200) (e.g., I-beams, etc.) and guardrails (202). With horizontal members (200) and guardrails (202) being substantially rigid, and with the connections between horizontal members (200) and posts (100, 101) (as well as the connections between guardrails (202) and posts (100, 101)) being substantially rigid, it will be appreciated that raising of posts (101) by cables (144, 146) in the present example will effect simultaneous raising of posts (100). In other words, the combination of posts (100, 101), horizontal members (200), and guardrails (202) may be raised or deployed collectively and simultaneously, merely by winch (17) pulling on cable (140). Tension may be maintained in cables (140, 144, 146) to keep posts (100, 101), horizontal members (200), and guardrails (202) in a raised or deployed position (e.g., by braking winch (17), etc.). Of course, there are a variety of other ways in which posts (100, 101), horizontal members (200), and/or guardrails (202) may be raised or otherwise deployed. One merely illustrative alternative is described in greater detail below (e.g., scissor arms (800, 802) assisting in raising of components, etc.), while others will be apparent to those of ordinary skill in the art in view of the teachings herein. Similarly, there are a variety of other ways in which posts (100, 101), horizontal members (200), and/or guardrails (202) may be kept in a raised position (e.g., without just relying on tension in cables (140, 144, 146), etc.). One merely illustrative alternative is described in greater detail below (e.g., scissor arms (800, 802) bearing weight of raised components, etc.), while others will be apparent to those of ordinary skill in the art in view of the teachings herein.
2. Exemplary Retraction Components
In some versions, a deployed combination of posts (100, 101), horizontal members (200), and guardrails (202) is retracted back into housing (4) by gravity. For instance, a brake on winch (17) may be released to relieve tension in cables (140, 144, 146), such that posts (100, 101) may simply fall back downwardly into their respective post guides (120, 121). As another merely illustrative alternative, winch (17) may be controllingly braked to slowly allow posts (100, 101) to fall back downwardly into their respective post guides (120, 121). In the present example, however, a deployed combination of posts (100, 101), horizontal members (200), and guardrails (202) is actively retracted back into housing (4).
As noted above, a retraction cable (141) extends from winch (17). As shown in
A pair of additional retraction cables (145, 147) are also secured to clevis (143), such that pulling on cable (141) is communicated to cables (145, 147) via clevis (142) to effect retraction of posts (100, 101). Similarly, pulling on cables (145, 147) is communicated to cable (141) via clevis (143) during deployment of posts (100, 101). In the present example, clevis (143) will move in a first direction (to the left in the view of
The following part of the description will describe deployment components that are employed to lower the deployment post (101) that would be at the left-hand side of
Pulley (167) is mounted to floor (40), and rotates about a horizontal axis that extends parallel to a longitudinal axis defined by housing (4). Pulley (167) redirects retraction cable (145) vertically upwardly to reach an eye-bolt (181). As shown in
The following part of the description will describe deployment components that are employed to lower the deployment post (101) that would be at the right-hand side of
Pulley (173) is mounted to sidewall (20), and rotates about a vertical axis that intersects floor (40). Like pulley (165) described above, pulley (173) redirects retraction cable (147), in a direction laterally transverse to housing (4), to reach pulley (175).
Pulley (175) is mounted to floor (40), and rotates about a horizontal axis that extends parallel to a longitudinal axis defined by housing (4). Like pulley (167) described above, pulley (175) redirects retraction cable (145) vertically upwardly to reach an eye-bolt (not shown). Like eye-bolt (181), this eye-bolt is secured to a horizontal member (200) that spans between post (101) and post (100) (i.e., the posts (101, 100) at the right-hand side in the view of
In the present example, cables (145, 147) each have a length selected to provide simultaneous lowering of both deployment posts (101) when deployment cable (141) is pulled by winch (17). It should be understood that the effective lengths of cables (145, 147) may be selectively adjustable using any of the components and techniques described above to provide selective adjustability of cables (144, 146); or using any other suitable structures, devices, or techniques. In addition, as noted above, posts (100, 101) are all connected by both a set of horizontal members (200) (e.g., I-beams, etc.) and guardrails (202). With horizontal members (200) and guardrails (202) being substantially rigid, and with the connections between horizontal members (200) and posts (100, 101) (as well as the connections between guardrails (202) and posts (100, 101)) being substantially rigid, it will be appreciated that lowering of posts (101) by cables (145, 147) in the present example will effect simultaneous lowering of posts (100). In other words, the combination of posts (100, 101), horizontal members (200), and guardrails (202) may be lowered or retracted collectively and simultaneously, merely by winch (17) pulling on cable (141). Of course, there are a variety of other ways in which posts (100, 101), horizontal members (200), and/or guardrails (202) may be lowered or otherwise retracted. One merely illustrative alternative is described in greater detail below, while others will be apparent to those of ordinary skill in the art in view of the teachings herein.
In some versions, one or more plates (not shown) may be provided in housing (4), to substantially cover at least some of the above described cables and/or pulleys, such as to protect such cables and/or pulleys from debris, etc. Of course, such plates are merely optional.
C. Exemplary Covers
Cover plates (5) are pivotally engaged relative to flanges (9) of housing (4), such that cover plates (5) may provide a selectively openable “lid” for barrier system (10). In particular, cover plates (5) are each mounted to a respective set of hinges (12), each of which is mounted to a corresponding flange (9). While each cover plate (5) has a plurality of associated hinges (12) in the present example, some versions may provide just a single hinge (e.g., a continuous hinge or piano hinge) for each cover plate (5). As shown in
Some versions may also include plates (not shown) on each side of hinges (12). Such plates may be configured to deflectingly force snow plow blades or the like to be raised above hinges (12), to avoid snow plow blades or the like getting snagged on hinges (12). For instance, such plates may wrap over at least part of the “knuckle” (e.g., the part that contains the hinge pin) of each hinge (12). As one merely illustrative alternative, each hinge (12) may be installed facing down such that the knuckles of hinges (12) are covered. To the extent that flanges (9) of housing (4) are exposed, such flanges (9) may include a beveled edge to also reduce the likelihood of snow plow blades or the like getting snagged on flanges (9). To the extent that tread plates or other components are positioned above flanges (9) and obscure flanges (9), such tread plates or other components may have such a beveled edge to also reduce the likelihood of snagging. In addition, cover plates (5) may each include a beveled edge to also reduce the likelihood of snow plow blades or the like getting snagged on cover plates (5). Of course, these features and configurations are merely optional, and may be varied, substituted, supplemented, or omitted as desired.
In the present example, and as shown in
Cover opening plates (190) also allow cover plates (5) to close as posts (100, 101) are lowered into housing (4). In particular, as posts (100, 101) are lowered back down into housing (4), cover plates (5) “ride” cover opening plates (190). Cover plates (5) then reach a closed position as cover opening plates (190) retract fully into compartments (260) of housing (4). As noted above, cover plates (5) may be substantially flush with the ground when in the closed position as shown in
As shown in
Cover opening plates (190) of this example may have a width selected to provide a desired angular orientation of cover plates (5) when cover opening plates (190) hold cover plates (5) in an open position. For instance, where concrete barrier walls (e.g., “Jersey Barrier” walls, etc.) (not shown) are adjacently positioned at each end of barrier system (10), cover opening plates (190) may have a width selected to provide an angular orientation of opened cover plates (5) that matches, approximates, or is less than the angle defined by the bases of the adjacent barrier walls. In some instances, such angles may keep the wheel of a vehicle that strikes barrier system (10) turned into barrier system (10) or adjacent walls. Furthermore, having the angles defined by opened cover plates (5) matching, approximating, or being less than the angle defined by the bases of adjacent concrete walls may reduce if not eliminate the likelihood of a vehicle's wheel being snagged by opened cover plates (5) as the vehicle drives closely alongside the length of barrier system (10).
In the present example, and as shown in
Of course, there are a variety of other structures, components, and techniques that may be employed to provide opening and/or closing of cover plates (5), in addition to or in lieu of those described above. By way of example only, lift assist springs (not shown) may be provided to assist in opening of cover plates (5). Similarly, a spring or other resilient member may bias cover plates (5) to a closed position. It should also be understood that, in versions where at least one limiting chain, cable rod, and/or linkage is used to restrict the degree to which cover plates (5) may be opened, completely separate chain(s), cable(s), rod(s), and/or linkage(s) may be used to assist in closing cover plates (5). For instance, components that assist in closing cover plates (5) may be secured to cover opening plates (190); while components that restrict the degree to which cover plates (5) may be opened may be secured to housing (4). In some other versions, cover opening plates (190) are omitted, and each post (101) includes a set of plates, rollers, and arms that are configured to urge and hold cover plates (5) open when posts (100, 101) are raised. Examples of such sets of plates, rollers, and arms are disclosed in U.S. Provisional Patent Application Ser. No. 61/143,466, filed Jan. 9, 2009, entitled “Vertically Actuated Vehicle Barrier System,” the disclosure of which is incorporated by reference herein. Still other suitable structures, components, and techniques for opening, holding open, and/or closing cover plates (5) will be apparent to those of ordinary skill in the art in view of the teachings herein.
