POWER TOOL TO SPRING TORSIONER CONVERTER

Abstract

A device to apply a rotational force to a spring of a rollup or overhead garage door counterbalancing mechanism. The device has a rotatable driven member mounted in a housing. The housing and the driven member have slots with an open end adapted to receive the shaft of the overhead garage door counterbalancing mechanism. A coupling member is configured to mount to the driven member and connect the driven member to the winding cone of a garage door spring to apply rotational force to the spring. The housing with the driven member may be connected to the body of an existing power tool in place of the original tool head, or, the housing may be permanently combined with a motor and transmission to provide a special purpose tool.

Claims

1. An apparatus for applying rotational force to portions of a garage door assembly comprising: (1) a housing with a first slotted portion; (2) a driven member mounted to the housing having a second slotted portion; (3) a transmission adapted to apply rotational force to the driven member; (4) a coupling member adapted to mate with the driven member, the coupling member comprising at least one engagement member adapted to engage portions of a winding member of a garage door assembly.

2. The apparatus according to claim 1, wherein the coupling member has an opening configured to admit a shaft.

3. The apparatus according to claim 1, further comprising a central aperture adapted to mate with portions of the coupling member.

4. The apparatus according to claim 1, further comprising a motor adapted to engage with the transmission and provide motive force thereto.

5. The apparatus according to claim 1, wherein the at least one engagement member includes one or more slots or at least one hooked member.

6. The apparatus according to claim 1, wherein the housing and transmission are adapted to attach to portions of a pre-existing power hand tool.

7. The apparatus according to claim 1, comprising a prong for engagement with portions of a winding cone of an overhead door counterbalance assembly.

8. The apparatus according to claim 1, configured to receive a transverse portion of a shaft when at least the first slotted portion and the second slotted portion are aligned.

Description

BRIEF DESCRIPTION OF THE DRAWING FIGURES

[0020] FIG. 1 shows an elevation view of a prior art sectional overhead door in the closed position;

[0021] FIG. 2 shows a fragmentary elevation view of the prior art spring area of the counterbalancing mechanism;

[0022] FIG. 3 shows a side elevation view of the housing portion of one embodiment of the invention, wherein the opposite side is substantially a mirror thereof;

[0023] FIG. 4 shows a plan view of the top of the coupling member configured to mount to the housing portion;

[0024] FIG. 5 shows a side elevation view of the coupling member;

[0025] FIG. 6 shows a plan view of the bottom of the coupling member;

[0026] FIG. 7 shows a side elevation view of the housing with mounted coupling member 122;

[0027] FIG. 8 shows the combined housing with coupling member 122 mounted to the shaft of a garage door counterbalance mechanism, with an engagement hook 131 secured to a winding cone.

LISTING OF REFERENCED ELEMENTS

[0028] 80 garage door coil torsioning apparatus [0029] 100 housing [0030] 102 handle [0031] 106 driven member [0032] 108 snap ring [0033] 110 coupler retainer [0034] 112 housing shaft slot [0035] 114 worm gear [0036] 116 worm [0037] 117 shaft [0038] 118 transmission [0039] 120 motor [0040] 122 coupling member [0041] 123 coupler cap [0042] 124 coupler fasteners [0043] 125 coupler body [0044] 126 coupler post [0045] 128 coupler post prongs [0046] 130 coupler shaft slot [0047] 131 engagement hook [0048] 132 engagement recess [0049] 200 garage door counterbalance mechanism [0050] 201 garage door [0051] 202 garage door tracks [0052] 204 coil springs [0053] 206 shaft [0054] 208 shaft drum [0055] 210 shaft bearing [0056] 212 anchor cone [0057] 214 cone set screw [0058] 216 central support [0059] 218 winding cone [0060] 219 open bore [0061] 220 tabs [0062] 222 cable

