1. Field of the Invention
This invention relates to movable elements, such as closure elements, and, more particularly, to an operating mechanism through which a) the closure element can be repositioned and b) a latch system can be operated.
2. Background Art
Movable elements, such as closure elements, are used in a wide range of environments, for both static and dynamic applications. Typically, closure elements are mounted to be moved between open and closed positions. The closure elements are typically either translated or pivoted between the open and closed positions therefor.
In one exemplary environment, closure elements are pivotably mounted on cabs of earth moving and agricultural equipment. One common operating mechanism for such closure elements includes an elongate, tubular element into which an operating assembly for a latch system is integrated. An exemplary system of this type is shown in pending U.S. application Ser. No. 10/316,359, commonly owned with the invention herein. The tubular element is spaced from a mounting surface on a side of the closure element to allow it to be surrounded and grasped by a user's hand to allow manipulation of the closure element. The operating mechanism includes an operating assembly with a pivotable actuator that can be selectively repositioned to operate a latch system through the same hand that is grasping the tubular element. This configuration of the operating mechanism permits a positive controlling of the closure movement while allowing the state of the latch system to be conveniently controlled with the same hand that is used to reposition the closure element.
While this configuration of operating mechanism has become well accepted in the industry, it has at least one significant limitation from the standpoint of its manufacture. The integration of the operating components into the tubular element, and the interconnection of the same to the latch system, may be somewhat difficult and time consuming, when this is carried out either on site or at a manufacturing facility. This problem is attributable in large part to the fact that the diameter of the tubular element, to be conveniently graspable, provides a relatively small internal space within which the operating components can be assembled.
One common construction for this type of operating mechanism utilizes an elongate rod which is shiftable axially relative to the tubular element to control the state of the latch system. The components of the operating assembly through which this rod is axially shifted are installed radially through the wall of the tubular element at a location spaced from the latch system. An exemplary system of this type is shown in U.S. Pat. No. 6,419,284. As can be seen therein, the working space available to the manufacturer/installer is relatively small. Additionally, the components of the operating assembly, installed radially through the opening, are commonly maintained in place by one or more separate fasteners that must be installed. These fasteners are generally quite small. A significant amount of skill and dexterity may thus be required for the installer to assemble the operating mechanism. This may account for a relatively lengthy assembly time, which translates into added costs to be borne either by the manufacturer or consumer.
Also, this conventional construction does not lend itself to on-site assembly and installation. One desirable feature with this type of operating mechanism is the ability to allow the purveyor to selectively use elongate, tubular elements of different configurations to best adapt to a field condition. With the above-described construction, the operating mechanism and latch system are commonly made and offered only in a fixed configuration. From the standpoint of those that supply these systems, inconvenience is contended with by reason of the fact that inventories must be prepared based upon anticipated demand for each different configuration. Additionally, if a custom application is required, the cost thereof to the consumer may be impractically high.
In one form, the invention is directed to an operating mechanism for a movable closure element to releasably engage a strike assembly on a frame support and thereby releasably maintain the movable closure element in a predetermined position relative to the frame support. The operating mechanism has a base with an elongate portion with a first axis and a wall extending around the first axis and defining a passageway. A latch system on the base has (a) a latched state in which the latch system engages a strike element on the strike assembly so as to maintain a movable closure element on which the operating mechanism is mounted in the predetermined position and (b) a released state wherein the latch system can be disengaged from the strike element so as to allow a movable closure element on which the operating mechanism is mounted to be moved from the predetermined position. The operating mechanism further includes an actuating system on the base that is changeable from a first state into a second state to thereby change the latch system from the latched state into the released state. The actuating system has at least a first link which is movable axially within the passageway from a first position into a second position to thereby change the latch system from the latched state into the released state. The actuating system further includes an actuating assembly that can be directed radially through the wall on the base into operative engagement with the base without requiring separate fasteners to maintain the operative engagement between the actuating assembly and the base.
In one form, the actuating system has a second link that can be operatively engaged with the at least first link without requiring separate fasteners.
In one form, the second link has a receptacle for supporting a part of the at least first link for pivoting movement about a second axis that is transverse to the first axis.
In one form, the second link has a slot communicating with the receptacle and extending radially relative to the second axis from the receptacle.
The actuating assembly may include an actuating element that is repositionable relative to the base between a normal position and an actuated position. The second link may connected to the actuating element.
In one form, the second link is connected to the actuating element for relative pivoting movement around a third axis.
The third axis may be substantially parallel to the second axis.
In one form, the actuating element is movable relative to the base around a fourth axis.