As yet another merely illustrative variation, barrier system (10) includes an integral cover plate (not shown) that is not hinged. For instance, an integral cover plate may span across the tops of posts (100, 101), and may have a width that is configured to overlay at least a portion of flanges (9) on both sides of housing (4). Thus, such an integral cover plate may fully cover or substantially cover the entire top opening defined by housing (4) when posts (100, 101) are in a retracted/undeployed position. Like closed cover plates (5), such a “closed” integral cover plate may also be substantially flush with the ground when posts (100, 101) are in a retracted/undeployed position. Such an integral cover plate may also raise unitarily with posts (100, 101) as posts (100, 101) are raised to the deployed position. In some versions where an integral cover plate is used in lieu of cover plates (5), cover opening plates (190) and compartments (260) are also omitted. Still various other suitable ways in which the top opening defined by housing (4) may be fully covered or substantially covered will be apparent to those of ordinary skill in the art in view of the teachings herein. Of course, some versions of barrier system (10) may provide cover that is less than substantial, or no cover at all, over the top opening defined by housing (4).
D. Exemplary Control
Control of barrier system (10) may be provided in a variety of ways. In some versions, control is provided locally. For instance, a switchbox or other device may be located proximate to barrier system (10) to permit selective activation of winch (17). Such a switchbox may include any of a variety of security features, including but not limited to keyed control, a card reader, a keypad for entry of a code, a biometrics reader, or any other suitable security feature. Barrier system (10) may also be triggered by an in-road sensor or other device. Furthermore, barrier system (10) may be capable of manual operation, such as in the case of a power loss or under other circumstances.
In some versions, control is provided remotely. For instance, in some versions, winch (17) is in communication with a small portable remote control device, similar to a conventional garage door opener controller. In particular, a receiver (not shown) may be coupled with winch (17), and may be configured to receive commands from a remote control device, and translate such commands into corresponding operation of winch (17) to deploy or retract posts (100, 101) and guardrails (202). Such communication may be encrypted using a rolling code or any other suitable techniques, such that the receiver only responds to a particular remote control device or particular group of remote control devices. By way of example only, suitable personnel such as firefighters, ambulance drivers, highway patrol, etc., may be provided with such remote control devices. Alternatively, to the extent that a building is wholly or partially surrounded by a barrier system (10), a building manager, building security, or other personnel may be provided with such a remote control device. Still other suitable personnel and other ways in which a portable remote control device may be used with barrier system (10) will be apparent to those of ordinary skill in the art in view of the teachings herein.
As another merely illustrative example of remote control, winch (17) may be in communication with a network, such that a user may selectively activate winch (17) from a remote location, via wire or wirelessly. Such a network may be a dedicated closed network, the Internet, or any other communication structure. It will be appreciated that any of the security features noted above with respect to local control of barrier system (10) may also be implemented for remote control of barrier system (10). It will also be appreciated that one barrier system (10) may be in communication with one or more other barrier systems (10). For instance, one barrier system (10) may act as a “master” system, such that other barrier systems (10) will automatically deploy or retract in response to deployment or retraction of the “master” system. Alternatively, one barrier system (10) may act as a relay for data or commands to and/or from other barrier systems (10). To the extent that a barrier system (10) is in communication with some type of network, operational data may be communicated to a remote location via the network. For instance, the charge left in battery (43), the operability of winch (17), the presence of water or debris in housing (4), the striking of posts (100, 101) and/or guardrails (202) by a vehicle, or any other type of data may be communicated via a network.
Barrier system (10) may also include safety or warning features such as lights or horns when barrier system (10) is activated. For instance, one or more limit switches may be used to stop winch (17) when posts (100, 101) have reached a fully raised/deployed and/or a fully lowered/retracted position. By way of example only, such limit switches may comprise at least one metal tab or other structure mounted to at least one post (100, 101) that provides contact with another switch position when posts (100, 101) have reached a fully raised/deployed and/or a fully lowered/retracted position. Alternatively, limit switches may take any other suitable form, to the extent that limit switches are even used. In addition, barrier system (10) may include a kill switch to prevent deployment of barrier system (10) when a person or obstacle is detected in the path of barrier system (10); and/or when there is a limit switch failure. Suitable components and arrangements for providing such sensor and kill switch systems will be apparent to those of ordinary skill in the art in view of the teachings herein. Still other ways in which barrier system (10) may be controlled or monitored will be apparent to those of ordinary skill in the art in view of the teachings herein. Similarly, various other suitable components, features, configurations, operabilities, and uses of barrier system (10) will be apparent to those of ordinary skill in the art in view of the teachings herein. By way of example only, a substitute or supplement for guardrails (202) may include chains, cables, rods, bars, rails, ropes, netting, plates, or any other suitable structures, including combinations of such structures, and including any suitable material or combination of materials.
II. Exemplary Vehicle Barrier with Chains
A. Overview
In some versions, barrier system (300) may stop a vehicle that is traveling at a high rate of speed, even if the driver of the vehicle is intent on passing through the barrier provided by barrier system (300). For instance, posts (320) and chains (302, 304) may be sufficiently anchored such that they provide little or no “give” when struck by a vehicle. By way of example only, some versions of barrier system (300) may meet a Department of State “K” certification requiring that the front line of cargo of a 15,000 pound vehicle traveling 50 mph must not go further than 1 meter past the line defined by barrier system (300). In addition or in the alternative, some versions of barrier system (10) may satisfy the American Association of State Highway and Transportation Officials (AASHTO) Manual for Assessing Safety Hardware (MASH) criteria. In some instances with some versions of barrier system (300), posts (320) and/or chains (302, 304) may essentially destroy a vehicle that strikes posts (320) and/or chains (302, 304), with relatively little damage being done to barrier system (300). For instance, barrier system (300) may be constructed such that no portions of barrier system (300) are released as projectiles when barrier system (300) is struck by a heavy vehicle moving at a high rate of speed. In some versions, as described in greater detail below, vertical chains (304) are coupled with housing (310) by shear joints, such that vertical chains (304) may break away from housing (310) to some degree. Nevertheless, horizontal chains (302) and/or posts (320) may still destroy or at least stop an impacting vehicle in some such versions, without barrier system (300) providing elastic “give.”
Housing (310) of the present example comprises sidewalls (312) and a floor (314). In addition, as shown in
As shown in
A horizontal member (305) spans across the tops of posts (320); and will raise and lower unitarily with posts (320). While just a single horizontal member (305) is used in the present example, it should be understood that more than one horizontal member (305) may be used. For instance, two or more horizontal member (305) may be placed adjacent to each other at a substantially common vertical height relative to posts (320). In addition or in the alternative, two or more horizontal members (305) may be placed at different vertical heights relative to posts (320). While horizontal member (305) comprises a rigid steel “T-rail” in the present example, horizontal member (305) may take a variety of alternative forms. By way of example only, in some versions horizontal member (305) comprises a horizontal chain (302) that is in tension, with vertical chains (304) being hung from horizontal chain (302). In some such versions, it may be desirable to add additional reciprocating posts (e.g., more than just posts (320) shown in
Horizontal member (305) of the present example is configured to cover the opening defined by sidewalls (312) of housing (310). In particular, horizontal member (305) may be substantially flush with the ground when posts (320) are in the lowered/undeployed position as shown in
It should be understood that using a chain or cable for horizontal member (305) may permit the opening defined by the top of housing (310) to have a relatively slimmer size. In some versions where a chain or cable is used for horizontal member (305,) the opening defined by the top of housing (310) is slim enough that a cover plate (5) is not needed in order to permit vehicles to safely drive over the top of housing (310) when barrier system is in a retracted configuration. In other words, the opening defined by the top of housing (310) may be configured to permit vehicles to safely drive over the top of housing (310) even in the absence of any cover plates. To the extent that flanges (319) of housing (310) are exposed, such flanges (319) may include a beveled edge to also reduce the likelihood of snow plow blades or the like getting snagged on flanges (319). To the extent that tread plates or other components are positioned above flanges (319) and obscure flanges (319), such tread plates or other components may have such a beveled edge to also reduce the likelihood of snagging. In addition, in versions where horizontal member (305) comprises a rigid “T-rail,” such a “T-rail” may also have beveled edges to reduce the likelihood of snow plow blades or the like getting snagged on horizontal member (305). Likewise, to the extent that cover plates (5) are provided as part of barrier system (300), such cover plates (5) may each include a beveled edge to also reduce the likelihood of snow plow blades or the like getting snagged on cover plates (5). Of course, these features and configurations are merely optional, and may be varied, substituted, supplemented, or omitted as desired.
