Removable tripod foot with securement

Abstract

Installation of a removable tripod foot is facilitated by a cross-axis aperture in the foot and loosening of the threaded connection of the foot and the tripod's leg is resisted by a resilient element engaging interfacing surfaces of the foot and the leg.

Claims

1. A foot for a tripod comprising: (a) a body including an interface region including a portion arranged to engage a terminal portion of a leg of a tripod and an elongate threaded portion with a terminal portion at the end thereof furthest distant from said interface region arranged substantially normal to the portion of the interface region, where said interface region has an outer diameter, where said elongate threaded portion has an outer diameter, where said outer diameter of said interface portion is greater than said outer diameter of said threaded portion; (b) a resilient element at least partially positioned between the interface region and said terminal portion of said elongate threaded portion; (c) wherein at least a portion of said resilient element is positioned proud of the portion of said interface region arranged to engage the leg of the tripod; (d) wherein said body includes an engaging member with a circular cross section to engage a surface supporting said tripod, where said engaging member is first tapering along a first portion of the length of said engaging member, where said engaging member is second tapering along a second portion of the length of said engaging member, where said body defines a discontinuity in the tapering between said first tapering and said second tapering; (e) where an outer diameter of said resilient element is greater than said outer diameter of said elongate threaded portion; (f) wherein said body defines an opening in said body, wherein said body defines said opening in said body at a location directly above a terminal portion of said engaging member, wherein said opening is aligned with said elongate threaded portion.

2. The foot for said tripod of claim 1 wherein the interface region includes a portion defining a circular groove and the resilient element comprises an elastomeric toroid retained in the groove with a portion of a surface of the resilient element projecting proud of the portion of the interface region arranged to engage the leg of a tripod.

3. The foot for said tripod of claim 1 wherein said elongate threaded portion of said body comprises a portion defining a threaded aperture.

4. The foot for said tripod of claim 1 further comprising said tripod.

5. The foot for said tripod of claim 2 further comprising said tripod.

6. The foot for said tripod of claim 3 further comprising said tripod.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is perspective view of a tripod.

(2) FIG. 2 is a perspective view of a claw-type tripod foot.

(3) FIG. 3 is a perspective view of the underside to the claw-type foot of FIG. 2.

(4) FIG. 4 is a perspective view of a spike tripod foot.

(5) FIG. 5 is an elevation view of a portion of a tripod leg and a removable foot.

(6) FIG. 6 is a section view of a portion of a tripod leg and a removable foot.

(7) FIG. 7 is an elevation view of a portion of a tripod leg and a removable foot of a second embodiment.

(8) FIG. 8 is an enlarged view of a portion of the section of FIG. 6.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

(9) Referring in detail to the drawings where similar parts are identified by like reference numerals, and, more particularly to FIG. 1, a tripod 20 is useful for both still and motion photography. Typically, a tripod comprises an apex mount 22 including a mechanism, such as a threaded stud 24, for securing a camera or an intermediate interface, such as a ball head or panoramic element, to which a camera can be secured. The apex mount 22 is secured to an apex structure 26 which is also the anchor point for the three legs 28 of the tripod. Each of the legs is typically secured to the apex structure 26 by a pivot joint 30 enabling the legs to be pivoted toward each other for transport and pivoted apart when the tripod is deployed for use. The legs 28 commonly comprise a plurality of leg sections, such as the three leg sections 32, 34, and 36, that telescope together to reduce the length of the collapsed tripod for transport or to enable adjustment of the height of the deployed tripod or compensation for an irregular supporting surface. A locking mechanism 38 which may be actuated by twisting secures the relative positions of the telescoping tube sections. Photographic tripods are preferably light weight and compact to facilitate transportation and the leg sections commonly comprise tubes of light weight materials such as aluminum or carbon fiber.

(10) Tripod feet 40 provide the interface between the legs of the tripod and the surface on which the tripod will be supported. The tripod feet commonly have a curved lower surface 42 which is often covered with rubber or plastic to resist sliding on a floor or other supporting surface. While the feet may be permanently affixed to the legs of the tripod, the feet are often removable enabling more specialized feet to be substituted when desired. Referring FIGS. 2 and 3, for example, one type specialized tripod foot is a claw foot 50 having body 52 comprising a crenated wall 54 with a plurality of facets 56 along the lower edge. The sharp edges 58 at the intersections of the facets are intended to bite into a hard, rough surface and secure the tripod even if the surface is wet. Referring to FIG. 4, another type of specialized tripod foot is a spike foot 70. The pointed end portion 72 of the foot's spike-like body 76 is intended to penetrate loose surface material providing additional support on shifting surfaces or in strong winds.

