Motorized door assembly with safety features for heated cabinet

Abstract

Motorized door assemblies having a door pivoting about a pivot axis extending across opposing jambs. In one aspect, the assembly includes a motor assembly having a motor, drive gears, slip clutch, and driven shaft connected to the door to pivot it about the pivot axis. The slip clutch includes a clutch plate slideable along the driven shaft, a drive plate driven by the motor via the drive gears, and a clutch spring urging the clutch plate into engagement with the drive plate, where the clutch and drive plates have profiled and counter-profiled faces. In another aspect, a break beam emitter and receiver are mounted to respective ones of the opposing jambs along a beam axis extending parallel to the pivot axis and proximate to an edge of the door opposite the pivot axis. Interruption of a light beam projected therebetween alters operation of a motor assembly.

Claims

1. A motorized door assembly comprising: a door positioned between opposing jambs of a door frame and movable between an open position and a closed position, wherein the door is pivotable about a pivot axis extending across the opposing jambs; and a motor assembly mounted adjacent to the door, the motor assembly comprising: an electric motor; a plurality of drive gears; a slip clutch; and a driven shaft operably connected to the door to pivot the door about the pivot axis; wherein the slip clutch includes a clutch plate that is slideable along the driven shaft, a drive plate driven by the electric motor via the drive gears, and a clutch spring urging the clutch plate into engagement with the drive plate, the clutch plate having a profiled face and the drive plate having a counter-profiled face for engagement with the profiled face.

2. The motorized door assembly of claim 1 wherein the motor assembly is mounted to one of the opposing jambs, opposite the door of the motorized door assembly.

3. The motorized door assembly of claim 2 wherein the motor assembly includes a bushing seated within the one of the opposing jambs, the bushing being coaxially mounted around the driven shaft.

4. The motorized door assembly of claim 3 wherein the clutch spring seats against the bushing, and the bushing is retained with the one of the opposing jambs by a bushing retainer which at least partially encircles the bushing.

5. The motorized door assembly of claim 1 wherein the electric motor is oriented perpendicular to the pivot axis, and the plurality of drive gears include a right angle gearbox.

6. The motorized door assembly of claim 1, wherein the driven shaft and the pivot axis are coaxial.

7. The motorized door assembly of claim 1, wherein the drive plate is integral with a drive gear.

8. The motorized door assembly of claim 1, wherein one of the clutch plate and the drive plate includes a regular pattern of convex rounded projections, and the other one of the clutch plate and the drive plate includes a corresponding pattern of concave rounded dimples.

9. A motorized door assembly comprising: a door positioned between opposing jambs of a door frame and movable between an open position and a closed position, wherein the door is pivotable about a pivot axis extending across the opposing jambs; a motor assembly operably connected to the door to pivot the door about the pivot axis; a control board controlling the motor assembly; a first break beam emitter mounted to one of the opposing jambs and operatively connected to the control board; and a first break beam receiver mounted to the other one of the opposing jambs and operatively connected to the control board; wherein the first break beam emitter and first break beam receiver are disposed along a beam axis extending parallel to the pivot axis and proximate to an edge of the door opposite the pivot axis, and wherein interruption of a light beam projected along the beam axis between the first break beam emitter and the first break beam receiver alters operation of the motor assembly.

10. The motorized door assembly of claim 9 wherein the first break beam emitter comprises an LED and a light pipe disposed over an emitting surface of the LED, with the light pipe extending through the one of the opposing jambs.

11. The motorized door assembly of claim 10 wherein the one of the opposing jambs is structurally hollow.

12. The motorized door assembly of claim 11 wherein the one of the opposing jambs is filled with an insulation.

13. The motorized door assembly of claim 9 wherein the second break beam emitter comprises a photodiode and a light pipe disposed over a receiving surface of the photodiode with the light pipe extending through the other one of the opposing jambs.

14. The motorized door assembly of claim 13 wherein the other one of the opposing jambs is structurally hollow.

15. The motorized door assembly of claim 9 wherein upon interruption of the light beam the control board stops operation of the motor assembly.

16. The motorized door assembly of claim 9 wherein upon interruption of the light beam the control board, when the motor assembly is closing the door, reverses operation to open the door.

17. The motorized door assembly of claim 9, further comprising: a second break beam emitter mounted to one of the opposing jambs and operatively connected to the same or another such control board; and a second break beam receiver mounted to the other one of the opposing jambs and operatively connected to the same or the other such control board; wherein the second break beam emitter and second break beam receiver are disposed along another beam axis extending parallel to the pivot axis and proximate to an edge of the door adjacent the pivot axis, and wherein interruption of another light beam projected along the other beam axis between the second break beam emitter and the second break beam receiver alters operation of the motor assembly.

18. The motorized door assembly of claim 17 wherein upon interruption of the other light beam the operatively connected one of the same or another such control board stops operation of the motor assembly.

