The present invention generally relates to locking devices, and more particularly but not exclusively to pushbar-type locking devices.
Commercial or public buildings are typically required by law to provide for an emergency exit in case of an adverse event such as a fire. Common emergency exits include a latch closed double door where both doors are mounted within a door frame, and a latch closed single door mounted in a door frame. An exit device mounted to the door is typically used by individuals to exit the building through the emergency exit. Different types of exit devices include panic bars, push pads, and pushbars. A pushbar is commonly located on a door at a convenient height for an individual to push when exiting through the door. Depressing the pushbar actuates retraction of a latchbolt, thereby allowing the door to be opened.
Even though the pushbar exit device provides certain advantages for individuals exiting a building or moving from one area to another area within a building, the pushbar exit device can often produce unwanted or undesired noise. This noise results from the operation of hardware located within the device and the pushbar latch contacting a door strike. In some environments, the noise is tolerable or even unnoticed such as, for instance, when pushbar exit devices are used in a sports facility. However, when the same pushbar exit device is located in a healthcare environment such as, for example, in a hospital, the noise produced by the pushbar exit device and latch is undesirable and can even be intolerable. For example, noise from the pushbar exit device can disturb a patient's sleep, which can in turn interfere with wound healing and pain management. Other environments where noise generated by a pushbar exit device is unwanted or undesirable include schools, libraries, office space, and other generally quiet environments.
Other types of locking devices used at a door include mortise locks, cylindrical locks, tubular locks, and remote latching devices used with either single or multiple exit doors and devices. Each of these locking devices includes moving mechanical components which can create undesirable or unwanted noise when actuated.
What is therefore needed is a locking device, and in some embodiments a pushbar exit device, having a reduced noise profile to reduce or minimize the level of noise produced by the locking device upon opening and closing of the door.
A quiet pushbar exit device provides a quiet environment in hospitals and other buildings such as libraries, schools and office space. Current exit doors, including corridor doors, main doors, and room doors in these buildings generate or produce noise when shut either manually or automatically by an associated door closer. One contributing factor in generation of the noise results from a latchbolt hitting a door strike, and then being released after the latchbolt clears the door strike. Embodiments of the present disclosure reduce noise when door is closed, thereby facilitating a quiet environment. Healthcare facilities in particular benefit from embodiments of the present disclosure as a quiet environment in patient wards or rooms has become an appropriate parameter for measuring patient satisfaction. The level of noise within a healthcare facility can also present financial implications to the hospital.
In one embodiment, there is provided a locking device for a door located at a door frame having a door strike. The locking device includes a latchbolt assembly having an extended position configured to engage the door strike, and a retracted position configured to move past the door strike. An actuator is adapted to move the latchbolt assembly from the extended position to the retracted position. A dampening device is disposed adjacent to the latchbolt assembly, wherein the dampening device resiliently engages the latchbolt assembly as the latchbolt assembly moves from the retracted position to the extended position.
In another embodiment, there is provided an exit device for a door located at a door frame having a door strike including a pushbar having a released position and a depressed position, wherein the pushbar defines a longitudinal axis. A latchbolt assembly is disposed along the longitudinal axis and includes an extended position configured to engage the door strike, and a retracted position configured to move past the door strike, wherein movement of the pushbar from the released position to the depressed position moves the latchbolt assembly from the extended position to the retracted position. A first bell crank mechanism is operatively connected to the pushbar and is disposed along the longitudinal axis at a first location. A second bell crank mechanism is operatively connected to the pushbar and is disposed along the longitudinal axis at a second location, wherein the first bell crank mechanism is located between the latchbolt assembly and the second bell crank mechanism. A dampening device is disposed along the longitudinal axis between the latchbolt assembly and the first bellcrank assembly, wherein the dampening device is configured to restrain movement of the latchbolt assembly during movement from the retracted position to the extended position.