(11) Referring to also FIGS. 5 and 6, replaceable tripod feet are commonly affixed to the leg of the tripod by screwing a threaded stud 80 projecting from the foot into a threaded aperture 82 in a ferrule 84 which is secured to the end of a tubular leg section 86. On the other hand, referring to FIG. 7, the gender of the threads in the ferrule and the foot may be reversed with male threads of a threaded stud 90 projecting from the ferrule to engage female threads in an aperture 92 in the foot. While a threaded connection makes replacement straight forward, it can be difficult to fully tighten the threaded connection. The feet can also loosen as a result of cyclic loads and vibration as the tripod is repeatedly deployed or moved across a supporting surface; a condition that is exacerbated by the difficulty in tightening the feet. When the threaded feet loosen, the tripod becomes unstable and the feet may eventually become detached from the tripod. To prevent the removable feet from loosening, a liquid thread locker is commonly applied to the threads but this is time consuming and the container may leak damaging other equipment in a camera bag. On the other hand, threaded connections with prevailing torque features increase the torque required to tighten, as well as loosen, the connection making tightening and removal more difficult and the features may wear and become ineffective with repeated use. The applicants concluded that a mechanism that would permit removable tripod feet to be easily tightened but would reliably resist loosening would substantially improve the utility of a tripod.

(12) The removable feet 50, 70 for use with the tripod 20 include a resilient element 94 at the interface between the foot and the ferrule 84 secured to the end of the tripod's leg 28. As illustrated in FIG. 5, the resilient element 94 may be supported by the leg engaging surface 60 of the removable foot, but, referring to FIG. 7, the resilient element 94 could be applied to the foot engaging surface 96 of the ferrule 84. The resilient element increases friction between the interfacing surfaces of the foot and the ferrule to resist loosening of the threaded connection. While the elastomeric element could have any shape and could be applied to the respective surface, it is, preferably, a toroidal element, and, more preferably, an elastomeric o-ring installed in a groove 98 in one of the interfacing surfaces 60, 96. Referring also to FIG. 8, the groove 98 has an inner wall 99 which is undercut at an angle 101. The diameter of the groove at the point of intersection of the inner wall with the interfacing surface 60 is slightly greater than the inner diameter of the resilient element 94. When the resilient element is installed in the groove it must be stretched slightly. When the resilient element is released in the groove, it returns to its original size and is trapped in the groove against the sloping inner wall. On the other hand, the resilient element could be retained in the groove by an outer wall that sloped to a diameter, at the interfacing surface, that is slightly smaller than the outer diameter of the resilient element. A portion of the resilient element projects proud of the respective leg engaging surface 60 or foot engaging surface 96 so that the resilient element is compressed when the threaded connection is tightened. While an o-ring is inexpensive, the dimensions and characteristics of o-rings are carefully controlled and the force exerted by the o-ring is predictable enabling the foot to be tightened so that the interfacing surfaces 60 and 96 come in contact. Contact between the rigid leg engaging and foot engaging surfaces enhances the stability of the foot and the tripod and increases friction in the threaded connection which resists loosening. The compressed resilient element exerts a resilient separating force at the interfacing surfaces maintaining friction in the engaged screw threads during vibration and cyclic loading and resisting loosening of the threaded connection. Since the resilient element 94 does not come in contact with both of the interfacing surfaces until the surfaces are proximate each other, the foot screws easily into the ferrule for a major portion of the length of the threaded connection.

(13) To compress the resilient element and bring the leg engaging surface into contact with the foot engaging surface, an aperture(s) 74 which extends substantially normal to the longitudinal axis of the threaded element in the foot is provided in the body of the foot. A tool, such as a rod, an Allen wrench 100 or the shank of a screw driver can be inserted into the aperture providing the necessary leverage to fully tighten the threaded connection.

(14) The resilient element at the interfacing surfaces of a removable foot and a tripod leg and a cross-axis aperture facilitates installation of the foot and resists loosening of the threaded connection.

(15) The detailed description, above, sets forth numerous specific details to provide a thorough understanding of the present invention. However, those skilled in the art will appreciate that the present invention may be practiced without these specific details. In other instances, well known methods, procedures, components, and circuitry have not been described in detail to avoid obscuring the present invention.

(16) All the references cited herein are incorporated by reference.

(17) The terms and expressions that have been employed in the foregoing specification are used as terms of description and not of limitation, and there is no intention, in the use of such terms and expressions, of excluding equivalents of the features shown and described or portions thereof, it being recognized that the scope of the invention is defined and limited only by the claims that follow.