B. Exemplary Deployment and Retraction System
Barrier system (300) of the present example is raised and lowered in a manner similar to the manner in which barrier system (10) described above is raised and lowered. A pair of post guides (324) extend upwardly from floor (314) of housing (310). Post guides (324) may comprise steel tubes having a square cross section. Alternatively, post guides (324) may be formed of any other suitable material(s) and may have any other suitable cross section. Post guides (120) may be laterally supported by support posts (not shown) (e.g., I-beams, etc.), which may be secured to floor (314) of housing (310). In addition, and as shown in
Post guides (324) may have a height that is greater than the height of sidewalls (312), though post guides (324) do not extend above sidewalls (312) in this example. For instance, while the upper rims of post guides (324) may be positioned below the upper rims of sidewalls (312), the lower portions of post guides (3234) may extend below floor (314) of housing (310). In particular, the lower portions of post guides (324) may be embedded in concrete (3) or in the ground, below floor (314). Alternatively, post guides (324) may have any other desired length and position relative to housing (310). In addition, the lower end of each post guide (324) may communicate with a drainage system, like post guides (120, 121) described above. Of course, a variety of other types of drainage systems may be provided; or barrier system (300) may even lack a drainage system.
Like barrier system (10) described above, barrier system (300) may include a winch (not shown). Such a winch may be secured to, within, or external to housing (310) (e.g., in the ground); and may receive power from a source in compartment (311) or elsewhere. The winch in the present example is in communication with cables (340, 341), which are shown in
In some versions, cables (340, 341) are simply opposing ends of a single, unitary cable. In other versions, cables (340, 341) are two separate cables that are coupled with the same winch. In some other versions, cables (340, 341) are two separate cables that are each coupled with their own corresponding winch, such that two winches are provided. Of course, any other suitable number of cables (340, 341) and winches may be used; and cables (340, 341) and winches may have any other suitable relationships. Furthermore, any suitable alternative, substitute, or supplement for cables (340, 341) and/or winch may be used.
While
As shown in
As shown in
It will therefore be understood that, with post (320) starting at a vertically down position, retracted within post guide (324), post (320) may be raised within post guide (324) by pulling from cable (340). Pulley (362) raises upwardly and unitarily with post (320) in this example. It will also therefore be appreciated that deployment post (320) may be raised within post guide (324) by pulling on deployment cable (340), with such pulling being powered by a winch (not shown) and communicated via pulleys (360, 362).
As noted above, deployment cable terminates at eye bolt (370), which is secured to post (320) via a bracket (372). As with eye bolt (180) described above with respect to barrier system (10), eye bolt (370) of barrier system (300) may be used to adjust the effective length of cable (340), such as to provide suitable simultaneous raising of both posts (320) when deployment cable (340) is pulled by the winch. Of course, a variety of alternative components, devices, or techniques may be used to adjust the effective length of one or more cables, including but not limited to one or more turnbuckles. As also noted above, while eye bolt (370) is secured to deployment post (320) in the present example, eye bolt (370) may alternatively be secured to any other suitable structure at any suitable location. By way of example only, the positioning of eye bolt (370) in relation to other components may cause cable (340) to become a “two-part line” as described above.
In addition, as noted above, posts (320) are connected by horizontal member (305). With posts (320) and horizontal member (305) all being substantially rigid (e.g., steel I-beams, etc.), and with the connections between posts (320) and horizontal member (305) being substantially rigid (e.g., welds, bolts, rivets, etc.), it will be appreciated that raising of posts (320) by cable (340) (and perhaps other cables) in the present example will effect simultaneous raising of horizontal member (305). In addition, with chains (302, 304) being secured to or secured relative to horizontal member (305) as described in greater detail below, raising of posts (320) will also effect simultaneous raising of chains (302, 304).
In other words, the combination of posts (320), horizontal member (305), and chains (302, 304) may be raised or deployed collectively and simultaneously, merely by a winch pulling on cable (340) (and perhaps other cables). Tension may be maintained in cables (340) (and perhaps other cables) to keep posts (320), horizontal member (305), and chains (302, 304) in a raised or deployed position (e.g., by braking the winch, etc.). Of course, there are a variety of other ways in which posts (320), horizontal member (305), and/or chains (302, 304) may be raised or otherwise deployed. One merely illustrative alternative is described in greater detail below (e.g., scissor arms (800, 802) assisting in raising of components, etc.), while others will be apparent to those of ordinary skill in the art in view of the teachings herein. Similarly, there are a variety of other ways in which posts (320), horizontal member (305), and chains (302, 304) may be kept in a raised position (e.g., without just relying on tension in cables, etc.). One merely illustrative alternative is described in greater detail below (e.g., scissor arms (800, 802) bearing weight of raised components, etc.), while others will be apparent to those of ordinary skill in the art in view of the teachings herein.
In some versions, a deployed combination of posts (320), horizontal members (305), and chains (302, 304) is retracted back into housing (310) by gravity. For instance, a brake on the winch may be released to relieve tension in cable (340) (and perhaps other cables), such that posts (320) may simply fall back downwardly into their respective post guides (324). As another merely illustrative alternative, the winch may be controllingly braked to slowly allow posts (320) to fall back downwardly into their respective post guides (324). In the present example, however, a deployed combination of posts (320), horizontal members (305), and chains (302, 304) is actively retracted back into housing (310).
As noted above, a retraction cable (341) extends from the winch. As shown in
In some versions, one or more plates (not shown) may be provided in housing (310), to substantially cover at least some of the above described cables and/or pulleys, such as to protect such cables and/or pulleys from debris, etc. Of course, such plates are merely optional.
C. Exemplary Chain Configurations
Chains (302, 304) of the present example include a plurality of horizontal chains (302) and a plurality of vertical chains (304). Each vertical chain (402) has a top end coupled with horizontal member (305) in the present example. By way of example only, vertical chains (302) may be coupled with horizontal member (305) via respective brackets, bolts, or using any other suitable devices, structures, components, and/or techniques. The top ends of vertical chains (304) are thus raised with horizontal member (305) when posts (320) are raised to the deployed position. The bottom end of each vertical chain (304) is coupled with anchors (350), which are secured to floor (314) of housing (310). If desired, vertical chains (304) may be coupled with anchors (350) with pins or bolts that will shear during impact of barrier system (300) by a vehicle, such as to prevent damage to floor (314) from being caused by such impact and/or for any other purpose. Alternatively, anchors (350) may be configured to allow vertical chains (304) to “break away” from anchors (350) upon sufficient force at the coupling of chains (304) with anchors (350). Examples of suitable break away anchors are described in U.S. Pub. No. 2007/0264080, entitled “Vehicle Barrier Deployment System,” published Nov. 15, 2007, the disclosure of which is incorporated by reference herein. Other suitable ways in which vertical chains (304) may be secured relative to housing (310), including alternative break away couplings and non-break away couplings, will be apparent to those of ordinary skill in the art in view of the teachings herein.
Vertical chains (304) are collapsed when barrier system (300) is in a retracted or undeployed position; and are extended vertically when barrier system (300) is in an extended or deployed position. In the present example, horizontal chains (302) and vertical chains (304) are coupled together at couplings (330). As shown in
Horizontal chains (302) span across posts (320). However, horizontal chains (302) are not directly attached to posts (320) in the present example. Nevertheless, horizontal chains (302) may be directly attached to posts (320) in some versions. As shown in
As shown in
Chains (302, 304) may comprise links that are formed of material (e.g., steel, etc.) that is approximately a half-inch thick, though any other suitable dimension or material(s) may be used. It should also be understood that horizontal chains (302) may have a different thickness than vertical chains (304) (e.g., horizontal chains (302) being thicker than vertical chains (304)). In the present example, six or seven horizontal chains (302) are used, and are vertically spaced evenly relative to horizontal member (305). Alternatively, any suitable number of horizontal chains (302) may be used. Similarly, any suitable number of vertical chains (304) may be used. Various other suitable ways in which chains (302, 304) may be configured, coupled together, coupled with other parts of barrier system (300), and anchored will be apparent to those of ordinary skill in the art in view of the teachings herein.
D. Exemplary Control
Control of barrier system (300) may be provided in a variety of ways. For instance, control may be provided locally or remotely, just as in the various options for control described above with respect to barrier system (10). Similarly, barrier system (300) may include safety or warning features, etc., just like those features described above with respect to barrier system (10). In fact, any teachings herein relating to barrier system (10) (or other barrier systems described herein) may be readily applied to barrier system (300) as will be apparent to those of ordinary skill in the art. Barrier system (300) may be thus deployed and undeployed using any of the deployment/undeployment mechanisms and control systems described herein. Alternatively, any other suitable deployment/undeployment mechanisms and/or control systems may be used. Likewise, any teachings herein relating to barrier system (300) may be readily applied to barrier system (10) (or other barrier systems described herein) as will be apparent to those of ordinary skill in the art. Various other suitable components, features, configurations, operabilities, and uses of barrier system (300) will also be apparent to those of ordinary skill in the art in view of the teachings herein. By way of example only, a substitute or supplement for chains (302, 304) may include guardrails, cables, rods, bars, rails, ropes, netting, plates, or any other suitable structures, including combinations of such structures, and including any suitable material or combination of materials.
