Patent Publication Number: US-2023133573-A1

Title: Height adjustable platforms and associated mechanisms

Description:
CLAIM OF PRIORITY 
     This patent application is a continuation of Kottman, et al. U.S. patent application Ser. No. 17/305,546, entitled “HEIGHT ADJUSTABLE PLATFORMS AND ASSOCIATED MECHANISMS,” filed on Jul. 9, 2021 (Attorney Docket No. 5983.426US3), which is a continuation of Kottman, et al. U.S. patent application Ser. No. 16/855,784, entitled “HEIGHT ADJUSTABLE PLATFORMS AND ASSOCIATED MECHANISMS,” filed on Apr. 22, 2020 (Attorney Docket No. 5983.426US2), which is a continuation of Lindblad, et al. U.S. patent application Ser. No. 16/290,840, entitled “HEIGHT ADJUSTABLE PLATFORMS AND ASSOCIATED MECHANISMS,” filed on Mar. 1, 2019 (Attorney Docket No. 5983.426US1), which claims the benefit of priority of Lindblad, et al. U.S. Provisional patent application Ser. No. 62/637,562, entitled “HEIGHT ADJUSTABLE PLATFORMS AND ASSOCIATED MECHANISMS,” filed on Mar. 2, 2018 (Attorney Docket No. 5983.426PRV), which is hereby incorporated by reference herein in its entirety. Additionally, this patent application claims the benefit of priority of Runger, et al. U.S. Provisional patent application Ser. No. 62/721,351, entitled “WORKSURFACE OPENING MECHANISM,” filed on Aug. 22, 2018 (Attorney Docket No. 5983.426PV2), which are hereby incorporated by reference herein in their entireties. 
    
    
     TECHNICAL FIELD 
     This document pertains generally, but not by way of limitation, to workstations. 
     BACKGROUND 
     Workstations can be freestanding (e.g., supported by a floor), coupled to a structure (e.g., a wall), or mobile (e.g., attached to a wheeled base). The workstation can include a worksurface, and the worksurface can allow a user to accomplish one or more tasks (e.g., writing, typing, manufacturing operations, or the like). 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In the drawings, which are not necessarily drawn to scale, like numerals may describe similar components in different views. Like numerals having different letter suffixes may represent different instances of similar components. The drawings illustrate generally, by way of example, but not by way of limitation, various embodiments discussed in the present document. 
         FIG.  1    shows an example of a height adjustable wall mount assembly. 
         FIG.  2    shows a front view of a riser. 
         FIG.  3    shows a cross-sectional of one example of a support bracket. 
         FIG.  4    shows a perspective view of the wall mount assembly of  FIG.  1   , including the support bracket of  FIG.  3   . 
         FIG.  5    shows a detailed perspective view of the wall mount assembly. 
         FIG.  6    shows another perspective view of the support bracket. 
         FIG.  7    shows a perspective view of a lock release assembly and the support bracket of  FIG.  3   . 
         FIG.  8    shows a perspective view of a tilting work station. 
         FIG.  9    shows a detailed perspective view of the tilting work station of  FIG.  8   . 
         FIG.  10    shows a detailed perspective view of the tilting work station of  FIG.  8    with a lock assembly in an unlocked configuration. 
         FIG.  11    shows a perspective view of the tilting work station of  FIG.  8    with the lock assembly in the locked configuration. 
         FIG.  12    shows a detailed perspective view of the tilting work station of  FIG.  8    with the lock assembly in an unlocked configuration. 
         FIG.  13    shows a perspective view of the height adjustable wall mount assembly of  FIG.  1    including an attachment system. 
         FIG.  14    shows a front view of the wall mount assembly including the attachment system of  FIG.  13   . 
         FIG.  15    shows another perspective view of the height adjustable wall mount assembly of  FIG.  1    including an attachment system of  FIG.  13   . 
         FIGS.  16 A- 16 C  show detailed perspective views of an interface assembly. 
         FIGS.  17 A- 17 C  show perspective views of an attachment mechanism. 
         FIGS.  18 A- 18 B  show additional perspective views of the attachment mechanism of  FIGS.  17 A- 17 C . 
         FIG.  19    shows a front view of the wall mount assembly of  FIG.  1    and the attachment system of  FIG.  13    during an installation operation. 
         FIG.  20    shows a perspective view of an example of a keyboard tray including a height adjustment mechanism. 
         FIG.  21    shows a front view of the keyboard tray of  FIG.  20   . 
         FIG.  22    shows a detailed perspective view of the keyboard tray of  FIG.  20   . 
         FIG.  23    shows another detailed perspective view of the keyboard tray of  FIG.  20   . 
         FIG.  24    shows a side view of an example of a mobile workstation. 
         FIG.  25    shows a perspective view of a display mount assembly. 
         FIG.  26    shows another perspective view of the display mount assembly. 
         FIG.  27    shows a perspective view of a display arm assembly in an expanded configuration. 
         FIG.  28    shows a perspective view of the display arm assembly in a contracted configuration. 
         FIGS.  29 A- 29 C  show perspective and top views the display arm assembly in an offset configuration. 
         FIG.  30    shows a perspective view of one example of a keyboard tray. 
         FIG.  31    shows a detailed view of an attachment bracket. 
         FIGS.  32 A- 32 B  show a top view of the keyboard tray in an expanded configuration and a contracted configuration. 
         FIGS.  33 A- 33 B  show a top view of the keyboard tray in a rotated configuration. 
         FIG.  34 A- 34 B  show perspective views of an example of a head unit that can optionally include a computer storage compartment. 
         FIG.  35    shows a perspective view of an example of the mobile cart of  FIG.  24    that can optionally include one or more cable access holes. 
         FIG.  36    shows a perspective view of the head unit. 
         FIGS.  37 A- 37 B  show perspective views of a wheeled base of the mobile work station. 
         FIG.  38    shows a perspective view of another example of the mobile workstation. 
         FIG.  39    shows a perspective view of an example of an accessory holder. 
         FIG.  40    shows a perspective view of an example of a strap. 
         FIG.  41    shows a perspective view of the head unit including a worksurface. 
         FIG.  42    shows another perspective view of the head unit. 
         FIG.  43    shows yet another perspective view of the head unit. 
         FIG.  44    shows a perspective view of a worksurface opening mechanism and glides. 
         FIG.  45    shows a detailed perspective view of a glide. 
         FIG.  46    shows another perspective view of the worksurface opening mechanism and the glide. 
         FIG.  47    shows yet another perspective view of the worksurface opening mechanism and the glide. 
         FIG.  48    shows a detailed perspective view of an example of the worksurface opening mechanism. 
         FIG.  49    shows another perspective view of the glide. 
         FIG.  50    shows yet another perspective view of the glide. 
         FIG.  51    shows a front view of the mobile workstation  2400 . 
         FIG.  52    shows a detailed side view of the head unit and the worksurface. 
         FIG.  53    shows a side view of the head unit, the glide, and the worksurface opening mechanism. 
         FIG.  54    shows another side view of the head unit, the glide, and the worksurface opening mechanism. 
         FIG.  55    shows a side view of the worksurface opening mechanism and the glides. 
     
    
    
     DETAILED DESCRIPTION 
       FIG.  1    shows an example of a height adjustable wall mount assembly  100 . In some examples, a worksurface  110  can be included in the wall mount assembly  100 . The height adjustable wall mount assembly  100  can include a fixed riser  120 , and a sliding bracket  130 . The fixed riser  120  can be fixedly attached to a structure, such as a wall. The fixed riser  120  can have a width, a height extending in vertical direction, and a depth. The sliding bracket  130  can be slidingly engaged with the fixed riser  120 . The sliding bracket  130  can translate with respect to a portion of the fixed riser  120 , for instance a frame  140  of the fixed riser  120 . 
       FIG.  2    shows a front view of the riser  120 . A height adjustment mechanism  200  can be connected between the fixed riser  120  and the sliding bracket  130  to provide height adjustment for the workstation  100 . The height adjustment mechanism  200  can further include a lock assembly  210 . The lock mechanism can maintain the worksurface  110  at a desired height by immobilizing the height adjustment mechanism  200 . 
     The frame  140  can define one or more mounting features, such as a mounting hole  220 . The mounting features can be adapted to help couple (e.g., affix, attach, or the like) the riser  120  with a support structure (e.g., a wall, a cubicle wall, a free-standing frame, or the like). The frame  140  can be adapted to house, and otherwise support, components of the wall mount assembly  100 . 
     The sliding bracket  130  can be adapted to couple with, and thereby support, components of the wall mount assembly  100 , for instance the work surface  110 . The sliding bracket  130  can be moveably coupled with the frame  140  such that the sliding bracket  130  is adapted to translate with respect to the frame  140 . A portion of the sliding bracket  130  can engage with a portion of the frame  140 , and thereby moveably couple the sliding bracket  130  with the frame  140 . In an example, the frame  140  defines a keyway and the sliding bracket  130  includes a key. The keyway can be sized and shaped to receive the key. The key can be sized and shaped to engage with the keyway. The engagement of the key with the keyway can help moveably couple the sliding bracket  130  with the frame  140 . 
     As described in this disclosure, the sliding bracket  130  can translate with respect to the frame  140 , e.g., linear translation, which can change the height of the sliding bracket  130  (and components attached to the sliding bracket  130 , such as the worksurface  110 ). 
     The riser  120  can include a counterbalance mechanism  230 , and the counterbalance mechanism  230  can be included in the height adjustment mechanism  200 . The counterbalance mechanism  230  can include one or more springs  231 . The counterbalance mechanism  230  can include a wheel cable  232  (e.g., a tensile member). One end of the wheel cable  232  can be coupled to the sliding bracket  130 , and the other end of the wheel cable  232  can be coupled to the one or more springs  231 . The counterbalance mechanism  230  can include a wheel/cam assembly  233 . The wheel cable  232  can engage with a portion of the wheel/cam assembly  233 . Additionally, the wheel cable  232  can engage with a pulley  234 . 
     In another example, the counterbalance mechanism  230  can include a plurality of wheel cables  232 . For instance, one end of a first wheel cable  232  can be coupled to the sliding bracket  130 , and the other end of the first wheel cable  232  can be coupled to the wheel/cam assembly  233 . A second wheel cable  232  can be coupled between the wheel/cam assembly  233  and the one or more springs  231 . 
