The present disclosure relates to window balance assemblies. More particularly, the invention pertains to window balance hardware and locking apparatus for balance carriers.
This section provides background information related to the present disclosure which is not necessarily prior art.
Modern window assemblies in residential, commercial and industrial buildings may include one or more window sashes that are movable vertically within a window jamb. Window sashes that move vertically to open and close often include two or more window balance assemblies. The balance assemblies urge the window sash upward (i.e., toward an open position for a lower sash or toward a closed position for an upper sash) to assist a user in moving the window sash and to retain the window sash at a position selected by the user.
Locking mechanisms to lock the carrier (also known as a “shoe”) in the jamb channels when the sash of a tilt-sash window assembly is tilted are known in the art. U.S. Pat. No. 5,353,548, entitled “CURL SPRING SHOE BASED WINDOW BALANCE SYSTEM”, issued Oct. 11, 1994 to Westfall, discloses a window balance system for a tilt-sash window assembly having a pair of constant force curl springs having curled convolutions carried by sash shoes and free end regions mounted in sash shoe channels above the region of travel of the shoes. The curl tendency of the springs imparts a lift to the curled spring convolutions, and the shoes transmit the lift to the sash. The springs curl into the convolutions as the shoes rise, and the springs uncurl from the shoes into the shoe channels when the shoes move downward. A single annular cam on a receiver in the shoe locks the shoe in the shoe channel when the sash is tilted outward. The receiver has an opening which receives a pin or pivot bar connected to the sash such that when the sash is tilted, the receiver rotates with the sash, whereby the cam rotates to separate the two body parts of the shoe body such that they bind against the shoe channel to prevent upward or downward movement of the shoe while the sash is tilted. The disclosure of U.S. Pat. No. 5,353,548 is hereby incorporated herein in its entirety.
This section provides a general summary of the disclosure, and is not a comprehensive disclosure of its full scope or all of its features.
The disclosure provides a window balance assembly with an improved locking carrier mechanism that is actuated by rotation of the pivot bar when the window sash is tilted. Cams on the receiver of the mechanism engage cam followers in the clamshell-type housing of the carrier forcing them apart outwardly to lock the carrier in the jamb channel of a window assembly and prevent movement of the carrier in the channel. The receiver incorporates cams that engage cam follower surfaces in the housing to improve the distribution of the locking forces of the carrier in the jamb channel. A dual locking carrier expands in both the axial and lateral directions to contact both front and back surfaces and opposing side surfaces of the jamb channel.
In one aspect, the disclosure provides a moving coil window balance assembly for installation in a window assembly having a carrier, a curl spring and a mounting bracket. In certain embodiments, the carrier has a clamshell-type housing and a receiver. The housing has opposing first and second housing portions and contains the curl spring. The housing includes a first aperture extending therethrough along a first axis and located proximate to a bottom end of the housing. In addition, the housing has arcuate recesses that at least partially surround the first aperture, and axial cam followers.
The receiver is rotatably engaged in the aperture. The receiver is a generally cylindrical member including slotted recesses formed in each end, and having two symmetric, annular cams extending around a portion of its perimeter.
When the receiver is in a first rotational (unlocked) position, the cams are received in the recesses and the first and second housing portions are closed against one another at the bottom end of the housing. When the receiver is in a second (locked) rotational position, the cams on the receiver engage the axial cam followers (e.g., interior faces of the first and second housing portions) and displace the first and second housing portions away from one another at the bottom end of the housing in a direction along the first axis (e.g., an axial direction).
In another aspect of the disclosure, the housing includes an insert comprising a friction enhancing feature that protrudes from an exterior face of the housing that is perpendicular to the first axis.
In still another aspect of the disclosure, the housing further includes lateral cam followers. When the receiver is in a second rotational position, the receiver engages the axial cam followers and displaces the first and second housing portions away from one another at the bottom end of the housing in a direction along the first axis (e.g., an axial direction). In addition, the receiver engages the lateral cam followers and displaces the first and second housing portions away from one another at the bottom end of the housing in a direction along a second axis that is generally perpendicular to the first axis (e.g., a lateral direction).
In still another aspect of the disclosure, the first and second housing portions include lateral cam followers extending from their interior faces adjacent to the first aperture. When the receiver is in a second rotational position, the cams engage the interior faces of the first and second housing portions and displace the first and second housing portions away from one another at the bottom end of the housing in a direction along the first axis, and the cams engage the lateral cam followers of the first and second housing portions and displace the first and second housing portions away from one another at the bottom end of the housing in a direction along a second axis that is generally perpendicular to the first axis.
