Patent Grant
6978516
1. Field of the Invention
This invention relates to apparatus for controlling various and different movements of a door by means of a torque mechanism for torquing a door hinge assembly, by means of a unique door leveling mechanism, and by means of a novel semi-automated mechanism that provides a 90 degree held open door and release of the 90 degree held open door.
2. Description of the Prior Art
Prior art devices for movement of a door by providing torqued hinges for doors within a frame often have component parts for torquing the door hinge that are subject to excessive stress and wear, thereby resulting in failure of the component parts. Further, applicants are unaware of any prior art providing for an adjustable door leveling means that operates on a door from the top of the door's frame or from the top of an opening in a structure closed by a door without a frame, and levels a door that is not properly leveled due to improper installation of the door in its frame or in the opening of a structure without requiring opening of the door. Nor does the prior art disclose any means to hold a door open 90 degrees by an a semi-automated mechanism together with a semi-automated release of the door held open 90 degrees.
It is, therefore, an object of the invention to provide apparatus including a door hinge assembly that can be torqued using component parts that avoid excessive stress and wear so that early failure of the parts is avoided.
2. Another object of the invention is to provide an apparatus having door leveling means for a door which is not installed level that operates on a door from the top of the door's frame or from the top of an opening in a structure closed by a door without a frame and without having to open the door to level it.
3. A further object of the invention is to provide a semi-automated mechanism that holds a door open 90 degrees and also provides immediate semi-automated release of the 90 degree held open door.
4. A still further object of the invention is to provide a torque mechanism having a gear member that produces the desired torque on a door by a tooth by tooth action.
The invention comprises an apparatus 10 for controlling various movements of a door which is made up of several subassemblies, namely, a torque mechanism 12 comprising a torque rod assembly 14 and a torque housing assembly 19, a hinge pin assembly 16, a door leveling assembly 18, and a semi-automatic mechanism 20 for holding a door open 90 degrees and then releasing it.
The torque mechanism 12 has a torque housing assembly 19 including torque housing spacer 22 in the preferred shape of a flat rectangular thin plate preferably about ⅛ inch in thickness with several cut out, or if made with a mold, several hollowed out portions or segments. Torque housing spacer 22 is preferably made of steel, aluminum, zinc, or plastic material.
Portion 24 is located at the left side of torque housing spacer 22 and has a semi-circular form as shown in
Portion 26 is shaped to accommodate torque cam 34. At the top of torque housing spacer 22 and between portions 24 and 26 are two rectangular cavities 40 and 42 cut out or hollowed out of torque housing spacer 22 and formed into a size capable of receiving springs 44 as shown in
The bottom of torque housing spacer 22 has an opening 46 located adjacent to the lower inner end of portion 26 as shown in
The inner portion of pawl arm 50 has circular opening 64 to receive pawl pivot pin 65 as shown in
Torque cam 34 has a circular opening 70 in the left side of bottom portion 72 to receive cam pivot pin 74. The bottom portion 72 of torque cam 34 has a cut out cavity 76 of a size and shape suitable to receive the outer end 78 of torque tool 80. The upper portion 82 of torque cam 34 is semi-circular in form to receive the outer end 84 of gear actuating lever 86. The inner end 88 of gear actuating lever 86 is formed to interlock with the teeth 68 of torque gear 30.
Each corner of torque housing spacer 22 has a circular opening 90 to receive holding rivets 92. The middle portion of the top and bottom of torque housing spacer 22 each have a circular opening 90 to receive rivets 92. The middle portion of the left end of torque housing spacer 22 has a circular opening 94 to receive a floating lock pin 96 and the middle portion of the right end of torque housing spacer 22 has a circular opening 98 to receive an installation screw 100.
The torque housing spacer 22 is covered by a top cover 102 and a bottom cover 104 which are part of torque housing 19. Both covers 102 and 104 have circular openings 90 at each corner and at the middle portion of their respective tops and bottoms that are congruent with the openings 90 of torque housing spacer 22 and receive rivets 92 to hold various component parts that are included in torque housing 19.
Top cover 102 and bottom cover 104 each have same size circular openings 108 at their left ends but slightly smaller than the circular opening 94 of torque housing spacer 22 and small enough to prevent floating locking pin 96 when inserted in torque housing spacer 22 from falling out. Floating locking pin 96 has a central portion 110 which has a circumference greater than the circumference of openings 108 but smaller than the circumference of opening 94 so that it may move up and down inside the torque housing 19.
The top cover 102 and bottom cover 104 each have a relatively large circular opening 112 of equal size at the left portion 114 of each to accommodate a circumferential shoulder 116 on each side of torque gear 30 to keep torque gear 30 in position.