     Referring again to  FIG.  2   , the springs  231 , the wheel cable  232 , and the wheel/cam assembly  233  can cooperate to help counterbalance a force applied to the sliding bracket  130 . Counterbalancing the force applied to the sliding bracket  130  can help maintain the amount of force required to translate the sliding bracket  130  with respect to the frame  140 . Stated another way, the counterbalance mechanism  230  can be adapted to support the sliding bracket  130  such that the amount of force necessary to translate the sliding bracket  130  with respect to the frame  140  remains substantially constant, despite increasing force created by the springs  231  during translation. Additionally, the counterbalance mechanism  230  can help maintain a position of the sliding bracket  130  with respect to the frame  140 , such as by providing a lift force equivalent to the combined weight of the sliding bracket  130  and all the components connected to it, including (but not limited to) the worksurface  110  (shown in  FIG.  1   ). 
     In an example, the sliding bracket  130  is coupled to the counterbalance mechanism  230  and the work surface  110  (shown in  FIG.  1   ). For example, a user can place a fifteen-pound object on the work surface  110 , and the counterbalance mechanism  230  can help maintain the position (e.g., height) of the sliding bracket  130  (and thereby the work surface  110 ) with respect to the user. Moreover, if the user desires to change the position of (e.g., raise or lower) the work surface  110 , the counterbalance mechanism  230  helps maintain the amount of force necessary to change the position of the sliding bracket  130  (and thereby the work surface  110 ) such that the amount of force necessary to change the position of the sliding bracket  130  with respect to the frame  140  is substantially the same whether or not the fifteen-pound load is applied to the work surface  110 . 
     Referring again to  FIG.  2   , the wall mount assembly  100  can include a lock rod  240 . The lock rod  240  can be coupled to the frame  140 . Although the lock rod  240  can be positioned internally within, or externally of, the frame  140 , the specific configuration depicted in  FIG.  2    depicts the lock rod  240  positioned on an external side of the frame  140 . The lock rod  240  can be spaced from the frame  140  at a first distance (e.g., a gap can exist between the lock rod  240  and the frame  140 ). The lock rod  240  can have a circular, square, rectangular, other geometric shape, or irregular cross-section (e.g., the lock rod  240  can define a keyway). 
     As described in this disclosure, the wall mount assembly  100  can include the lock assembly  210 . The lock assembly  210  can be sized and shaped to receive the lock rod  240 . The lock assembly  210  can be adapted to selectively translate with respect to (e.g., along) the lock rod  240 . The lock assembly  210  can be coupled to, or included in, the sliding bracket  130 . The lock assembly  210  can help maintain the position of the sliding bracket  130  with respect to the frame  140 . The lock assembly  210  can be coupled to the worksurface  110  (shown in  FIG.  1   ). The lock assembly  210  can be adapted to couple with the worksurface  110 , such as indirectly with the sliding bracket  130  or directly to the worksurface  110 . The lock assembly  210  can help maintain the position of the worksurface  110  with respect to the riser  120  (or the frame  140 ). In an example, the lock assembly  210  can translate in a first direction (e.g., vertically) with respect to the lock rod  240 . The translation of the lock assembly  210  in the first direction can correspondingly cause the worksurface  110  to translate in the first direction. 
       FIG.  3    shows a front view of one example of a support bracket  300 . Portions of the support bracket  300  can be removed for clarity. One or more of the support bracket  300  can be included in the wall mount assembly  100  (shown in  FIG.  1   ). For instance, the support bracket  300  can be coupled to the sliding bracket  130  (shown in  FIG.  1   ). In some examples, the support bracket  300  includes a U-shaped cross-section. The support bracket  300  can include a first side  310 , a second side  320  opposite the first side  310 , and a third side  330  connecting a lower end of the first  310  and second sides  310 ,  320 . The height of the first side  310  and the second side  320  can increase as the cross section approaches a rear end of the support bracket  300  where the support bracket  300  can be coupled to the sliding bracket  130  to provide additional structural support for the worksurface  110 . A first flange  340  and a second flange  350  can be formed at upper ends of the first side  310  and the second side  320 , respectively. A worksurface  110  can be attached to the support bracket  300  through one or more apertures located on the first and second flanges  340 ,  350  (e.g., one or more fasteners can extend through the apertures to couple the worksurface  110  and the support bracket  300 ). 
       FIG.  4    shows a perspective view of the wall mount assembly  100  of  FIG.  1   , including the support bracket  300  of  FIG.  3   . A lock release assembly  400  can be operationally connected to the worksurface  110  (shown in  FIG.  1   ). The lock release assembly  400  can be used to selectively release the lock mechanism  210  to adjust the height of the worksurface  110 . The lock release assembly  400  can be partially located inside the support bracket  300 , for instance as illustrated in  FIG.  4   . The lock release assembly  400  can include a fixed handle bracket  410 , and an elongated member  420 . In some examples, the fixed handle bracket  410  can be attached to the underside of the worksurface  110  (shown in  FIG.  1   ). A handle  430  can be connected to a first end  421  of the elongated member  420 . In some examples, the handle  430  can be slidingly engaged with the fixed handle bracket  410 . The handle  430  can be located at a first distance  450  from the support bracket  300 . 
     Additionally, a second end  422  of the elongated member  420  can extend into the support bracket  300 . As described in greater detail herein, the elongated member  420  can include one or more connection holes  440  along a length of the elongated member  420 . The one or more connection holes  440  can facilitate repositioning the handle  430  with respect to the support bracket  300 . For instance, the connection holes  440  can facilitate repositioning the handle  430  at a second distance from the support bracket  300  (e.g., the second distance  700  shown in  FIG.  7   ). 
       FIG.  5    shows a detailed perspective view of the wall mount assembly  100 . As described in this document, the handle  430  can be slidingly engaged with the fixed handle bracket  410 . In an example, the fixed handle bracket  410  can include a groove  500 , and the handle  430  can be sized and shaped to receive the groove  500  (e.g., the sliding handle  430  can define a channel that can be sized and shaped to receive the groove  500 ). 
       FIG.  6    shows another perspective view of the support bracket  300 . A portion of the support bracket  300  is hidden to show internal components of the support bracket  300 . A first guide bracket  600  and a second guide bracket  610  can be coupled with the support bracket  300 , and the first guide bracket  600  can be spaced apart from the second guide bracket  610 . The first guide bracket  600  and the second guide bracket  610  can define a first aperture  601  and a second aperture  611 , respectively. The elongated member  420  can pass through the first aperture  601  and the second aperture  611 . For instance, the elongated member  420  can be slidably engaged with the first aperture  601  and the second aperture  611 . The first aperture  601  and the second aperture  611  can provide guidance for the elongated member  420  during translation of the elongated member  420  with respect to the support bracket  300 . 
     A connecting bracket  620  can be fixedly attached to the elongated member  420 . The connecting bracket  620  can include a first face  621 , a second face  622 , and a third face  623 . The first face  621  can be parallel with the second face  622 , and the third face  623  can connect the first face  621  and the second face  622 . The first face  621  can define a third aperture  624 , and the second face  622  can define a fourth aperture  625 . The elongated member  420  can pass through the third aperture  624  and the fourth aperture  625 . The third face  623  of the connecting member  630  can define a hole  626 . A fastener  630  can be inserted through the hole  626 , and the fastener  630  can be engaged with the elongated member  420 . For instance, the fastener  630  (e.g., a screw, pin, or the like) can be engaged with the one or more connection holes  440  to couple the connecting member  620  with the elongated member  420 . In some examples, the connecting member  620  can be located between the first guide bracket  600  and the second guide bracket  610 . 
     The lock release assembly  400  can further include a biasing member  640  (e.g., a spring). The biasing member  640  can be located between the second guide bracket  610  and the second face  622  of the connecting bracket  620 . The biasing member  640  can be coupled to the guide bracket  610  and the connecting bracket  620 , and the biasing member  640  can bias the connecting bracket  620  in first direction (e.g., as denoted by the arrow  660  shown in  FIG.  6   ). The connecting bracket  620  can engage with a stop  670 , and the stop  670  can inhibit the movement of the connecting bracket  620  relative to the support bracket  300 . In an example, the stop  670  can be included in the second guide bracket  610 . In another example, stop  670  can be coupled with a portion of the support bracket  300 . A user can operate (e.g., pull, twist, push, or the like) the handle  430 , and operation of the handle  430  can displace the connecting bracket  620  in a second direction opposite to the first direction (e.g., along a length axis of the elongated member  420 ). Displacement of the connecting bracket  620  can displace the biasing member  640 , and when the handle  430  is released, the biasing member  640  can bias the connecting bracket  620  in the first direction to engage with the stop  670 . 
     Referring again to  FIG.  6   , the lock release assembly  400  can include a lock release cable  650 . The lock release cable  650  can be coupled with the connecting bracket  620  (e.g., the second face  622 ) and with the lock mechanism  210  (shown in  FIG.  2   ). As described herein, a user can operate the handle  430 , and displace the connecting member  620 , for instance in the second direction. The connecting bracket  620  can correspondingly displace the lock release cable  650 , and displacement of the lock release cable  650  can operate the lock mechanism  210 , and facilitate height adjustment of the worksurface  110 . 
     As described in this document, the handle  430  can be repositioned with respect to the support bracket  300 . In an example, the wall mount assembly  100  can accommodate work surfaces  110  of varying dimensions (e.g., varying depths). Repositioning the handle  420  with respect to the support bracket  300  can allow the handle  430  to be mounted proximate to the front edge of the worksurface  110 , for instance to ease accessibility to the handle  430  by the user. 
       FIG.  7    shows a perspective view of the lock release assembly  400  and the support bracket  300  of  FIG.  3   . As described in this document, the handle  430  (and the fixed handle bracket  410 ) can be located at a first distance  450  (shown in  FIG.  4   ) from the support bracket  300 . In another example the handle  430  can be located at a second distance  700  from the support bracket  300 . Repositioning the handle  430  can facilitate locating the handle  430  proximate to a front edge of the work surface  110 . The second distance  700  can be larger than the first distance  450  (shown in  FIG.  4   ). 
     Repositioning the handle  430  can be achieved while keeping the first guide bracket  600 , second guide bracket  610 , and connecting bracket  620  at the same position relative to the support bracket  300 . In an example, the handle  460  can be repositioned by disengaging the fastener  630  from the one or more connecting holes  440 . Disengaging the fastener  630  from the connecting holes  440  can allow the elongated member  420  to translate relative to the connecting bracket  630 . Translating the elongated member  420  relative to the connecting bracket  630  can vary the distance between the handle  430  and the support bracket  300  (e.g., between the first distance  450  and the second distance  700 ). The fastener  630  can be inserted through the connecting bracket  620 , and engaged with the connecting holes  440 . The engagement of the fastener  630  with the connecting holes  440  can inhibit the translation of the elongated member  420  with respect to the connecting bracket  620 . Accordingly, when the fastener  430  is engaged with the connecting bracket  430  and the connecting holes  440 , the handle  430  can be operated to displace the lock release cable (shown in  FIG.  6   ) and operate the lock assembly  210  (shown in  FIG.  2   . 
