The present invention relates generally to sliding door systems, and more particularly to a telescoping door with a swing clear hinge to facilitate breakout functionality.
Sliding door systems are used as entryways and exits to intensive care units (“ICU”) and critical care units in hospitals. In particular, patient rooms in these units are equipped with large manual sliding doors. The doors are often glass to allow medical professionals a view of the patients that need round-the-clock monitoring. Because stretchers, wheelchairs, and other medical equipment are frequently moved in and out of the ICU, sliding doors are often employed. In addition, an intensive care unit has certain environmental standards that should be maintained to ensure a healthy environment for patient recovery. For example, in certain ICUs, the sliding doors do not have tracks. For example, many intensive care units have sliding doors that are supported without a bottom track that is fixed to the floor. In these types of doors, the upper track provides the primary support and guides the linear motion of the door as it slides to open and close.
Another concern with sliding doors is that they have the ability to breakout. That is, they should have the ability to rotate off the track, so that a pushing force will cause the door to swing open. The terms “breakout,” “breakaway,” and “swingout” refer to the ability of the door to be opened by rotating the panels of the door off of the track, as opposed to the normal sliding motion of the panels. This feature may be employed in an emergency and should be able to be accomplished without requiring detailed knowledge of the workings of the door or specific steps that must be followed to allow emergency egress through a telescoping sliding door that has been broken away.
A telescoping door system includes a header that spans across a doorway. A trailing jamb and a lead jamb disposed a clear opening distance from the trailing jamb defines a clear opening of the doorway. A sidelite panel is coupled to the trailing jamb by at least one swing clear hinge. A slow slide panel and a fast slide panel move linearly within the header. The slow and fast slide panels are configured to create a first-sized opening when positioned in the header. The sidelite panel, the slow slide panel, and the fast slide panel are configured to pivot out of the header in a breakout position such that a trailing rail of the sidelite panel is disposed at least partially outside the clear opening and in front of the trailing jamb.
The swing clear hinge of the telescoping door system allows the pivot axes of the slow and fast slide panels to be positioned closer to the trailing door jamb than in conventional telescoping door systems, which allows for a larger slide opening. Also, the swing clear hinge allows for a larger pivot opening than in conventional telescoping door systems when the sidelite and the slide panel or panels are pivoted out of the header in a breakout position.
Another embodiment may include a guide pin support system. The guide pin support system may include: a first support plate; a second support plate pivotally attached to the first support plate; a first guide pin supported by the first support plate; a second guide pin supported by the second support plate and the second guide pin pivotable with respect to the first guide pin.
Another embodiment may include a guide pin support system including: a door system having a first panel, a second panel, and a third panel; a second panel track mounted to a bottom of the second panel; a third panel track mounted to a bottom of the third panel; a guide pin support system attached to the second panel, the guide pin support system having two guide pins, both configured to slide in the third panel track wherein one of the guide pins in the guide pin support assembly is configured to move in a pivoting motion with respect to the other guide pin in the second support assembly.
Still other embodiments have a guide pin support system including: a door system having a first panel, a second panel, and a third panel; a second panel track mounted to a bottom of the second panel; a third panel track mounted to a bottom of the third panel; a first guide pin support system attached to the first panel, the first guide pin support system having a first guide pin configured to slide in the second panel track; a second guide pin support system attached to the second panel, the second guide pin support system having two guide pins, both configured to slide in the third panel track wherein one of the guide pins in the second guide pin support assembly is configured to move in a pivoting motion with respect to the other guide pin in the second support assembly.
Other technical advantages will be readily apparent to one of ordinary skill in the art from the following figures, descriptions, and claims. Moreover, while specific advantages have been described above, various embodiments may include all, some, or none of the enumerated advantages.
A more complete understanding of the present invention may be acquired by reference to the following Detailed Description when taken in conjunction with the accompanying Drawings wherein:
The telescoping door system 10 may include a floor mounted track that helps to guide the linear motion of the slide panels 16, 18, or according to some embodiments, the floor mounted track may be omitted. In certain healthcare facilities, such as an intensive care unit in a hospital, it may be undesirable to have a floor track.
The sidelite 14 includes a top rail 22, a bottom rail 24, a lead rail 26, a trailing rail 28, and a mid-rail 30. An upper pane of glass 32 is framed by a portion of the lead rail 26, the trailing rail 28, the top rail 22, and the mid-rail 30. A lower pane of glass 34 is framed by portions of the lead rail 26, the trailing rail 28, the bottom rail 24, and the mid-rail 30. The slow slide panel 16 similarly includes upper and lower glass panes 36, 38 framed by a top rail 40, a bottom rail 42, a lead rail 44, a trailing rail 46, and a mid-rail 48. The fast slide panel 18 also includes upper glass pane 50 and lower glass pane 52 framed by an upper rail 54, a bottom rail 56, a lead rail 58, a trailing rail 60, and a mid-rail 62. The rails may be made of any suitable material. However, in certain embodiments a light weight material, such as aluminum may be used for the various rails of the door system 10. According to an alternate embodiment, each panel may have only one glass pane or more than two glass panes.