Torque rod assembly 14 has a torque rod 118 made of preferably ⅛ inch square steel wire and is cut at its lower end 120. Lower end 120 is pinched or coined to make it larger so it will be securely fixed in position at the time of assembly of torque rod assembly 14. A preferable length of torque rod 118 is about 30 inches. The size, weight, gauge, shape, and length of torque rod 118 may vary to accommodate a particular application so long as some flexibility is maintained.
Cylindrical torque nut 122 has a top portion 124 with a reduced outer circumference forming shoulder 125 and has a square opening 126 leading to square bore 127. Its lower portion 128 has its outer circumference formed in a hexagonal shape. The cylindrical lower bore 129 is formed with a cylindrical interior shoulder 130 to help secure the coined or enlarged portion of lower end 120 of torque rod 118 when lower end 120 is placed in position in torque rod nut 122. Torque rod nut 122 is slipped over the top end 132 of torque rod 118 and slid down the torque rod 118 to its lower end 120 so that the coined or enlarged portion of lower end 120 of torque rod 118 is contained in cylindrical bore 129 of torque nut 122.
Torque rod washer 134, preferably made of nylon or other similar suitable material that resists wear, is then slipped over the top end 132 of torque rod 118 and slid down torque rod 118 to seat on the top surface 136 of shoulder 125 of torque nut 122.
Torque rod bushing 138 is then installed by slipping it over top end 132 of torque rod 118 and sliding it down torque rod 118 to seat on top of torque rod washer 134. The torque rod bushing 138 has a bore 140 with a diameter of a size sufficient to accommodate torque rod 118 and is formed with an interior shoulder 142 at its top 144 and is tapered slightly with an increasing outer circumference toward its base 146 to allow easy insertion in a door and a press fit of base 146 at the bottom of a door. A preferable taper amount is about ½ degree and may vary from 442/1000 to 458/1000 of an inch. Base 146 of torque rod bushing 138 is formed with a cylindrical outer flange 147 that seats on torque rod washer 134.
Torque rod tubing 148 of a suitable length is then slipped over the top end 132 of torque rod 118 and is slid down torque rod 118 to abut its lower end 150 against the top surface of shoulder 142, thereby creating a bearing surface on the top of bushing 138 as shown in
Torque rod block 152, having a square center bore 154, is then slipped over the top end 132 of torque rod 118 and slid down to seat its bottom on the top end 158 of torque rod tubing 148 so that the top 156 of torque rod block 152 is near the top end 132 of torque rod 118.
All of the foregoing components of torque rod assembly 14 are held firmly and the top end 132 of torque rod 118 is twisted one quarter of a turn, preferably, thereby securing all component parts of torque rod assembly 14 in place, particularly the portion of the lower end 120 of torque rod 118 that is coined or enlarged and has been inserted into square opening 126 and bore 127 of torque nut 122. The turn of top end 132 may be varied in amount by plus or minus ⅛ inch, turning clockwise or counterclockwise.
Hinge pin assembly 16 has a cylindrical hinge pin housing 160 with a cylindrical plug 162 coined in the lower end 164 of hinge pin housing 160 in one embodiment as shown in
The hinge pin housing 160 is preferably made of aluminum but any suitable metal may be used having qualities similar to aluminum. It is formed with a slight taper which increases the size of its outer circumference as it progresses toward its top end 172 to provide a press fit at the top of a door in conjunction with flange 170.
Hinge pin 176 is formed in one rigid piece with an elongated inner shank portion 178 having a reduced circumference, an elongated middle body portion 180, and an elongated outer shank portion 182 which has a circumference larger than the circumference of the elongated inner shank portion 178 but smaller than the circumference of elongated middle body portion 180 as shown in
Top end 184 of elongated inner shank portion 178 produces a shoulder 186 in conjunction with the bottom end 188 of elongated middle body portion 180.
The bottom end 190 of elongated outer shank portion 182 produces a shoulder 192 in conjunction with the top end 194 of elongated middle body portion 180 which abuts against the inside shoulder or edge 174 of hinge pin housing 160 as shown in
Hinge pin 176 has three bearing surfaces, elongated inner shank portion 178, elongated middle body portion 180, and elongated outer shank portion 182, which distribute the load on hinge pin housing 160, thereby reducing stress on hinge pin housing 160 and preventing a short life and premature failure of hinge pin housing 160. The load on hinge pin housing 160 comes from the weight of the door on which it is being used and the movement of the door.
Cylindrical hinge pin spring 195 is placed around hinge pin 176 with its bottom 196 abutting against the top surface of plug 162 and retained there, and with its top 198 abutting against shoulder 186, thereby spring loading the hinge pin assembly 16 as shown in
The hinge pin assembly 16 is assembled by first inserting hinge pin 176 into hinge pin housing 160, next placing hinge pin spring 195 around elongated inner shank portion 178 and positioning spring top 198 against shoulder 186, and then inserting plug 163 either by threading it or coining plug 162 at the lower end 164 of hinge pin housing 160.