III. Exemplary Vehicle Barrier with Cables
A. Overview
In addition, barrier system (400) is operable to selectively raise and lower posts (420) relative to housing (410) in a manner that is substantially identical to the manner in which barrier system (300) is operable to selectively raise and lower posts (320) as described above. In particular, barrier system (400) of the present example includes raising and lowering components that are substantially identical to the raising and lowering components described above with respect to barrier system (300). Of course, barrier system (400) may include any other suitable types of raising and lowering components, as desired. Posts (420) may be raised such that the lowermost horizontal cable (402) is at a height of anywhere between approximately 27 inches and approximately 36 inches (e.g., relative to the ground and/or relative to concrete (3), etc.), or at any other suitable height. Furthermore, like horizontal member (305) described above, a horizontal member (405) is configured to substantially close posts (420) and cables (402, 404) within housing (410) when posts (420) and cables (402, 404) are retracted downward.
In some versions, barrier system (400) may stop a vehicle that is traveling at a high rate of speed, even if the driver of the vehicle is intent on passing through the barrier provided by barrier system (400). For instance, posts (420) and cables (402, 404) may be sufficiently anchored such that they provide little or no “give” when struck by a vehicle. By way of example only, some versions of barrier system (400) may meet a Department of State “K” certification requiring that the front line of cargo of a 15,000 pound vehicle traveling 50 mph must not go further than 1 meter past the line defined by barrier system (400). In addition or in the alternative, some versions of barrier system (10) may satisfy the American Association of State Highway and Transportation Officials (AASHTO) Manual for Assessing Safety Hardware (MASH) criteria. In some instances with some versions of barrier system (400), posts (420) and/or cables (402, 404) may essentially destroy a vehicle that strikes posts (420) and/or cables (402, 404), with relatively little damage being done to barrier system (400). For instance, barrier system (400) may be constructed such that no portions of barrier system (400) are released as projectiles when barrier system (400) is struck by a heavy vehicle moving at a high rate of speed. In some versions, as described in greater detail below, vertical cables (404) are coupled with housing (410) by shear joints, such that vertical cables (404) may break away from housing (410) to some degree. Nevertheless, horizontal cables (402) and/or posts (420) may still destroy or at least stop an impacting vehicle in some such versions, without barrier system (400) providing elastic “give.”
Housing (410) of the present example comprises sidewalls (412) and a floor (414). In addition, as shown in
A horizontal member (405) spans across the tops of posts (420); and will raise and lower unitarily with posts (420). While just a single horizontal member (405) is used in the present example, it should be understood that more than one horizontal member (405) may be used. For instance, two or more horizontal member (405) may be placed adjacent to each other at a substantially common vertical height relative to posts (420). In addition or in the alternative, two or more horizontal members (405) may be placed at different vertical heights relative to posts (420). While horizontal member (405) comprises a rigid steel “T-rail” in the present example, horizontal member (405) may take a variety of alternative forms. By way of example only, in some versions horizontal member (405) comprises a horizontal cable (402) that is in tension, with vertical cables (404) being hung from horizontal cable (402). In some such versions, it may be desirable to add additional reciprocating posts (e.g., more than just posts (420) shown in
Horizontal member (405) of the present example is configured to cover the opening defined by sidewalls (412) of housing (410). In particular, horizontal member (405) may be substantially flush with the ground when posts (420) are in the lowered/undeployed position as shown in
It should be understood that using a chain or cable for horizontal member (405) may permit the opening defined by the top of housing (410) to have a relatively slimmer size. In some versions where a chain or cable is used for horizontal member (405,) the opening defined by the top of housing (410) is slim enough that a cover plate (5) is not needed in order to permit vehicles to safely drive over the top of housing (410) when barrier system is in a retracted configuration. In other words, the opening defined by the top of housing (410) may be configured to permit vehicles to safely drive over the top of housing (410) even in the absence of any cover plates. To the extent that flanges (419) of housing (410) are exposed, such flanges (419) may include a beveled edge to also reduce the likelihood of snow plow blades or the like getting snagged on flanges (419). To the extent that tread plates or other components are positioned above flanges (419) and obscure flanges (419), such tread plates or other components may have such a beveled edge to also reduce the likelihood of snagging. In addition, in versions where horizontal member (405) comprises a rigid “T-rail,” such a “T-rail” may also have beveled edges to reduce the likelihood of snow plow blades or the like getting snagged on horizontal member (405). Likewise, to the extent that cover plates (5) are provided as part of bather system (400), such cover plates (5) may each include a beveled edge to also reduce the likelihood of snow plow blades or the like getting snagged on cover plates (5). Of course, these features and configurations are merely optional, and may be varied, substituted, supplemented, or omitted as desired.
B. Exemplary Deployment and Retraction System
As noted above, barrier system (400) may include the same deployment and retraction components described above with respect to barrier system (300). For instance, barrier system (400) may include components that are analogous to post guides (324), cables (340, 341), pulleys (360, 361, 362), a winch, etc. In other words, the combination of posts (420), horizontal member (405), and cables (402, 404) may be raised or deployed collectively and simultaneously, merely by a winch pulling on one or more cables (not shown). Tension may be maintained in such one or more cables to keep posts (420), horizontal member (405), and cables (402, 404) in a raised or deployed position (e.g., by braking the winch, etc.). Of course, there are a variety of other ways in which posts (420), horizontal member (405), and/or cables (402, 404) may be raised or otherwise deployed. One merely illustrative alternative is described in greater detail below (e.g., scissor arms (800, 802) assisting in raising of components, etc.), while others will be apparent to those of ordinary skill in the art in view of the teachings herein. Similarly, there are a variety of other ways in which posts (420), horizontal member (405), and cables (402, 404) may be kept in a raised position (e.g., without just relying on tension in cables, etc.). One merely illustrative alternative is described in greater detail below (e.g., scissor arms (800, 802) bearing weight of raised components, etc.), while others will be apparent to those of ordinary skill in the art in view of the teachings herein.
Furthermore, it will be appreciated that the combination of posts (420), horizontal member (405), and cables (402, 404) may be lowered or retracted collectively and simultaneously, merely by a winch pulling on one or more cables (not shown). Of course, there are a variety of other ways in which posts (420), horizontal member (405), and/or cables (402, 404) may be lowered or otherwise retracted. One merely illustrative alternative is described in greater detail below, while others will be apparent to those of ordinary skill in the art in view of the teachings herein.
In some versions, one or more plates (not shown) may be provided in housing (410), to substantially cover at least some of the above described cables and/or pulleys, such as to protect such cables and/or pulleys from debris, etc. Of course, such plates are merely optional.
C. Exemplary Cable Configurations
Cables (402, 404) of the present example include a plurality of horizontal cables (402) and a plurality of vertical cables (404). Each vertical cable (404) has a top end coupled with horizontal member (405) in the present example. By way of example only, vertical cables (402) may be coupled with horizontal member (405) via respective brackets, bolts, or using any other suitable devices, structures, components, and/or techniques. The top ends of vertical cables (404) are thus raised with horizontal member (405) when posts (420) are raised to the deployed position as will be described in greater detail below. The bottom end of each vertical cable (404) is coupled with anchors (450), which are secured to floor (414) of housing (410). If desired, vertical cables (404) may be coupled with anchors (450) with pins or bolts that will shear during impact of barrier system (400) by a vehicle, such as to prevent damage to floor (414) from being caused by such impact and/or for any other purpose. Alternatively, anchors (450) may be configured to allow vertical cables (404) to “break away” from anchors (450) upon sufficient force at the coupling of cables (404) with anchors (450). Examples of suitable break away anchors are described in U.S. Pub. No. 2007/0264080, entitled “Vehicle Barrier Deployment System,” published Nov. 15, 2007, the disclosure of which is incorporated by reference herein. Other suitable ways in which vertical cables (404) may be secured relative to housing (410), including alternative break away couplings and non-break away couplings, will be apparent to those of ordinary skill in the art in view of the teachings herein.
Vertical cables (404) are collapsed when barrier system (400) is in a retracted or undeployed position; and are extended vertically when barrier system (400) is in an extended or deployed position. In the present example, horizontal cables (402) and vertical cables (404) are coupled together at couplings (430). Various suitable forms that couplings (430) may take, including but not limited to structures, features, components, and configurations of couplings (430), will be apparent to those of ordinary skill in the art in view of the teachings herein. The coupling of horizontal cables (402) with vertical cables (404) is such that, as vertical cables (404) are lifted to an extended position by horizontal member (405), vertical cables (404) lift horizontal cables (402). The coupling of horizontal cables (402) with vertical cables (404) also maintains a degree of vertical spacing between horizontal cables (402) when horizontal cables (402) have been lifted to the raised position. In some versions, vertical cables (404) are provided in pairs—one vertical cable (404) being on one side of each horizontal cable (402) at each coupling (430) and another vertical cable (404) being on the other side of each horizontal cable (402) at each coupling (430). It should be understood, though, that some versions may include just one vertical cable (404) on just one side of horizontal cables (402).