A user moves the telescoping door system 10 from a fully open position to a fully closed position by manually applying a force to a handle 64 disposed on the lead rail 58 of the fast slide panel 18 to displace the fast slide panel 18 toward a lead jamb 66. The fast slide panel 18 is linearly displaced a certain distance, and it catches the slow slide panel 16 and displaces it toward the lead jamb 66 until the fast slide panel 18 reaches the lead jamb 66. The fast slide panel 18 may be positively latched to maintain the door system 10 in the fully closed position. To move the telescoping door system 10 from the fully closed position to the fully open position, the reverse occurs when the user applies the force to the fast slide panel 18 to linearly displace it toward the trailing jamb 13 (also referred to herein as a pivot jamb), and after the fast slide panel 18 is linearly displaced a certain distance, it catches the trailing end 17 of the slow slide panel 16 and displaces it toward the trailing jamb 13. Alternatively, the linear motion of the slide panels 16, 18 may be driven by an operator for automatic sliding movement of the panels 16, 18.
The telescoping door system 10 may also be one half of dual telescoping door system 10 where a second multi-panel telescoping door is disposed opposite the telescoping door system 10 such that a fully closed position has the two telescoping door systems 10 meeting each other in a center of the door frame or opening.
The teachings of the present disclosure are not limited to a three-panel telescoping door system, but rather may be also be employed with a dual-panel slide/swing door system or a door system employing more than three panels.
In this breakout position, the panels cannot be linearly moved with respect to each other to close the slide opening 72. The breakout opening 74 is significantly larger than the slide opening 72. In a hospital, the slide opening 72 is used for ingress and egress of typical foot traffic, but if a bed or other large equipment needs to be moved through the door system 10, the panels 14, 16, 18 may be pivoted to create the larger breakout opening 74.
According to some embodiments, the sidelite panel 14 includes a latch assembly that enable deployment and retraction of flush bolt. The flush bolt is retracted from the header to allow the sidelite panel 14 to pivot out of the door frame. A biasing member, such as a spring, may bias the flush bolt toward its extended and locked position.
In pivoting the panels 14, 16, 18 to form the breakout opening 74, each panel 14, 16, 18 pivots on its own pivot axis. Each pivot axis allows the other adjacent panels to pivot approximately 90 degrees without the panels interfering with each other.
It should be understood that the slide open limit of the slow slide panel 16 is associated with its pivot axis. So, when the slow slide panel 16 is slid open such that its trailing end 17 is positioned closest to the trailing jamb 13, the slow slide panel 16 is in position to allow it to pivot to its breakout position without interfering with the pivot motion of the sidelite 14. The same is true for the fast slide panel 18. When the fast slide panel 18 is in its fully open position such that a trailing end 19 of the fast slide panel 18 is positioned closest to the trailing jamb 13, the fast slide panel 18 is in position to allow it to pivot 90 degrees without interfering with the pivot motion of the slow slide panel 16. Thus, the distance the pivot axis of each of the slide panels 16, 18 is away from the trailing jamb 13 is a factor that determines the distance of the slide opening 72.
According to an embodiment of the present disclosure, the pivot motion of the sidelite panel 14 to its breakout position is enabled by the swing clear hinge 12. The swing clear hinge 12 is disposed outside of the clear opening 70 and in front of the trailing jamb 13. If a face 76 of the trailing jamb 13 is considered zero and a direction 80 toward the lead jamb 66 is the positive direction 80 and the opposite direction 82 away from the lead jamb 66 is a negative direction 82, then the swing clear hinge 12 is disposed a distance 84 in a negative direction 82 from the face 76 of the trailing jamb 13. By positioning the swing clear hinge 12 a negative distance 78 from the face 76 of the trailing jamb 13, the sidelite panel 14 is allowed to swing substantially clear of the clear opening 70.
The pivot axis 77 of the slow slide panel 16 is disposed a closer distance 79 to the face 76 of the trailing jamb 13 than the distance 81 of the slow slide panel pivot axis 83 (see
The pivot motion of the sidelite 14 is facilitated by the swing clear hinge 12.
Reference is made to
The jamb attachment member 100 has a cross section generally in a shape of an “L.” An extension of the jamb attachment member 100 is secured to the face 76 of the trailing jamb 13 using any suitable fasteners, such as screws or the like. The jamb attachment member 100 wraps around the trailing jamb 13 and is secured to a pivot-side face 106 of the trailing jamb 13 using screws or other suitable fasteners. An elongated fixed gear portion 108 of the jamb attachment member 100 is disposed in front of the pivot-side face 106 of the trailing jamb 13.