In still another embodiment, there is provided an exit device for a door located at a door frame having a door strike. The exit device includes a pushbar having a released position and a depressed position wherein the pushbar defines a longitudinal axis. A latchbolt assembly is disposed along the longitudinal axis and includes an extended position configured to engage the door strike and a retracted position configured to move past the door strike, wherein movement of the pushbar from the released position to the depressed position moves the latchbolt assembly from the extended position to the retracted position. A first bell crank mechanism is operatively connected to the pushbar and is disposed along the longitudinal axis at a first location. A second bell crank mechanism is operatively connected to the pushbar and is disposed along the longitudinal axis at a second location, wherein the first bell crank mechanism is located between the latchbolt assembly and the second bell crank mechanism. A first dampening device is disposed adjacent to the latchbolt assembly, wherein the dampening device resiliently engages the latchbolt assembly as the latchbolt moves from the retracted position to the extended position. A second dampening device is disposed along the longitudinal axis between the latchbolt assembly and the first bellcrank assembly, wherein the second dampening device is configured to restrain movement of the latchbolt assembly during movement from the retracted position to the extended position.
In a further embodiment, there is provide a method for reducing noise produced by a pushbar exit device including a pushbar, a latchbolt having an extended position and a retracted position, and a latchbolt link operatively connected to the pushbar and configured to move the latchbolt from the extended position to the retracted position and back to the extended position. The method includes locating the latchbolt link at a first position to place the latchbolt at the extended position, moving the latchbolt link from the first position to a second position to place the latchbolt at the retracted position, and limiting movement of the latchbolt link from the second position to the first position when the latchbolt moves from the retracted position to the extended position.
For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the embodiments illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation on the scope of the invention is hereby intended. Any alterations and further modifications in the described embodiments, and any further applications of the principles of the invention as described herein are contemplated as would normally occur to one skilled in the art to which the invention relates.
In the illustrated embodiment, a latchbolt 20 (
The drive assembly 52 includes a drive bar 54 that moves longitudinally along the base plate 46 in both directions. The drive bar 54 is operatively connected to a split link 56, which is in turn operatively connected to a locking link 58. The drive bar 54 is located within a main spring 60 which has one end fixed in position by a collar 62 fixedly coupled to the drive bar 54. The other end of the main spring 60 is fixedly located at a second collar 63 which is positioned adjacent the bracket 44. A terminating end of the drive bar 54 is operatively connected to the split link 56 with a link spring 64.
Movement of the drive bar 54 is transmitted by the split link 56 and the locking link 58 to the latchbolt 20. Movement of the drive bar 54 in a rightward direction (as illustrated), also known as a retracting direction, causes the latchbolt 20 to retract toward an unlatching position. The main spring 60 is compressed between the collar 62 and the mounting bracket 44. The second collar 63 acts as an anchor such that the main spring 60 exerts a main spring biasing force on the collar 62 and toward the latchbolt 20 to maintain the latchbolt 20 in the extended position when the pushbar 16 is in the extended position. Depressing the pushbar 16 moves each of the bell cranks 42 and 48 toward the base plate 46, which moves the drive assembly 52, and in particular, the drive bar 54, in a direction to the right (as illustrated) to retract the latchbolt 20. At the same time, the main spring 62 and the link spring 64 are compressed, which increases the tension of each, which is then released once the pushbar 16 is released to return the latchbolt 20 to the extended position.
The exit device 10 further includes a dampening device having a damper housing 70 which is fixedly coupled to the base plate 46 at a location between the bell crank 48 and the latchbolt 20. The housing 70 includes an aperture 72 sized and configured to receive a body 74 of a damper 76 having rod 78 (
The dampening device further includes a bias arrangement 82 which includes a flexible contact member 84 that is fixedly coupled to the mounting bracket 32. The contact member 84 is resilient, and in one embodiment is cantilevered. The contact member 84 extends along the longitudinal direction of the base plate 46 and is covered by a cover 86, which is also fixedly coupled to the bracket 32. The cover 86 defines an interior region 88 having a space sufficient to enable the cantilever member 84 to flexibly move within the interior region 88. In one embodiment, the cantilever member 84 includes a leaf spring having a length longer than a width, and includes a bend 90 located between a free end 92 and a fixed end 94. The bend 90 is located at an aperture 95 which provides a recessed area on an underneath or bottom side of the cover 86 to locate the bend 90.