In some versions, vertical cables (404) are substituted with chains, while horizontal cables (402) are still used. For instance, vertical cables (404) may be substituted with the same vertical chains (304) described above with respect to barrier system (300). Various suitable ways in which vertical chains (304) may be incorporated into barrier system (400) in place of vertical cables (404) will be apparent to those of ordinary skill in the art in view of the teachings herein. By way of example only, horizontal cables (402) may be inserted through links of such vertical chains. Alternatively, horizontal cables (402) may be clipped to, clamped to, or otherwise coupled with such vertical chains.
Horizontal cables (402) span across posts (420). However, horizontal cables (402) are not directly attached to posts (420) in the present example. Nevertheless, horizontal cables (402) may be directly attached to posts (420) in some versions. Each post (420) of the present example has a recess formed in it, substantially identical to recesses (322) in posts (320) described above, to provide space to accommodate horizontal cables (402). One difference between barrier system (400) of the present example and barrier system (300) described above is that barrier system (400) includes angled recesses (403) at opposing longitudinal ends of barrier system (400). These recesses (403) provide clearance for horizontal cables (402) to exit the longitudinal ends of barrier system (400) when barrier system (400) is in the retracted configuration shown in
In the present example, the free ends of horizontal cables (402) are coupled with preexisting above-ground cables and/or posts in a highway median or elsewhere. Recesses (403) may thus permit horizontal cables (402) to maintain their connection with external above-ground components, even as barrier system (400) is in the retracted configuration shown in
Cables (402, 404) may comprise steel or any other suitable material(s), and may have strength sufficient to stop a vehicle traveling at a high rate of speed. For instance, cables (402, 404) may be configured in accordance with cables typically found in highway medians. Alternatively, cables (402, 404) may have any other desired properties. In the present example, six or seven horizontal cables (402) are used, and are vertically spaced evenly relative to horizontal member (405). Alternatively, any suitable number of cables (402, 404) may be used.
D. Exemplary Control
Control of barrier system (400) may be provided in a variety of ways. For instance, control may be provided locally or remotely, just as in the various options for control described above with respect to barrier systems (10, 300). Similarly, barrier system (400) may include safety or warning features, etc., just like those features described above with respect to barrier systems (10, 300). In fact, any teachings herein relating to barrier systems (10, 300) (or other barrier systems described herein) may be readily applied to barrier system (400) as will be apparent to those of ordinary skill in the art. Barrier system (400) may be thus deployed and undeployed using any of the deployment/undeployment mechanisms and control systems described herein. Alternatively, any other suitable deployment/undeployment mechanisms and/or control systems may be used. Likewise, any teachings herein relating to barrier system (400) may be readily applied to barrier systems (10, 300) (or other barrier systems described herein) as will be apparent to those of ordinary skill in the art. Various other suitable components, features, configurations, operabilities, and uses of barrier system (400) will also be apparent to those of ordinary skill in the art in view of the teachings herein. By way of example only, a substitute or supplement for cables (402, 404) may include guardrails, chains, rods, bars, rails, ropes, netting, plates, or any other suitable structures, including combinations of such structures, and including any suitable material or combination of materials.
IV. Exemplary Vehicle Barrier with Beams
A. Overview
Posts (504, 506) include passive posts (504) and lifting posts (506), as will be described in greater detail below. It will be appreciated that any suitable number of passive posts (504) and/or lifting posts (506) may be used in any suitable arrangement. In the present example, lifting posts (506) comprise steel I-beams, while passive posts (504) comprise steel square tubes. That is, lifting posts (506) of the present example comprise steel extrusions having an “I”-shaped cross section, while passive posts (504) of the present example comprise steel tubes having a square cross section. Optionally, posts (504) may include “I-beams” or other suitable structures secured within their interior for reinforcement. Alternatively, posts (504, 506) may be formed of any other suitable material(s) and may have any other suitable cross sectional form(s). By way of example only, posts (504) may alternatively have a cross sectional form that is similar to the cross sectional form of posts (506) in some versions, or vice versa. Furthermore, in some versions posts (504) are omitted entirely, such that only posts (506) are included. In some such versions, posts (506) are coupled together via one or more horizontal members (508, 520, 560) and/or other components.
As will be described in greater detail below, posts (504, 506) are connected by a plurality of horizontal members (508, 520, 560) in the present example, such that posts (504, 506) move vertically substantially simultaneously. In some versions, a single horizontal member (508) spans across all posts (504, 506) (e.g., along the tops of posts (504, 506)), while separate horizontal gate beams (520, 560) span between adjacent posts (504, 506). While barrier system (500) of the present example comprises two horizontal gate beams (520) and one horizontal gate beam (560), it should be understood that any other suitable number of horizontal gate beams (520) and/or horizontal gate beams (560) may be used. It should also be understood that various structures other than horizontal gate beams (520, 560) may be used. Several structures that may be used as an alternative to horizontal gate beams (520, 560) are described elsewhere herein, while others will be apparent to those of ordinary skill in the art in view of the teachings herein.
In some versions, barrier system (500) may stop a vehicle that is traveling at a high rate of speed, even if the driver of the vehicle is intent on passing through the barrier provided by barrier system (500). For instance, posts (504, 506) and horizontal members (508, 520, 560) may be sufficiently anchored such that they provide little or no “give” when struck by a vehicle. By way of example only, some versions of barrier system (500) may meet a Department of State “K” certification requiring that the front line of cargo of a 15,000 pound vehicle traveling 50 mph must not go further than 1 meter past the line defined by barrier system (500). In addition or in the alternative, some versions of barrier system (10) may satisfy the American Association of State Highway and Transportation Officials (AASHTO) Manual for Assessing Safety Hardware (MASH) criteria. In some instances with some versions of barrier system (500), posts (504, 506) and/or horizontal members (508, 520, 560) may essentially destroy a vehicle that strikes posts (504, 506) and/or horizontal members (508, 520, 560), with relatively little damage being done to barrier system (500). For instance, barrier system (500) may be constructed such that no portions of barrier system (500) are released as projectiles when barrier system (500) is struck by a heavy vehicle moving at a high rate of speed.
Housing (510) of the present example comprises sidewalls (512) and a floor (514). Flanges (519) extend outwardly from the top portions of sidewalls (512). In some versions, tread plates (not shown) are secured to flanges (519). In addition, a compartment (not shown) may be provided at an end of housing (510) or at any other suitable location. A cover plate (not shown) may be secured over the top of such a compartment. In some versions, such a compartment contains some if not all of the same components contained in compartment (11) as described above. Various suitable ways in which such components may be incorporated into barrier system (500) of this example will be apparent to those of ordinary skill in the art in view of the teachings herein. Similarly, various other types of components that could be provided in such a compartment or otherwise be incorporated into barrier system (500) will be apparent to those of ordinary skill in the art in view of the teachings herein. Housing (510) may also be provided with various structures and features for reinforcement, including but not limited to structures and features described elsewhere herein in the context of reinforcement for other housings (4, 310, 410). Alternatively, housing (510) may have any other suitable type of reinforcement; or may even lack reinforcement features and structures if desired. As with other components described herein, each of these components may be substituted, supplemented, relocated, or omitted in any suitable fashion as desired.
Cover plates (502) are pivotally coupled to upper flanges (519) of housing (510) via hinges (517), such that cover plates (502) may provide a selectively openable “lid” for barrier system (500). In some versions, hinges (517) comprise a single continuous hinge (e.g., a “piano hinge”) on each side of barrier system (500), such that a single hinge (517) couples each cover plate (502) with its respective flange (519). In some other versions, a plurality of hinges (517) are provided on each side of barrier system (500). Some versions may also include plates (not shown) on each side of hinges (517) such plates may be configured to deflectingly force snow plow blades or the like to be raised above hinges (517), to avoid snow plow blades or the like getting snagged on hinges (517). For instance, such plates may wrap over at least part of the “knuckle” (e.g., the part that contains the hinge pin) of each hinge (517). As one merely illustrative alternative, each hinge (517) may be installed facing down such that the knuckles of hinges (517) are covered. To the extent that flanges (519) of housing (510) are exposed, such flanges (519) may include a beveled edge to also reduce the likelihood of snow plow blades or the like getting snagged on flanges (519). To the extent that tread plates or other components are positioned above flanges (519) and obscure flanges (519), such tread plates or other components may have such a beveled edge to also reduce the likelihood of snagging. Of course, these features and configurations are merely optional, and may be varied, substituted, supplemented, or omitted as desired.
As shown in
While a pair of pivoting cover plates (502) are shown, it will be appreciated that cover plates (502) may be varied or modified in a number of ways. For instance, a single hinged cover plate may be used. Furthermore, cover plates (502) may be modified to slide open, to swing downward into housing (510), or to open in any other suitable way. Other variations of cover plates (502) and methods of opening cover plates (502) will be apparent to those of ordinary skill in the art in view of the teachings herein.