In one form, the slot extends radially along a line relative to the second axis from the second axis. The second link is movable around the fourth axis between first and second orientations. The second link is in the first orientation with the actuating element in the normal position and in the second orientation with the actuating element in the actuated position. With the second link in and between the first and second orientations, a line of a force acting between the second link and the part of the at least first link is non-parallel to the line of the slot.
In one form, the second link has an end that slides axially relative to the first axis guidingly along the wall as the actuating element is repositioned between the normal and actuated positions.
In one form, the wall has a first opening bounded by an edge with a thickness. The actuating system further has a frame with first and second oppositely facing surfaces. The actuating element is mounted for pivoting movement relative to the frame around the fourth axis. At least a part of the frame is deformable so that as the frame is pressed into the wall opening, the at least part of the frame changes from an undeformed state into a deformed state to allow the first surface on the frame to move past the edge and thereafter reassume the undeformed state so that the edge of the wall is captive between the first and second surfaces, whereupon the actuating assembly is in operative engagement with the base.
In one form, the first and second surfaces are spaced by a distance that is approximately the same as the thickness of the edge.
In one form, the second surface extends substantially fully around the wall opening and bears against a surface on the base that faces radially outwardly relative to the first axis.
In one form, the part of the at least first link has a diameter, with the slot having a width. The slot width is less than the diameter of the part of the at least first link.
In one form, the wall has an annular, outwardly facing surface and there is no opening in the outwardly facing surface diametrically opposite to the first opening.
In one form, the actuating system has a frame to which the actuating element is mounted for pivoting movement around the fourth axis and the housing is reversibly mountable in first and second different positions relative to the base so that the actuating element pivots in opposite directions around the fourth axis as the actuating element is repositioned from the normal position into the actuated position with the housing in the first and second different positions.
In one form, the base has a first tubular element with an outside surface having a first diameter through which the first opening is formed. The operating mechanism may be further provided in combination with a second tubular element having an outside surface through which a second opening corresponding to the first opening is formed. The second tubular element has a second diameter that is different than the first diameter. The frame can be selectively pressed into the first and second openings to place the actuating assembly into operative engagement with the base.
In one form, the second link has a first configuration. An interchangeable link may be provided having a configuration that is different than that of the second link and useable in place of the second link with the actuating assembly in operative engagement with the base, using the second tubular element.
In one form, the actuating system further has a spring acting between the actuating element and the second link for normally urging the second link towards the second orientation.
In one form, the base has a tubular element that defines the elongate portion and first and second supports for the tubular element that are spaced axially relative to the first axis.
The tubular element may be releasably connectable to each of the first and second supports to allow selective connection of tubular elements of different configuration to the first and second supports.
In one form, the tubular element can be selectively connected to the first support in first and second different, predetermined, angular orientations.
The tubular element may be releasably connectable with the first support without requiring any separate fasteners. With the tubular element connected to the first support and the first and second supports mounted to a closure element, the tubular element and first support cannot be separated from each other.
In one form, the second link exerts a tensile force on the at least first link as the at least first link is moved from the first position into the second position.
Alternatively, the second link may exert a compressive force on the at least first link as the at least first link is moved from the first position into the second position.
In one form, the at least first link has an elongate portion with a free end and the part of the at least first link is spaced from the free end.
In one form, the elongate portion has a substantially straight section extending along a first line substantially parallel to the first axis and the part of the at least first link extends transversely to the first line along a second line.
In one form, the at least first link has a free end section which projects a) along a third line that is transverse to the second line and b) to the free end of the elongate portion.
The first and third lines may be substantially parallel to each other.
In one form, the elongate portion of the at least first link is connected to the second link by directing the elongate portion of the at least first link through the receptacle by relatively reorienting the at least first link and second link, while relatively moving the elongate portion of the at least first link and second link along the first and second lines, as the elongate portion of the at least first link is directed through the receptacle.
The operating mechanism may be provided in combination with a movable closure element to which the operating mechanism is attached.
The operating mechanism and movable element may further be provided in combination with a frame support having a strike assembly. The movable element is mounted for movement between the predetermined position and a second position, with the latch system engaging the strike assembly with the movable element in the predetermined position.
In one form, the wall has an opening bounded by an edge and the frame has a wall and a transverse flange that cover the edge so that the edge is not exposed to a user of the operating mechanism.