       FIG.  8    shows a perspective view of a tilting work station  800 . The tilting work station  800  can include the height adjustable wall mount assembly  100 . An attachment bracket  810  can be coupled to the sliding bracket  130 . The attachment bracket  810  can include a hinge  820 , and the support bracket  300  can be coupled to the attachment bracket  810 . In an example, the support bracket  300  can rotate about the hinge  820 , and the rotation of the support bracket  300  can allow the worksurface  110  to transition between a horizontal position and a vertical position. A hook pin  830  can be coupled with the attachment bracket  810 . 
       FIG.  9    shows a detailed perspective view of the tilting work station  800  of  FIG.  8   . The work station  800  can include a lock assembly  900 , and the lock assembly  900  can include the hook pin  830 . The hook pin  830  can extend between sides of the attachment bracket  810 . In some examples, the hook pin  830  can be can be located proximate to an upper end of the attachment bracket  810 . Additionally, the hinge  820  can extend between the sides of the attachment bracket  810 , and the hinge  820  can be located proximate a lower end of the attachment bracket  810 . Further, the hinge  820  can be spaced apart from the hook pin  830 . 
       FIG.  10    shows a detailed perspective view of the tilting work station  800  of  FIG.  8    with the lock assembly  900  in an unlocked configuration. The lock assembly  900  can include a latch assembly  1000 , and the latch assembly  1000  can include a first arm  1010 . The first arm  1010  can define a pin channel  1020 , and the pin channel  1020  can be sized and shaped to receive the hook pin  830 . The locking assembly  900  can be in the unlocked configuration when the hook pin  830  is not received within the pin channel  1020 . Additionally, the lock assembly  900  can include a locked configuration, and the lock assembly  900  can be in the locked configuration when the hook pin  830  is received within the pin channel  1020 . The reception of the hook pin  830  within the pin channel  1020  can prevent the support bracket  300  from rotating about the hinge  820 . For instance, the hook pin  830  can engage with a channel wall  1030  of the pin channel  1020 , and the engagement can maintain the worksurface  110  (shown in  FIG.  8   ) in a horizontal position. 
       FIG.  11    shows a perspective view of the tilting work station  800  of  FIG.  8    with the lock assembly  900  in the locked configuration. Portions of the tilting work station  800  have been removed from  FIG.  11    for clarity. For instance, the worksurface  110  shown in  FIG.  9   , and sides of the support bracket  300  have been removed from  FIG.  11    for clarity. As shown in  FIG.  11   , the hook pin  830  is received within the pin channel  1020 . Accordingly, the support arm  300  is located in a horizontal position. 
     As described in this document, the latch assembly  1000  can include the first arm  1010 . Additionally, the latch assembly  1000  can include a second arm  1100  coupled with the first arm  1010 . For instance, the first arm  1010  can be rotatingly coupled with the second arm  1100  with an arm hinge  1110 . The arm hinge  1110  can be coupled with the support bracket  300 , and the arms  1010 ,  1100  can rotate with respect to the support bracket  300 . In another example, the first arm  1010  and the second arm  1100  can be formed as integral parts of a single component, and the arms  1010 ,  1100  can rotate about the arm hinge  1110 . 
     The latch assembly  1000  can include a latch operator  1120 , and manipulation of the latch operator  1120  can displace the arms  1010 ,  1100  relative the support bracket  300 . For instance, the operator  1120  can be coupled with a latch bar  1130 , and the latch bar  1130  can translate with respect to the support bracket  300  (e.g., the latch bar  1130  can slide within the support  300  when the latch operator  1120  is manipulated by a user). The latch bar  1130  can include a catch  1140 , and the catch  1140  can engage with the arm  1110  to displace the arm  1010 . In this example, because the arms  1010 ,  1100  are coupled together, displacement of the arm  1100  correspondingly displaces the arm  1010  (e.g., the arms  1010 ,  1100  rotate about the arm hinge  1110  when the arm  1100  is displaced). As described in greater detail in this document, displacement of the arms  1010 ,  1100  can disengage the hook pin  830  from the pin channel  1030 , and allow the lock assembly  900  to transition from the locked configuration to the unlocked configuration. 
       FIG.  12    shows a detailed perspective view of the tilting work station  800  of  FIG.  8    with the lock assembly  900  in an unlocked configuration. The latch assembly  1000  can include a biasing member  1200 , and the biasing member  1200  can bias the first arm  1010  toward engagement with the lock pin  830 . As described herein, the pin channel  1020  can receive the hook pin  830 . In an example, the biasing member  1200  can bias the arm  1010  to maintain the hook pin  830  within the pin channel  1020 . Manipulation of the latch operator  1120  can overcome the bias of the biasing member  1200 , and allow for the hook pin  830  to disengage from the pin channel  1030 . 
     Additionally, the arm  1010  can include a cam surface  1210 , and the cam surface  1210  can be configured to engage with the hook pin  830 . The engagement of the cam surface  1210  with the hook pin  830  can displace the arm  1010 , and allow for reception of the hook pin  830  in the pin channel  1020 . In an example, the work surface  110  can be transitioned from a vertical (e.g., storage) position to a horizontal (e.g., working) position. The cam surface  1210  can allow for the locking assembly  900  to transition to the locking configuration when the work surface  110  (shown in  FIG.  1   ) is raised to the horizontal position. The hook pin  830  can engage with the cam surface  1210  when the work surface is raised, and align with the pin channel  1020 . The biasing member  1020  can bias the arm  1010  toward engagement with the hook pin  830 , and the hook pin  830  can be received in the pin channel  1020 . Accordingly, the cam surface  1210  can allow the locking assembly  800  to transition into the locked configuration when the work surface  110  is raised. 
       FIG.  13    shows a perspective view of the height adjustable wall mount assembly  100  of  FIG.  1    including an attachment system  1300 . As described in this document, the height adjustable wall mount assembly  100  can be directly attached to a structure (e.g., a wall). In another example, the wall mount assembly  100  can be attached to a structure (e.g., a wall, a wall panel, a cubicle wall, or the like) with the attachment system  1300 . As discussed in greater detail in this document, the attachment system  1300  can allow the wall mount assembly  100  to couple with a structure having varying dimensions or characteristics. 
       FIG.  14    shows a front view of the wall mount assembly  100  including the attachment system  1300  of  FIG.  13   . As described in this document, the attachment system  1300  can allow the wall mount assembly  100  to couple with a structure having varying dimensions or characteristics. In an example, the structure can include slotted brackets  1400 A,  1400 B that include a plurality of slots  1410 , and the plurality of slots  1410  can be arranged in series (e.g., spaced apart and arranged in a column). The attachment system  1300  can engage with the slots  1410  and allow the mount assembly  100  to couple with the structure. 
       FIG.  15    shows another perspective view of the height adjustable wall mount assembly  100  of  FIG.  1    including an attachment system  1300 . In an example, the attachment system  1300  can include a first interface assembly  1500  and a second interface assembly  1510 . The interface assemblies  1500 ,  1510  can be coupled to the structure on a first side. Additionally, the interface assemblies  1500 ,  1510  can be coupled to the riser  120  on a second side to couple the mount assembly  100  to the structure. In an example, the riser  120  can include a first engaging bracket  1520 , a second engaging bracket  1530 , and a third engaging bracket  1540 . The engaging brackets  1520 ,  1530 ,  1540  can be sized and shaped to receive the interface assemblies  1500 ,  1510 , and the reception of the interface assemblies  1500 ,  1510  by the engaging brackets  1520 ,  1530 ,  1540  can couple the riser  120  with the interface assemblies  1500 ,  1510 . 
       FIGS.  16 A- 16 C  show detailed perspective views of the interface assembly  1500 . The interface assembly  1500  can include an elongated support member  1600  and an insert  1610 . The support member  1600  can be sized and shaped to receive the insert  1610 , and the insert  1610  can be located in an end  1605  of the support member  1600 . An outside profile of the insert  1610  can at least partially correspond with the inside profile of the support member  1600 . The insert  1610  can be located in the support member  1600  and one or more fasteners  1620  can be used to couple the insert  1610  with the support member  1600 . 
     The insert  1610  can include an insert body  1611  and a key  1612  (e.g., a cone, protrusion, or the like). The key  1612  can extend from the insert body  1611 . the key  1612  can have a slight taper from a first end to a second end of the key  1612 . A threaded hole  1613  can be defined in the key  1612 , and the threaded hole  1613  can receive a fastener to couple the insert with other components of the attachment system  1300 . 
       FIGS.  17 A- 17 C  show perspective views of an attachment mechanism  1700 . The attachment mechanism  1700  can be included in the interface assembly  1500 . The attachment mechanism  1700  can couple with the slotted brackets  1400 A,  1400 B (shown in  FIG.  14   ). For instance, the attachment mechanism  1700  can include a first tab  1710  having a first hook protrusion  1720 , and a second tab  1730  having a second hook protrusion  1740 . The hook protrusions  1720 ,  1740  can be received in the slots  1410 , and the reception of the hook protrusions  1720 ,  1740  in the slots  1410  can couple the attachment mechanism  1700  with the slotted brackets  1400 A,  1400 B. 
     As shown in  FIGS.  17 A and  17 C , the first hook protrusion  1720  can be oriented in a first direction and the second hook protrusion  1740  can be oriented in a second direction. For example, the first hook protrusion  1720  can include a first channel  1721  that opens in the first direction (e.g., downward). The second hook protrusion  1740  can include a second channel  1741  that opens in the second direction (e.g., upward). 
     The tabs  1710 ,  1730  can be coupled with an attachment body  1750 . One or more of the tabs  1710 ,  1730  can translate with respect to the attachment body  1750 , for example to couple the attachment mechanism  1700  with the slotted brackets  1400 A,  1400 B (shown in  FIG.  14   ). In an example, a nut  1760  can be located in the attachment body  1750  and located proximate to a first flange  1711  of the tab  1710 . A bolt  1770  can be inserted through a second flange  1731  of the tab  1730  and the bolt  1770  can engage with the nut  1760 . A user can manipulate (e.g., turn, twist, drive, or the like) the bolt  1770  and manipulation of the bolt  1770  can translate the tab  1720  with respect to the attachment body  1750 . 
     As described in this document, the attachment mechanism  1700  can couple with the slotted brackets  1400 A,  1400 B (shown in  FIG.  14   ). In an example, the attachment mechanism can clamp to the slotted brackets  1400 A,  1400 B. The hook protrusions  1720 ,  1740  can be located in the slots  1410  (shown in  FIG.  14   ) and the second tab  1730  can be translated with respect to the attachment body  1750  to close the distance between the tabs 1710 ,  1730  (and accordingly between the hook portions  1720 ,  1740 ). 