B. Exemplary Guide Structures
As shown in
A pair of longitudinal reinforcement members (580) extend substantially parallel to the longitudinal axis defined by housing (510). Reinforcement members (580) each include a vertically extending portion (584) that is welded to the exterior of post guide (507). Reinforcement members (580) also each include a horizontally extending portion (582). Reinforcement members (580) are each engaged with floor (514) of housing (510) via a respective pair of feet (586). Feet (586) are also welded to floor (514) in this example. Of course, reinforcement members (580) may be joined with post guide (507) and/or floor (514) in any other suitable fashion using any other suitable types of devices, components, features, or techniques. In the present example, reinforcement members (570, 580) are configured and arranged such that the top surfaces of horizontal portions (572) of reinforcement members (570) are substantially coplanar with each other and are substantially coplanar with horizontal portions (582) of reinforcement members (580). It should be understood that reinforcement members (570, 580) may have any other suitable components, configurations, and arrangements. It should also be understood that reinforcement members (570, 580) may provide bearing support for barrier system (500) and passing traffic when barrier system (500) is in the retracted position. Of course, post guides (507) and/or any other components of barrier system (500) may be supported or reinforced in any other suitable fashion.
As shown in
Post guides (505, 507) are configured to receive posts (504, 506). In particular, posts (504) are inserted in post guides (505); while posts (506) are inserted into post guides (507). Post guides (505, 507) are configured to restrict lateral movement of posts (504, 506), while permitting posts (504, 506) to move vertically (e.g., reciprocate) within post guides (505, 507). While five posts (504) and two posts (506) are shown in the present example, it should be understood that any desired number of posts (504, 506) may be used. Likewise, any suitable number of post guides (505, 507) may be used. As shown in
Post guides (505, 507) may have a height that is greater than the height of sidewalls (512), though post guides (505, 507) do not extend above sidewalls (512) in this example. For instance, while the upper rims of post guides (505, 507) may be positioned below the upper rims of sidewalls (512), the lower portions of post guides (505, 507) may extend below floor (514) of housing (510). In particular, the lower portions of post guides (505, 507) may be embedded in concrete (3) or in the ground, below floor (514). Alternatively, post guides (505, 507) may have any other desired length and position relative to housing (510). In addition, the lower end of each post guide (505, 507) may communicate with a drainage system, like post guides (120, 121) described above. Of course, a variety of other types of drainage systems may be provided; or barrier system (500) may even lack a drainage system.
As shown in
In the present example and as shown in
C. Exemplary Horizontal Member Configurations
1. Exemplary Upper Horizontal Member Configuration
Horizontal member (508) of the present example has a “U”-shaped cross-section, and comprises a horizontal section (516) and a pair of opposing, downwardly extending vertical sections (518). Horizontal section (516) of horizontal member (508) spans across the tops of posts (504, 506); and will raise and lower unitarily with posts (504, 506). As shown in
Horizontal member (508) of the present example is configured to cooperate with cover plates (502) to cover the opening defined by sidewalls (512) of housing (510), when barrier system (500) is in the undeployed configuration shown in
As shown in
2. Exemplary Gate Beam Configurations
In the present example, and as best shown in
Gate beams (520, 560) are coupled with posts (504, 506) via collar assemblies in the present example. For instance,
In the present example, structural angles (732) have clipped ends such that structural angles (732) and gate beam (560) together define gaps (692) as shown in
In the present example, structural angles (742) have clipped ends such that structural angles (742) and gate beam (520) together define gaps (692) as shown in
D. Exemplary Deployment and Retraction System
In some respects, barrier system (500) of the present example is raised and lowered in a manner similar to the manner in which barrier system (10) described above is raised and lowered. As noted above, vertical posts (504, 506) are operable to reciprocate relative to housing (510), within their respective post guides (505, 507). As also noted above, vertical posts (506) of the present example comprise “I-beams”; while vertical posts (504) comprise square or rectangular tubes in the present example.
Like barrier system (10) described above, barrier system (500) may include a winch (not shown). Such a winch may be secured to, within, or external to housing (510) (e.g., in the ground); and may receive power from a source in a local compartment or elsewhere. The winch in the present example is in communication with cables (540, 541), which are shown in
In some versions, cables (540, 541) are simply opposing ends of a single, unitary cable. In other versions, cables (540, 541) are two separate cables that are coupled with the same winch. In some other versions, cables (540, 541) are two separate cables that are each coupled with their own corresponding winch, such that two winches are provided. Of course, any other suitable number of cables (540, 541) and winches may be used; and cables (540, 541) and winches may have any other suitable relationships. Furthermore, any suitable alternative, substitute, or supplement for cables (540, 541) and/or winch may be used.
While
As shown in
Similarly, as shown in
In addition to the above noted pivotal couplings, scissor arms (800a, 800b) are also pivotally coupled with scissor arms (802a, 802b). In particular, and as best seen in
As shown in
As also shown in
In the present example, deployment cable (840) extends from the winch to reach pulley (814). Of course, deployment cable (840) may first encounter one or more additional pulleys after the winch, before reaching pulley (814). Deployment cable (840) goes over and around the top portion of pulley (814), and pulley (814) redirects deployment cable (840) downward to reach pulley (812). Pulley (812) then redirects deployment cable (840) upwardly to reach pulley (810). After passing over pulley (810), deployment cable (840) continues toward pulley (804). After wrapping around part of pulley (804), deployment cable (840) terminates at scissor arm (800a). In particular, the free end of deployment cable (840) is secured to scissor member (800a) at a coupling (842). Such a coupling (842) may be provided on the vertically extending portion (811) of scissor arm (800a) or the transverse portion (807) of scissor arm (800a). Various forms that coupling (842) may take will be apparent to those of ordinary skill in the art in view of the teachings herein.
It should be understood that, with post (506) starting at the vertically down position, retracted in post guide (507), scissor arms (800a, 800b, 802a, 802b) start in the folded position as shown in
In addition, as also shown in
To the extent that scissor arms (800a, 800b) rest on scissor arms (802a, 802b) when scissor arms (800a, 800b, 802a, 802b) reach a hyper-extended position, one or more features may be provided to allow adjustability of the degree to which scissor arms (800a, 800b, 802a, 802b) are hyper-extended. By way of example only, and as shown in
By scissor arms (800a, 800b, 802a, 802b) assuming the weight bearing of posts (504, 506) and horizontal members (508, 520, 560) when scissor arms (800a, 800b, 802a, 802b) are in an unfolded configuration, scissor arms (800a, 800b, 802a, 802b) may substantially reduce or totally remove the dead load on cable (840) and the winch break when barrier system (500) is in the fully deployed position. Scissor arms (800a, 800b, 802a, 802b) may thus act as a “safety” support in the event of winch or cable failure when deployed. Also, during a crash (e.g., when a moving vehicle strikes barrier system (500)), scissor arms (800a, 800b, 802a, 802b) may be placed in tension during initial impact by a vehicle and may assist cable (840) and the winch brake with absorbing any initial upward load resulting from the vehicle impact. Similarly, extended scissor arms (800a, 800b, 802a, 802b) may provide column-like support that substantially resists downward forces exerted on posts (504, 506) and horizontal members (508, 520, 560) when a vehicle strikes a fully deployed barrier system (500). Scissor arms (800a, 800b, 802a, 802b) may thus assist with downward loads that would be encountered by cable (840) and the winch brake resulting from a vehicle impact.
As noted above, a retraction cable (841) also extends from the winch. As shown in
As post (506) is being raised as described above, retraction cable (841) eventually engages pulley (806). In particular, and with reference to the view shown in
To lower/retract post (506), the winch pulls on retraction cable (841) as slack is provided to deployment cable (840). In the initial stages of such retraction, the increased tension in retraction cable (841) urges pulley (806) to the right in the view shown in
As shown in
Eye bolt (900) is secured to post (506) via bracket (902) in the present example. In particular, bracket (902) is welded to (or otherwise secured to) post (506), and eye bolt (900) is inserted through bracket (902). The end of deployment cable (840) is secured to eye bolt (900). Eye bolt (900) and bracket (902) of this example are thus analogous to eye bolt (180) and bracket (184) described above in the context of barrier system (10). In other words, post (506) is raised to the deployed position in a manner similar to post (101) described above in the context of barrier system (10). It will therefore be understood that post (506) is raised to the deployed position in this example by the winch pulling on deployment cable (840). Since posts (504, 506) and horizontal members (508, 520, 560) are all coupled together via welds and/or bolts, etc., it will also be understood that posts (504, 506) and horizontal members (508, 520, 560) raise to the deployed position substantially unitarily, in response to pulling on deployment cable (840) by the winch in this example.
