Technological Field
This disclosure relates to cranes and crane safety components and to crane stops for limiting a swing angle of a crane.
Related Art
Cranes can be built in an array of sizes for various implementations. Cranes can be used for moving large or unwieldy objects in an array of different environments. Large cranes can be used in the construction or transportation industry for loading ships or moving large amounts of materials at a construction site or loading dock, for example. One such type of crane is a jib crane. Jib cranes are used in a wide variety of applications, such as a workshop or garage, and can be relatively small in comparison to the larger tower, overhead, or railroad cranes. On the other hand, large high capacity jib cranes can be found in foundries, heavy equipment manufacturing plants, and in the aerospace, and high technology industries.
In general, this disclosure describes a device and method for restricting a swing angle of a jib crane. More particularly, this disclosure describes implementation of a mechanical stop for use with jib cranes that can be used to confine or limit the azimuth through which a jib crane can swing. The methods and devices of this disclosure each have several innovative aspects, no single one of which is solely responsible for the desirable attributes disclosed herein.
One aspect of the disclosure provides a device for limiting a swing angle of a jib crane, the jib crane having a jib rotatably mounted to a mast. The device can have a collar having a collar height and a collar width, the collar being configured to be fit to the mast at a stop height. The device can also have one or more stopping tabs enagagable with the collar and configured to be positioned on the collar at one or more points about a circumference of the mast. The stop height can place the one or more stopping tabs in a position coincident with the jib to interfere with the swing angle of the jib.
Another aspect of the disclosure provides a method for limiting a swing angle of a jib crane, the jib crane having a jib rotatably mounted to a mast. The method can include determining a stop height on the mast coincident with a portion of the jib. The method can also include securing a collar at the stop height on the mast, the collar configured to be slidably fit around the mast engaging one or more stopping tabs with the collar at one or more points about a circumference of the mast, the stop height placing the one or more stopping tabs in a position coincident with the jib. The method can also include limiting an effective swing angle of the jib based on the one or more points.
Another aspect of the disclosure provides a device for limiting a swing angle of a jib crane, the jib crane having a jib rotatably mounted to a mast. The device can have a first collar portion having a first joint end and a first flange end, the first flange end having a first flange disposed orthogonally to the first flange end. The device can also have a second collar portion having a second joint end and a second flange end, the second flange end having a second flange disposed orthogonally to the second flange end, the first collar portion and the second collar portion having a semi-circular shape. The device can also have a joining plate engageable with the first joint end and the second joint end wherein the first collar portion and the second collar portion are configured to surround the mast to form a collar when engaged with the joining plate. The device can also have one or more stopping tabs configured to engage with the collar and be positioned at one or more points around the collar, the one or more stopping tabs being positioned coincident with a movement of the jib and limiting the movement of the jib to an angle determined by the stopping tabs.
Other features and advantages of the present disclosure should be apparent from the following description which illustrates, by way of example, aspects of the disclosure.
The details of embodiments of the present disclosure, both as to their structure and operation, may be gleaned in part by study of the accompanying drawings, in which like reference numerals refer to like parts, and in which:
The detailed description set forth below, in connection with the accompanying drawings, is intended as a description of various embodiments and is not intended to represent the only embodiments in which the disclosure may be practiced. The detailed description includes specific details for the purpose of providing a thorough understanding of the embodiments. However, it will be apparent to those skilled in the art that the disclosure without these specific details. In some instances, well-known structures and components are shown in a simplified form for brevity of description.
The jib crane 100 can also have a jib 120. The jib 120 can have a proximal end 122 and a distal end 124. As described herein the proximal end 122 is the end of the jib 120 closest to the mast 110 and the mast head 114. The distal end 124 is the end of the jib 120 farthest from the mast 110. The jib 120 can have a boom 130 that extends in a generally horizontal direction away from the mast 110 and supports a hook 132 and associated tackle 134 for hoisting a load. In some embodiments the associated tackle can include a trolley (not shown) for moving the tackle along the boom 130. The jib 120 can also have a support 140 that reinforces and provides support to the boom 130 and the trolley, the hook 132, and the tackle 134. The support 140 can be a lattice structure as shown or another suitable structure that provides support to the boom 130. The support 140 can be separated horizontally from the mast 110 by a short distance indicated by the arrows 146 (distance 146). Such a distance may be only a few inches, for example. This is described in more detail below.
The jib crane 100 can have a span that describes the distance (not shown) from the center of the mast head 114 (e.g., at the upper bearing 117) to the distal end 124 of the boom 130. The span can also describe the distance away from the center of the mast head 114 that the tackle 134 and hook 132 can slide via the trolley along the jib 120.