DEFINITIONS

[0063] Unless otherwise explained, any technical terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure belongs. The singular terms a, an, and the include plural referents unless the context clearly indicates otherwise. Similarly, the word or is intended to include and unless the context clearly indicates otherwise. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of this disclosure, suitable methods and materials are described below. It should be understood that the objects, features and aspects of any embodiment disclosed herein may be combined with any object, feature or aspect of any other embodiment without departing from the scope of the invention. The term comprises means includes. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety for all purposes. In case of conflict, the present specification, including explanations of terms, will control. In addition, the materials, methods, and examples are illustrative only and not intended to be limiting.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0064] In order that the various embodiments of the invention be fully understood, it is necessary to describe in sufficient detail the structure and function of coil type garage door counterbalance mechanisms.

[0065] Explanation of Common Garage Door Assemblies:

[0066] Prior Art FIGS. 1 and 2 show common coil spring counterbalanced garage door assemblies. FIG. 1 shows a conventional overhead door 201 in the closed position mounted against a wall. Overhead doors are usually made of metal, plastic or wood panels and have considerable weight. FIG. 2 shows a counterbalance mechanism 200 which is used to facilitate the safe and easy opening and closing of door 201.

[0067] Counterbalance mechanism 200 is located above the top of door 201 and has a generally transverse shaft 206. Transverse shaft 206 is typically either a hollow tube or solid bar, the material determined by the weight to be lifted. Opposite end portions of shaft 206 are supported in bearing supports 210. The center portion of shaft 206 is supported by central bearing support 216 which is itself supported by a mount affixed to the wall. In some installations, shaft 206 may be supported in bearings on the remote ends of the garage door tracks 202. Drums 208 are concentrically mounted to the shaft via a set screw in the positions shown, and rotate with the shaft. A cable 222 is wound about each drum, with one end of the cable tethered to the drum, and the other end attached to the lower end of the garage door. Shaft 206 is subjected to rotational forces by a pair of coil or helical springs 204 with typically one end of each coil spring 204 free to turn with the shaft 206, terminating with a winding cone 218, while the opposite end of each spring is constrained from turning by an anchor cone 212. When door 201 moves from the open to the closed position, springs 204 are energized by the twisting action of shaft 206, and the shaft 206 rotates as door 201 moves to its closed position, inducing sufficient torque into springs 204 to counterbalance the majority of the weight of door 201. Springs 204 then have sufficient torque so that door 201 can be opened with little effort. When door 201 is in the open position, springs 204 must retain a small amount torque to keep cables 222 taut, preventing the accidental closing of door 201. During door installation, winding cones 218 must be rotated and then secured to shaft 206 by set screws when door 201 is in the closed position, in order to set the initial amount of torque in springs 204 required for proper operation of door 201.

[0068] Winding cones 218 have a plurality of radial open bores 219 for the purpose of receiving long removable rods which are used to manually load the springs, to selectively hold and rotate the cones 1/4 turn per rod insertion, thereby applying torque to the springs. When sufficient torque is applied to the springs, winding cones 218 are secured to shaft 206 constraining the winding cones to rotate only with the shaft; i.e., not independently.

[0069] To obviate the task of manually loading the springs which can be an exhausting and dangerous procedure, the present invention enables one person to easily place the springs 204 under tension by turning the winding cones 218. Once the winding cones are loaded with the required torque, they are secured to shaft 206 in the same manner as with manual loading.

[0070] Referring generally to FIGS. 3-8, an overhead garage door coil torsioning apparatus 80 comprises a housing 100; typically a cast metal housing/casing includes the following sections: a reduction gear section 118, e.g., a transmission, worm section 116, the driven member 106 section and handle 102. The worm gear, that is, the gear portion 114 that the worm 116 drives may be the driven member having a slot formed the gear, or the driven member may be a slotted plate centrally mounted to gear 114. Where there is a slot is formed in gear 114, the gap width (w) of the slot 112 is less than the length of worm 116 so that the worm may bridge the extremities of the slot 112, meaning that a leading or trailing end of the slot is always in contact with the worm when passing the worm 116 irrespective of the direction of rotation of the gear portion 114, such that continuous non-intermittent rotational motion of the gear portion is possible. A motor housing 120a includes a reversible rotation electric motor 120 that is mounted to the transmission 118 of the housing 100. While typically the motor is powered by household current; e.g., 115/120 VAC, battery operation is possible. An on-off trigger switch and a reversing switch, typically on the motor housing are used to control the power to the motor.