Door leveling assembly 18 has a leveling housing 199 that includes leveling housing spacer 200 in a preferred shape of a flat rectangular thin plate preferably about 3/16 inch in thickness and with a cut out rectangular portion 202 in its center that is sufficient in size to allow movement of slide plate 204 and adjustment plate 206 as shown in
Each corner 220 of leveling housing spacer 200 has a circular opening 222 of the same size to receive rivets 224. The center of the right side 226 of leveling housing spacer 200 has a circular opening 272 to accommodate an installation screw 228. The center of the left side 230 of leveling housing spacer 200 has a circular opening 232 to accommodate floating locking pin 234.
Leveling housing 199 includes a slide plate 204 formed from a rectangular plate that has its right side 236 cut out at an angle, preferably 45 degrees, from the bottom 238 of slide plate 204, so as to render its bottom 238 shorter than its top 240 as shown in
Leveling housing 199 includes adjustment plate 206 formed from a rectangular plate smaller than the rectangular plate of slide plate 204 but having the same thickness as slide plate 204 with its left side 246 cut out at an angle, preferably 45 degrees, so as to render its top 248 shorter than its bottom 250 and to produce a longitudinal projection or tongue 252 and groove 253 which receive projection or tongue 242 and groove 243 of slide plate 204, thereby creating a double interlocking condition of slide plate 204 and adjustment plate 206 in a constraining condition in an angled interface. Any other suitable means may be used to interlock slide plate 204 and adjustment plate 206 such as a dovetail.
The size of adjustment plate 206 is preferably about one/half of the size of slide plate 204 but any other ratio of sizes may be used such as 60/40 so long as the desired result is obtained. Further, the 45 degree angle of the right side of slide plate 204 and the 45 degree angle of the left side of adjustment plate 206 may be varied so long as the desired result is obtained, an angled interface.
Bottom side wall 250 of adjustment plate 206 has a circular opening 256 in its right portion for receiving adjustment screw 212. Adjustment plate 206 has a threaded bore 258 which permits threading with the threads 260 of adjustment screw 212 as shown in
Adjustment screw 212 has a head 261 which has a greater circumference than its threads 260 and may be slotted or have a Phillips type head. Adjustment screw 212 is formed with a flange 262 located around its middle section which prevents adjustment screw 212 from falling out of leveling housing 199 since flange 262 has a greater circumference than the circular opening 210 at the right side wall of leveling housing spacer 200. The top 263 of flange 262 is no higher than the top 201 of leveling housing spacer 200 and is preferably in alignment with top 201. The bottom right edge 265 of adjustment plate 206 has a slight indentation 267 to prevent possible interference with flange 262 of adjustment screw 212. However, indentation 267, although it improves performance, may be omitted without causing serious adverse effects on the operation of adjustment plate 206.
The top end 214 of adjustment screw 212 is blunt in form (not shown) and has a circumference smaller than the threaded portions of adjustment screw 212. The insertion of top end 214 into recess 216 increases the stability of adjustment screw 212 as it is being turned.
When adjustment plate 206 is interlocked with slide plate 204, for a door hinged on its right side, clockwise turning of adjustment screw 212 moves adjustment plate 206 towards the front of leveling housing spacer 200, which causes slide plate 204 to move to the right. Counterclockwise turning of adjustment screw 212 moves adjustment plate 206 towards the back of leveling housing spacer 200, which causes slide plate 204 to move to the left.
When adjustment plate 206 is interlocked with slide plate 204, for a door hinged on its left side, counterclockwise turning of adjustment screw 212 moves adjustment plate 206 towards the front of leveling housing spacer 200, which causes slide plate 204 to move to the right. Clockwise turning of adjustment screw 212 moves adjustment plate 206 towards the back of leveling housing spacer 200, which causes slide plate 204 to move to the left.
The slide plate 204 and adjustment plate 206 may both be modified by forming them without a tongue and groove, and will still work to cause adjustment of a door. However, the tongue and groove embodiments of the slide plate 204 and adjustment plate 206 are preferred embodiments.
When the adjustment plate 206, formed without a tongue and groove, moves in a back to front direction, forces applied against the angle in the adjustment plate which pushes against the slide plate 204, which also does not have a tongue and groove, causes the slide plate 204 to move in a sideways motion when the adjustment screw 212 is turned in one direction.
When the adjustment screw 212 is turned in the opposite direction, the adjustment plate 206 moves in a front to back direction because the forces relieved in adjustment plate 206 allows the slide plate 204 to move by the weight of the door.
