Quick-release telescoping tripod

Abstract

A telescoping stand with a quick-release locking mechanism for binding and releasing a telescoping section including an inner extension member that telescopes into and out of an outer receiving member. The locking mechanism includes a pair of opposed actuator members, each with a hole through it and disposed so that the inner extension member of a telescoping pair passes through the holes. When the actuator members are generally perpendicular to the extension member, the extension member slides freely through the holes. In the normal configuration the actuator members are biased so that each is canted with respect to the extension member and so that the two actuator members are canted in opposed directions. In this configuration the actuator members provide a double binding frictional engagement with the extension member to hold it in fixed relation with respect to its associated receiving member. The actuator members are provided with tab ends that a user may squeeze together to move the actuator members toward their generally perpendicular orientation and thereby release the frictional engagement with the extension member.

Description

BACKGROUND OF THE INVENTION

The present invention relates to portable telescoping tripods or similar support stands such as may be used for supporting worklights or the like.

Portable worklights are found in a variety of settings such as construction sites, industrial plants, automotive and auto body repair shops, artist and photographic studios, and around the home for do-it-yourself projects. These lights are often used with a separate upright stand such as a telescoping tripod for adjusting the height off the ground or work surface. In keeping with common usage, such telescoping support structures may generally be referred to herein a; “tripods” and no limitation specifically to a three-legged structure is intended. In the conventional tripod a telescoping section is held in place by a surrounding threaded grip mechanism that is tightened down onto the extendable piece by turning the grip handle about its central axis.

SUMMARY OF THE INVENTION

The present invention provides a telescoping support structure with a quick-release mechanism that may be readily actuated for quickly raising and lowering the telescoping sections with much less effort than generally required by the conventional release mechanism. The present quick-release mechanism provides an extremely secure grip for preventing the sections from slipping once adjusted to the desired height, yet may be released especially quickly and easily with a minimum of effort.

Unlike the conventional mechanism, the present mechanism requires no twisting or unscrewing to loosen the mechanism and is not subject to overtightening as is the conventional twist mechanism.

Briefly, a quick-release locking mechanism according to the invention is used with a conventional telescoping stand in which a telescoping section includes an outer receiving member and an inner extension member that can telescope in and out of the receiving member. The locking mechanism includes a pair of opposed actuator members, each with a hole through it and disposed so that the inner extension member of a telescoping pair passes through the holes. When the actuator members are generally perpendicular to the extension member, the extension member slides freely through the holes. In the normal configuration the actuator members are biased so that each is canted with respect to the extension member and so that the two actuator members are canted in opposed directions. In this configuration the actuator members provide a double binding frictional engagement with the extension member to hold it in fixed relation with respect to its associated receiving member. The actuator members are provided with tab ends that a user may squeeze together to move the actuator members tow ard their generally perpendicular orientation and thereby release the frictional engagement with the extension member.

Other aspects, advantages, and novel features of the invention are described below or will be readily apparent to those skilled in the art from the following specifications and drawings of illustrative embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an overall perspective view of a tripod with a quick-release mechanism according to the invention.

FIG. 2 is a cross-sectional view of an embodiment of quick-release mechanism according to the invention.

FIG. 3 is a plan view of an embodiment of an actuator member forming a part of the quick-release mechanism of FIG. 2.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

FIG. 1 shows an extendable tripod support stand including a base section 10, a first extendable section indicated generally at reference numeral 11, and a plurality of deployable tripod legs 12 for supporting the stand on the ground or other work surface. The extendable section 11 comprises a tubular extension member 13 in telescoping relation with a tubular receiving member provided here by tubular base member 10. A quick-release locking mechanism 15 according to the invention is interposed between extension member 13 and receiving member 10 and holds the extension member securely in its extended position, yet can be quickly and easily released to permit the extension member to be retracted into the receiving member 10.

The arrangement of tripod legs and the manner by which they are deployed are entirely conventional and do not form a part of the invention. Moreover, the number of legs plays no role in the invention, a three-legged tripod being shown here only for purposes of illustration. Also for purposes of illustration, the tubular members 10 and 13 are shown as cylindrical although no limitation to cylindrical sections is intended, and tubular members of other cross-sectional shapes, such as square, rectangular, trianguloid, or even shapes with curving sides or rounded corners may be used. A single extendable section 11 is shown here for illustration, although further telescoping tubular members can also be used.