     Referring again to  FIG.  17 A- 17 C , the attachment body  1750  can define a keyway  1780 . The keyway  1780  can be sized and shaped to receive the key  1612  of the insert  1610  (shown in  FIGS.  16 A- 16 C ). The engagement of the key  1612  with the keyway  1780  can mate the insert  1610  with the attachment mechanism  1700 . The keyway  1780  can have a keyway profile that corresponds to the key profile of the key  1612 . In an example, the keyway  1780  can be tapered to correspond to the tapered profile of the key  1612 . 
     A first through hole  1790 A can be defined in the attachment body  1750 . The first through hole  1790 A can allow access to the bolt  1770 , and allow a user to manipulate the bolt  1770  and translate the tabs  1710 ,  1730  relative to the attachment body. Additionally, a second through hole  1790 B can be defined in the attachment body  1750 . A fastener (e.g., a screw) can be inserted into the through hole  1790 B to couple the insert  1610  (shown in  FIGS.  16 A- 16 C ) with the attachment mechanism  1700 . In an example, the fastener can engage with the threaded hole  1613  of the insert  1610  and the engagement of the fastener with the insert  1610  can couple the insert  1610  with the attachment mechanism  1750  (e.g., prevent the translation of the key  1612  within the keyway  1780 . 
       FIGS.  18 A- 18 B  show additional perspective views of the attachment mechanism  1700  of  FIGS.  17 A- 17 C . As described in this document, the tab  1730  can translate with respect to the attachment body  1750  (and the tab  1710 ). In an example, and as shown in  FIG.  18 A , the tab  1730  can be translated to abut against the tab  1710 . In another example, the tab  1730  can be translated to be remote from the tab  1710 , for instance to allow the attachment mechanism  1700  to be inserted into the slots  1410  (shown in  FIG.  14   ). The tab  1730  can be translated (e.g., by manipulating the bolt  1770 , shown in  FIG.  17   ) to abut against the tab  1710 , for instance to couple (e.g., clamp) the attachment mechanism  1700  to the slotted bracket  1400 A,  1400 B. 
       FIG.  19    shows a front view of the wall mount assembly  100  of  FIG.  1    and the attachment system  1300  of  FIG.  13    during an installation operation. As described herein the attachment mechanism  1700  can be coupled with the slotted brackets  1400 A,  1400 B. In an example, a plurality of attachment mechanisms  1700  can be coupled to the slotted brackets  1400 A,  1400 B. For instance, a first attachment mechanism  1700 A and a second attachment mechanism  1700 B can be coupled to the slotted bracket  1400 A. A third attachment mechanism  1700 C and a fourth attachment mechanism  1700 D can be coupled with the slotted bracket  1400 B. 
     As described in this document, the interface assemblies  1500 ,  1510  can include the support member  1600 . Additionally, the insert  1610  can be coupled with the supporting member  1600 . In an example, a first insert  1610 A and a second insert  1610 B can be coupled with the supporting member  1600 . The support member  1600  of the interface assembly  1510  can be coupled with the attachment mechanisms  1700 B,  1700 D by coupling the inserts  1610 A,  1610 B with the attachment mechanisms  1700 B,  1700 D. Further, the support member  1600  of the interface assembly  1500  can be coupled with the attachment mechanisms  1700 A,  1700 C by coupling the inserts  1610 A,  1610 B with the attachment mechanisms  1700 A,  1700 C. The support member  1600  can have an adjustable length (e.g., the support member  1600  can include telescoping sections that allow for a variable length). Accordingly, the support member  1600  can span the distance between the attachment mechanism  1700 A,  1700 C if the distance between the slotted brackets  1400 A,  1400 B changes between structures (e.g., a first cubical wall having a first distance between the brackets  1400 A,  1400 B and a second cubical wall having a second distance between the brackets  1400 A,  1400 B). 
     The support member  1600  of the interface assembly  1500  can engage with (e.g., be received in) the first bracket  1530  (shown in  FIG.  15   ) of the riser  120 . Still further, the support member  1600  of the interface assembly  1510  can engage with the engaging brackets  1540 ,  1550  (shown in  FIG.  15   ). Accordingly, and as shown in  FIG.  14   , the riser  120  can be coupled to the slotted brackets  1400 A,  1400 B with the attachment system  1300 . 
       FIG.  20    shows a perspective view of an example of a keyboard tray  2000  including a height adjustment mechanism  2010 . One or more suspension assemblies  2020  can be connected to the underside of a worksurface (e.g., the worksurface  110  shown in  FIG.  1   ). As shown in  FIG.  20   , the keyboard tray  2000  can be coupled to the suspension assembly  2020 . 
       FIG.  21    shows a front view of the keyboard tray  2000  of  FIG.  20   . In an example, two suspension assemblies  2020  can be connected to the worksurface  110 . A first suspension assembly  2020 A and a second suspension assembly  2020 B can have similar construction (e.g., the assemblies  2020 A,  2020 B can be a mirror image of each other). 
       FIG.  22    shows a detailed perspective view of the keyboard tray  2000  of  FIG.  20   . The suspension assembly  2020  can include a first mounting bracket  2200  and a second mounting bracket  2210 . The mounting brackets  2200 ,  2210  can hold an end of a first suspension bracket  2220 , and can be connected to the underside of the worksurface  110  (shown in  FIG.  21   ). The first suspension bracket  2220  can be formed in a hollow cross-section, and a second suspension bracket  2230  can be located in the hollow cross-section of the first suspension bracket  2220 . The second suspension bracket  2230  can be slidably engaged with the first suspension bracket  2220 , and the bracket  2230  can translate with respect to the bracket  2220 . The first suspension bracket  2220  can further include a slotted bracket  2240  connected to a side of the first suspension bracket  2220 . One or more slots  2250  can be formed on slotted bracket  2240 . The keyboard tray  2000  can be connected to the second suspension bracket  2230 . Accordingly, the keyboard tray  2000  can translate with respect to the bracket  2220 . 
       FIG.  23    shows another detailed perspective view of the keyboard tray  2000  of  FIG.  20   . Portions of the suspension assembly  2020  have been hidden for clarity. The second suspension bracket  2230  can include a hollow section  2300 , and a hook arm  2310  can be located inside the hollow section  2300  of the second suspension bracket  2230 . The hook arm  2310  can be rotatingly coupled with the second suspension bracket  2230 , for instance at a hinge  2320 . The hook arm  2310  can include a hook  2340 , and the hook  2340  can engage with the slotted bracket  2240  to maintain the position of the second suspension bracket  2230  relative to the first suspension bracket  2220 . A handle  2350  can be rotatingly coupled to the second suspension bracket  2230 , and manipulation of the handle  2350  can rotate the hook arm  2310  about the hinge  2320 . The handle  2350  can be fixedly attached to the hook arm  2310 , and accordingly the handle  2350  and the hook arm  2310  can rotate around the hinge  2320  in unison. 
     As described in this document, the second suspension bracket  2230  can be slidingly engaged with the first suspension bracket  2220 . The second suspension bracket  2230  can be repositioned with respect to the first suspension bracket  2220 , and the engagement of the hook  2340  with the slotted bracket  2240  can maintain the position of the second suspension bracket  2230 . In an example, the hook  2340  can be received in the slots  2250  to maintain the position of the bracket  2230  with respect to the bracket  2220 . 
     A biasing member  2360  can be included in the suspension assembly  2020 , and the biasing member  2360  can maintain the engagement of the hook  2340  with the slots  2250 . In an example, a torsion spring can be located at an axis of the hinge  2320 . The torsion spring can bias the hook arm  2310  in counter-clockwise direction so that hook  2340  can always be engaged with an individual slot of the one or more slots  2250 . In this example, when the handle  2350  is rotated about the hinge  2320 , the hook arm  2310  can rotate in clockwise direction together with the handle  2350 , and the hook  2340  can disengage from the individual slot. Accordingly the second suspension bracket  2230  can translate relative to the first suspension bracket  2220 . 
       FIG.  24    shows a side view of an example of a mobile workstation  2400 . The mobile workstation  2400  can include a wheeled base  2410 , and a riser  2420  connected to the wheeled base  2410 . The riser  2420  can be similar to the riser  120  shown in  FIG.  1   . For instance, a sliding bracket (e.g., the sliding bracket  130  shown in  FIG.  1   ) can be slidably engaged with the riser  2420 . A head unit assembly  2430  and a cable storage box  2440  can be connected to the sliding bracket. Additionally, a counterbalance mechanism (e.g., the counterbalance mechanism  230  shown in  FIG.  2   ) can be connected to the riser  2420  and can be coupled to the sliding bracket. As described herein, the counterbalance mechanism can provide height adjustment for the sliding bracket. The distance between the wheeled base  2410 , and the head unit  2430  and the cable storage box  2440  can be selectively adjusted by translating the sliding bracket with respect to a portion of the riser  2420 . 
     The head unit assembly  2430  can include a worksurface  2431  and a computer storage compartment  2432 , for instance the storage compartment  2432  can be located beneath the worksurface  2431 . Additionally, a keyboard tray  2433  can be located below the computer storage compartment  2432 . A keyboard tray arm assembly  2434  can be connected to the head unit assembly  2430 , and to the keyboard tray  2433 . The keyboard tray arm assembly  2434  can provide some articulation for the keyboard tray  2433  relative to the worksurface  2431 . 
     A display mount assembly  2450  can be coupled to the mobile workstation  2400 , for instance the display mount assembly  2450  can be located above the worksurface  2431 . A display mount  2453  can be connected to the head unit  2430  via a display arm assembly  2451  and a display mounting riser  2452 . The display mounting riser  2452  can be coupled to the head unit  2430 , for instance above the worksurface  2431 . The display arm assembly  2451  can be coupled to the display mounting riser  2452  and to the display mount  2453 . The display arm assembly  2451  can provide articulation for the display mount  2453  relative to the display mounting riser  2452 . A display (e.g., the display  2600  shown in  FIG.  26   ) can be attached to the display mount  2453  to position the display above the worksurface  2431 . In some examples, the display mounting riser  2452  can provide height adjustment for the display relative to the worksurface  2431 . 
       FIG.  25    shows a perspective view of the display mount assembly  2450 . As described in this document, the display mounting riser  2452  can be connected to the head unit  2430  (shown in  FIG.  24   ) to hold a display above the worksurface  2431 . The display mounting riser  2452  can include a mounting block  2500 , a first member  2510 , and a second member  2520  that can be slidably coupled with the first member  2510 . The second member  2520  can be coupled to the mounting block  2500 , and the mounting block can be coupled to the head unit  2430 . A counterbalance mechanism (e.g., a counterbalance mechanism similar to the counterbalance mechanism  230  shown in  FIG.  2   ) can be coupled to the second member  2520  and the first member  2510  to selectively adjust the distance of the display mount from the worksurface  2431  (shown in  FIG.  24   ). In some examples, the display arm assembly  2451  can be connected to an upper end  2530  of the display mounting riser  2452 . 