In an alternate configuration, an insert is disposed in second apertures formed in the first and second housing portions. The insert serves as a lateral cam follower and further includes a friction enhancing feature that protrudes from exterior faces of the first and second housing portions.
In a still further aspect of the disclosure, the housing has at least one opening near the first aperture and a locking pad is mounted in the opening. The locking pad has a rear cam follower and a forward surface. When the receiver is in a first rotational position, the locking pad is in a first retracted position in the housing. When the receiver is in a second rotational position, the cam engages the cam follower of the locking pad and the locking pad is in a second extended position wherein the forward surface extends from the housing.
In yet another aspect of the disclosure, the mounting bracket comprises a body portion having a back wall and at least one side wall. A spring attachment portion is located at an upper end of the side wall for engaging the curl spring. A mounting hook extends from an upper portion of the back wall and a tab member extends from a lower portion of the back wall. The mounting bracket also includes an attachment portion for connecting to the upper end of the carrier.
Further areas of applicability will become apparent from the description provided herein. The description and specific examples in this summary are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.
Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings, as appropriate.
Example embodiments will now be described more fully with reference to the accompanying drawings.
With reference to
The lower sash 14 may include a pair of pivot bars 22 and a pair of tilt latch mechanisms 24. The pivot bars 22 may extend laterally outward in opposing directions from a lower portion of the lower sash 14 and may engage corresponding ones of the window balance assemblies 20, as will be subsequently described. The tilt latch mechanisms 24 may extend laterally outward in opposing directions from an upper portion of the lower sash 14 and may selectively engage corresponding ones of the window jambs 16. The tilt latch mechanisms 24 may be selectively actuated to allow the lower sash 12 to pivot about the pivot bars 22 relative to the window jambs 16 to facilitate cleaning of an exterior side of the window assembly 10, for example.
It will be appreciated that in a double hung window assembly, the upper sash 12 may also be connected to two or more window balance assemblies to assist the user in opening the upper sash 12 and maintaining the upper sash 12 in a selected position relative to the window sill 18. In such a window assembly, the upper sash 12 may also include tilt latches and pivot bars to allow the upper sash 12 to pivot relative to the window jambs 16 in the manner described above.
Each of the window jambs 16 may include a jamb channel 26 defined by a first wall 28, a second wall 30 opposite the first wall 28, and third and fourth walls 32, 34 disposed perpendicular to the first and second walls 28, 30 (
The window balance assemblies include a carrier (also referred to as a shoe), a biasing member that provides the counterbalancing force against the weight of the window sash, and a mounting bracket that attaches one end of the balance assembly to the window jamb. Referring to the figures, in the embodiments shown, balance assemblies 20 may include a carrier 40, a curl spring 42, and a mounting bracket 44. The configuration shown is a so-called “moving coil” constant force balance assembly; however, other types of balance assemblies can employ the locking carrier of this disclosure.
The window balance assemblies 20 may be initially assembled and shipped in an uninstalled or shipping configuration (shown in
Referring to
Again with reference to
Each of the first and second housing portions 46, 48 may include an exterior face 52, an interior face 54, a top end 56, a bottom end 58, a first side 60, and a second side 62. An aperture 64 disposed proximate the bottom end 58 may extend through the exterior and interior faces 52, 54 and may rotatably engage the receiver 50. Arcuate recesses 65 formed in the interior face 54 may be concentric with the aperture 64 and may partially surround the aperture 64. A first slot 66 in communication with the aperture 64 may be formed in the exterior face 52 and may extend vertically upward along the Y-axis (see, e.g.,
A barbed protuberance 68 may be disposed at or proximate to the first side 60 and may extend outward from the interior face 54. A second slot 70 may be formed in the second side 62 generally opposite the barbed protuberance 68 such that when the first and second housing portions 46, 48 are assembled together, the barbed protuberances 68 may engage the second slots 70 (shown best in
The interior face 54 may include generally cylindrical recesses 72. When the first and second housing portions 46, 48 are assembled together, the cylindrical recesses 72 cooperate with each other to form a nest that receives the curled portion 45 of the curl spring 42. Openings 76 in communication with the recess 72 may be formed in the first and second sides 60, 62 through which the uncurled portion 47 of the curl spring 42 may extend toward the mounting bracket 44.