When post (506) is raised to the deployed position, tension spring (904) and cable (908) are configured to urge scissor arms (800a, 800b, 802a, 802b) to the hyper-extended position shown in
In view of the foregoing, it should be understood that as post (506) is raised by pulling on deployment cable (840), scissor arms (800a, 800b, 802a, 802b) eventually reach a substantially vertical position. However, due to the bias imposed on pulley (805) by tension spring (904) and cable (908), the pivotal junction of scissor arms (800a, 800b) with scissor arms (802a, 802b) is urged toward post (506). This urging causes hyperextension of scissor arms (800a, 800b, 802a, 802b), as described above. Scissor arms (800a, 800b, 802a, 802b) thus rotate past a purely vertical position until they rest against post (506), under the urging of cable (908) and tension spring (904). With scissor arms (800a, 800b, 802a, 802b) in such a hyper-extended position, resting against post (506), scissor arms (800a, 800b, 802a, 802b) are configured to hold post (506) in the raised/deployed position. In other words, scissor arms (800a, 800b, 802a, 802b) bear the weight of posts (504, 506) and horizontal members (508, 520, 560) to keep barrier system (500) in the deployed position. Of course, as noted above, scissor arms (800a, 800b) may rest on corresponding scissor arms (802a, 802b) at notches (809, 815) when scissor arms (800a, 800b, 802a, 802b) reach a hyper-extended position in addition to or in lieu of resting against post (506).
The lowering/retraction of post (506) in this example is substantially identical to the lowering/retraction of post (506) described above in the context of
It should be understood that the foregoing examples of components and features that may be used to assist in raising/deployment of post (506), maintaining post (506) in the raised/deployed position, and lowering/retraction of post (506) are merely illustrative. Any such features and components may be varied, substituted, supplemented, or omitted as desired, as will be apparent to those of ordinary skill in the art in view of the teachings herein. With reference to
In some versions, one or more plates (not shown) may be provided in housing (510), to substantially cover at least some of the above described cables and/or pulleys, such as to protect such cables and/or pulleys from debris, etc. Of course, such plates are merely optional.
E. Exemplary Control
Control of barrier system (500) may be provided in a variety of ways. For instance, control may be provided locally or remotely, just as in the various options for control described above with respect to barrier systems (10, 300, 400). Similarly, barrier system (500) may include safety or warning features, etc., just like those features described above with respect to barrier systems (10, 300, 400). In fact, any teachings herein relating to barrier systems (10, 300, 400) (or other barrier systems described herein) may be readily applied to barrier system (500) as will be apparent to those of ordinary skill in the art. Barrier system (500) may be thus deployed and undeployed using any of the deployment/undeployment mechanisms and control systems described herein. Alternatively, any other suitable deployment/undeployment mechanisms and/or control systems may be used. Likewise, any teachings herein relating to barrier system (500) may be readily applied to barrier systems (10, 300, 400) (or other barrier systems described herein) as will be apparent to those of ordinary skill in the art. Various other suitable components, features, configurations, operabilities, and uses of barrier system (500) will also be apparent to those of ordinary skill in the art in view of the teachings herein. By way of example only, a substitute or supplement for gate beams (520, 560) may include guardrails, chains, cables, rods, bars, rails, ropes, netting, plates, or any other suitable structures, including combinations of such structures, and including any suitable material or combination of materials.
V. Exemplary Uses
It will be appreciated by those of ordinary skill in the art that each barrier system (10, 300, 400, 500) described herein may be used in a variety of ways. In one merely exemplary use, barrier system (10, 300, 400, 500) is positioned in a median of a multi-lane highway or interstate, between a pair of preexisting median barriers such as preexisting guardrails, cables, or concrete walls, etc. For instance, barrier system (10, 300, 400, 500) may be constructed into a new concrete barrier wall, positioned in a preexisting gap between preexisting barrier walls, or “cut into” a preexisting barrier wall, etc. Guide plates or other features may be mounted to the preexisting median barriers in order to guide or reinforce one or more portions of barrier system (10, 300, 400, 500) (e.g., guardrails (202), etc.). Concrete (3) of barrier system (10, 300, 400, 500) or any other component of barrier system (10, 300, 400, 500) may also be anchored with a preexisting concrete median wall. In this example, barrier system (10, 300, 400, 500) is oriented substantially parallel to the flow of traffic on a roadway, and is configured to restrict passage across a highway median rather than restricting passage across a lane of a roadway. It will be appreciated that having barrier system (10, 300, 400, 500) in such a location may be useful for emergency vehicles that need to cross the median of a highway or interstate, etc., who may otherwise need to travel substantial distances out of the way just to get to the other side of the highway. Furthermore, barrier system (10, 300, 400, 500) may be installed where gaps already exist between median barriers (e.g., where such gaps were created for use by patrol cruisers or emergency vehicles), and may be set in a deployed configuration by default to prevent unauthorized use of such gaps by non-state and non-emergency vehicles, such that obstructive portions of barrier system (10, 300, 400, 500) may be lowered when authorized vehicles need to cross the median.
Similar to the example above, barrier system (10, 300, 400, 500) may be positioned in the median of a highway that does not have guardrails or walls in the median. In particular, barrier system (10, 300, 400, 500) may be positioned in the median of a highway that uses cables and posts to prevent vehicles from crossing the median. For instance, some such medians may currently have openings in the cable and post lines to permit emergency vehicles to cross the median. Any version of barrier system (10, 300, 400, 500), particularly, barrier system (400), may be positioned in such paths to prevent non-emergency vehicles from crossing such paths while permitting emergency vehicles to lower the barrier (10, 300, 400, 500) to permit passage through the paths. As noted above with respect to barrier system (400), cables (402) may tie into the preexisting system of cables and posts in the median. For instance, the cables (402) of barrier system (400) may be coupled with whichever posts or cables are immediately adjacent to each end of barrier system (400). As yet another alternative, a barrier system (400) may be retrofitted to a preexisting cable median barrier system such that posts (420) are coupled directly with a span of the preexisting cables, and such that posts (420) and horizontal member (405) may be used to selectively raise and lower the preexisting cables. Still other ways in which barrier system (400) (or other types of barrier systems (10, 300, 500)) may be used in conjunction with a preexisting system of posts and cables in a highway median will be apparent to those of ordinary skill in the art in view of the teachings herein.
In another merely exemplary use, barrier system (10, 300, 400, 500) is provided in a roadway (not shown). Barrier system (10, 300, 400, 500) may have a length such that it extends across the width of the roadway to any suitable length (e.g., across one or more traffic lanes in the roadway, across the entire width of the roadway, etc.). To permit normal passage of traffic across the roadway, barrier system (10, 300, 400, 500) may be kept in a retracted configuration. When the provision of a barrier is desired, the winch (or other type of component) may be activated to transition barrier system (10, 300, 400, 500) to a deployed configuration. Such a deployed barrier system (10, 300, 400, 500) may provide a barrier substantially preventing passage of vehicles approaching barrier system (10, 300, 400, 500) from either direction. If a vehicle strikes one or more obstructive portions of barrier system (10, 300, 400, 500), such barrier system (10, 300, 400, 500) may quickly bring such a vehicle to a stop. Alternatively, if a vehicle does not strike barrier system (10, 300, 400, 500), and if a barrier is no longer desired, a winch (or other type of component) may be activated again to transition barrier system (10, 300, 400, 500) back to the retracted configuration to once again permit passage of vehicular traffic.
While barrier system (10, 300, 400, 500) has been described as being capable of spanning across an entire width of a roadway, it will be appreciated that barrier system (10, 300, 400, 500) may span across any other suitable length. For instance, a barrier system (10, 300, 400, 500) may span across only one lane of traffic. Alternatively, barrier system (10, 300, 400, 500) may be configured to span across distances that far exceed the width of a roadway. For instance, a barrier system (10, 300, 400, 500) may be constructed to span across the entire width of the face of a building, park, or other location, or may be constructed to span around the entire perimeter of such a location.
In another exemplary use, barrier system (10, 300, 400, 500) is installed behind a pre-existing gate (not shown) that it is used to selectively restrict access to a road, driveway, or the like. Barrier system (10, 300, 400, 500) may therefore provide reinforcement or a “back up” for existing barriers (e.g., where existing barriers are less able to prevent passage of a moving vehicle intent on passing through the barrier). Barrier system (10, 300, 400, 500) may thus be used to provide security for non-authorized vehicle entry. As another merely exemplary use, barrier system (10, 300, 400, 500) may be used by the military to provide checkpoints, by police to provide blockades, or by other persons or entities for a variety of purposes.