The free end 92 and a portion of the cantilever member 84, located between the bend 90 and the free end 92, is disposed adjacent to a latchbolt link 96 which is rotatably coupled to the pin 34. The latchbolt link 96 includes an extension or pawl 98 that extends from the pin 34 and contacts the cantilever member 84 as the latchbolt link 96 pivots. When the locking link 58 moves longitudinally in either direction 79, the pawl contacts the cantilever member 84. By contacting the cantilever member 84, noise resulting from movement of the latchbolt 20, the auxiliary latchbolt 36, the latchbolt link 96, and/or other related components is reduced or dampened. This reduction in noise results from these and other parts being substantially prevented from moving too quickly, or from sudden movement of parts contacting other parts, and more particularly metal-to-metal contact. In one embodiment, the pawl 98 contacts the cantilever member 84 continuously throughout the movement thereof. In another embodiment, the pawl 98 does not contact the cantilever member 84 throughout the entire range of travel. In other embodiments, a latchbolt assembly includes one, some, or all of the latchbolt 20, the auxiliary latchbolt 36, and the latchbolt link 96.
The rod 78 is pulled away from the body 74 of the damper 76 to extend the internal spring to increase tension. The locking link 58 also moves to the right, which moves the pawl 98 to the right along the resilient member 84. Once the pushbar 16 is released, the locking link 58 moves to the left (as illustrated), the movement of which is buffered by the spring 64 and the damper 76 as the rod 78 retracts into the body 74. The retraction of the rod 78 provides dampening of the movement of the movable support 80 to slow down movement of the drive assembly 52, which could otherwise be present if there were no damper 76. By slowing down the entire assembly, noise is reduced as the latchbolt 20 and auxiliary latchbolt 36 move to the extended positions.
While the invention has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only the preferred embodiments have been shown and described, and that all changes and modifications that come within the spirit of the inventions are desired to be protected. For instance, the present disclosure is not limited to pushbar type exit or locking devices, but other types of locking devices having a handle or other types of actuators are also contemplated. Actuators including both electrical and mechanical actuators to displace a latchbolt from an engaged position with a strikeplate to a disengaged position relative to the strikeplate are included. The other types of locks include, but are not limited to, mortise locks, cylindrical locks, tubular locks, and remote latching devices used with single or multiple exit doors and devices.
One feature of each of the locking devices includes an actuator which moves from a neutral position to a displaced position to lock and unlock the device. Typically, the actuator remains in the neutral position until moved to the displaced position by an external force. In the case of the pushbar device, the neutral position is the released position of the pushbar, and the displaced position is the depressed position of the pushbar. In the case of a cylindrical lock having a handle or knob, rotation of the knob about a rotational axis moves the knob from the neutral position to the displaced position. Each of these locking devices includes moving mechanical components, and the noise generated by movement of the mechanical components being reduced when configured to include the disclosed embodiments and other modifications as set forth in the present disclosure.
It should be understood that while the use of words such as preferable, preferably, preferred or more preferred utilized in the description above indicate that the feature so described may be more desirable, it nonetheless may not be necessary and embodiments lacking the same may be contemplated as within the scope of the invention, the scope being defined by the claims that follow. In reading the claims, it is intended that when words such as “a,” “an,” “at least one,” or “at least one portion” are used there is no intention to limit the claim to only one item unless specifically stated to the contrary in the claim. When the language “at least a portion” and/or “a portion” is used the item can include a portion and/or the entire item unless specifically stated to the contrary.
Number | Date | Country | |
---|---|---|---|
Parent | 15363180 | Nov 2016 | US |
Child | 17103311 | US |