The first and second housing portions 46, 48 may also include a projection 80 and a third slot 82 disposed at the top end 56. The projection 80 may extend from the exterior face 52 beyond the interior face 54 and may include a generally I-shaped cross-section having upper and lower flanges 84, 86. The third slots 82 may be sized and shaped to enable the third slots 82 of the first housing portion 46 and the second housing portion 48 to slidably engage the lower flanges 86 of the second housing portion 48 and the first housing portion 46, respectively. In a similar manner, pegs 88 and apertures 90 formed in the interior face 54 of the first and second housing portions 46, 48 may be sized and positioned to slidably engage each other when the first and second housing portions 46, 48 are assembled together.
As illustrated in
When the receiver 50 is oriented such that the slotted recess 92 is oriented horizontally relative to the carrier 40 (i.e., along the X-axis), the cams 94 may be fully received within the arcuate recesses 65 (see
When the lower sash 14 is tilted relative to the window jamb 16, the pivot bar 22 rotates the receiver 50 toward the orientation shown in
Moreover, as shown in
Accordingly, when the lower sash 14 is in a tilted position, the window balance assembly 20 may be prevented from exerting a net upward force on the lower sash 14. The cams 94 and cam followers are preferably formed to provide full locking engagement with a tilt of the sash of 20 degrees or less with respect to the vertical position, since as the tilt angle increases, the amount of the weight of the sash being supported by the balance decreases such that the balance may raise the sash if not locked in the balance channel. In some embodiments, the rib portions and cam followers are formed to provide full locking engagement with only a small tilt, for example 5 degrees, of the sash. In other embodiments, full locking engagement occurs at tilt angles greater than 5 degrees.
Including two cams 94 on the receiver 50 engaging two cam follower surfaces in the housing improves the distribution of the locking forces from the exterior faces 52 of the carrier 40 across the surfaces 28, 30 of the jamb channel 26 over that of prior art carrier designs having a receiver with a single cam, such as that shown in U.S. Pat. No. 5,353,548.
When the carrier 40 is locked in place within the jamb channel 26, the lower sash 14 can be removed from the window assembly 10 for maintenance or replacement, for example. To remove the lower sash 14, the pivot bars 22 can be removed from the receivers 50 by moving the pivot bars 22 upward out of the slotted recesses 92 and into the first slot 66 in the carriers 40. Thereafter, the pivot bars 22 can be removed from the window balance assemblies 20 so that the lower sash 14 can be removed from the window assembly 10.
The opposite procedure may be employed to install the lower sash 14 into the window assembly 10. That is, with the lower sash 14 tilted relative to the upper sash 12, the pivot bars 22 may be inserted into the first slots 66 in the carrier 40 and lowered into engagement with the slotted recesses 92 in the receivers 50. The lower sash 14 may then be pivoted to the upright position relative to the upper sash 12, which includes rotating the receiver 50. As described above, rotating the receiver 50 allows the first and second housing portions 46, 48 to fully close together, thereby reducing or eliminating friction between the carrier 40 and the jamb channel 26 to allow unrestricted movement of the carrier 40 therein.
Variations of another locking carrier 40′ for a tilt-sash counter balance assembly and including an improved locking mechanism is shown in
The dual locking carrier 40′, however, includes a lateral cam follower 500. For example, a lateral cam follower 500 can extend from the interior face 54′ of each of the first and second housing portions 46′, 48′ adjacent to the aperture 64′. A recess 502 in the interior face 54′ is located adjacent to the aperture 64′ on the side opposite to that of the cam follower 500. In this manner, and because first and second housing portions 46′, 48′ may be identical components that fit together to form a clamshell-type housing, when the first and second housing portions 46′, 48′ are assembled together, the lateral cam followers 500 of one of the housing portions may engage the opposed recesses 502 of the other of the housing portions.
The aperture 64′ may rotatably engage the receiver 50′. Arcuate recesses 65′ formed in the interior faces 54′ of the first and second housing portions 46′, 48′ may be concentric with the aperture 64′ and may partially surround the aperture 64′. As described above, the receiver 50′ may be rotatable within the aperture 64′ to allow the lower sash 14 to pivot about the pivot bar 22 between an upright position and a tilted position. The angular span of the cams 94′ may correspond to the angular span of the arcuate recesses 65′ that partially surround the aperture 64′ in the first and second housing portions 46′, 48′ such that when the lower sash 14 is in the upright position, the cams 94′ fit within the arcuate recesses 65′ and the gaps 93′ between the cams 94′ are positioned adjacent to the lateral cam followers 500.