It should also be understood that barrier system (10, 300, 400, 500) may be constructed such that it spans around corners, such as at right angles, along a curve, or otherwise (e.g., to conform to property lines or desired security perimeter, etc.). For instance, one or more cables (402) or chains (302) could easily be extended around a corner using a pulley or other component. Similarly, any suitable number of cables may be coupled with a deployment cable or a retraction cable via a clevis or other component, and such additional cables may be extended around a corner using a pulley or other component. Thus, even if several deployment posts (101, 320, 420, 506) are used at different positions about one or more corners, such deployment posts (101, 320, 420, 506) may all be simultaneously deployed using a single winch in some implementations. For instance, a single barrier system (10, 300, 400, 500) may be arranged in a rectangle or square surrounding the perimeter of an entire building, and a single winch may be used to simultaneously raise and/or simultaneously lower posts (101, 320, 420, 506) on all four sides of the building perimeter. Such posts (101, 320, 420, 506) could be positioned at each side of each corner and/or elsewhere.
It will also be appreciated that, in many situations, length may be added to a barrier system (10, 300, 400, 500) simply by lengthening guardrails (202), chains (302), cables (402), gate beams (520, 560), etc., and possibly adding additional posts (100, 101, 320, 420, 504, 506). For instance, a barrier system (300) with chains (302) and/or a barrier system (400) with cables (402) may be used to protect areas that span 200 feet or more (e.g., as opposed to just one traffic lane spanning 12 feet). Furthermore, in many situations, all posts (100, 101, 320, 420, 504, 506) may still be deployed by a single drive mechanism (e.g., winch (17)). To the extent that increasing the length of barrier system (10, 300, 400, 500) requires the addition of more posts (100, 101, 320, 420, 504, 506) additional cables may be easily coupled with cables described herein, and additional pulleys may be provided, as desired.
It should be understood that any barrier system (10, 300, 400, 500) described herein may include an audio and/or visual warning system that may be activated when barrier system (10, 300, 400, 500) is transitioning from an extended position to a retracted position; and or when barrier system (10, 300, 400, 500) is transitioning from a retracted position to an extended position. For instance, such a warning system may include a horn/klaxon, bell, or other type of alarm and/or a flashing light, etc. Such a warning system may thus provide a warning to traffic that barrier system (10, 300, 400, 500) is changing its position.
Of course, barrier system (10, 300, 400, 500) may be used in a variety of other contexts and for a variety of other purposes. Various other contexts and purposes in which barrier system (10, 300, 400, 500) may be used, as well as various other techniques for using barrier system (10, 300, 400, 500), will be apparent to those of ordinary skill in the art in view of the teachings herein.
VI. Exemplary Alternatives
Some merely illustrative alternative versions of barrier system (10, 300, 400, 500) use a pair of rolling cars (not shown) to provide deployment and retraction of posts (100, 101, 320, 420, 504, 506). Examples of such rolling car actuation are described in greater detail in U.S. Provisional Patent Application Ser. No. 60/799,439, entitled “Vehicle Barrier Deployment System,” filed May 10, 2006, the disclosure of which is incorporated by reference herein. In fact, it should be understood that any barrier system (10, 300, 400, 500) described herein may be modified in accordance with any of the teachings in U.S. Provisional Patent Application Ser. No. 60/799,439, entitled “Vehicle Barrier Deployment System,” filed May 10, 2006, the disclosure of which is incorporated by reference herein. Any barrier system (10, 300, 400, 500) described herein may also be modified in accordance with any of the teachings in U.S. Pub. No. 2007/0264080, entitled “Vehicle Barrier Deployment System,” published Nov. 15, 2007, the disclosure of which is incorporated by reference herein. Various suitable ways in which the teachings of U.S. Provisional Patent Application Ser. No. 60/799,439 and/or U.S. Pub. No. 2007/0264080 may be incorporated with the teachings herein (and vice versa) will be apparent to those of ordinary skill in the art.
In will be understood in view of the above that a deployed barrier system (10, 300, 400, 500) may provide a bi-directional barrier. Furthermore, barrier system (10, 300, 400, 500) is operable to provide such a barrier with a single drive mechanism (e.g., winch (17)). In some versions as described above, the drive mechanism that is used to deploy a barrier is mechanical or electromechanical, such as winch (17) or some other mechanical/electromechanical device. It will be appreciated that, where a mechanical or electromechanical drive mechanism is used, barrier system (10, 300, 400, 500) may be substantially free of any hydraulic or pneumatic devices. In other words, a drive mechanism need not rely on hydraulics or pneumatics to operate, which may be preferable in certain situations. In other situations, hydraulics or pneumatics may be preferred, and a hydraulic or pneumatic device may be incorporated into a barrier system (10, 300, 400, 500), either for a drive mechanism or otherwise.
Barrier system (10, 300, 400, 500) has been described herein as deploying obstructive components in a manner that does not require a sweeping motion that is transverse to a longitudinal plane defined by barrier system (10, 300, 400, 500). Instead, obstructive components of (10, 300, 400, 500) (e.g., guardrail (202), chains (302), cables (402), gate beams (520, 560), etc.) simply move up and down along the longitudinal plane defined by barrier system (10, 300, 400, 500) during deployment and retraction. It will be appreciated that the absence of transverse sweeping by such components for deployment of such components may permit barrier system (10, 300, 400, 500) to occupy a relatively short portion of a lane of a roadway. Those of ordinary skill in the art will recognize that the narrow profile achieved by relying on deployment motion that is along a longitudinal plane of barrier system (10, 300, 400, 500) (and therefore transverse to roadway—vertically transverse and/or horizontally transverse as opposed to parallel) may ease installation of barrier system (10, 300, 400, 500) or provide other benefits. Alternatively, a barrier system (10, 300, 400, 500) may be modified to have a deployment motion that spans across any other suitable plane, including those transverse to a longitudinal plane defined by barrier system (10, 300, 400, 500) or those that are parallel with the roadway.
In any version of barrier system (10, 300, 400, 500) described herein that uses pulleys and cables, it should be understood that one or more of the pulleys (and/or an additional pulley incorporated into a cable/pulley system as described herein) may comprise a tension pulley. For instance, such a tension pulley may be spring loaded, and may be added to any cable section to maintain a positive tension on the winch drum for substantially uniform winding.
Any version of barrier system (10, 300, 400, 500) may include a heavy canvas, rubber sheeting or strips, sheet metal, and/or any other suitable structures or material(s) to substantially cover and protect the interior of housing (4, 310, 410, 510) from debris and/or snow, etc. when barrier system (10, 300, 400, 500) is in the fully deployed position. Such a protective covering may even be provided in versions where cover plates (5, 502) already provide some degree of protection to the interior of housing (4, 510). Such a protective covering may be secured to one or more portions of housing (4, 310, 410, 510) and/or to any other suitable components of barrier system (10, 300, 400, 500).
It should also be understood that any version of barrier system (10, 300, 400, 500) may be configured to substantially prevent or at least reduce the likelihood of “wheel snagging” occurring when a vehicle strikes barrier system (10, 300, 400, 500). For instance, components of barrier system (10, 300, 400, 500) may be sized, spaced, and otherwise arranged (relative to each other and relative to surrounding structures such as the ground) to substantially prevent or at least reduce the likelihood of “wheel snagging.” Various ways in which barrier system (10, 300, 400, 500) may be configured to substantially prevent or at least reduce the likelihood of “wheel snagging” will be apparent to those of ordinary skill in the art in view of the teachings herein. It should also be understood that posts (100, 101, 320, 420, 504, 506) (or portions thereof) may be configured to “break away” from other components of barrier system (10, 300, 400, 500) upon sufficient impact by a vehicle, such as to prevent or reduce snagging.
Having shown and described various embodiments of the present invention, further adaptations of the methods and systems described herein may be accomplished by appropriate modifications by one of ordinary skill in the art without departing from the scope of the present invention. Several of such potential modifications have been mentioned, and others will be apparent to those skilled in the art. For instance, the examples, embodiments, geometrics, materials, dimensions, ratios, steps, and the like discussed above are illustrative and are not required. Accordingly, the scope of the present invention should be considered in terms of the following claims, and is understood not to be limited to the details of structure and operation shown and described in the specification and drawings.
This application claims priority to U.S. Provisional Patent Application Ser. No. 61/143,466, filed Jan. 9, 2009, entitled “Vertically Actuated Vehicle Barrier System,” the disclosure of which is incorporated by reference herein. This application is also a continuation-in-part of U.S. Non-Provisional patent application Ser. No. 11/742,648, filed May 1, 2007, entitled “Vehicle Barrier Deployment System;” which in turn claims priority to U.S. Provisional Patent Application Ser. No. 60/799,439, filed May 10, 2006, entitled “Vehicle Barrier Deployment System.” The disclosures of U.S. Non-Provisional patent application Ser. No. 11/742,648 and U.S. Provisional Patent Application Ser. No. 60/799,439 are also each incorporated by reference herein.
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Entry |
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Screenshots from www.roboticsecuritysystems.com printed Apr. 17, 2007. |
Number | Date | Country | |
---|---|---|---|
20100098486 A1 | Apr 2010 | US |
Number | Date | Country | |
---|---|---|---|
61143466 | Jan 2009 | US | |
60799439 | May 2006 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 11742648 | May 2007 | US |
Child | 12643000 | US |