       FIG.  26    shows another perspective view of the display mount assembly  2450 . A display  2600  (e.g., a monitor, television, screen, or the like) can be coupled to the display mount  2453 . The position of the display  2600  relative to the display mounting riser  2452  can be adjusted by articulating the display arm assembly  2451 . The display mount  2453  can further include a tilting bracket  2610  to adjust an angle of the display  2600  relative to the display mounting riser  2452 . 
       FIG.  27    shows a perspective view of the display arm assembly  2451  in an expanded configuration. The display arm assembly  2451  can include a first arm  2700 , a second arm  2710 , a third arm  2720 , and a fourth arm  2730 . The first arm  2700  and the second arm  2710  can be rotatingly coupled at a first hinge  2740 . The second arm  2710  and the third arm  2720  can be rotatingly coupled at a second hinge  2750 . The third arm  2720  and the fourth arm  2730  can be rotatingly coupled at a third hinge  2760 . The fourth arm  2730  and the first arm  2700  can be rotatingly coupled to each other at a fourth hinge  2770 . A rotation axis  2780  of the hinges  2740 ,  2750 ,  2760 ,  2770  can be parallel to each other. The rotation axes  2780  can be parallel to the direction of motion of the height adjustment in the display mounting riser  2452  (shown in  FIG.  24   ). The display arm assembly  2451  can be connected to the display mounting riser  2452  at the first hinge  2740 . Accordingly, the first arm  2700  and the second arm  2710  can be rotatably coupled to the display mounting riser  2452  at the first hinge  2740 . The display mount  2453  can be connected to the display arm assembly at the third hinge  2760 . Accordingly, the third arm  2720  and the fourth arm  2730  can be rotatably coupled to the display mount  2453  at the third hinge  2760 . 
       FIG.  28    shows a perspective view of the display arm assembly  2451  in a contracted configuration. The display arm assembly  2451  can articulate to allow for a change in distance between the display mount  2453  and the display mounting riser  2452 . As shown in  FIG.  28   , the display mount  2453  is located proximate to the display mounting riser  2452 . As shown in  FIG.  27   , the display mount  2453  can be located remote from the display mounting riser  2452 . 
     Referring again to  FIG.  28   , the first arm  2700  and the second arm  2710  can rotate around the first hinge  2740 , and accordingly the second hinge  2710  and the fourth hinge  2730  can be moved away from each other. The third arm  2720  and the fourth arm  2730 , which are coupled to the first arm  2700  and the second arm  2710  at the second hinge  2750  and the fourth hinge  2760 , respectively, can also rotate relative to each other. Accordingly, the third hinge  2760  can be moved closer to the first hinge  2740  as illustrated in  FIG.  28   . 
       FIGS.  29 A- 29 C  show perspective and top views of the display arm assembly  2451  in an offset configuration. The display arm assembly  2451  can allow the display mount  2453  to move laterally (e.g., right or left) with respect to the display mounting riser  2452 . The first arm  2700  and the second arm  2710  can rotate (e.g., in a counterclockwise direction), and accordingly the third hinge  2760  can move. The display mount  2453  can move laterally (e.g., to the right) of the display mounting riser  2452 , for example as illustrated in  FIG.  29 C . Additionally, the display mount  2453  can be rotated about the third hinge  2760  to rotate the display  2600  with respect to the display arm assembly, for instance to make the display  2600  face a side direction. 
       FIG.  30    shows a perspective view of one example of the keyboard tray  2433 . As described in this document, the keyboard tray  2433  can be connected to the head unit  2430  under the computer storage compartment  2432  (shown in  FIG.  24   ). An attachment bracket  3000  can be coupled to the head unit  2430  to couple the keyboard tray arm assembly  2434  and the keyboard tray  2433  to the head unit  2430 . A holding block  3010  can be coupled between the keyboard tray arm assembly  2434  and the keyboard tray  2433 . 
     The keyboard tray arm assembly  2434  can include a first arm  3020 , a second arm  3030 , a third arm  3040 , and a fourth arm  3050 . The first arm  3020  and the second arm  3030  can be rotatingly coupled at a first hinge  3060 . The first hinge can be included in the holding block assembly  3010 , and the first arm  3020  and the second arm  3030  can be rotatingly coupled to the holding block  3010  at the first hinge  3060 . The first arm  3020  and the fourth arm  3040  can be rotatingly coupled at a second hinge  3070 . The second arm  3030  and the third arm  3040  can be rotatingly coupled at a third hinge  3080 . A fourth hinge  3090  can be included in the attachment bracket  3000 , and the fourth hinge  3090  can extend through the attachment bracket  3000 . 
       FIG.  31    shows a detailed view of the attachment bracket  3000 . Portions of the attachment bracket  3000  have been removed from  FIG.  31    for clarity. The attachment bracket  3000  can include a hinge holding bracket  3100 . The hinge holding bracket  3100  can be rotatingly coupled with the attachment bracket  3000  at the fourth hinge  3090 . 
     The third arm  3040  can include a first gear block  3110 , and the fourth arm  3050  can include a second gear block  3120 . The first gear block  3110  can be rotatingly coupled with the hinge holding block  3100  at a fifth hinge  3130 , and the second gear block  3120  can be rotatingly coupled with the hinge holding block  3100  at a sixth hinge  3140 . Rotation axes  3150  of the hinges  3060 ,  3070 ,  3080 ,  3090 ,  3130 ,  3140  can be parallel to each other, and the rotation axes  3150  can be in a vertical orientation. 
     The gear blocks  3110 ,  3120  can each include a plurality of teeth  3160 , for instance the teeth  3160  can be included on outside surfaces of the gear blocks  3110 ,  3120 . The teeth  3160  on the gear blocks  3110 ,  3120  can engage each other to synchronize the rotation of the arms  3040 ,  3050  about the hinges  3130 ,  3140 . The synchronization can allow the arms  3040 ,  3050  to rotate in equal increments about the hinges  3130 ,  3140 . 
       FIGS.  32 A- 32 B  show a top view the keyboard tray  2433  in an expanded configuration and a contracted configuration. The keyboard tray arm assembly  2434  can allow the keyboard tray  2433  to articulate with respect to the attachment bracket  3000 , and accordingly change the distance or orientation of the keyboard tray  2433  with respect to the attachment bracket  3000 . In an example, and as shown in  FIG.  32 B , the keyboard tray arm assembly  2434  can be articulated to position the keyboard tray  2433  proximate to the attachment bracket  3000 . Positioning the keyboard tray  2433  proximate to the attachment bracket  3000  can allow the keyboard tray  2433  to be stowed under the computer storage compartment  2432  (shown in  FIG.  24   ), for instance when the keyboard tray  2433  is not in use. In another example, and as shown in  FIG.  32 A , the keyboard tray arm assembly  2434  can be articulated to position the keyboard tray  2433  remote from the attachment bracket  3000 . Positioning the keyboard tray  2433  remote from the attachment bracket  3000  can expose the keyboard tray  2433 , for instance by a user pulling the keyboard tray  2433  out from under the computer storage compartment  2432 . 
       FIGS.  33 A- 33 B  show a top view of the keyboard tray  2433  in a rotated configuration. The keyboard tray arm assembly  2434  can rotate around the fourth hinge  3090  and allow the keyboard tray to move laterally (e.g., to the right or to the left) with respect to the attachment bracket  3000 . Additionally, the keyboard tray  2433  can rotate about the first hinge  3060  to face different directions as illustrated in  FIGS.  33 A- 33 B . 
       FIGS.  34 A- 34 B  show perspective views of an example of the head unit  2430  that can optionally include the computer storage compartment  2432 . As described in greater detail in this document, the computer storage compartment  2432  can be covered by the worksurface  3431 . Additionally, the worksurface  2431  can be removable from the head unit  2430 . A control panel  3400  can be included in the head unit  2430 , for instance the control panel  3400  can be located in a control panel housing  3405 . The control panel housing  3405  can be located proximate to the computer storage compartment  2432 . In an example, a display (e.g., the display  2600  shown in  FIG.  26   ) can be included in the control panel  3400 . The display can be touch sensitive, and various functions of the mobile workstation  2400  can be controlled with the display. For instance, the display can control height adjustment of the mobile workstation  2400 , internet access of a computer connected to the mobile workstation  2400 , power monitoring of one or more components (e.g., a computer, a battery, or the like) alerts, and the like. 
     The head unit  2430  can include one or more handles  3410 . In an example, the head unit  2430  can define the handles  3410 , and the handles  3410  can be located proximate to the computer storage compartment  2432 . Additionally, the head unit  2430  can include one or more accessory shelves  3420 , for instance the shelves  3420  can be connected to the head unit  3430  proximate to the computer storage compartment  2432 . In another example, the control panel housing  3405 , the handles  3410 , and the accessory shelves  3420  can be defined by the head unit  2430 . In yet another example, the control panel housing  3405 , the handles  3410 , and the accessory shelves  3420  can be formed separately and later attached to the head unit  2430 . 
     Additionally, the head unit  2430  can define one or more recesses  3440 . The recesses  3440  can be used to attach an accessory platform  3450  to the head unit  2430 . In an example, one or more ridges  3460  can be included in the accessory platform  3450 . The ridges  3460  can engage with the recesses  3440  to attach the accessory platform to the head unit  2430 . Further, one or more tabs  3470  can be included in the accessory platform  3450 . The tabs  3470  can engage with the head unit  2430  to provide extra stiffness to the connection between the head unit  2430  and the accessory shelf  3450 . For instance, a screw can be inserted through the head unit  2430 , and the tab  3470  to engage with the accessory shelf  3450  and provide additional security to couple the accessory shelf  3450  to the head unit  2430 . 
     The accessory platform  3450  can include a bottom surface  3451 . The bottom surface  3451  of the accessory platform  3450  can be flat, or have various shapes to match the accessory to be located on the accessory platform  3450 . The bottom surface  3451  of the accessory platform  3450  can have one or more slots  3452  to mount accessories (e.g., a sanitizing wipe container, a scanner holder, a printer, or the like) on to the accessory platform. In some example configurations, a fastener (e.g., a screw) can be inserted through the slots  3452 , and the fastener can engage the accessory to secure the accessory to the accessory platform  3450 . 