The orientation of both slide plate 204 and adjustment plate 206 may be modified by turning each over so that their respective back sides are facing up while both are in their original location.
The top 210 of leveling housing spacer 200 is covered by a top cover 264 and its bottom 208 with a bottom cover 266. Both covers 264 and 266 have circular openings 222 at each corner to receive rivets 224 and are of the same size as the circular openings 222 of leveling housing spacer 200 and are congruent with the circular openings 222 of leveling housing spacer 200.
The middle portion of the left side of both covers 264 and 266 have circular openings 268 of the same size as each other but slightly larger than the circular opening 232 of leveling housing spacer 200 and small enough to prevent floating locking pin 234 when inserted in door leveling assembly 18 from falling out.
Floating locking pin 234 has a central portion 269 which has a circumference greater than the circumference of openings 268 but smaller than the circular opening 232 so that it may move up and down inside leveling housing 199 without falling out of leveling housing 199.
Top cover plate 264 and bottom cover plate 266 each have the same size slot 270 cut in their left portions and are congruent with each other.
Slot 270 is also located within the open area of rectangular portion 202 of leveling housing spacer 200 and is large enough to accommodate the outer shank portion 182 of hinge pin 176. The middle portion of the right sides of leveling housing spacer 200, top cover plate 264, and bottom cover plate 266 each have the same size circular opening 272 to receive installation screw 274.
When top cover plate 264 and bottom cover plate 266 are placed in position with leveling housing spacer 200 in between, top cover plate 264 and bottom cover plate 266 maintain adjustment screw 212 within leveling housing 199 due to the shoulder 262 of adjustment screw 212. The door leveling assembly 18 has the capability of moving a door hinge in a left or right direction up to ⅛ inch from center to allow a door installed in an out of square or level position in its frame to be properly squared in its frame, which accounts for the great majority of doors out of square or not completely level with its frame.
Further, the foregoing construction and arrangement of component parts accomplishes the leveling process at the top of the out of square door instead of at the bottom, which greatly facilitates and decreases the amount of time and the amount of work required for the leveling process.
A door which is more than ¼ inch out of square or level is an unusual situation which either requires the door to be removed and replaced in its frame or which requires the removal of the frame and door together and then to be reinstalled due to improper initial installation.
The door leveling assembly 18 may be easily adapted for use in an application where the door in question does not have a separate frame but closes an opening in any structure having a top, a bottom, and two sides.
The semi-automated door held open and release mechanism 20 (door held open and release mechanism 20) has a door hold open arm 276 formed with a semi-circular left end 278 and a convex right end 280 and a jog 281 in its left portion. Jog 281 elevates the right portion of hold open arm 276 to a plane parallel to and above the plane of the left portion as shown in
Door hold open arm 276 has a longitudinal slot 282 in its center portion. Slot 282 has its right end 277 formed in a semi-circular cavity 284 downwardly oriented and has a curved left end 285 as shown in
Door hold open arm 276 is pivotally mounted at its end portion that is nearest to the hinge side of door 298 and on the top surface 294 of the top 296 of door 298 at its hinge side by a pivot 300 inserted through a circular opening 302 located at the end portion of door hold open arm 276 and nearest to the hinge side of door 298 and secured in a threaded bore (not shown) in the top surface 294 of the top 296 of door 298 by retaining ring 306 as shown in
Pivot 300 has a circular groove 301 in its center portion 303 which is located just above the top surface of door hold open arm 276 and receives retaining ring 306 which is snapped into position in groove 301. Retaining ring 306 has a circumference greater than the circumference of circular opening 302 and of threaded bore (not shown). The lower portion (not shown) of pivot 300 has a larger circumference than the upper portion of pivot 300 and is hexagonally formed and threaded which allows lower portion of pivot 300 to be firmly threaded into threaded bore (not shown) in top surface 294 of top 296 of door 298. Although the foregoing embodiment of the pivot 300 is preferred, any suitable alternative means for securing pivot 300 may be used. For example, hexagonal lower portion 305 may not be hexagonal or larger than center portion 303 and opening 302 need not be circular.
The upper right end portion of hold open arm 276 has a circular opening 308. Door holding assembly 310 is received in opening 308 and is made up of a flat round washer cover 312, preferably made of brass or aluminum or other suitable material, having a central opening 313 and a downwardly projecting flange 314 around its circumference except for a slot or open or portion 316, a washer 318 preferably made of urethane or other suitable resilient material, and a rivet 320 preferably made of steel.