The invention is further directed to an operating mechanism for a movable closure element to releasably engage a strike assembly on a frame support and thereby releasably maintain the movable closure element on which the operating mechanism is mounted in a predetermined position relative to the frame support. The operating mechanism has a base with an elongate portion with a first axis and a wall extending around the first axis and defining a passageway. The operating mechanism further includes a latch system on the base and having (a) a latched state in which the latch system engages a strike element on the strike assembly so as to maintain a movable closure element on which the operating mechanism is mounted in the predetermined position and (b) a released state wherein the latch system can be disengaged from a strike element so as to allow a movable closure element on which the operating mechanism is mounted to be moved from the predetermined position. The operating mechanism further includes an actuating system on the base that is changeable from a first state into a second state to thereby change the latch system from the latched state into the released state. The actuating system has at least a first link which is movable axially within the passage from a first position into a second position to thereby change the latch system from the latched state into the released state. The actuating system further has an actuating assembly for the at least first link and a second link that can be operatively connected to the at least first link without requiring separate fasteners.
The second link may have a receptacle for supporting a part of the at least first link for pivoting movement about a second axis that is transverse to the first axis.
In one form, the second link has a slot communicating with the receptacle and extending radially relative to the second axis from the receptacle.
The actuating assembly may have an actuating element that is repositionable relative to the base between a normal position and an actuated position. The second link is connected to the actuating element.
The second link may be connected to the actuating element for relative pivoting movement around a third axis.
In one form, the third axis is substantially parallel to the second axis.
The actuating element may be movable relative to the base around a fourth axis.
In one form, the second link has an end that slides axially relative to the first axis guidingly along the wall as the actuating element is repositioned between the normal and actuated positions.
In one form, the second link is selectively reversibly mountable for movement in opposite directions around the fourth axis as the actuating element is changed from the normal position into the release position.
The actuating system may further include a spring acting between the actuating element and the second link for normally urging the second link in movement around the third axis.
In one form, the second link exerts a tensile force on the at least first link as the at least first link is moved from the first position into the second position.
The second link may exert a compressive force on the at least first link as the at least first link is moved from the first position into the second position.
In one form, the at least first link has an elongate portion with a free end and the part of the at least first link is spaced from the free end.
The elongate portion may have a substantially straight section extending along a first line substantially parallel to the first axis. The part of the at least first link extends transversely to the first line along a second line.
The at least first link may have a free end section which projects a) along a third line that is transverse to the second line and b) to the free end of the elongate portion.
In one form, the first and third lines are substantially parallel to each other.
The elongate portion of the at least first link may be connected to the second link by directing the elongate portion of the at least first link through the receptacle by relatively reorienting the at least first link and second link while relatively moving the elongate portion of the at least first link and second link along the first and second lines as the elongate portion of the at least first link is directed through the receptacle.
The operating mechanism may be provided in combination with a movable closure element to which the operating mechanism is attached.
The movable closure element and operating mechanism may be further provided in combination with a frame support having a strike assembly. The movable element is mounted for movement between the predetermined position and a second position. The latch system engages the strike assembly with the movable element in the predetermined position.
A schematic representation of a system, incorporating the present invention, is shown at 10 in
The system 10 is shown in generic form because it is contemplated that the environment for the present invention and the configuration thereof may take myriad different forms. One exemplary environment for, and form of, the present invention, will now be described. It should be understood that the following description is intended to be exemplary in nature only and not limited to the specific structure shown and described.
In
As seen in
An L-shaped operator 58 is mounted to a tab 60 on the housing 38 for pivoting movement around an axis 62. With the latch system 18 in the latched state, pivoting movement of the operator 58 in the direction of the arrow 64 in
As previously noted, the operating mechanism 16 is contemplated to be used with myriad different types of latch systems including, for example, those utilizing a single rotor. The latch system 18 is intended only as one representative structure. The inventive concept, as explained in greater detail below, can be used in association with any latch system that is operable by repositioning an element through the application of either a compressive or tensile force. In the initial embodiment described herein, the latch system 18 is changeable from the latched state into the released state by exerting a force on an arm 72 of the operator 58 generally in the direction of arrow 74 in
The base 26 on the operating mechanism 16 consists of an elongate portion 76 defined by a hollow tubular element 78 having a central axis 80 around which a wall 82 extends. The tubular element 78 has spaced axial ends 84,86. The end 84 is mounted to the closure 12 through a support element, in this embodiment defined by the housing part 42. A separate support at 88 mounts the opposite end 86 of the tubular element 78 to the closure 12 so that the tubular element 78 is spaced from an inside surface 90 (
In this embodiment, a bolt 94 extends through the support/housing part 42 and the tubular element 78 and is secured by a U-shaped spring nut 96 clipped to the end of the tubular element 78. The housing 38, including the support/housing part 42, is suitably secured to the closure 12, as shown for example in previously referenced U.S. patent application Ser. No. 10/316,359.