       FIG.  35    shows a perspective view of an example of the mobile cart  2400  of  FIG.  24    that can optionally include one or more cable access holes  3500 . The head unit  2430  can define the one or more cable access holes  3500 . The cable access holes  3500  can allow access to the computer storage compartment  2432  from an exterior of the head unit  2430 . In an example, the cable access holes  3500  can allow cable routing between the cable storage box  2440  or the computer storage compartment  2432 , and accessories located on the accessory shelves  3420  (or the accessory platform  3450 , shown in  FIGS.  34 A- 34 B ). In an example, a power supply for a laptop computer can be located in the computer storage compartment  2432  (or on the accessory shelf  3420 ). A first power supply cable can pass through the cable access holes  3500  from the computer storage compartment  2432  and be coupled with a second power supply cable located in the cable storage box  2440 . 
       FIG.  36    shows a perspective view of the head unit  2430 . One or more light sources  3600  can be built in to the head unit to provide extra light when the ambient lighting is not sufficient for performing various tasks associated with the mobile workstation. A first light source  3600 A can be attached to the head unit  2430  above the worksurface  2431  to illuminate the objects located on the worksurface  2431 . A second light source  3600 B and a third light source can be attached to underside of the accessory shelves  3420  to illuminate the keyboard tray  2433  when the keyboard tray  2433  is panned to the right or left side of the head unit  2430 . A fourth light source  3600 C can be attached to the underside of the control panel housing  3405  to illuminate the keyboard tray  3433  when the keyboard tray  3433  is in front of the head unit  3430 . 
     Power and dimming features for the light sources  3600  can be controlled by the control panel  3400 . In an example, the brightness of each light source (e.g., the first light source  3500 A) can be set manually, or the brightness can automatically be adjusted using an ambient light sensor that  3610  that can be included in the mobile workstation  2400 . In an example, and as shown in  FIG.  37 B , the ambient light sensor  3700  can be located in the control panel housing  3405 . 
       FIGS.  37 A- 37 B  show perspective views of the wheeled base  2410  of the mobile work station  2400 . The one or more light sources  3600  can also be included in the wheeled base  2410 . As shown in  FIG.  37 A , a fifth light source  3600 D can be attached to the wheeled base  2410  proximate to a first side of the wheeled base  2410 . Additionally, and as shown in  FIG.  37 B , a sixth light source  3600 E can be attached to a second side of the wheeled base  2410 . The light sources  3600 D,  3600 E can be used to illuminate an area around the workstation  2400 . 
       FIG.  38    shows a perspective view of another example of the mobile workstation  2400 . A storage basket  3800  can be coupled to the head unit  2430  (e.g., to a side of the head unit  2430 ), and the storage basket  3800  can be configured to store accessories. In an example, the storage basket  3800  can store a remote control, medical equipment (e.g., an oximeter, a blood pressure cuff a stethoscope, or the like), or other accessories. Additionally, the mobile workstation  2400  can include an accessory holder  3810 . The accessory holder  3810  can be coupled to the head unit  2430 , for instance the accessory holder can be coupled to an underside of the head unit  2430 . 
       FIG.  39    shows a perspective view of an example of the accessory holder  3810 . The accessory holder  3810  can be coupled to the head unit  2430  (shown in  FIG.  38   ). The accessory holder  3810  be used to attach an accessory  3900 , including (but not limited to), sanitizing wipes, a scanner, or the like to the mobile workstation  2400  (shown in  FIG.  38   ). The accessory holder  3810  can have an L-shaped profile and can include a first side  3910 , and a second side  3920  which extends in transverse direction from the first side  3910 . In another example, the accessory holder  3810  have other profiles, for instance a U-shaped, straight, or other profile that can fit a variety of accessories  3900 . An upper end  3930  of the first side  3920  can be attached to the head unit  2430  (e.g., an underside of the head unit  2430 ). 
     The accessory holder  3810  can includes one or more slots  3940 . The slots  3940  can be defined in the sides  3910 ,  3920  of the accessory holder  3810  and sized and shaped to receive a strap  3950 . The strap  3950  (e.g., a strap including a hook and loop fastener, an elastic strap, or the like) can be wrapped around the accessory  3900  to secure the accessory  3900  to the accessory holder  3810 . A first end of the strap  3950  can be connected to the accessory holder  3810  by engaging the strap  3950  with the one or more slots  3940 . Additionally, a clip  3960  can be coupled to the accessory holder  2810 , for instance by coupling the clip  3960  with the slots  3940 . The clip  3960  can be inserted through the slots  3940  the clip can extend from the second side  3920  of the accessory holder  3810 . Further, the strap  3950  can define the slots  3940 , and the strap  3950  can couple with the clip  3960  or other accessories. 
     In an example, the accessory  3900  (e.g., a sanitizing wipes container) can be secured to the accessory holder  3810 . A first end  3951  of the strap  3950  can be inserted in to the slot  3940 A. The strap  3950  can be wrapped around the accessory  3900 , and a second end  3952  of the strap  3950  can be secured to the accessory holder  3810 . For instance, the second end  3951  of the strap  3950  can be secured to the accessory holder  3810  using the clip  3960 . 
       FIG.  40    shows a perspective view of an example of the strap  3950 . As described in this document, the strap  3950  can be received in the slots  3940  (e.g., the slot  3940 A shown in  FIG.  39   ). A tab  4000  can engage with the accessory holder  3810  (e.g., the side  3910 ) and secure the strap  3950  to the accessory holder  3810 . For instance, the tab  4000  can have dimensions greater than the slots  3940  and the tab  4000  can prevent the second end  3952  of the strap  3950  from translating through the slots  3940 . The tab  4000  can include a pin  4010 , and the strap  3950  can define one or more holes  4020  that are sized and shaped to receive the pin  4010 . The strap  3950  can be wrapped around the accessory  3900  (shown in  FIG.  39   ), and the strap  3950  can engage with the pin  4010  to secure the accessory  3900  to the accessory holder  3810  (shown in  FIG.  38   ). 
       FIG.  41    shows a perspective view of the head unit  2430  including the worksurface  2431 . As described in this document, the head unit  2430  can be included in the mobile workstation  2400 . As described in greater detail in this document, the worksurface  2431  can translate with respect to the head unit  2430 . In an example, the worksurface  2431  can translate between an open configuration and a closed configuration. Additionally, the worksurface  2431  can be removed from the head unit  2430 , for instance to allow access to the computer storage compartment  2432  (shown in  FIG.  35   ). 
       FIG.  42    shows another perspective view of the head unit  2430 . The worksurface  2431  has been removed from  FIG.  42    for clarity. As described in this document, the head unit  2430  can include the computer storage compartment  2432 . The worksurface  2431  (shown in  FIG.  41   ) can be translated with respect to the head unit  2430  (or removed from the head unit  2430 ) to allow access to the compartment  2432 . In an example, the worksurface  2431  can be engaged with one or more glides  4200 , for instance a first glide  4200 A or a second glide  4200 B. The glides  4200  can be rotatably coupled to the head unit  2430  with one or more hinges  4210 . For instance, the glide  4200 A can be rotatably coupled to the head unit  2430  with a first hinge  4210 A, and the glide  4200 B can be coupled to the head unit  2430  with a second hinge  4210 B. The rotatable coupling between the glides  4200  and the hinges  4210  can allow the glides  4200  to translate with respect to the head unit  2430 . In this example, because worksurface  2431  (shown in  FIG.  41   ) is engaged with the glides  4200 , the worksurface  2431  can translate with respect to the head unit  2430 . 
       FIG.  43    shows yet another perspective view of the head unit  2430 . The mobile workstation  2400  can include a worksurface opening mechanism  4300 , and the opening mechanism  4300  can include a latch release handle  4310 . The latch release handle  4310  can be coupled to the head unit  2430 , and can transition the opening mechanism  4300  between a locked configuration and an unlocked configuration. In this example, when the opening mechanism  4300  is in the locked configuration, the worksurface  2431  (shown in  FIG.  41   ) is secured in the closed configuration. When the opening mechanism is in the unlocked configuration, the worksurface  2431  is allowed to transition from the closed configuration to the open configuration. A user can manipulate (e.g., pull, twist, push, or the like) the latch release handle  4310  to transition the opening mechanism  4300  between the locked configuration and the unlocked configuration. 
       FIG.  44    shows a perspective view of the worksurface opening mechanism  4300  and the glides  4200 . Portions of the mobile workstation  2400  have been removed for clarity (e.g., portions of the head unit  2430 ). The opening mechanism  4300  can include a support bracket  4400 , and the support bracket  4400  can support a shaft  4410 . The latch release handle  4310  can be coupled to the shaft  4410 , and displacement of the latch release handle  4310  can translate the shaft  4410 . In an example, a user can manipulate the latch release handle  4310  and displace the latch release handle  4310 . The displacement of the latch release handle  4310  can rotate the shaft  4410 . As described in greater detail in this document, rotation of the shaft  4410  can transition the opening mechanism  4300  between the locked configuration and the unlocked configuration. 
       FIG.  45    shows a detailed perspective view of the glide  4200 A. Portions of the glide  4200 A have been removed for clarity. The glide  4200 A can include a latch  4500 , and the latch  4500  can translate (e.g., slide, reciprocate, or the like) with respect to a glide body  4510  of the glide  4200 A. In an example, the latch  4500  can project from the glide body  4510 , and the latch  4500  can translate to be located (either partially or completely) within the glide body  4510 . A latch biasing member  4520  can bias the latch  4500  away from the glide body  4510 . The latch biasing member  4520  (e.g., a spring or the like) can be located between the latch  4500  and the glide body  4510 , and the biasing member  4520  can bias the latch  4500  away from the glide body (e.g., the latch  4500  can be biased to project from the glide body  4510 ). 
       FIG.  46    shows another perspective view of the worksurface opening mechanism  4300  and the glide  4200 B. As described herein, the latch release handle  4310  (shown in  FIG.  43   ) can translate the shaft  4410 . A lobe  4600  can be coupled to the shaft  4410 , and the translation of the shaft  4410  can displace (e.g., rotate, move, or the like) the lobe  4600 . The lobe  4600  can engage with a push rod  4610 , and displacement of the lobe can translate the push rod  4610 . The push rod  4610  can engage with the latch  4500  (shown in  FIG.  47   ) and the translation of the push rod  4610  can translate the latch  4500  with respect to the glide body  4510 . 
     A catch  4620  can be included in the worksurface opening mechanism  4300 . In some examples, the catch  4620  can be included in a guide bracket  4630 , and the guide bracket  4630  can be coupled to the support bracket  4400 . The latch  4500  can engage with the catch  4620 , and the engagement of the latch  4500  with the catch  4620  can restrain (e.g., secure, hold, or the like) the glide  4200 B. In this example, when the glide  4200 B is restrained and the worksurface  2431  is engaged with the glides  4200 , the worksurface  2431  can be maintained in the closed configuration. Displacement of the latch  4500  with respect to the glide body  4510  (e.g., by the push rod  4610 ) can disengage the latch  4500  from the catch  4620  and allow the glides  4200  to translate with respect to the head unit  2430  (shown in  FIG.  42   ). Accordingly, the worksurface  2431  can transition to the open configuration. 