Washer 318 is placed in position in circular recess 322 cut out from the upper right end portion of hold open arm 276 and around circular opening 308. The right half 324 of recess 322 is formed with inner shoulder 326 and outer shoulder 328 but the left half 330 of recess 322 is formed with only an inner shoulder 332, as shown in
The difference in the size of the right half 324 and left half 328 is needed to allow a portion of washer 318 to be exposed due to the slot or open portion 316 of the flange 314 of washer cover 312 when washer cover 312 is placed in position over washer 318. Washer cover 312 and washer 318 are maintained in position by steel rivet 320 inserted in circular opening 313 of washer cover 312 and in circular opening 308 and coining the bottom portion of steel rivet 320 to hold washer cover 312 and washer 318 firmly in position.
The top 334 of the head 336 of rivet 320 is in alignment with the top surface 338 of washer cover 312 by providing head 336 with an inwardly tapered body portion (not shown) which is congruent with the outwardly tapered portion 339 of the top 342 of washer cover 312. A 5/16th inch slotted head screw 344 is located within the slot 282 of hold open arm 276 and screwed into the bottom surface of the top of frame 346 with threads at its lower half.
Screw 344 has a circular smooth upper portion of its shank 348 for contacting the exposed portion of washer 318. A preferred application of screw 344 is to thread it into a flared and threaded nut 345 installed in a circular recess 347 in bottom surface 349 of the top of frame 346, as shown in
Jog 281 formed at the left portion of hold open arm 276 redirects the left portion of hold open arm 276 downwards to allow attachment of it to pivot 300.
The location of cavity 284 is critical and its position is determined by a phantom straight line 293 drawn from center 354 of circular opening 308 and of rivet 320 through point 287 to intersect a phantom straight line drawn from the center 356 of circular opening 302 of hold open arm 276 through the center 352 of cavity 284 and terminating tangentially at the circumference 358 of washer 318 as shown in
Point 287 is formed at the junction of the right end of bottom 292 of slot 282 with the left end of inner surface 283 of cavity 284 opposite to the exposed portion of washer 318 as shown in
The position of the exposed portion of washer 318 is determined by phantom straight line 293 drawn from the center 354 of circular opening 308 and of rivet 320 through point 287, bisecting the exposed portion of washer 318 and the open portion or slot 316 of flange 314 of washer cover 312.
Diameter 360 of shank 348 of screw 344 is in a preferred ratio of 0.45 to 1.00 with the diameter 362 of washer 318. Thus, a preferred actual size is shank diameter 360 being 280/1000 of an inch and washer diameter 362 being 625/1000 of an inch. These sizes may be varied plus or minus 2% so long as the preferred ratio is maintained.
The distance from the center of the exposed portion of washer 318 to point 287 formed at the upper end of inner surface 283 of cavity 284 opposite to the exposed portion of washer 318 is preferably 220/1000 of an inch but may vary plus or minus 5% without adversely affecting the operation of the semi-automated door held open and release mechanism 20. The distance from point 287 to the center of the top and bottom edges of slot or opening 316 of flange 314 along phantom straight line 293 is preferably 300/1000 of an inch but may vary plus or minus 5% without adversely affecting the operation of the semi-automated door held open and release mechanism 20.
The diameter 364 of cavity 284 is preferably 280/1000 of an inch but may vary plus or minus 5% without adversely affecting the operation of the door held open and release mechanism 20.
The diameter of flange 314 is preferably 670/1000 of an inch and can vary plus or minus 2%. The width of slot or open portion 316 of flange 314 is preferably 76/1000 of an inch and can vary plus or minus 2%. The diameter of washer 318 is preferably 625/1000 of an inch and can vary plus or minus 2%. The exposed portion of washer 318 can be compressed or deformed to reduce the diameter of washer 318 at the point of compression by 60/1000 of an inch or about 10% of the original or undeformed diameter of washer 318. The center of the exposed portion of washer 318 overhangs cavity 284 to the extent of 80/1000 of an inch measured along phantom straight line 283 beginning from the top and bottom edges of the slot or open portion 316 of flange 314.
The invention is assembled on door 298 and frame 346 in the following way.
Torque housing assembly 19 is installed at the top surface 365 of the bottom 366 of the hinge side of frame 346 by inserting floating locking pin 96 into a circular locking hole not shown having slots at either end (not shown) formed in top surface 365 of the left side of frame 346 and by securing torque housing 19 with installation screw 100 screwed in threaded hole (not shown) in top surface 365 of bottom 366. The slots in circular locking hole (not shown) allow for movement of torque housing 19 to the left for a left hand door, or to the right for a right hand door.
Door leveling assembly 18 is installed in bottom surface 372 of top 374 of the hinge side of frame 346 by placing the door leveling assembly 18 in position with the floating locking pin 234 over a circular opening (not shown) having locking slots at either end (not shown) formed in bottom surface 372 of top 374 of frame 346 and then inserting floating locking pin 234 into circular opening (not shown) and securing door leveling assembly 18 with installation screw 274 screwed in a threaded hole (not shown) in bottom surface 372 of the top 374 of the hinge side of frame 346.