The support 88 consists of an elbow 98 with a reduced diameter male portion 100 on one leg 102 and a circular flange 104 on the other leg 106. The male portion 100 of the elbow 98 is press fit into the passageway 114. The flange 104 has a flat surface 108 which can be borne facially against the inside surface 90 of the closure 12 and secured therethrough as through a threaded fastener 110. In this embodiment, the fastener 110 is integrated into a cap 112 with a rounded, exposed side 114 and a stepped opposite side 116. The opposite side 116 has a reduced diameter portion 118 that extends into a part of the closure 12, such as a window, so that an annular flat portion 119 bears facially against the outside thereof.
The tubular element 78 has a rectangular opening 120 through the wall 82. The opening 120 is a blind opening. In other words, there is no opening through the wall 82 diametrically opposite to the location of the opening 120. The opening 120 is bounded by a continuous edge 122. The opening 130 is dimensioned to accommodate an actuating assembly at 124 on the operating mechanism 16, and consisting of a frame 126, an actuating element 128, and the aforementioned second link 30.
The frame 126 has a wall 130 with a surface 132 that is curved to substantially match the curvature of the radially outwardly facing surface 92 on the tubular element 78. A flange 134 projects away from the surface 132 and has an outer peripheral surface 136 that nominally matches the shape and dimension of the edge 122 bounding the opening 120 through the tubular element 78. The flange 134 has spaced tabs 138,140, which define surfaces 142,144 which each face the surface 132. The tabs 138,140 have the same configuration. Exemplary tab 138 has a ramp surface 146 which is angled relative to the planes of the surfaces 132,142,144. The tab 140 has a like ramp surface 148.
The frame 126 can be pressed into operative engagement with the base 26, as shown in
With the frame 126 operatively positioned, the wall 130 and flange 134 cover the edge 122 of the opening 120 to provide a consistently neat appearance, even if the edge 122 has some minor irregularities. Depending upon how the opening 120 is formed, the edge 122 may have a rough shape with potentially sharp and/or jagged portions and/or flash thereon. The frame 126 shields the user from this edge 122 so that the edge 122 is not inadvertently contacted during use, as might otherwise cause discomfort to the user.
The actuating element 128 has a length dimension L and a width dimension W1 that are each slightly less than the corresponding length and width dimensions L1,W2 of an opening 152 bounded by an inside surface 154 of the flange 134 on the frame 126. With this arrangement, the length and width dimensions L,W1, respectively, of the actuating element 128 can be directed through the frame opening 152 through the corresponding length and width dimensions L1,W2.
The actuating element 128 is preferably operatively engaged with the frame 126 before the frame 126 is snap fit to the tubular element 78. The actuating element 128 has an actuating surface 156 that is placed in a leading direction as the actuating element 128 is directed through the frame opening 152 from the inside 158 of the frame 126 to the outside 160 of the frame 126. The frame 126 and actuating element 128 can be relatively angularly reoriented, and otherwise relatively moved with the actuating element 128 extending into the opening 152, to allow pivot stub shafts 162,164, which project towards each other from the flange 134 on the frame 126 across the width of the opening 152, to be extended into openings 166,168, respectively, in spaced walls 170,172 on the actuating element 128. The walls 170,172 have undercut guide slots 174,176, respectively, which converge outwardly towards the openings 166,168, to guide the pivot stub shafts 162,164 into alignment with the openings 166,168. The spacing between the walls 170,172 is selected so that as the pivot stub shafts 162,164 move within the guide slots 174,176, the walls 170,172 are compressed slightly towards each other by the pivot stub shafts 162, 164. Once the pivot stub shafts 162,164 move up to the openings 166,168, the walls 170,172 relax to cause the pivot stub shafts 162,164 to seat in the openings 166,168. With the actuating element 128 assembled in this manner, the pivot stub shafts 162,164 cooperatively define a pivot axis at 178 for the actuating element 128, which is movable therearound between a normal position, as shown in
The link 30 is mounted between the walls 170,172 and is maintained in position by a pivot pin 184, which spans between the walls 170,172 and guides a mounting end 186 of the link 30 in pivoting movement around an axis 188, that is substantially parallel to the axis 178. The link 30 has an actuating end 190 with a curved edge 192 that bears against the inside surface 154 of the tubular element 78 at a location diametrically opposite to the location of the opening 120.