The proximal end 122 of the jib 120 can be rotatably mounted to the mast head 114 via an upper bearing 117. A bottom 144 of the support 140 can also be rotatably mounted to the mast via a lower bearing 118. The upper bearing 117 and the lower bearing 118 can allow the jib 120 to rotate such that the jib 120 can rotate an angular distance around the mast 110 (see
In some embodiments, the jib crane 100 can be installed in a workshop, garage, a manufacturing facility, or other environment having limited space. For example, the jib crane 100 may be installed in a corner of such a space. This may result in certain spatial constraints that must be observed by a crane operator to avoid damage to other surrounding equipment or structures. For example, if the jib crane 100 that can swing 360 degrees is installed in a corner of a workshop, the space available in such a place may be limited by adjacent walls, thus allowing the jib 120 to rotate only 90 degrees, for example. Accordingly, the crane operator should only allow the crane to swing within the confined of the 90 degree corner to avoid damaging the walls when hoisting or moving a heavy load with the crane. In another example, more than one jib crane 100 can be installed in proximity to one another. Accordingly, there may be many reasons to restrict the rotation of the jib 120 to avoid damage to other structures or equipment. It should be noted that the jib crane 100 may not be drawn to scale. Certain features of the jib crane may also vary slightly depending on design.
The jib crane 100 can include a jib stop assembly 200. In
The collar 210 can have a first collar portion 212a and a second collar portion 212b that each have a clamp end 214 (shown as clamp ends 214a, 214b). The first collar portion 212a and the second collar portion 212b can be formed as mirror images each formed with a curvature that matches that of the mast 110 to which they can be fitted. In some embodiments, the first collar portion 212a and the second collar portion 212b can be identically formed. Alternatively, the collar 210 can be formed as a single or unitary piece.
In some embodiments, the first collar portion 212a and the second collar portion 212b can also each have a joint end 216 (shown as joint ends 216a, 216b). The joint ends 216, and therefore the first collar portion 212a and the second collar portion 212b, can be joined by a joining mechanism 221. The joining mechanism 221 can connect or otherwise secure the first collar portion 212a and the second collar portion 212b to form the collar 210. In some embodiments, the joining mechanism 221 can be a joining plate 222 that can be joined using fasteners 220a, 220b, for example. The joint ends 216 can each have one or more apertures arranged to align with corresponding apertures in the joining plate 222. The apertures in the joining plate and the apertures in the joint ends 216 can be internally threaded and sized to accept the fasteners 220. The fasteners 220 can have external threads formed to mate with the internal threads of the apertures in the joining plate 222 and the apertures in the joint ends 216. Two fasteners 220 are shown as fasteners 220a, 220b. The fasteners 220 can be bolts or other appropriate fastening means. In some embodiments, for example, the fasteners 220 can be half-inch steel bolts. In other embodiments, the size of the fasteners 220 can be dictated by the size of the jib crane 100 and increased loads associated with the larger jib crane 100. In some embodiments, the fasteners 220 can be countersunk into the joining mechanism 221, for example, the joining plate 222. Countersinking the fasteners 220 can minimize the profile of the joining plate 222 providing clearance to the support 140 (
The jib stop assembly 200 can also have a compression mechanism 239 (indicated in dashed lines) for compressing the clamp ends 214 toward each other to decrease the inner diameter 202 of the collar 210 and secure the jib stop assembly 200 to the mast 110.
In some embodiments, the compression mechanism 239 can have a clamp tab 226 formed at the clamp ends 214. In some embodiments, the first collar portion 212a can have the clamp tab 226a and the second collar portion 212b can have the clamp tab 226b. The clamp tabs 226 can also be referred to herein as flanges. The compression mechanism 239 can also have a clamp fastener 230. In some embodiments, the clamp fastener 230 can be for example, a bolt, nut, and washer assembly used to tighten the collar 210 and secure the jib stop assemblies 200 around the mast 110. In another embodiment the clamp fastener 230 can comprise a quick release or lever-activated compression mechanism 239. Each of the clamp tabs 226 can have an aperture 228 (shown as apertures 228a, 228b) sized to receive a clamp fastener 230. The clamp fastener 230 can, for example, be tightened in order to compress the flanges of the compression mechanism 239 together.
In some embodiments, the first collar portion 212a and the second collar portion 212b can be formed of a metallic material such as a metal strap band or multiple pieces of metal welded or otherwise joined.
