This disclosure relates to a patient support apparatus having a manual brake for braking one or more of the wheels of the patient support apparatus. More disclosure relates patient support apparatuses having four wheels or casters attached to the base frame for rolling the apparatus from location to location and a braking mechanism for activating brakes on all four wheels simultaneously.
Patient support apparatuses such as hospital beds are moved from location to location. Casters which support the hospital bed allow the bed to be rolled and steered between locations. During movement it is desirable to have free rolling wheels but upon reaching the desired location, brakes are usually applied to the wheels to maintain the bed at the desired location.
It is well known to provide hospital beds with brake/steer casters which include mechanisms for blocking the rotation of the caster wheel or wheels, i.e. braking mechanisms, and mechanisms for blocking swiveling movement of the caster wheel fork, i.e. anti-swivel or directional lock mechanisms. Some beds with four castered wheels include pedals located on opposite sides of the bed which control the braking and anti-swivel mechanisms in each caster. An example of such a bed is shown in Rudolf et al., U.S. Pat. No. 5,377,372 which is expressly incorporated by reference herein. The pedals in Rudolf et al. may not be readily accessible by a caregiver who is currently pushing the bed. Another approach is shown in Mobley et al., U.S. Pat. No. 6,321,878 which is expressly incorporated by reference herein. The pedals adjacent the head end of base in Mobley et al. both provide the same actuation in the same direction. In other words, if one can only achieve a single function by stepping on the pedal(s). To reverse the function from the head end, the pedal(s) must be lifted.
Other hospital beds equipped with such brake/steer casters include four separate brake and/or steer pedals each associated with only one of the four casters with each brake pedal only engaging the brake on the caster with which it is associated and each steer pedal only actuating the anti-swivel mechanism on the caster with which it is associated. One such hospital beds having four casters with four unconnected brake mechanisms, prior to movement of the bed the caregiver must disengage all four brakes by operating all four pedals and after movement of the bed engage all four brakes by again operating all four pedals.
The present application discloses one or more of the features recited in the appended claims and/or the following features which alone or in any combination, may comprise patentable subject matter.
According to a first aspect of the present disclosure, a brake system for a patient support apparatus having a base frame may include a plurality of wheels supporting the base frame on surface of a floor. The system may include a brake moveable between a first position in which the brake inhibits rotation of one of the plurality of wheels and a second position in which the brake permits the one of the plurality of wheels to rotate freely. The system may also include a plurality of pedals positioned to be moved by a user to move the brake, at least a first one of the plurality of pedals positioned adjacent a head end of the base. The system may still also include a mechanism positioned to coordinate movement of the plurality of pedals so that movement of any one of the plurality of pedals causes movement of the brake, wherein downward movement of the at least one pedal positioned adjacent the head end of the base causes the brake to move from the second position to the first position.
The plurality of pedals may include a second one of the plurality of pedals positioned adjacent the head end of the base, wherein downward movement of the second one of the plurality of pedals causes the brake to move from the first position to the second position.
Downward movement of the second one of the plurality of pedals positioned adjacent the head end may cause the first one of the plurality of pedals positioned adjacent the head end to move upwardly.
The mechanism may be supported for movement relative to a frame of the patient support apparatus.
The patient support apparatus may include a pedal assembly positioned on a lateral side of the patient support apparatus, the pedal assembly operable to move the mechanism.
The brake system may include a plurality of casters and the wheels are part of the casters.
The casters may have multiple modes. The mechanism may be movable to change the mode of the casters. A caster may include a neutral mode where the caster wheel is free to rotate and the caster stem is free to rotate. A caster may include a brake mode wherein the caster wheel is secured against rotation and the caster stem is secured against rotation. A caster may include a steer mode wherein the caster stem is secured against rotation.
The plurality of pedals positioned adjacent the head end of the base each may have a fulcrum axis that corresponds to a fulcrum of the pedal, the fulcrum axes of each of the plurality of pedals being generally collinear.
At least one of plurality of pedals positioned adjacent the head end of the base may be coupled to the mechanism at a position above the fulcrum axes.
At least one of plurality of pedals positioned adjacent the head end of the base may be coupled to the mechanism at a position below the fulcrum axes.