19. The motorized door assembly of claim 17 wherein upon interruption of the other light beam operatively connected one of the same or other such control board, when the motor assembly is opening the door, reverses operation to close the door.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIGS. 1A and 1B are front views of a heated cabinet including a motorized door assembly, with each view offset to one side to show the jamb of the other side of the door frame.

(2) FIG. 2 is a perspective view of a motor assembly mounted between the right side jamb of FIGS. 1A and 1B and the exterior of a cabinet (not shown).

(3) FIGS. 3A and 3B are perspective views of the motor assembly with and without a cooperating bushing retainer, respectively, and without and with a gear assembly retaining plate, respectively.

(4) FIG. 4 is a perspective view of the opposite side of the motor assembly shown in FIG. 3A.

(5) FIG. 5 is a perspective view of the driven portion of the slip clutch element.

(6) FIG. 6 is a perspective view of a face of a drive portion of the slip clutch element.

(7) FIG. 7 is a schematic view of a break beam emitter and break beam receiver positioned across a (partial) door frame and upon/with the jambs of the frame.

DETAILED DESCRIPTION

(8) As shown in FIGS. 1A and 1B, the devices disclosed herein are elements of a motorized door assembly including a door 100 that is movable between an open position and a closed position within a door frame 110. The door 100 is positioned between opposing jambs 120a and 120b of the door frame 110, which may be elements of a door assembly module or elements of a cabinet in which the door and other elements of the motorized door assembly are installed. The door may be positioned between a head and a sill (including, for the purposes of this application, any fixed rails or other structures separating doors within a vertical stack of doors), between a head and a lower door, between an upper door and a sill, or between upper and lower doors in a vertical stack of doors, depending upon the arrangement and number of compartments provided in a particular cabinet. The door 100 pivots about an axis 130, such as the illustrated axis adjacent to the top of the door 100 or, alternately, an axis adjacent to the bottom of the door. Consequently, the door 100 creates at least two potential pinch points 132 and 134. A first pinch point 132 is created along the edge of the door opposite the pivot axis 130 where closure of the door may potentially capture an extremity such as a finger, hand, or forearm of a customer reaching within the enclosed space of a compartment. A second pinch point 134 is created near the edge of the door adjacent to the pivot axis 130 where opening of the door may potentially capture an extremity such as the finger of a customer resting their hand against the door frame between the edge or external face of the door and an adjacent head, sill, or other door.

(9) In a first aspect, FIG. 2 shows a motor assembly 200 mounted to a jamb 120, specifically the right side jamb 120b of FIGS. 1A and 1B opposite the door 100. It will be appreciated that the aspect is not restricted to this specific, illustrated mounting. The motor assembly 200 includes an electric motor 210, a plurality of drive gears 220, a driven shaft 230, and a slip clutch 240 (the driven shaft 230 and slip clutch 240 being shown in FIGS. 3B, and 4-6). The electric motor is preferably oriented perpendicular to the pivot axis 130 of the door 100, allowing the motor assembly 200 to have relatively low profile or width and thus allow for a relatively narrow cabinet side wall, with the plurality of drive gears 220 including a so-called right angle gearbox or 90 degree gearbox 222 (best shown in FIG. 4). In the illustrated construction the driven shaft 230 and pivot axis 130 are coaxial, however it will be appreciated that the driven shaft 230 may connect to a driven gear assembly, multi-point linkage, or other mechanism disposed on the door side of the jamb 120 for pivoting the door 100 about a non-coaxial pivot axis 130.

(10) FIG. 3A shows the motor assembly 200 in isolation. The motor assembly may further include a bushing 250 which seats within the jamb 120 and blocks convective heat transfer through the jamb 120 from the heated compartment into the motor assembly. The bushing 250 may be retained within the jamb 120 by a bushing retainer 260 which at least partially encircles the bushing. As shown in FIG. 3B, the bushing 250 is otherwise coaxially mounted around the driven shaft 230, and may provide a seat 252 for a clutch spring 242 of the slip clutch. In motor assemblies that lack a bushing 250, the driven shaft 230 would extend through a bare aperture in the jamb 120 to the door 100 or to any driven gear assembly, multi-point linkage, or other mechanism for pivoting that is provided. In motor assemblies that lack a bushing 250, the jamb 120 would function as or provide a seat for clutch spring 242.