[0071] In some embodiments, housing 100 may attach to an existing power tool body such as that of a hand held rotary grinder or a pipe threader by removing the existing head portion of the hand held power tool and substituting housing 100 which would be attachable to the hand held power tool by any suitable means, e.g., bolts and/or other fasteners. In such cases, a mounting portion of the housing would fastenably align with the original head portion of the grinder to the motor 120 housing of the hand held power tool. Once attached to the power tool motor housing, power is transmitted via the tool motor to the driven member 106; which in the particular embodiment depicted is gear 114 contained in the housing, worm 116 being driven by transmission 118 which is driven by the motor of the hand held power tool. Driven member 106 rests against a bearing shoulder of the housing of the same size as snap ring 108, and is secured in the housing 100 by snap ring 108. Driven member 106 has a slot 112 of a size required to accommodate shaft 206 and a concentric semi-octagonal hole to admit the coupling member 122, which also has a slot 130 adapted to admit shaft 206. Slots 112 and 130 are align-able and must be aligned in order to admit shaft 206. The opening in the cast housing 100 is slightly larger than slot 112 to allow for motor-spin and any movement of driven member 106 after electrical power cut-off.

[0072] Referring to FIGS. 4-6 three views of coupling member 122 for connecting to and rotating the winding cones 218. The cap 123 of coupling member 122 may be an alloy such as chrome steel with four holes provided for fasteners, bolts, etc., to attach cap 123 to body 125. A stainless hook 131 is welded to cap 123 and engages an open bore 219 on either winding cone 218, in order to wind either spring 204 to the required torque. Coupling member 122 is inserted into coupler retainer 110 in driven member 106 from the side toward the spring to be wound as shown in FIG. 8. The tool with engaged coupling member is typically placed directly adjacent the winding cone to be wound with the projection of the hooked member 131 inserted directly into one of the open bores 119 of the winding cone 218. An alternative method of winding springs 204 is to omit cap 123 and engage tabs 220 on winding cones 218 into the slots 132 in body 125.

[0073] Body 125 of the coupling member has a post 126 with three prongs 128 which are configured to correspond with the semi-octagonal aperture/coupler retainer which firmly retains the coupling member 122 with an internal snap ring so that when coupler shaft slot 130 is aligned with shaft slot 112 of the driven member, and projections of the coupler post prongs 128 aligned with corresponding points of the semi-octagonal coupler retainer of driven member 106. This positions coupling member 122 concentrically with driven member 106, and with winding cones 218 and shaft 206, perfectly aligning all parts for winding springs 204 to the required amount of torque.

[0074] FIG. 7 shows the coupling member 122 mounted to the housing 100 of the apparatus 80 wherein coupler post 126 is inserted into the coupler retainer 110 and aligned therein by post prongs 128.

[0075] FIG. 8 shows the apparatus 80 attached to shaft 206 with engagement hook 131 of the coupling member 122 engaged with a winding cone 218, wherein one end of the hook is inserted into an open bore 219 of the cone 218.

[0076] Housing 100 can also be used as a portable pipe threader to cut threads onto pipe ends by replacing coupling member 122 with the appropriate size pipe die and cutting blades.

[0077] While there have been shown and described preferred embodiments of the invention, it is understood that changes in materials, size of the components, power transmission structures, coupling structures and other components can be made by those skilled in the art without departing from the invention.