The bottom surface 380 of door 298 has square opening 382 which leads to internal square bore 384 extending upwards to square opening 383 in top surface 294 of top 296 of door 298 on the hinge side of door 298.
Torque rod assembly 14 is installed inside bore 384 by inserting the torque rod assembly 14 in square opening 382 and bore 384, oriented so that the top end 132 of torque rod 118 goes into bore 384 first along with the smaller tapered portion of torque rod bushing 138. The insertion of torque rod assembly 14 continues inside bore 384 until the increasing outer circumference of torque rod bushing 138 at the top surface of flange 147 of base 146 of torque rod bushing 138 forms a press fit with square opening 382. The press fit holds torque rod assembly 14 firmly in position.
Hinge pin assembly 16 is installed in door 298 on the hinge side of door 298 by inserting it in square opening 383 in the top surface 294 of the top 296 of door 298 and in bore 384, oriented so that the reduced circumference of elongated inner shank portion 178 of hinge pin 176 goes into bore 384 first along with the smaller tapered portion of hinge pin housing 160. The insertion of hinge pin assembly 16 continues inside bore 384 until the increasing outer circumference of the taper of hinge pin housing 160 at the circular flange 170 of hinge pin housing 160 forms a press fit with square opening 383. The press fit holds hinge pin assembly 16 firmly in position so that about 75% of hinge pin 176 remains inside hinge pin housing 160 and 25% outside.
After the press fit is accomplished, circular flange 170 rests on top surface 294 of the top 296 of door 298.
Before any assembly of components is installed in door 298, pivot 300 of door held open and release mechanism 20 is initially installed on top surface 294 of top 296 of door 298 by screwing the threaded and hexagonally formed lower portion (not shown) of pivot 300 into threaded bore (not shown) of top 296 just far enough to leave room to install the left portion with a downward oriented jog 281 of hold open arm 276, using circular opening 302 on pivot 300 below groove 301 of pivot 300, so that hold open arm 276 rests on the top surface of hexagonal formed lower portion 305 of pivot 300. Threaded bore (not shown) is located a suitable distance in the opposite direction from the hinge side of door 298, preferably a distance of about 15% of the length of the top of a door.
Hold open arm 276 is then placed in a position over pivot 300 such that circular opening 302 permits insertion of hold open arm 276 over the top of pivot 300 to rest on the top surface of hexagonal formed lower portion 305 of pivot 300. Retaining ring 306 is then snapped into groove 301, thereby securing pivot 300 in position with hold open arm 276.
Frame 346 is conventionally installed in the opening of a cabinet or case (not shown). Door 298 is then installed in frame 346 by inserting the hexagonally shaped bottom portion of torque rod nut 122 into torque gear 30.
Hinge pin 176 is then depressed and aligned with door leveling assembly 18 by aligning hinge pin 176 with slide plate 204 and aligning the outer shank portion 182 of hinge pin 176 with slot 270 of bottom cover plate 264 and with circular opening 244 of slide plate 204. Hinge pin 176 is then released and due to it being spring loaded, outer shank portion 182 engages circular opening 244 of slide plate 204 and goes through slot 270 of top cover plate 262 as shown in
Door 298 is now completely installed.
Next, semi-automated door held open and release mechanism 20 is installed in frame 346 by opening door 298 to access longitudinal slot 282. Screw 344 is inserted into slot 282 and threaded into nut 345 installed in circular recess 347 in the bottom surface 372 of the top 374 of frame 346 so that the circular smooth upper portion of shank 348 of screw 344 remains exposed.
Door 298 is torqued by inserting a torque tool 80, which can be a piece of square rod, a screwdriver, Allan wrench of suitable size, or any suitable tool having the capability of in the direction of door handle 390, depending on whether door 298 is a left opening door or right opening door. A minimum of three rotations is recommended to get proper door torquing so that door 298 may be pretorqued to keep door 298 in a closed position and to close door 298 when it is about 3 to 6 inches open.
As torque tool 80 turns torque cam 34, torque cam 34 turns around cam pivot pin 74, and torque cam 34 moves gear actuating lever 86, thereby engaging teeth 68 of torque gear 30. As torque gear turns one tooth at a time by gear actuating lever 86, pawl arm 50 locks torque gear 30 immediately after gear actuating lever 86 has rotated one tooth of teeth 68, automatically due to pawl arm 50 being spring loaded. Only one tooth of teeth 68 can be rotated at a time, which provides precise and accurate control of the torquing process.
When torque tool 80 is removed, gear actuating lever 86 returns to a relaxed position due to being preloaded by springs 44.