(11) FIG. 4 shows the other side of the motor assembly 200 shown in FIGS. 3A and 3B. In addition to the clutch spring 242, the slip clutch 240 includes a clutch plate 244 that is slidable along the driven shaft 230 and has profiled clutch plate face (shown in FIG. 5) and a drive plate 246 (shown in FIG. 6) that has a counter-profiled drive plate face. The drive plate may be a separate part mounted on a drive shaft 248 driven by the plurality of drive gears 220, but may advantageously be integral with a drive gear 224. FIG. 6 shows an example of such a drive gear. One of the clutch and drive plate faces, e.g. the profiled clutch plate face, may include regular pattern of convex rounded projections 245 and the other of the clutch and drive plate faces, e.g., the counter-profiled drive plate face, may include a corresponding pattern of concave rounded dimples 247. The spring force of the clutch spring 242 and profile of the faces of the clutch and drive plates 244, 246 define the maximum torque that may be transmitted through the slip clutch, with torque in excess of the maximum causing the profiled clutch face plate to ride out of the counter-profiled drive plate face and break rotational engagement of the driven shaft 230 with the plurality of drive gears 220 (i.e., drive shaft 248 or drive gear 224). Accordingly, proper definition of the maximum torque by selection of the spring force and profiles of each face can mitigate a risk of pinch injury at pinch point 132 upon closing of door 100. Definition of the maximum torque by selection of the spring force and profiles of each face can also mitigate a risk of pinch injury at pinch point 134 upon opening of door 100, but may require a lower maximum torque since pinch point will be closer to the pivot axis 130 and can likely exert greater force at a particular level of torque.

(12) In a second aspect, FIG. 7 illustrates a break beam device 300 bracketing a door frame and, specifically, mutually opposing jambs 120a and 120b. With reference to FIG. 1, a first break beam device 300 may be positioned at a door-opening side of door frame jambs 120a and 120b proximate to, but not adjoining, the door's closed position. Thus, a break beam emitter 310a and break beam receiver 320a may be disposed along a beam axis parallel to the pivot axis 130 and proximate the edge of door 100 opposite the pivot axis 130. The emitter 310a and receiver 320a are operatively connected to a control board 330 (shown in FIG. 2), and interruption of a light beam projected along the beam axis between the emitter 310a and receiver 320a alters a signal of the operative connection (e.g., interrupts a signal generated by the receiver upon receipt of the emitted beam). The beam axis thus serves to detect intrusion into the first pinch point 132, where closure of the door may potentially capture an extremity such as a finger, hand, or forearm of a customer reaching within the enclosed space of a compartment. Optionally, a second break beam device 300 may be positioned at a door-opening side of door frame jambs 120a and 120b proximate to, but not adjoining, the door's open position. Thus, a break beam emitter 310b and break beam receiver 320b may be disposed along a beam axis parallel to the pivot axis 130 and proximate the edge of door 100 adjacent to the pivot axis 130. The emitter 310b and receiver 320b may be operatively connected to the same control board 330, and interruption of a light beam projected along the beam axis between the emitter 310b and receiver 320b alters a signal of the operative connection (e.g., interrupts a signal generated by the receiver 320b upon receipt of the emitted beam from emitter 320a).

(13) Altering the signal of the operative connection so as to indicate an interruption of the light beam may cause the control board 300 to halt operation of the motor assembly 200. Alternately, altering the signal of the operative connection so as to indicate an interruption of the light beam may cause the control board 300 reverse operation of the motor assembly 200. Any reversal of operation may be dependent upon the operating state of the motor assembly 200. For example, when the motor assembly is closing the door 100, but not opening the door 100, altering the signal of the operative connection for the device 310a/320a may trigger the control board 330 to open the door 100. For further example, when the motor assembly is opening the door 100, but not closing the door 100, altering the signal of the operative connection for the device 310b/320b may trigger the control board 330 to close the door 100.

(14) Returning to FIG. 7, a break beam emitter 310 may comprise an LED 312, supporting electronics 314 (such as an LED driver, diagnostic circuitry, and the like) and a light pipe 316 disposed over the emitting surface of the LED 312. The light pipe may comprise a linear or curvilinear segment of transparent plastic such as polycarbonate, or of a transparent glass such as silica glass. The light pipe may be a segment of fiber optic cabling. As shown in FIG. 6, the emitter 310 is mounted with the light pipe 316 extending through the jamb 120, which is preferably hollow to reduce conductive heat transfer and even more preferably filled with an insulation to reduce convective transfer from the heated compartment. The light pipe 316 and jamb 120 thereby protect the LED 312 and supporting electronics 314 from most conductive and convective heat transfer from the compartment.

(15) A break beam receiver 320 may comprise a photodiode 322, supporting electronics 324 (such as an amplifier, diagnostic circuitry, and the like) and a light pipe 326 disposed over the receiving surface of the photodiode 322. The light pipe may comprise a linear or curvilinear segment of one of the above-described materials, but need not be made from the same material. As shown in FIG. 7, the receiver 320 is mounted with the light pipe 326 extending through the opposing jamb 120, which again is preferably hollow to reduce conductive heat transfer and even more preferably filled with an insulation to reduce convective transfer from the heated compartment. The light pipe 326 and jamb 120 thereby protect the photodiode 322 and supporting electronics 324 from most conductive and convective heat transfer from the compartment.

(16) Although the invention is shown and described with respect to certain aspects and embodiments, it should be clear that modifications will occur to those skilled in the art upon reading and understanding the specification, and the present invention includes all such modifications.