At least two of plurality of pedals may be positioned adjacent the head end of the base, the at least two pedals having generally collinear fulcrum axes with one of the at least two pedals coupled to the mechanism at a position below the fulcrum axes and another of the at least two pedals coupled to the mechanism at a position above the fulcrum axes.
According to another aspect of the present disclosure, a patient support apparatus comprises a lower frame including a plurality of casters and a mode changing mechanism operable to simultaneously modify the mode of at least two casters. Each caster includes at least two operating modes. The mode changing mechanism includes a first actuation mechanism. The first actuation mechanism has a first actuator, a first control arm pivotably coupled to the first actuator, and a first follower pivotably coupled to the first control arm. The first follower is engaged with a first mode key to transfer motion from the first actuator to the first mode key to rotate the first mode key about a first axis. The mode changing mechanism also includes a first transfer arm pivotably coupled to the actuator and positioned between the at least two casters such that movement of the first actuator causes rotation of the first mode key and movement of the first transfer arm.
The actuator includes a force receiving area. The actuator and the transfer arm may be pivotably coupled at a second axis. The first control arm may be pivotably coupled to the actuator at a third axis. The third axis may be positioned between the force receiving area and the second axis.
The first control arm and the first follower may be pivotably coupled at a fourth axis. The fourth axis may be offset from the first axis.
The first mode key may be engaged with a first caster such that at least a portion of the mode changing mechanism is supported from a first caster.
In some embodiments, the patient support apparatus may further comprise a second follower engaged and a second mode key. Movement of the transfer arm may cause movement of the second mode key.
The second mode key may be engaged with a second caster such that the mode changing mechanism is dependently supported from the first and second casters.
The fourth axis may be positioned closer to the first axis than to the second axis.
In some embodiments, the fourth axis may be positioned closer to the second axis than to the first axis.
The distance between the first axis and the second axis may vary when the first mode key is rotated.
In some embodiments, the distance between the third axis and fourth axis may remain fixed when the first mode key is rotated.
In some embodiments, the distance between the first axis and the third axis remains fixed when the first mode key is rotated.
A force applied to the force receiving area of the actuator may cause rotation of the first mode key.
In some embodiments, the follower extends generally vertically upwardly from the first mode key.
In other embodiments, the follower extends generally vertically downwardly from the first mode key.
The mode changing mechanism may further comprise a second actuation mechanism, the second actuation mechanism having a second actuator, a second control arm pivotably coupled to the second actuator, a second follower pivotably coupled to the second control arm, the second follower engaged with a second mode key to transfer motion from the second actuator to the second mode key to rotate the second mode key about a second axis.
In some embodiments, the second actuator may be pivotably coupled to the first transfer arm. The pivotable coupling of the second control arm and the second follower may be vertically higher than the second axis while the pivotable coupling of the first control arm and the first follower may be vertically higher than the first axis.
In some embodiments, the pivotable coupling of the second control arm and the second follower may be vertically lower than the second axis while the pivotable coupling of the first control arm and the first follower may be vertically higher than the first axis.
In some embodiments, the first actuator and the second actuator move in the same vertical direction when the mode changing mechanism is moved between positions. In other embodiments, the first actuator and the second actuator move in opposite vertical directions when the mode changing mechanism is moved between positions.
In some embodiments, the first follower and the second follower may be connected by a transfer bar so that rotation of the first follower may be transferred to the second follower.
In some embodiments, the second actuator may be pivotably coupled to a second transfer arm so that movement of either the first or second actuators may be transferred to both the first and second mode change keys and to both the first and second transfer arms.
In some embodiments, the mode changing mechanism further includes a second actuation mechanism having a second follower, the second follower pivotable about a second axis and pivotably coupled to the first transfer arm at a third axis such that rotation of the follower about the second axis causes movement of the first transfer arm. The second follower may be coupled to a second mode key, the second mode key pivotable about the second axis.
In some embodiments, the second mode key may be engaged with one of the plurality of casters to change the mode of the caster with which the second mode key may be engaged.
In other embodiments, the second mode key may be coupled to an input assembly, the input assembly including a second actuator operable to rotate the second mode key.
The input assembly may comprise a pair of pedals coupled to a parallelogram linkage, the pedals maintaining a horizontal orientation during movement of the pedals between a first position and a second position.