As seen in FIG. 1 locking mechanism 15 includes a housing 16, which is secured to the receiving base member 10. Extension member 13 slides through the housing as it telescopes into and out of receiving base member 10. The housing is provided with a window 17, out of which extend a pair of projecting tabs 18 and 19 to be grasped by a user for actuating the release mechanism to re-position extension member 13. In the normal configuration locking mechanism 15 grips extension member 13 and holds it firmly in place. To release the mechanism for collapsing the telescoping sections or for adjusting the height of the extension member, it is only necessary for the user to squeeze the two tabs 18 and 19 together and then slide the upper extension member to the desired height. This provides a marked improvement over the prior art with respect to such factors as ease of use, the swiftness with which the mechanism can be released (almost instantaneously), and even reliability of operation. In the past the user has typically had to firmly grasp and twist a locking member, which could prove difficult if the locking member had been overtightened and sometimes even required two hands to achieve.

Turning now to FIGS. 2 and 3, the locking mechanism 15 includes a pair of actuator members 20 and 21. Each actuator member is formed with a hole 22 through it for receiving extension member 13 and has a linearly projecting portion providing the projecting tab 18 or 19. The tabs 18 and 19 are formed to project outside of the housing and to be engaged by a user. The hole is formed and dimensioned to have sufficient clearance that extension member 13 can freely slide through it when the actuator member is oriented generally perpendicular to the extension member. When the actuator member is tipped or canted with respect to the extension member, however, the edge of the hole comes into binding frictional engagement with the extension member.

As seen in FIG. 2, the two actuator members are biased into opposed canted orientation with respect to extension member 13. That is to say, actuator member 20 is biased upward so that it contacts extension member 13 at the upper edge 23 of its hole while actuator member 21 is biased downward so that it contacts extension member 13 at the lower edge 24 of its hole. In the embodiment of FIG. 2 the biasing is provided by compression spring 26. The tabs 18, 19 include recessed areas 27, 28 for receiving an end of spring 26. Housing 16 is formed with a midsection 29 that includes a spring-retaining bore 30 disposed between the tabs 18 and 19 for receiving and retaining compression spring 26. In their opposed canted orientation the actuator members provide a double binding action al the edges 23 and 24 holding extension member 13 in position. As the actuator members are moved so that each approaches the generally perpendicular orientation, the binding engagement is released and extension member 13 is free to slide through the actuator members.

In general, the actuator members are structured and arranged such that squeezing the tabs 18 and 19 together will have the effect of urging the actuator members toward their generally perpendicular orientation. In the embodiment of FIG. 2 this is achieved by providing the actuator members 20, 21 with pivot arms 31, 32 extending away from the hole on the opposite side of the hole from the projecting tabs 18, 19. The housing is formed interiorly to capture the pivot arms at their ends so that the actuator members are restrained to pivot up and down about the pivot arm ends. In this way, the actuator members may be easily moved between the doubly binding, opposed canted orientation and the freely sliding, generally perpendicular orientation merely by squeezing the tabs toward one another. In FIG. 2 the interior of the housing is formed with separate upper and lower cavities 33 and 34 for the two actuator members. This arrangement provides a natural stop for the actuator movement so that the actuator members cannot be urged beyond their generally perpendicular orientation to become canted in the reverse direction. The separate cavities also provide a natural spacing to provide room for the compression spring in its fully compressed configuration between the two actuator members.

For the actuator members in their opposed canted orientation to hold the extension member in a desired fixed position with respect to the receiving member, it is of course necessary that the actuator members themselves be secured to the receiving member. In the illustrated embodiment the actuator members are secured to the receiving member entirely by virtue of being retained within the housing, which is in turn fixed to receiving member 10. In FIG. 2 the housing is threaded onto the lower receiving member 10, but the particular manner in which the housing is secured to the receiving member is not important to the operation of the invention and any convenient manner of securement may also be used.