In use, each of the first collar portion 212a and the second collar portion 212b can be placed in position at the stop height 104 or the height 106 as needed. The joining mechanism 221, or the joining plate 222, can then be positioned to secure each of the joint ends 216 to form the collar 210, surrounding the mast 110. In an embodiment using a single joining plate 222, the apertures in the joining plate 222 can be aligned with the respective apertures in the joint ends 216 to receive the fasteners 220. The fasteners 220 can be inserted through the joining plate 222 and the joint ends 216 and tightened in place, with the first collar portion 212a and the second collar portion 212b surrounding the mast 110 to form the collar 210. The compression mechanism 239 can then be tightened or otherwise compressed to secure the jib stop assembly 200 to the mast 110. In at least one embodiment, the clamp fastener 230 can be inserted through apertures in the clamp tabs 226. The clamp fastener 230 can then be tightened to decrease a distance 234 between the clamp ends 214. As the compression mechanism 239 is tightened, the clamp ends 214 can be compressed toward one another decreasing the inner diameter 202. This action can tighten the collar 210 about the mast 110 at a desired stop height 104, 106 and rotational position. In some embodiments a pad 204 can further be inserted between the collar 210 and a surface of the mast 110. The pad 204 can have a thickness that can accommodate any irregularities in the surface of the mast 110 where the jib stop assembly 200 is installed. The pad 204 can also provide an amount of friction that can prevent the jib stop assembly 200 from rotating around the mast 110 or moving out of position once the clamp fastener 230 is tightened as desired. For example, the rubber may have a thickness of ⅛ to 3/16 inches. In some embodiments, the pad 204 can be a piece of rubber applied to the inner surface of the collar 210. In some other embodiments, the pad 204 can be affixed to an inner surface of the first collar portion 212a and the second collar portion 212b independently such that it will be in contact with the mast 110 in use.
In some embodiments, the collar 210 and each of its subcomponents can be formed of a metallic material or alloy. In some embodiments, the first collar portions 212a and the second collar portion 212b can be formed from a metal strap band and bent to form the clamp ends 214 and the clamp tabs 226. In some other embodiments, the first collar portion 212a and the second collar portion 212b can be forged or otherwise welded together and formed from smaller portions of metal. In some other embodiments, the collar can be formed from a portion of pipe. In still other embodiments, the collar 210 and the other components of the jib stop assemblies 200a, 200b can be formed from 50 series steel, 836 steel, or other similar or suitable materials for the application.
The collar 210 can have a collar thickness 238 (indicated by arrows 238). The collar thickness 238 can be approximately one quarter inch to one half inch. In some embodiments, the collar thickness 238 can be more than one half inch. In other embodiments, the collar thickness 238 can be three quarters of an inch or more, depending on the strength of the materials required. In some embodiments, a combined thickness of the joining plate 222, the fasteners 220, the collar 210, and the pad 204 is described by the arrows 232 (combined thickness 232). In some embodiments, the combined thickness 232 should be less than the distance 146 (
The jib stop assembly 200 can also have one or more stopping tabs, such as the horizontal stopping tab 300 (
The horizontal stopping tab 300 and the vertical stopping tab 320 are shown together in this figure for convenience of description. In some embodiments, however, the stopping tabs (e.g., the horizontal stopping tabs 300 and the vertical stopping tabs 320) are used in like pairs. For example, two horizontal stopping tabs 300 can be used for the jib stop assembly 200a (
In some embodiments, for example, the collar height 236 can be one to three inches, depending on the application and the size and capacity of the jib crane 100. Similarly, the distance 308 can measure one to four or more inches, depending on the application, size, and span of the jib crane 100. The distance 322 can also measure from one inch to five or more inches. The distance 308 and the distance 322 for example can vary by application. As different manufacturers have different sizes and capacities of jib cranes 100, the dimensions of the jib stop assemblies 200 can vary accordingly. These dimensions, and the other exemplary dimensions that follow, are provided by way of example and not limitation.
The joining mechanism 221 is shown as the joining plate 222 exploded from the left-hand side of
The horizontal tab arm 306 can have a thickness indicated by arrows 307 (tab thickness 307). The tab thickness 307 can be selected for ease of manufacture and structural stability for use with the jib crane 100. Accordingly, the tab thickness 307 can be approximately one quarter inch to one half inch. In some embodiments, the tab thickness 307 can be more than one half inch, depending on the strength of the materials required.