According to another aspect of the present disclosure, a patient support apparatus comprises a frame, a motion transfer mechanism, and an input assembly. The input assembly provides rotational input to the motion transfer mechanism. The input assembly includes a first input actuator for receiving an input force and a pair of links pivotably coupled to the input actuator at first and second axes. The first and second axes are positioned to lie on a first generally vertical line. The first of the links is pivotably coupled to the frame at a third axis. The second of the links is coupled to the motion transfer mechanism at a fourth axis. The third and fourth axes are collinear to a second generally vertical line that is parallel to the first generally vertical line. A force applied to the first input actuator results in torque applied to the motion transfer mechanism at the fourth axis.
In some embodiments, the third and fourth axes may remain stationary when a force is applied to the first input actuator.
In some embodiments, the first input actuator may include a pedal pad. The pedal pad may have a surface maintaining a substantially horizontal orientation during movement of the pedal pad when force is applied to the first input actuator.
The input assembly may include a second input actuator coupled to the first and second links at fifth and sixth axes respectively. The fifth and sixth axes may be positioned on a third generally vertical line. The third generally vertical line may be parallel to the first generally vertical line.
In some embodiments, a force applied to the first input actuator may cause the first input actuator to be lowered and the second input actuator to be raised.
In some embodiments, a vertically downward force applied to the second input actuator may result in torque applied to the motion transfer mechanism at the fourth axis. The torque applied may be in a direction opposite the torque applied when a vertically downward force is applied to the first input actuator.
In some embodiments, the second input actuator includes a pedal pad, the pedal pad having a surface maintaining a substantially horizontal orientation during movement of the pedal pad when force is applied to the second input actuator.
According to yet another aspect of the present disclosure, a brake system for a patient support apparatus having a base comprises a plurality of casters supporting the base on surface of a floor the casters having a plurality of modes, a caster mode changing mechanism moveable between a plurality of positions, and a plurality of pedals positioned to be moved by a user to move the caster mode mechanism between the plurality of positions, at least a first one of the plurality of pedals positioned adjacent a head end of the base. The caster mode changing mechanism coordinates movement of the plurality of pedals so that movement of any one of the plurality of pedals causes movement of the caster mode changing mechanism. Movement of the caster mode changing mechanism will thereby rotate a mode change key to change the mode of at least one caster. Downward movement of the at least one pedal positioned adjacent the head end of the base causes the caster mode key to move from a first position to a second position.
In some embodiments, the plurality of pedals includes a second one of the plurality of pedals positioned adjacent the head end of the base. Downward movement of the second one of the plurality of pedals causes the caster mode changing mechanism to move from the second position to the first position.
In some embodiments, downward movement of the second one of the plurality of pedals positioned adjacent the head end causes the first one of the plurality of pedals positioned adjacent the head end to move upwardly.
In some embodiments, the caster mode changing mechanism is supported for movement relative to a frame of the base of the patient support apparatus.
In some embodiments, the patient support apparatus further includes an input assembly positioned on a lateral side of the patient support apparatus, the input assembly operable to move the caster mode changing mechanism. In some embodiments, the input assembly comprises a pair of pedals coupled to a parallelogram linkage, the pedals maintaining a horizontal orientation during movement of the pedals between a first position and a second position.
In some embodiments, the plurality of pedals positioned adjacent the head end of the base each have a fulcrum axis that corresponds to a fulcrum of the pedal, the fulcrum axes of each of the plurality of pedals being generally collinear. In some embodiments, at least one of plurality of pedals positioned adjacent the head end of the base is coupled to the mechanism at a position above the fulcrum axes. In some embodiments, at least one of plurality of pedals positioned adjacent the head end of the base is coupled to the mechanism at a position below the fulcrum axes.
In some embodiments, at least two of plurality of pedals are positioned adjacent the head end of the base, the at least two pedals having generally collinear fulcrum axes with one of the at least two pedals coupled to the mechanism at a position below the fulcrum axes and another of the at least two pedals coupled to the mechanism at a position above the fulcrum axes.
Additional features and advantages of the invention will become apparent to those skilled in the art upon consideration of the following detailed description of illustrated embodiments exemplifying the best mode of carrying out the invention as presently perceived.