The elongated fixed gear portion 108 of the jamb attachment member 100 is in toothed engagement with an elongated revolving gear portion 110 of the panel attachment member 102. The toothed engagement controls the motion of the two gear portions 108, 110 of the swing clear hinge 12. That is, the toothed engagement of the stationary jamb attachment portion 100 facilitates the rotational motion of the pivotable panel attachment member 102 and the sidelite panel 14.
The gear portion coupler 104 holds the two gear portions 108, 110 in toothed engagement. The hinge coupler has a generally C-shaped cross section. A rod-shaped portion 112 is disposed at each distal end of the “C.” The centers of the rod-shaped portions 112, 114 coincide with the axes of rotation for each gear-shaped portion 108, 110. The fixed gear portion 108 includes an arcuate bearing surface 113, and the revolving gear portion 110 includes a revolving arcuate bearing surface 115. The rod-shaped portion 114 contacts the fixed arcuate bearing surface 113, and the rod-shaped portion 112 contacts the revolving arcuate bearing surface 115. This fixed arcuate bearing surface 113 is positioned a distance in a negative direction from the trailing jamb face 76 of the trailing jamb 13 and outside of the clear opening 70. Thus, the sidelite panel 14 pivots to be positioned at least partially in front of the trailing jamb 13, as shown in
Returning to
As an example, a size of the slide opening 72 is in a range of 60-65 inches, for example, 62.5 inches. According to one embodiment, the size of the breakout opening 74 is increased a range of 0.75-1 inch. As an example, the size of the breakout opening 74 for one embodiment is in a range of 97.5-99.5 inches, for example, 98.6 inches. Increased slide and pivot openings sizes are important to users of telescoping door systems, so even a small increase is significant.
In some embodiments, the door panels 14, 16, and 18 may be guided by an adjacent panel whereby one sliding panel 14, 16, and/or 18 will have a pin 152 (See
The brackets or plate assemblies 136 shown in
The screw 149 acts as a pivot shaft to allow the plates 150 and 170 to pivot with respect to the L bracket 140.
The pin 152 has narrow portion 164 and a wider portion 166. The narrow 164 and wider portions 166 of the pin 152 allow the pin 152 to be captured in a track 174 (See
In some embodiments, a problem may develop in that there may be nothing to prevent the swivel bracket 136 from rotating when the panels 14, 16, and 18 are sliding normally. If the swivel bracket 136 rotates when the panels 14, 16, and 18 are sliding normally, the panels 14, 16, and 18 can separate during a sliding operation. The separation of the panels 14, 16, and 18 during a sliding operation may, in some instances, be undesirable.
To address the feature of panel 14, 16, and 18, separation during sliding, in some embodiments, a second pin (also referred to herein as a rigid post 148 and resilient sleeve 146, See
In some instances, when the door system 10 moves to the breakout position, the panels 14, 16, and 18 may unevenly separate from each other as shown in
The screw 148 acts as a pivot shaft to allow the plates 150 and 170 to pivot with respect to the L bracket 140.
The pin 152 has narrow portion 164 and a wider portion 166. The narrow 164 and wider portions 166 of the pin 152 allow the pin 152 to be captured in a track 174 (See
Typically, both the pin 146 and the pin 152 are located in the same track 174 at the same time. When the door panel 18 needs to pivot to a breakout position, the pin 146 leaves the track 174 to facilitate the pivoting of the panel 18. In order to leave the track 174, a relief opening 176 is located in the bottom rail 56 of the panel 18.
Although preferred embodiments of the present invention have been illustrated in the accompanying Drawings and described in the foregoing Detailed Description, it will be understood that the invention is not limited to the embodiments disclosed, but is capable of numerous rearrangements, modifications and substitutions without departing from the spirit of the invention as set forth and defined by the following claims.
This application is a continuation of U.S. patent application Ser. No. 16/372,102 (now U.S. Pat. No. 11,396,770), filed Apr. 1, 2019, which is a Continuation-in-part application of and claims priority to U.S. patent application Ser. No. 16/172,315 (now U.S. Pat. No. 10,851,569), filed on Oct. 26, 2018, and entitled “Telescoping Door with Swing Clear Breakout Hinge,” which claims priority to U.S. Provisional Application No. 62/694,884, filed on Jul. 6, 2018, and entitled “Hinge System and Method for Breakout Door,” all of which are incorporated herein by reference in their entirety.
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Horton Automatics, Architectural Details, Manual slide Doors—ICU/CCU, Jan. 2009, 1 page. |
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20220356749 A1 | Nov 2022 | US |
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62694884 | Jul 2018 | US |
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Parent | 16372102 | Apr 2019 | US |
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