The horizontal stopping tab 300 can also have tab body 302 having an aperture 304. The aperture 304 can have a height 314 and a width 315 and be sized to receive the collar 210 in a clearance fit. The clearance fit can allow one of the joining ends 216 to extend through the aperture 304 and allow the horizontal stopping tab 300 to be moved in the direction 240 (
Referring to
In some embodiments, the vertical stopping tab 320 can also have a tab pad 332 similar to the tab pad 310. The tab pad 332 can be a portion of rubber (e.g., ⅛ to 3/16 inches) affixed to the tab body 326 or fitted between the mast 110 and the vertical stopping tab 320.
The tab pad 332 also provides additional security by compressing between the vertical tab 332 and the mast 110 when tightening the clamp fastener 230. Accordingly, the tab pad 332 can accommodate certain irregularities on the surface of the mast 110 and provide increased friction preventing the collar from rotating on the mast 110.
In some embodiments, the dimensions of the jib stop assemblies 200 and their various components can vary depending on the load-bearing capacity and the span of the jib crane 100. Accordingly, in larger jib cranes 100, the size and dimensions of the jib 120, the support 140, the distance 146, among other dimensions can all dictate variations in dimensions of the components of the jib stop assembly 200a, 200b. In particular, the collar height 236 and the collar thickness 238 of the collar 210; the tab thickness 307, the height 312, and the width 313 of the horizontal stopping tab 300; and the thickness 334, the height 335, and the width 323 of the vertical stopping tab 320, can vary with application and the size of the jib crane 100 and its components.
Referring briefly back to
In some embodiments, such as that shown in
In some embodiments, the jib stop assembly 200b can have one vertical stopping tab 320 and one horizontal stopping tab 300 (not shown). This configuration can place the vertical stopping tab 320 in a plane coincident with the proximal end of the boom 130, while the horizontal stopping tab 300 extends a sufficient distance to contact the support 140 of the jib crane 100. Accordingly, multiple combinations of the horizontal stopping tabs 300 and the vertical stopping tabs 320 are possible.
The jib crane 600 can include a jib stop assembly 700. The jib stop assembly 700 can be positioned a distance 604 from the mast head, beneath the shroud 630. Accordingly, portions of the jib stop assembly 700 are shown in dashed lines indicating their position beneath the shroud 630. Much like the jib stop assemblies 200, the jib stop assembly 700 can be implemented to limit the angle through which the jib 620 can swing. This can serve to protect nearby equipment and structures, similar to above.
The jib stop assembly 700 can have a collar 710 mounted to the mast 610. The collar 710 can have one or more stopping tabs, shown as a vertical stopping tab 720 (shown in dashed lines). The jib stop assembly 700 can also have a shroud extension 730 affixed or otherwise fastened to a safety channel 640 of the shroud 630. The safety channel 640 can be a portion of C-channel welded or otherwise affixed to the shroud 630. In some embodiments, the collar 710, the vertical stopping tabs 720, and the shroud extension 730 can be the major parts of the jib stop assembly 700. Other features are described in the following figures.
In some embodiments, the collar 710 can be a round metal ring with an inner diameter 704 that is slightly larger than the outer diameter 608 of the mast 610. The collar 710 can also have a height 702 and a width 703. For example, the height 702 can be approximately one inch to three inches. In some cases, the height 702 can exceed three inches depending on the span and capacity of the jib crane 600. In some embodiments, the width 703 can be approximately a half inch. In some embodiments, the width 703 can exceed one half inch depending on the material used and the size and load requirements of the jib crane 600.
In some embodiments, the collar 710 can be formed of more than one collar portion, (similar to the first collar portion 212a and the second collar portion 212b of the jib stop assemblies 200) and affixed to the mast 610 at a the desired height and distance 604 from the mast head 614. In some embodiments, the collar 710 can be affixed to the mast 610 by welding. In some other embodiments, the collar 710 may be unitary piece that can be installed over the mast 610, for example, prior to attaching the jib 620 to the mast head 614. In some other embodiments, the collar 710 can be installed during manufacturing of the jib crane 600.
In some embodiments, the collar 710 can be formed with a plurality of collar apertures 706. The collar apertures 706 can be oriented radially about the collar 710. Fourteen collar apertures 706 are shown in this figure with one aperture 706 hidden by the perspective behind the vertical stopping tab 720a. Not all of the collar apertures 706 are labeled for brevity. In some embodiments, the number of apertures can be larger or smaller than that shown, depending on application and the outer diameter 608 of the mast 610 and the inner diameter 704 of the collar 710. Each of the collar apertures 706 can also have internal threads (not shown) formed to accept a bolt or other suitable fastener 712.