A wall 194 on the actuating element 128, spanning between the walls 170,172, and defining the actuating surface 156, has a cantilevered post 196 that projects therefrom in a first direction. The link 30 has a corresponding cantilevered post 198 projecting therefrom generally oppositely to the first direction. The lines of projection of the posts 196,198 nominally coincide so that a compression coil spring 200 can be mounted over the posts 196,198 to act between the wall 194 and link 30 in compression. The spring 200 biases the link 30 in one direction in movement around the axis 188. Movement in this direction is limited by the abutment of an arm 202 on the link 30 to a stop tab 204 projecting inwardly from the wall 194 of the actuating element 128. Opposite pivoting movement of the link 30 is limited by abutment of an edge 206 on the link to a separate stop tab 208 projecting inwardly from the wall 194 on the actuating element 128.
The actuating assembly 124, consisting of the frame 126, actuating element 128, link 30, and spring 200, can be preassembled preparatory to installation by radial movement through the opening 120 in the tubular element 78. The actuating assembly 124 can be directed radially, as a unit, to be snap fit into, and maintained in, operative engagement with the tubular element 78. The actuating assembly 124 can thus be assembled without requiring any separate fasteners in a simple press fit step through the blind opening 120 to maintain the operative engagement between the actuating assembly and the tubular element 78.
It is further possible to operatively connect the at least one link 28 to the link 30 without requiring separate fasteners. To make this possible, the link 30 is provided with a receptacle 210 to receive a part 212 of the link 28 so as to guide the part 212 and link 30 in relative movement around an axis 214. The link 30 has a slot 216 in communication with the receptacle 210 and projecting radially therefrom along a reference line RL, as seen in
As seen in FIGS. 8 and 15–17, the link 28 has an elongate part 218 with a length that extends along a reference line RL2. The elongate part 218 has a straight section 220 which joins to the part 212. The part 212 is straight and extends along a reference line RL3, which is generally orthogonal to the reference line RL2. The end of the part 212 remote from the straight section 220 is return bent to define a straight, free end section 224 that projects along a reference line RL4, which is shown to be orthogonal to the reference line RL3 and substantially parallel to the reference line RL2. The free end section 224 terminates at a free end 226.
The connection of the link 28 to the link 30 is accomplished by directing the straight section 220 of the link 28 through the receptacle 210 while strategically relatively angularly and translationally reorienting the links 28,30. As seen in
As seen in
With the links 28,30 operatively connected, and the actuating assembly 124 snap fit in place, the edge 192 of the link is loaded against the radially inwardly facing surface 154 on the tubular element 78 through the spring 200. The spring 200 likewise biases the actuating element 128 to the normal position, as shown in FIGS. 7 and 24–27.
By pressing inwardly on the surface 156 of the actuating element 128 at a location remote from the pivot axis 178, the actuating element 128 is pivoted to the actuated position of
The slot 216 is oriented so that the line RL thereof is not parallel to the force line RL4, as might tend to draw the part 212 radially through the slot 216. The diameter D1 of the part 212 is greater than the width W of the slot 216 so that separation of the part 212 from the link 30 will not occur.
As shown in
The actuating element 128 and tubular element 78 are configured so that an operator can extend a hand around the actuating element 128 and tubular element 78 so as to exert a squeezing force on the surface 156 and a portion of the tubular element 78 at 240 that is diametrically opposite to the surface 156. By effecting this squeezing action, the latch system 18 can be placed in the released state, whereupon the user can change the position of the closure 12 by conveniently manipulating the grasped tubular element 78.
As shown in
With the axial end 84 of the tubular element 78 connected to the support/housing part 42, as shown in
As an alternative to using the bolt 94 as shown in
The invention also makes possible the provision of a kit with tubular elements 78,78′, as shown in
As see in
As shown in
In this embodiment, as show in
As previously mentioned, the precise configuration of the latch system 18 is not critical to the present invention. An exemplary, modified form of latch assembly, usable with the present invention, is shown at 18′ in
An L-shaped latch element 280′ is mounted on an axle 326 for pivoting movement around an axis 328. The latch element 280′ is normally biased in the direction of the arrow 330 in
The invention also contemplates utilizing latch systems that may have a single rotor or other types of latching mechanism.
Another variation of the present invention is shown in
In
As also shown in
While the invention has been described with particular reference to the drawings, it should be understood that various modifications could be made without departing from the spirit and scope of the present invention.
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Number | Date | Country | |
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20050212307 A1 | Sep 2005 | US |