The detailed description of the drawings particularly refers to the accompanying figures in which:
A patient support apparatus, such as a hospital bed 2, for example, includes a mattress 4, an articulated deck 6 with movable sections, an upper frame 8, a lift mechanism 10, and a base 12. The base 12 of the patient support apparatus 2 includes a number of casters 14a, 14b, 14c, and 14d as shown in
The base 12 may be used in place of the base structure shown in the patient support apparatus described in either U.S. application Ser. Nos. 12/891,909, filed Sep. 28, 2010 and titled “Hospital Bed with Chair Lockout” and 12/957,491, filed Dec. 1, 2010 and titled “Removable Integrated Board and Partial Foot Section,” each of which is hereby incorporated by reference herein.
As will be discussed in further detail below, the brake mechanism of the bed 2 may include several embodiments, with certain elements of each embodiment being interchangeable to implement different input arrangements depending on the needs of a particular implementation.
In a first embodiment, the base 12 includes a mechanism 32, shown in
Depressing any one of the pedals 34, 36, 44, 46, 48, or 50 will cause the mechanism 32 to transfer motion from the depressed pedal throughout the mechanism 32 and to the other of the pedals 34, 36, 44, 46, 48, or 50. The mechanism 32 includes a number of hex shafts 52a, 52b, 52c, and 52d that engage to the respective casters 14a, 14b, 14c, and 14d. The casters 14a, 14b, 14c, and 14d include an internal mechanism which is actuated by rotation of the hex shafts 52a, 52b, 52c, and 52d to change the mode of the respective casters 14a, 14b, 14c, and 14d between the brake mode, neutral mode, and, if present, steer mode. The hex shafts 52a, 52b, 52c, and 52d each function as a mode change key, with rotation of a hex shaft 52a, 52b, 52c, or 52d changing the mode of the respective caster 14a, 14b, 14c, or 14d. An example of an illustrative caster 14a, 14b, 14c, and 14d is shown in Mobley et al., U.S. Pat. No. 6,321,878. Other casters may be used within the scope of this disclosure as will be understood by those of skill in the art.
The mechanism 32 includes two longitudinal arms 60 and 62 that are interconnected and supported by the pedals 34 and 36 and by a pair of brackets 64 and 66 so that the mechanism 32 is movable relative to a frame 54 of the base 12. Two brackets 68 and 70 depend from the respective arms 60 and 62 and are interconnected by a cross-bar 72 so that motion of one arm 60, 62 is transferred to the other of the arms 60, 62.
The frame 54 of the base 12 acts as a ground for the mechanism 32 so that components of the mechanism 32 move relative to the frame 54. The pedal 34 is pivotable relative to the frame 54 about an axis 56 and the pedal 36 is pivotable relative to the frame 54 about an axis 76. The arm 60 includes a flange 78 and the pedal 34 is pivotably coupled to the flange 78 at an axis 82. The axis 56 and the axis 76 are generally collinear. The pedal 36 includes a link 184 that is pivotably coupled to the arm 62 at an axis 80.
In operation, axis 56 and axis 76 are the ground point for the mechanism with the axis 82 being positioned above the axes 56 and 76 and the axis 80 positioned below the axes 56 and 76. The axis 56 acts as a fulcrum point for pedal 34 and the axis 76 acts as a fulcrum point for pedal 36. When a downward force is applied to the pedal 34 as indicated by arrow 84, the pedal tends to rotate about axis 56 with the force being transferred to a pin 90 at axis 82 so that the pin 90 is urged toward the head end 26 of the base 12 as indicated by arrow 86. A shaft 244 is positioned at the axis 56 and a pair of links 240 are coupled to shaft 244 and engaged by a pin 90. The arm 62 includes an oval aperture 242 that allows some lost motion between the pin 90 and the arm 62. The shaft 244 is supported on the frame 54 by two bearings 142. The links 240 each include a clamp that is used to secure the links 240 to the shaft 244. This causes the arm 60 to be moved in the direction of arrow 88. This motion is transferred throughout the mechanism 32 as will be discussed in further detail below. Similarly, the application of a force to the pedal 38 as represented by arrow 92 causes a pin 94 at axis 80 to be urged toward the foot end 24 of the base 12 as represented by a curved arrow 98. This motion is transferred through the pin 94 to the arm 62 and the arm 62 is urged in the direction of arrow 96. Thus, the force in the direction of arrow 92 acts on the mechanism 32 in a direction opposite the direction 84. Because the axis 82 is above the fulcrum point of pedal 34 and axis 80 is below the fulcrum point of pedal 38, the mechanism moves in opposite directions.