If adjustment of the door 298 is needed, door 298 may be adjusted to a level position in a left or right direction by turning adjustment screw 212 in the desired direction, resulting in lateral movement of hinge pin 176. This operation is easier to accomplish than prior art devices because it is carried out at the top of the door, which provides a more convenient access for the operator than prior art devices that are limited to access to the bottom of the door for leveling purposes.
Further, adjustment of the door 298 according to the present invention is accomplished without opening the door, which remains in closed position during the adjustment. In contrast, the prior art known to applicants requires opening of the door during the adjustment process as well as operating at the bottom of the door, making the adjustment process more difficult and more time consuming.
When door 298 is manually opened to 90 degrees and is desired to be held open at 90 degrees, the semi-automated door held open and release mechanism 20 is activated as follows.
The opening of door 298 causes the main torquing of door 298 due to the twisting of torque rod 118. The opening of door 298 causes turning of square torque rod block 152 which is firmly held in position inside internal square bore 384 of door 298. The square central bore 154 of torque rod block 152 keeps the portion of torque rod 118 inside torque rod block 152 firmly held in its original position inside torque rod block 152 while door 298 is opening.
Meanwhile, the portion of lower end 120 of torque rod 118 inserted into square bore 127 of torque rod nut 122 is maintained in position by engagement of lower portion 128 of torque rod nut 122 in torque gear 30. Since the top end and the bottom end of torque rod 118 are both fixed and maintained in position, the turning of door 298 twists the middle portion of torque rod 118, thereby producing the main torque on door 298.
Although lower portion 128 of torque nut 122 is preferably hexagonal in shape and the interior of torque gear 30 is preferably formed in a 12 point internal drive or recess to produce a positive engagement of these component parts to prevent torque nut 122 from turning independently from torque gear 30, various alternative forms are possible to achieve positive engagement. Lower portion 128 and the interior of torque gear 30 each could be square, triangular, or any shape or combination of shapes that would have the effect of producing positive engagement of them when assembled.
As door 298 is being opened, hold open arm 276 pivotally moves from its resting position with the door closed as shown in
The actual size of opening 291 of cavity 284, 300/1000 of an inch, is greater than the diameter 280/1000 of an inch of the smooth upper shank 348 of screw 344 but is made slightly smaller, 220/1000 of an inch due to the exposed portion of washer 318 opposite inner surface 283 of cavity 284 and bisected by phantom straight line 293 between point 287 and center 354 as shown in
At the 90 degree open position of door 298, hold open arm 276 has completed its pivoting and has brought the location of screw 344 past opening 291 and into engagement with the inner surface 283 of cavity 284 so that screw 344 is completely enclosed in cavity 284 as shown in
While screw 344 rests, the exposed portion of washer 318 that was deformed by screw 344 to a deformation of 60/1000 of an inch changes to a deformation of 20/1000 of an inch thereby returning opening 291 to a smaller open width size while the exposed portion of washer 318 maintains contact with the smooth upper shaft 348 of screw 344, thus serving to help maintain engagement of smooth upper shaft 348 with the inner surface 283 of cavity 284 and the resting position of screw 344 as well as the extended position of hold open arm 276 as shown in
The material of which washer 318 is made must have sufficient resilience to allow deformation of the exposed portion of washer 318 to a deformation of 60/1000 of an inch which widens opening 291 sufficiently to pass screw 344 through opening 291 and then to allow its return from its deformed condition of 60/1000 of an inch to a deformed condition of 20/1000 of an inch and then to its original undeformed condition. It must also have enough resistance or strength to maintain its deformed condition of 20/1000 by engagement with the smooth upper shank 348 of screw 344 while screw 344 is in its resting position. A preferred material for washer 318 is a urethane plastic having a Durometer value hardness of 75D plus or minus 5D, a tensile strength of 62 Mpa(9,000 psi) plus or minus 5%, elasticity property of Mpa 32(4,650 psi) plus or minus 5%, a compression set using Method A(ASTM D395) measured at 9.3 Mpa(1,350 psi) of 10% plus or minus 5%, and resilience property using Rebound(Bashore) of 45% plus or minus 5%.
The engagement of the smooth upper shank 348 of screw 344 against the inner surface of cavity 284 is mainly due to the torque pressure produced from the opening of door 298. The exposed portion of washer 318 assists the engagement of the smooth upper shank 348 of screw 344 against the inner surface 283 of cavity 284 by preventing the existing torque on door 298 from allowing the smooth upper shank 348 of screw 344 to re-deform the exposed portion of washer 318 which would restore the actual width of opening 291 and release screw 344 from its resting position. Since the actual width of opening 291 has a diameter larger than the smooth upper shank 348 of screw 344, restoration of the actual width of opening 291 would release screw 344 from its resting position inside cavity 284 by allowing screw 344 to pass back through opening 291 on its way to its starting position inside slot 282 as door holding arm 276 pivots in returning to its closed position due to the existing torque on door 298 closing door 298.