The embodiment of quick-release locking mechanism illustrated herein includes a housing. A housing is desirable to protect the mechanism against possible damage or accumulation of dust, dirt or grime at the worksite. A housing can also be styled to have a decorative outward appearance and to enhance the overall decorative lines of the support stand. And as mentioned, the housing in the illustrated embodiment serves to secure the actuator members to the receiving member. Nevertheless, a locking mechanism according to the invention may be embodied without a housing. For example, a support arm or other shape secured to the receiving member at one extremity may be formed to pivotally support each actuator member about a separate pivot point, or about a common a pivot point for the two actuator members, with no need to provide a full housing for the locking mechanism. Further, the support arm may also be configured to provide support for the compression spring, or alternatively two separate compression springs may be supported to separately bias each actuator member. Yet further, other forms of springs or resilient members may be used to bias the actuator members instead of the compression spring illustrated here, and the actuator members themselves may even have a natural resiliency contributing to or providing the necessary biasing.

Thus, it is not intended to limit the invention only to the embodiments explicitly illustrated or described herein, which are offered here only to illustrate and give examples of various embodiments and aspects of the invention. Given the benefit of the teachings contained herein, those skilled in the art may be able to devise various modifications and alternate constructions that differ from the examples disclosed herein, but nevertheless enjoy the benefits of the invention and fall within the scope of the invention, which is to be defined by the following claims.

Claims

1. In a vertically extendable support stand for a worklight or the like having one or more extendable sections comprising a tubular extension member in telescoping relation with a tubular receiving member, the improvement comprising: a releasable locking mechanism between said extension and receiving members, comprising: a pair of opposed actuator members, each actuator member having a hole through it and a projecting tab formed for engagement by a user, the actuator members being disposed so that said extension member passes through said holes; wherein said holes are formed and dimensioned so that said extension member slides freely through said holes when said actuator members are in generally perpendicular orientation with respect to said extension member and so that said actuator members frictionally engage said extension member at said holes when said actuator members are canted with respect to said extension member; biasing means urging said actuator members into opposed canted orientation with respect to said extension member, with said projecting tabs being urged apart under the action of said biasing means; and wherein said actuator members are secured to said receiving member and are structured and arranged to approach said generally perpendicular orientation when said projecting tabs are urged together by a user; whereby said actuator members are normally urged into said opposed canted orientation under the action of said biasing means for frictional engagement with said extension member so as to secure said extension member in position with respect to said receiving member under the load of said worklight or the like and said extension member is released when said projecting tabs are urged together by user engagement so as to enable said extension member to be freely telescoped into and out of said receiving member.

2. The apparatus of claim 1 wherein each said actuator member is formed with a pivot portion extending away said hole on the opposite side of said hole from said projecting tab, and said pivot portions are restrained such that said actuator members pivot thereabout when said projecting tabs are urged together by a user for moving said actuator members toward said generally perpendicular orientation.

3. The apparatus of claim 2 wherein said biasing means comprises at least one compression spring disposed to urge said projecting tabs apart.

4. The apparatus of claim 3 wherein said biasing means comprises only one compression spring.

5. The apparatus of claim 1, further comprising a housing affixed to said receiving member and having a central bore receiving said extension member, said housing defining a window through which said projecting tabs extend for user engagement.

6. The apparatus of claim 5 wherein said biasing means comprises a compression spring, and wherein said housing further comprises a portion formed with a spring-retaining hole therethrough and disposed between said projecting tabs; and said compression spring extends through said spring-retaining hole between said projecting tabs.

7. The apparatus of claim 5 wherein said housing is formed in its interior to hold said actuator pivot portions in pivoting disposition.

8. The apparatus of claim 7 wherein said housing is formed in its interior with an upper cavity for receiving a first of said actuator members and a lower cavity for receiving the other of said actuator members, said upper and lower cavities each being formed with a recessed region to receive and retain the pivot portion of the respective actuator member.

9. The apparatus of claim 8 wherein said biasing means comprises a compression spring, and wherein said housing further comprises a portion formed with a spring-retaining hole therethrough and disposed between said projecting tabs; and said compression spring extends through said spring-retaining hole between said projecting tabs.