       FIG.  47    shows yet another perspective view of the worksurface opening mechanism  4300  and the glide  4200 B. Portions of the support bracket  4400  and the guide bracket  4630  have been hidden in  FIG.  47    for clarity. In some examples, the guide bracket  4630  (and the support bracket  4400 ) can define a rod channel  4700 , and the rod channel  4700  can be sized and shaped to receive the push rod  4610 . The push rod  4610  can be slidingly engaged with the rod channel  4700 , and translate with respect to the support bracket  4400  (or the head unit  2430 ). As described in this document, the translation of the push rod  4610  can displace the latch  4500  and allow the latch  4500  to disengage from the catch  4620 . 
       FIG.  48    shows a detailed perspective view of an example of the worksurface opening mechanism  4300 . The worksurface opening mechanism  4300  can include a lift system  4800 . The lift system  4800  can bias the glides  4200  (and the worksurface  2431 ) away from the head unit  4230 . In an example, the lift system  4800  can include a plunger  4810 , and the plunger  4810  can engage with the glides  4200  (e.g., the glide  4200 B) and bias the glides  4200  away from the head unit  4230  (shown in  FIG.  42   ). In this example, when the worksurface  2431  is engaged with the glides  4200 , the lift system  4800  can bias the worksurface  2431  away from the head unit  4230 . In some examples, the lift system  4800  includes a plurality of plungers  4810 . For instance, a first plunger  4810  can be located proximate to the glide  4200 A, and a second plunger  4810  can be located proximate to the glide  4200 B. 
     Additionally, the lift system  4800  can include a biasing member  4820  and a lift housing  4830 . The biasing member  4820  (e.g., a spring or the like) can be located between the plunger  4810  and the lift housing  4830 , and the biasing member  4820  can bias the plunger  4810  in a first direction (e.g., upward, or toward engagement with the glides  4200 ). In this example, the plunger  4810  can bias the glides  4200  in the first direction because the plunger  4810  can engage with the glides  4200  (e.g., the glide  4200 B). As discussed in greater detail in this document, the lift system  4800  can bias the worksurface  2431  toward the open configuration when the latch  4500  (shown in  FIG.  47   ) is disengaged from the catch  4620  (shown in  FIG.  46   ). 
       FIG.  49    shows another perspective view of the glide  4200 A. The glides  4200  (e.g., the glide  4200 A) can include an ejection system  4900 . The ejection system  4900  can bias the worksurface  2431  in a second direction (e.g., along a length axis of the glide  4200 A) when the worksurface  2431  (shown in  FIG.  41   ) is engaged with the glides  4200 . In an example, the ejection system  4900  can include an ejection tab  4910 , and the ejection tab  4910  can engage with the worksurface  2431  to bias the worksurface  2431  in the second direction. 
     The glides  4200  can include a glide channel  4920 , and the glide channel  4920  can be sized and shaped to receive the worksurface  2431 . The ejection tab  4910  can extend into a glide channel  4920  defined by the glide body  4510 , and the ejection tab  4910  can engage with the worksurface  2431  when the worksurface  2431  is engaged with the glide channel  4920 . The glide channel can be defined by the glide body  4510  and a glide rail  4930  The ejection tab  4910  can engage with the worksurface  2431  and bias the worksurface  2431  in the second direction (e.g., along a length of the glide channel  4920 ). In an example, the ejection tab  4910  can translate with respect to the glide body  4510  and accordingly translate the worksurface  2431  with respect to the glide body  4510 . 
       FIG.  50    shows yet another perspective view of the glide  4200 A. Portions of the glide  4200 A have been hidden in  FIG.  50    for clarity. the ejection assembly  4900  can include an ejection sled  5000  and an ejection biasing member  5010 . The ejection sled  5000  can include the ejection tab  4910 , and the ejection tab can extend through a slot  5020  defined by the glide body  4510  into the glide channel  4920 . The biasing member  5010  (e.g., a spring or the like) can be coupled with the ejection sled  5000  and the glide body  4510 . and the biasing member  5010  can bias the ejection sled  5000  (and the ejection tab  4910 ) in the second direction. In an example, the ejection tab  4910  can engage with the glide body  4510  (e.g., a wall of the slot  5020 ) to limit a range of motion of the ejection sled  5000 . For instance, the glide body  4510  can be configured to stop the translation of the ejection sled  5000  with respect to the glide body  4510 . 
       FIG.  51    shows a front view of the mobile workstation  2400 . As described herein, the mobile workstation  2400  can include the head unit  2430 , the worksurface  2431 , and the glides  4200 . The glides  4200  can define the glide channel  4920 , and the worksurface  2431  can be engaged with the glide channel  4920 . In an example, the worksurface  2431  can include a worksurface tab  5100 , and the glide channel  4920  can be sized and shaped to receive the worksurface tab  5100 . The worksurface tab  5100  can be slidingly engaged with the glide channel  4920 , and the worksurface tab  5100  can translate with respect to the glide channel  4920 . Accordingly, the worksurface  2431  can translate with respect to the glide body  4510 . Additionally, the ejection tab  4910  (shown in  FIG.  49   ) can engage with the worksurface tab  5100 , for instance to bias the worksurface  2431  in the second direction. 
       FIG.  52    shows a detailed side view of the head unit  2430  and the worksurface  2431 . An angled bracket  5200  can be coupled with the worksurface  2431 , and the angled bracket  5200  can engage with the head unit  2430  to displace the worksurface  2431  relative to the head unit  2430 . In an example, a user can transition the worksurface  2431  from the open configuration (as shown in  FIG.  54   ) toward the closed configuration (as shown in  FIG.  53   ). The angled bracket  5200  can engage with the head unit  2430  to guide the worksurface  2431  toward the closed configuration. For instance, the engagement of the angled bracket  5200  with the head unit  2431  can overcome the bias provided by the ejection biasing member  5010  (shown in  FIG.  50   ) and allow the worksurface  2431  to translate with respect to the glide body  4510  (shown in  FIG.  50   ). 
       FIG.  53    shows a side view of the head unit  2430 , the glide  4200 B, and the worksurface opening mechanism  4300 . Portions of the head unit  2430 , the glide  4200 B, and the worksurface opening mechanism  4300  have been hidden in  FIG.  53    for clarity. The worksurface  2431  is in the closed configuration in  FIG.  53   . Additionally, the worksurface opening mechanism  4300  is in the locked configuration in  FIG.  53   . The plunger  4810  of the lift system  4800  can be engaged with the glide  4200 B. Further, the latch  5000  can be engaged with the catch  4620  to maintain the opening mechanism  4300  in the locked configuration and the worksurface  2431  in the closed configuration. 
       FIG.  54    shows another side view of the head unit  2430 , the glide  4200 B, and the worksurface opening mechanism  4300 . Portions of the head unit  2430 , the glide  4200 B, and the worksurface opening mechanism  4300  have been hidden in  FIG.  54    for clarity. The worksurface  2431  is in the open configuration in  FIG.  54   . Additionally, the worksurface opening mechanism  4300  is in the unlocked configuration in  FIG.  54   . The plunger  4810  is engaged with the glide  4200 B, and the glide  4200 B is biased in the first direction (e.g., as shown by the arrow  5400 ). The worksurface  2431  is allowed to transition to the open configuration (and the glide  4200 B is allowed to rotate about the hinge  4210 B, shown in  FIG.  42   ) because the latch  4500  is disengaged from the catch  4620 . As described in this document, the push rod  4610  can engage with the latch  5000  to displace the latch  5000  and disengage the latch  4500  from the catch  4620 . 
     Further, the ejection system  4900  can bias the worksurface  2431  in the second direction (e.g., as shown by the arrow  5410 ). In this example, the worksurface  2431  can translate with respect to the glide body  4510 . The worksurface  2431  can project from the glide  4200 A, for instance to allow a user to access the computer storage compartment  2432  (shown in  FIG.  42   ). Additionally, because the worksurface  2431  is in the open configuration, the worksurface  2431  can be removed from the head unit  2430 . In an example, a user can translate (e.g., pull, push, or the like) the worksurface  2431  relative to the glide  4200 A, and disengage the worksurface tab  5100  (shown in  FIG.  51   ) from the glide channel  4920  (shown in  FIG.  51   ). 
       FIG.  55    shows a side view of the worksurface opening mechanism  4300  and the glides  4200 B. The opening mechanism  4300  can include a lock  5500  (e.g., a key lock, code lock, or the like). The lock  5500  can inhibit the manipulation of the latch release handle  4310  (shown in  FIG.  43   ). Accordingly, the lock  5500  can prevent transitioning the opening mechanism  4300  from the locked configuration to the unlocked configuration. 
     Various Notes &amp; Examples 
     Aspect 1 may include or use subject matter (such as an apparatus, a system, a device, a method, a means for performing acts, or a device readable medium including instructions that, when performed by the device, may cause the device to perform acts), such as may include or use a mobile workstation, comprising: a height adjustable riser; a head unit assembly coupled to the riser; a worksurface coupled to the head unit assembly and configured to translate with respect to the head unit assembly between an open configuration and a closed configuration; a first glide rotatably coupled to the head unit assembly and engaged with the worksurface, wherein the first glide includes a first latch configured to translate with respect to a first glide body of the first glide; and a worksurface opening mechanism having a locking configuration and an unlocking configuration, the worksurface opening mechanism including: a latch release handle moveably coupled to the head unit assembly, wherein movement of the latch release handle is configured to transition the worksurface opening mechanism between the locked configuration and the unlocked configuration; a release assembly coupled to the latch release handle and configured to selectively engage with the first latch; a lift system configured to bias the worksurface away from the head unit assembly; and a catch configured to engage with the first latch to restrain the first glide and maintain the worksurface in the closed configuration. 
     Aspect 2 may include or use, or may optionally be combined with the subject matter of Aspect 1, to optionally include or use wherein the worksurface is received in a worksurface channel of the first glide, and further comprising an ejection assembly including: an ejection sled slidingly coupled with the first glide, the ejection sled including an ejection tab extending into the worksurface channel; and an ejection spring configured to bias the ejection sled in a first direction, wherein the ejection sled engages with the worksurface and biases the worksurface in the first direction. 
     Aspect 3 may include or use, or may optionally be combined with the subject matter of Aspect 2 to optionally include or use wherein the ejection tab extends into the worksurface channel through a slot, and the slot extends a first distance along a length of the worksurface channel. 
     Aspect 4 may include or use, or may optionally be combined with the subject matter of Aspect 3 to optionally include or use wherein the ejection tab is configured to engage with a wall of the slot, and the engagement of the ejection tab with the wall of the slot prevents translation of the ejection tab with respect to the first glide. 