Applicants estimate that about 90% of the holding of screw 344 in its resting position in cavity 284 comes from its engagement with the inner surface 283 of cavity 284 opposite the exposed portion of washer 318. In contrast, the exposed portion of washer 318 in its original undeformed condition contributes about 10% of the holding of screw 344 in its resting position.
So long as screw 344 remains in its resting position, door 298 is held open to 90 degrees. Conventional door holding open devices are limited to 87 degrees or less of door opening and holding. While screw 344 is in its resting position, screw 344 is subjected continually to about 2½ pounds of force, plus or minus ½ a pound, due to the torque created by opening door 298 using its handle to a 90 degree open position. The amount of torque on door 298 created by pre-torquing is so slight as to have no effect on the hold open process.
This force of 2½ pounds is insufficient to deform the exposed portion of washer 318 sufficiently to restore the original size of opening 291 and allow disengagement of screw 344 from the inner surface 283 of cavity 284 so that screw 344 may exit cavity 284.
Held open door 298 may be then closed by a person applying manual slight pressure of at least 5 pounds of force, plus or minus ½ a pound, inwardly on door handle 390 or anywhere inwardly on door 298, thereby activating the semi-automated operation of the hold open and release mechanism 20 to close door 298.
The inward pressure on door 298 produces inward movement of hold open arm 276 initially that causes inner surface 283 of cavity 284 to press against the smooth upper shank 348 of screw 344 which in turn presses against and deforms the exposed portion of washer 318 sufficiently to open the path through opening 291 to its original width and to release engagement of the smooth portion of screw 344 with the inner surface 283 of cavity 284 and allow screw 344 to pass back through opening 291. Since the release of screw 344 also releases door 298 immediately from its 90 degree held open position, the existing torque on door 298 immediately brings door 298 back to its closed position.
When screw 344 is released from cavity 284, hold open arm 276 begins to pivot back towards its original position and door 298 begins to close. The release of screw 344 allows unwinding of the twisted torqued portion of torque rod 118, which applies closing torque to door 298 that returns door 298 to a completely closed position.
For applications of the invention where an air tight seal of the door in its frame is required, a rubber or other elastomeric type gasket may be attached to the interior perimeter of door 298 to form an airtight seal when door 298 is closed as well as to other doors employing the invention.
Although the invention has been described in detail with reference to the accompanying drawings illustrating preferred embodiments of the invention, it is understood that numerous changes may be made in the details of construction and arrangement of parts without departing from the spirit and scope of the invention as hereinafter claimed.
| Number | Name | Date | Kind |
|---|---|---|---|
| 262005 | Clark et al. | Aug 1882 | A |
| 317147 | Krumscheid | May 1885 | A |
| 998692 | Keene et al. | Jul 1911 | A |
| 1334563 | Shelton | Mar 1920 | A |
| 1766011 | Byrd | Jun 1930 | A |
| 3251088 | Boundy | May 1966 | A |
| 3285324 | Stein et al. | Nov 1966 | A |
| 3339225 | Booth | Sep 1967 | A |
| 3365747 | Barroero | Jan 1968 | A |
| 3507074 | Gallegos | Apr 1970 | A |
| 3662429 | Johnson et al. | May 1972 | A |
| 3683453 | McLeland et al. | Aug 1972 | A |
| 3702491 | Pelletiere | Nov 1972 | A |
| 3866658 | Smith | Feb 1975 | A |
| 3867790 | Frank | Feb 1975 | A |
| 3932913 | Johnson | Jan 1976 | A |
| 4064590 | Smith | Dec 1977 | A |
| 4106876 | Tregoning | Aug 1978 | A |
| 4547929 | Lew et al. | Oct 1985 | A |
| 4692963 | Barroero | Sep 1987 | A |
| 4696078 | Stromquist | Sep 1987 | A |
| 4800678 | Loos | Jan 1989 | A |
| 4905347 | Wroth | Mar 1990 | A |
| 4953259 | Frye et al. | Sep 1990 | A |
| 5050270 | Burgei et al. | Sep 1991 | A |
| 5321870 | Wada et al. | Jun 1994 | A |
| 5333355 | Beswick et al. | Aug 1994 | A |
| 5490305 | Domingo Ribot | Feb 1996 | A |
| 5495639 | Wartian | Mar 1996 | A |
| 5568673 | Ryczek | Oct 1996 | A |
| 5571493 | Fulmer et al. | Nov 1996 | A |
| 5606773 | Shappell | Mar 1997 | A |
| 6176040 | Sugihara | Jan 2001 | B1 |
| 6205616 | Hwang | Mar 2001 | B1 |