The pedal assemblies 38 and 40 are coupled to the arms 62 and 60 respectively. Referring now to pedal assembly 40, a pedal arm 100 is pivotably coupled to the bracket 64 and pivotable about an axis 102. A hex shaft 200 is engaged with the pedal arm 100 and supports the mechanism 32 for movement relative to the frame 54 of the base 12. A bearing 142 is engaged with the bracket 64 and receives one end of the hex shaft 200. A second bearing 142 is engaged with the outer wall 112 of the tube 114 of the frame 54. A cut-out 110 formed in the outer wall 112 of the tube 114 of the frame 54 permits movement of a pin 116 that couples the pedal arm 100 to the longitudinal arm 60. The pin 116 is supported in a bearing 148 that is received in the wall 112. When force is applied to pedal 48 as indicated by arrow 104, the mechanism 32 is moved in the direction of arrow 88. When a force is applied to pedal 50 as indicated by arrow 106, the mechanism 32 is moved in the direction of arrow 96. Thus, force in the direction 104 corresponds to a force in the direction 84 and a force in the direction of arrow 106 corresponds to a force in the direction of arrow 92 in terms of causing movement of the mechanism 32.
The mechanism 32 includes flange 118 that is coupled to the arm 60 to move therewith. The flange 118 includes an oval shaped aperture 120 that has a longitudinal length that is aligned vertically. A pin 122 secures the flange 118 to the bracket 68 with the bracket 68 being secured to the cross-bar 72. When the mechanism 32 is in the neutral position shown in the figures, the pin 122 is positioned in the upper most portion of the aperture 120. Movement of the mechanism 32 in either direction 88 or 96 causes the flange 118 to move and act on the pin 122. The movement of the pin 122 causes the bracket 68 to pivot relative to a support tube 124 that supports the cross-bar 72. The support tube 124 is secured to v-shaped bracket 126 that is secured to the tube 114 of the frame 54 of the base 12. The cross-bar 72 is supported in a bearing 128 that rotates relative to the support tube 124 such that the cross-bar 72 transfers movement of the pedal assembly 40 to a similar structure on the opposite side of the frame 54 so that motion of the pedals 48 and 50 is transferred to the pedals 34, 36, 44, and 46. The cross-bar 72 is hex-shaped and the bracket 68 includes a hex shaped opening 130 to secure the bracket 68 to the cross-bar 72 with a bolt 132 and a nut 134 used to clamp the bracket 68 to the cross-bar 72.
The motion of the mechanism 32 transfers rotation to the hex shafts 52a, 52b, 52c, and 52d in a similar manner, so the discussion will focus on the operation of caster 14a and hex shaft 52a. The caster 14a is supported in a caster post 136 that is secured to the tube 114. The hex shaft 52a is engaged with a hex shaped aperture 138 formed in a link 140. A bearing 142 is received in the wall of the tube 114 and supports the hex shaft 52a for rotation relative to the base 12. The bearing 142 also bears against the link 140 as it rotates. The link 140 also includes a circular aperture 144 that is positioned below the hex shaped aperture 138 when the mechanism 32 is in the neutral position. A pin 146 is received in the aperture 144 and is free to rotate relative to the link 140. The pin 146 is also received in a bearing 148 that is secured to the arm 60. An aperture 150 is formed in the wall of tube 114 to provide clearance for movement of the pin 146 as it rotates about the hex shaft 52a. The hex shaft 52a provides a ground point for the mechanism 32 to support at least a portion of the mechanism 32 as it moves relative to the frame 54. As the mechanism moves in the direction of arrow 88, the hex shaft 52a is rotated in the direction of arrow 152 and as the mechanism moves in the direction of arrow 96, the hex shaft 52a is moved in the direction of arrow 154.
Because casters 14b and 14c are positioned on the opposite side of the frame 54 from the casters 14a and 14d, the motion transferred to the casters 14a, 14b, 14c, and 14d is effectively the same action on the internal mechanism if the casters 14a, 14b, 14c, and 14d.