When the receiver 50′ is oriented such that the slotted recess 92′ is oriented horizontally relative to the carrier 40′, the cams 94′ may be fully received within the arcuate recesses 65′ (see
When the lower sash 14 is tilted relative to the window jamb 16, the pivot bar 22 rotates the receiver 50′ to lock the carrier, as shown in
In addition, however, the same rotation of the receiver 50′ also causes the outer diameter surfaces 504 of the cams 94′ to force the cam followers 500 of the first and second housing portions 46′, 48′ laterally away from each other in a direction along the X-axis. As such, second sides 62′ of the first and second housing portions 46′, 48′ are forced against the third and fourth walls 32, 34 of the jamb channel 26. As a result, the exterior faces 52′ and sides 62′ are forced outward against all four walls 28, 30, 32, 34 of the jamb channel 26 to create friction that may be sufficient to lock the carrier 40′ in place.
As shown in
For example, without the insert 508″, the carrier 40″ operates substantially as the carrier 40, with the face surfaces 95″ of the cams 94″ engaging the interior faces 54″ of the first and second housing portions 46″, 48″ when the receiver 50″ is rotated, thereby forcing the housing portions 46″, 48″ axially outwardly along the direction of the Z-axis. The outer diameter surfaces 504″ of the cams 94″, however, do not engage any portion of the first and second housing portions 46″, 48″, and therefore do not force the first and second housing portions 46″, 48″ laterally outwardly along the direction of the X-axis.
With inserts 508″ included in the carrier 40″, however, the carrier 40″ operates substantially as the carrier 40′. In this regard, the inserts 508″ are received in the apertures 506″ of the housing portions 46″, 48″, as shown in
Moreover, the insert 508″ includes a head portion 512″ that includes an exterior surface 514″. When the insert 508″ is installed, the exterior surface 514″ of the head portion 512″ lies approximately flush with the exterior face 52″ of the housing portions 46″, 48″; that is, it can protrude slightly from the exterior face 52″. The exterior surface 514″ may include a friction enhancing feature 516″ to improve the frictional contact between the carrier 40″ and the walls 28, 30 of the jamb channel 26 when the carrier 40″ is locked in place. The friction enhancing feature 516″ may comprise a material or a treatment to the surface 514″ that modifies the coefficient of friction of the exterior surface 514″.
Still another alternative configuration of a dual locking carrier 40′″ is shown in
In yet another embodiment of a locking carrier 320 shown in
The front surfaces of the cam surfaces 220, 240 of the receiver 140 contact the back surfaces 360, 380 of the locking pads 260, 280, which serve as cam followers, to drive the locking pads 260, 280 outward from the carrier housing 300. In
In other embodiments of the present invention, the locking pads extend from the back of the shoe to contact the back wall of the shoe channel. In further embodiments, the back and front of the shoe are symmetric with a first pair of locking pads extending from the front of the shoe and a second pair of locking pads extending from the back of the shoe. In still further embodiments of the present invention, a single locking pad is contacted by both ribs of the cam to extend from the back of the shoe. In other embodiments, a single locking pad extends from the back of the shoes, and a pair of locking pads extends from the front of the shoe.
In yet another embodiment, as shown in
Still other alternative embodiments of a window balance assembly according to the disclosure are shown in
As previously described, the carrier 40 may engage the lower sash 14 and house a curled portion 45 of the curl spring 42. The mounting bracket 440, 540 may engage an uncurled end portion 47 of the curl spring 42 and may be fixed relative to the window jamb 16. The curl spring 42 may resist being uncurled such that the curl spring 42 exerts an upward force on the carrier 40, thereby biasing the lower sash 14 toward the open position.
As shown in
Included at an upper end of the body portion 460 is a mounting hook 484. The mounting hook 484 extends outwardly from the back wall 481 of the mounting bracket 440 in a direction generally opposite to the direction in which the side walls 482 project from the back wall 481. Projecting outwardly from a lower portion of the back wall 481, but in the same direction as the mounting hook 484, is a tab member 485. The mounting hook 484 and tab member 485 are each operable to engage a corresponding receiving slot 600, 602 in a wall 30 of the jamb channel 16 to co-operably secure the mounting bracket 440 in position in the jamb channel 16, as best seen in
As can be appreciated, installation of the mounting bracket 440 is achieved by inserting the mounting hook 484 into the upper receiving slot 600 with the mounting bracket 440 in an orientation generally forming an acute angle with the jamb channel 16 wall 30. Thereafter, the mounting bracket 440 is rotated to an orientation generally parallel with the jamb channel 16 wall 30 so that the tab member 485 is inserted into the lower receiving slot 602. Once installed, the mounting bracket 440 is secured in the jamb channel 16 against the vertical forces applied to the balance assembly 400. Additionally, an optional mounting aperture 486 may also be included in the body portion 460 of the mounting bracket 440 and a corresponding fastener may be employed to further secure the mounting bracket 440 to a jamb wall 30.