The collar apertures 706 can be evenly spaced apart by an aperture spacing 708 about the collar 710. The even spacing can allow a user to remove the fasteners 712 and quickly reposition the vertical stopping tabs 720 as needed. One of the fasteners 712a is shown exploded from the vertical stopping tab 720a. Similar to above, the fasteners 712 can be half-inch steel bolts, for example. In some embodiments, bolts larger than half-inch can also be used depending on the load-bearing capacity and the span of the jib crane 600.
The tab shank 724 can have one or more apertures 726, shown as apertures 726a, 726b. The apertures 726 can be formed as a circular or oblong shape, sized to receive the fasteners 712. In some embodiments, the apertures 726 can be spaced apart by an aperture spacing 728. The aperture spacing 728 can be measured from the center of the aperture 726a to the center of the aperture 726b, for example. The aperture spacing 728 can be approximately equal to the aperture spacing 708. This can enable the apertures 726 to match with the collar apertures 706 facilitating installation of the vertical stopping tabs 720 on the collar 710. In some embodiments, the apertures 726 with an oblong shape can provide increased flexibility in repositioning the vertical stopping tabs 720 in various collars 710 with aperture spacing 708 that is not equal to the aperture spacing 728. In some embodiments, the oblong shape can further allow installation of the vertical stopping tabs 720 allowing some horizontal movement to fine-tune the angular swing limits (e.g., the angular distance 722) for the jib 620. In some other embodiments, the apertures 726 can have internal threads matching the external threads of the fasteners 712. In some other embodiments, the apertures 726 can be countersunk to receive fasteners 712 to with a tapered head, decreasing the profile of the vertical stopping tab 720 when installed under the shroud 630. This is similar to the fasteners 220 (
The vertical arm 727 can extend a tab height 732 away from the tab shank 724. The tab height 732 can measure one to three or more inches depending on the application. In some embodiments, the tab height 732 can be as much as 5 inches, depending on the placement of the safety channel 640. The vertical and horizontal distance between the shroud extension 730 and the placement of the collar 710 can determine a need for a longer or shorter tab height 732.
The tab shank 724 can have a shank height 735. In some embodiments, the shank height 735 can be approximately equal to the collar height 702 (e.g., one half inch to more than two inches). The vertical arm 727 and the tab shank 724 can also have a thickness indicated by the arrows 734 (thickness 734). The thickness 734, similar to above, can be approximately one half inch. The thickness 734 as well as the width 703 can be limited by the amount of space provided between the mast 610 and the shroud 630. In some embodiments, space can be limited to little more than one inch. Accordingly, careful selection of materials and dimensions can be required. The tab height 732 and the thickness 734 can be dependent on the application of the vertical stopping tab 720 and the positioning on the mast 610 and available space under the shroud 630. In some embodiments, the area beneath the shroud is limited requiring, for example, a longer or thinner vertical arm 727.
In some embodiments, the safety channel 640 can be formed with apertures corresponding to apertures formed in the flanges 738 of the shroud extension 730. Fasteners 646 can be inserted through the apertures in the flanges 738 and into the corresponding apertures in the safety channel 640 and used to secure the shroud extension 730 to the safety channel 640. In some embodiments, the shroud extension can be affixed to the safety channel 640 via a variety of welding, adhesives, or mechanical fasteners such as rivets. The fasteners 646 are shown in this figure, for example, as bolts.
In some embodiments, the shroud extension can have a height 740 and a length 741. The length 741 can be two to three inches for a small application to more than four inches in a larger application. Similar to above, the composition and size of the shroud extension 730 can be predicated on the amount of available space under the shroud 630. This can be, of course, manufacturer-specific. The safety channel 640 can also have a channel height 742 (
As the jib 620 rotates about the mast 610, the shroud extension 730 can come in contact with the vertical stopping tab 720a or the vertical stopping tab 720b depending on which direction the jib 620 swings. The vertical stopping tabs 720 can then impede the jib 620 from swinging past the selected position. In some embodiments, the fasteners 712 can be removed; the vertical stopping tab 720 can be moved to a new location and refastened in the new location using the same fasteners 712.
The preceding detailed description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. The described embodiments are not limited to use in conjunction with a particular type of machine. Hence, although the present disclosure, for convenience of explanation, describes a jib stop various types of jib cranes, it will be appreciated that the jib stop in accordance with this disclosure can be implemented in various other configurations and can be used in other types of machines. Furthermore, there is no intention to be bound by any theory presented in the preceding background or detailed description. It is also understood that the illustrations may include exaggerated dimensions to better illustrate the referenced items shown, and are not consider limiting unless expressly stated as such