It should be noted that pedal assemblies 38 and 40 have pedal covers such as those shown on pedal 44 and 46 respectively, with the pedal covers omitted from pedals 48 and 50. The pedal covers are color codes so that a user may readily recognize the resulting action from stepping on one of the pedals 44, 46, 48, and 50. Similarly, pedals 34 and 36 are color coded so that a user will recognize that pedals 34, 50, and 46 all result in the same action, such as activating the brake mode, for example, and pedals 36, 44, and 48 all result in the same action, such as activating the steer mode, for example. With this configuration, a user may step on pedal 34 to move the casters to a first non-neutral mode from the neutral mode. A user may then step on pedal 36 to return to the neutral mode or with continued actuation, move the casters to a second, non-neutral mode.
In another embodiment shown in
In the embodiment of
As shown in
Referring now to
The transfer bar 328 is coupled to the follower 334 and is centered on the axis 332 to transfer rotation of the hex shaft 330 and follower 334 to the actuation mechanism 326 as will be described in further detail below. In addition, if the actuation mechanism 326 receives an input, movement of the actuation mechanism 326 will be transferred to the actuation mechanism 324 through the transfer bar 328.
In the illustrative embodiment of
It should be understood that in some embodiments, actuation mechanism 350 may be supported from the caster 14b such that the hex rod 352 is operable to change the mode of caster 14b.
Referring now to
Referring now to
The actuator 362 includes a force receiving area 378 which corresponds to the pedal 306 in the embodiment of
In yet another embodiment of an actuation mechanism 380 shown in
The actuation mechanism 380 can be used as a direct replacement for the actuation mechanism 360 as the relationship between the motion of the actuator 382 and the transfer arm 316 is similar to that of the actuator 362 in the actuation mechanism 360.
Referring to
In other embodiments, an actuator 410 may be coupled to the hex rod 352 as shown in
In yet another embodiment, the actuation mechanism 350 may include an input assembly 420 that is configured as a parallelogram linkage to maintain a first pedal 422 and a second pedal 424 in a level configuration throughout the rotation of the hex rod 352 as shown in
The link 434 is supported on the hex rod 352 and pivots about the axis 354. The link 436 is pivotably supported on pin 444 that is fixed to the frame 300 with the link 436 pivotable about an axis 446 defined by the pin 444. A second actuator 448 supports the pedal 424 and is pivotably connected to the links 434 and 436 by respective pins 450 and 452. The pins 450 and 452 each define a respective pivot axis 454 and 456 which lies on a line 458. The axis 354 of the hex rod 352 and the axis 446 of the pin 444 also lie on a line 460. Each side of the input assembly 420 defines a four bar parallelogram linkage that is grounded on the hex rod 352 and pin 444 such that movement of either actuator 426 or actuator 448 vertically, causes the links 434 and 436 to pivot on the respective axes 354 and 446 through an angle 480 shown in
It should be understood that the actuation mechanisms disclosed herein may be positioned at multiple locations around the perimeter of the base 12 such that one or more actuation mechanisms may be used to actuate a caster mode mechanism between multiple positions to thereby position the respective casters in a specific mode by rotating the mode key, which is embodied as a hex rod. An actuation mechanism acts on a mode key by transferring a torque to the mode key to rotate the mode key and change the mode of a caster. In some embodiments, an actuation mechanism includes an actuator that, when acted on by a force, transfers the force to the mode key. The direction of rotation of the mode key may be reversed for a given input force by configuring the actuation mechanism to operate with a reverse torque.
It should be understood that the various actuation mechanisms 324, 326, 350, 360, and 380 as well as mirrored actuation assemblies may be applied at multiple locations about the base 12, to create various mode conditions. For example, the some pedals may move downwardly when a first pedal is pushed down while others may move up. In some embodiments, some pedals may move up and some may move down with a given motion. In other embodiments, all of the pedals may move in the same direction. A single actuator may be used to change the mode of all of the casters, or a portion of the caster mode mechanism may operate independently from the remainder of the caster mode mechanism.
Still further, a powered device may be used to apply a force to an actuator to change the caster mode within the scope of this disclosure.
Although the invention has been described with reference to the preferred embodiments, variations and modifications exist within the scope and spirit of the invention as described and defined in the following claims.
This application claims the priority benefit of an earlier filing date of U.S. Provisional Application Ser. No. 61/440,749, filed Feb. 8, 2011 which is hereby incorporated by reference herein.
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