In an uninstalled or shipping configuration, the mounting bracket 440 is located on top of the carrier 40, where the lower attachment portion 480 of the mounting bracket 440 connects to the upper end of the carrier 40. The lower attachment portion 480 of the mounting bracket 440 may include tapered or curved extension portions 487, 488 that protrude from the back wall 481 and side walls 482 that cooperate with the lower end 489 of the body portion 460 to slidably engage projections 80 of the carrier 40. In this manner, the mounting bracket 440 and carrier 40 are joined together when the balance assembly is in the uninstalled or shipping configuration. Alternatively, a “break-away” or stress riser feature may be included in the lower attachment portion 480 of the mounting bracket 440 to join the mounting bracket 440 with the carrier 40, such as disclosed in International application Publication no. WO 2011/100280 entitled, “Window Balance Assembly,” which is assigned to the assignee of the present disclosure. The disclosure of International application Publication no. WO 2011/100280 is hereby incorporated by reference.
Another alternative window balance assembly 500 is shown in
Included at an upper end of the body portion 560 is a mounting hook 584. The mounting hook 584 extends outwardly from the back wall 581 of the mounting bracket 540 in a direction generally opposite to the direction in which the side walls 582 project from the back wall 581. Projecting outwardly from a lower portion of the back wall 581, but in the same direction as the mounting hook 584, is a tab member 585. The mounting hook 584 and tab member 585 are each operable to engage a corresponding receiving slot 604, 606 in a wall 30 of the jamb channel 16 to co-operably secure the mounting bracket 540 in position in the jamb channel 16, as best seen in
In an uninstalled or shipping configuration, the mounting bracket 540 is located on top of the carrier 40, where the lower attachment portion 560 of the mounting bracket 540 connects to the upper end of the carrier 40. The lower attachment portion 560 of the mounting bracket 540 may include tapered or curved extension portions 587 that protrude from the back wall 581 that cooperate with the lower end 589 of the body portion 560 to slidably engage projections 80 of the carrier 40. In this manner, the mounting bracket 540 and carrier 40 are joined together when the balance assembly is in the uninstalled or shipping configuration. Alternatively, a “break-away” or stress riser feature may be included in the lower attachment portion of the mounting bracket to join the mounting bracket with the carrier.
The carriers of the window balance assembly are preferably mountable in either a left jam channel or a right jam channel. To this end, the receiver 50 is preferably symmetric so that it can be mounted in either direction in the carrier body. The carrier body is also preferably symmetric to the extent that it can be oriented in either direction in a jamb channel of a window. When the balance is a curl spring balance, the carrier is preferably symmetric to the extent that the curl spring can be mounted in either orientation in the carrier housing.
Although the invention has been described in embodiments for curl spring window balances, the locking mechanism may be used in any type of window balances, including, but not limited to, curl spring balances, block-and-tackle balances, spiral balances, and hybrid balances, within the spirit of the present disclosure. Accordingly, it is to be understood that the embodiments of the invention herein described are merely illustrative of the application of the principles of the invention.
This application is a continuation-in-part of U.S. patent application Ser. No. 13/576,440, filed on Aug. 1, 2012, which is a National Stage of International Application No. PCT/US2011/024134, filed on Feb. 9, 2011, which claims the benefit of U.S. Provisional Application No. 61/302,722, filed on Feb. 9, 2010 and U.S. Provisional Application No. 61/302,715, filed on Feb. 9, 2010. This application also claims the benefit of U.S. Provisional Application No. 61/665,558, filed on Jun. 28, 2012. The entire disclosures of each of the above applications are incorporated herein by reference.
Number | Date | Country | |
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61302722 | Feb 2010 | US | |
61302715 | Feb 2010 | US | |
61665558 | Jun 2012 | US |
Number | Date | Country | |
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Parent | 13576440 | Aug 2012 | US |
Child | 13930290 | US |