     Aspect 5 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 2 through 4 to optionally include or use an angled bracket coupled with a portion of the worksurface and configured to engage with the head unit assembly, wherein the engagement of the angled bracket with the head unit assembly displaces the worksurface in a second direction and overcomes the bias of the ejection spring. 
     Aspect 6 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 2 through 5 to optionally include or use wherein the ejection assembly is located proximate to the hinge. 
     Aspect 7 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 1 through 6 to optionally include or use wherein the work surface opening mechanism includes: a shaft coupled with the latch release handle and rotatingly coupled with the head unit; a lobe coupled to the shaft, wherein movement of the latch release handle rotates the shaft and displaces the lobe; and a push rod slidingly engaged with the head unit and configured to engage with the latch, wherein the lobe is engaged with push rod and displacement of the lobe translates the push rod with respect to the head unit, wherein translation of the push rod with respect to the head unit selectively engages the push rod with the latch to translate the latch with respect to the first glide and allows the latch to disengage from the catch. 
     Aspect 8 may include or use, or may optionally be combined with the subject matter of Aspect 7 to optionally include or use a guide bracket coupled with the head unit assembly and sized and shaped to receive the push rod. 
     Aspect 9 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 1 through 8 to optionally include or use wherein the worksurface is slidingly coupled with the first glide, and the work surface is removable from the first glide. 
     Aspect 10 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 1 through 9 to optionally include or use wherein the lift system includes: a plunger configured to engage with the first glide; a biasing member located between the head unit assembly and the plunger and configured to bias the plunger in a first direction; wherein engagement of the plunger with the first glide biases the first glide in the first direction. 
     Aspect 11 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 1 through 10 to optionally include or use wherein the worksurface is configured to be received in a worksurface channel of the first glide, and further comprising an ejection assembly including: an ejection sled slidingly coupled with the first glide, the ejection sled including an ejection tab extending into the worksurface channel; and an ejection spring configured to bias the ejection sled in a first direction, wherein the ejection sled is configured to engage with the worksurface and bias the worksurface in the first direction. 
     Aspect 12 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 1 through 11 to optionally include or use a second glide rotatably coupled to the head unit assembly and engaged with the worksurface, wherein the second glide includes a second latch configured to translate with respect to the second glide, and wherein the release assembly is configured to selectively engage with the second latch. 
     Aspect 13 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 1 through 12 to optionally include or use a storage compartment configured to receive one or more electronic devices. 
     Aspect 14 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 1 through 13 to optionally include or use wherein the hinge is located proximate to an end of the first glide. 
     Aspect 15 may include or use subject matter (such as an apparatus, a system, a device, a method, a means for performing acts, or a device readable medium including instructions that, when performed by the device, may cause the device to perform acts), such as may include or use a worksurface opening mechanism for a mobile workstation, comprising: a support bracket; a latch release handle moveably coupled to the support bracket, wherein movement of the latch release handle is configured to translate the worksurface opening mechanism between a locked configuration and an unlocked configuration; a release assembly coupled to the latch release handle and configured to selectively engage with a latch; a lift system configured to bias a first glide away from the support bracket; and a catch configured to engage with the latch to restrain the glide and maintain the worksurface in the closed configuration. 
     Aspect 16 may include or use, or may optionally be combined with the subject matter of Aspect 15, to optionally include or use a shaft coupled with the latch release handle and rotatingly coupled with the support bracket; a first lobe coupled to the shaft, wherein movement of the latch release handle rotates the shaft and displaces the first lobe; and a first push rod slidingly engaged with the support bracket and configured to engage with the latch, wherein the first lobe is engaged with first push rod and displacement of the first lobe translates the first push rod with respect to the support bracket, wherein translation of the first push rod with respect to the support bracket is configured to selectively engage the first push rod with the latch to translate the latch to disengage the first latch from the catch. 
     Aspect 17 may include or use, or may optionally be combined with the subject matter of Aspect 16 to optionally include or use wherein the latch is a first latch and the catch is a first catch, and further comprising: a second lobe coupled to the shaft, wherein movement of the latch release handle rotates the shaft and displaces the second lobe; and a second push rod slidingly engaged with the support bracket and configured to engage with the second latch, wherein the second lobe is engaged with the second push rod and displacement of the second lobe translates the second push rod with respect to the support bracket, wherein translation of second first push rod with respect to the support bracket is configured to selectively engage the second push rod with a second latch to translate the second latch to disengage the second latch from a second catch. 
     Aspect 18 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 15 through 17 to optionally include or use wherein the lift system includes: a first plunger configured to engage with the first glide; a first biasing member located between a first lift housing and the first plunger and configured to bias the first plunger in a first direction. 
     Aspect 19 may include or use, or may optionally be combined with the subject matter of Aspect 18 to optionally include or use wherein the lift system includes: a second plunger configured to engage with a second glide; a second biasing member located between a second lift housing and the second plunger and configured to bias the second plunger in the first direction. 
     Aspect 20 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 15 through 5 to optionally include or use a guide bracket coupled with the head unit assembly and sized and shaped to receive the push rod. 
     Aspect 21 may include or use subject matter (such as an apparatus, a system, a device, a method, a means for performing acts, or a device readable medium including instructions that, when performed by the device, may cause the device to perform acts), such as may include or use a tilting work station configured to couple to a vertical support surface, comprising: a work surface; a wall mount assembly configured to couple to the vertical support surface, including: a frame; and a sliding bracket that translates with respect to the frame; a support bracket configured to couple with the work surface, wherein the support bracket is coupled to the sliding bracket with a hinge, and wherein the support bracket is configured to rotate about the hinge; and a lock assembly having a locked configuration and an unlocked configuration, wherein: in the locked configuration, the lock assembly is engaged with the sliding bracket and the work surface is in a horizontal first position; and in the unlocked configuration, the lock assembly is disengaged from the sliding bracket and the work surface is configured to translate to a vertical second position. 
     Aspect 22 may include or use, or may optionally be combined with the subject matter of Aspect 21, to optionally include or use a latch assembly coupled with the sliding bracket, wherein the latch assembly defines a pin channel; a pin coupled with the sliding bracket; and wherein the pin channel is sized and shaped to receive the pin, and reception of the pin within the pin channel configures the lock assembly in the locked configuration. 
     Aspect 23 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 21 or 2 to optionally include or use wherein the latch assembly includes: a first arm defining the pin channel; a second arm coupled with the first arm with a latch hinge; and a latch actuator coupled with the second arm, wherein movement of the latch actuator rotates the second arm and the first arm about the pivot. 
     Aspect 24 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 21 through 3 to optionally include or use wherein the wall mount assembly includes: a first attachment mechanism configured to engage with a first slotted bracket; a first attachment body; a first tab including a first hook protrusion oriented in a first direction; a second tab including a second hook protrusion oriented in a second direction opposite the first direction; and wherein the second tab is configured to translate with respect to the attachment body and the translation of the second tab varies a first distance between the first tab and the second tab. 
     Aspect 25 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 21 through 4 to optionally include or use that wherein the wall mount assembly includes: a second attachment mechanism configured to engage with a second slotted bracket; a second attachment body; a third tab including a third hook protrusion oriented in the first direction; a fourth tab including a fourth hook protrusion oriented in the second direction; and wherein the third tab or the fourth tab is configured to translate with respect to the attachment body and the translation of the third tab or the fourth tab varies a second distance between the third tab and the fourth tab. 
     Aspect 26 may include or use, or may optionally be combined with the subject matter of one or any combination of Aspects 24 or 25 to optionally include or use wherein the wall mount assembly includes: a support member configured to span between the first attachment mechanism and the second attachment mechanism, wherein the support member includes a first key and a second key; wherein the first attachment body includes a first keyway configured to receive the first key, and the second attachment body includes a second keyway configured to receive the second key; and wherein the frame is configured to engage with the support member to couple the frame with the structure. 
     Aspect 27 may include or use, or may optionally be combined with any portion or combination of any portions of any one or more of Aspects 1 through 26 to include or use, subject matter that may include means for performing any one or more of the functions of Aspects 1 through 26. 
     The above description includes references to the accompanying drawings, which form a part of the detailed description. The drawings show, by way of illustration, specific embodiments in which the invention can be practiced. These embodiments are also referred to herein as “examples.” Such examples can include elements in addition to those shown or described. However, the present inventors also contemplate examples in which only those elements shown or described are provided. Moreover, the present inventors also contemplate examples using any combination or permutation of those elements shown or described (or one or more aspects thereof), either with respect to a particular example (or one or more aspects thereof), or with respect to other examples (or one or more aspects thereof) shown or described herein. 
     In the event of inconsistent usages between this document and any documents so incorporated by reference, the usage in this document controls. 
     In this document, the terms “a” or “an” are used, as is common in patent documents, to include one or more than one, independent of any other instances or usages of “at least one” or “one or more.” In this document, the term “or” is used to refer to a nonexclusive or, such that “A or B” includes “A but not B,” “B but not A,” and “A and B,” unless otherwise indicated. In this document, the terms “including” and “in which” are used as the plain-English equivalents of the respective terms “comprising” and “wherein.” Also, in the following claims, the terms “including” and “comprising” are open-ended, that is, a system, device, article, composition, formulation, or process that includes elements in addition to those listed after such a term in a claim are still deemed to fall within the scope of that claim. Moreover, in the following claims, the terms “first,” “second,” and “third,” etc. are used merely as labels, and are not intended to impose numerical requirements on their objects. 
     Geometric terms, such as “parallel”, “perpendicular”, “round”, or “square”, are not intended to require absolute mathematical precision, unless the context indicates otherwise. Instead, such geometric terms allow for variations due to manufacturing or equivalent functions. For example, if an element is described as “round” or “generally round,” a component that is not precisely circular (e.g., one that is slightly oblong or is a many-sided polygon) is still encompassed by this description. 
     The above description is intended to be illustrative, and not restrictive. For example, the above-described examples (or one or more aspects thereof) may be used in combination with each other. Other embodiments can be used, such as by one of ordinary skill in the art upon reviewing the above description. The Abstract is provided to comply with 37 C.F.R. § 1.72(b), to allow the reader to quickly ascertain the nature of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. Also, in the above Detailed Description, various features may be grouped together to streamline the disclosure. This should not be interpreted as intending that an unclaimed disclosed feature is essential to any claim. Rather, inventive subject matter may lie in less than all features of a particular disclosed embodiment. Thus, the following claims are hereby incorporated into the Detailed Description as examples or embodiments, with each claim standing on its own as a separate embodiment, and it is contemplated that such embodiments can be combined with each other in various combinations or permutations. The scope of the invention should be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled.