JP4747661B2 - Display stand - Google Patents

Description

The present invention relates to a de I spray stand, in particular, to de I spray stand as a mechanism for locking or unlocking the movement of the movable member can be easily formed with respect to the fixed member.

  Conventionally, a lock mechanism using a cam is known. This locking mechanism has, for example, a member that operates with respect to a fixed member, the fixed member is provided with a cam groove, and the movable member corresponds to the cam groove of the fixed member. By providing the lock pin at the position where On the other hand, it is locked (stopping exercise) or unlocked (resuming exercise).

  By the way, in recent years, the display device is used alone, as shown in Patent Document 1, as shown in Patent Document 1, a multi-display configured by attaching a plurality of display devices to a display stand, or as shown in Patent Document 2. Furthermore, it has been proposed to be used as a scalable TV system in which an arbitrary number of display devices can be arranged horizontally and vertically.

  However, in the above-described system composed of a plurality of display devices, each display device is often installed close to the display stand, and individual display devices can be removed from or attached to the display stand. It was difficult.

  Corresponding to this, a display stand has been proposed in which a mounting portion on which a display device is mounted can be taken out by a user's hand.

JP 2004-191601 A JP 2003-195843 A

  In such a display stand, when a conventional locking mechanism using a cam is used to lock or unlock the mounting portion on which the display device is mounted with respect to the display stand, the conventional cam groove is It was necessary to provide a complicated shape, and it took time and effort to form it.

  The present invention has been made in view of such a situation, and makes it possible to easily form a mechanism for locking or unlocking the movement of a movable member with respect to a fixed member.

The display stand of the present invention has a fixed member fixed at a predetermined position of the main body , a movable member that moves relative to the fixed member, and the display device can be attached to and detached from the fixed member and the movable member. In the course of passing between the two cam plates by the reciprocating motion that the movable member is installed on the other of the two cam plates and the fixed member and the movable member, and the movable member is moved relative to the fixed member. And a lock pin for locking and unlocking the movable member.

  The two cam plates can be configured in a shape and positional relationship in which the movable member can be locked or unlocked by only one reciprocating motion by the lock pin.

  The two cam plates can be installed on the fixed member, and the lock pin can be installed on the movable member.

In the first aspect of the present invention, the two cam plates move with respect to the fixed member fixed at a predetermined position of the main body and the fixed member, and one of the movable members to which the display device can be attached and detached is predetermined. It is installed in the position relationship. A lock pin is installed on the other of the fixed member and the movable member. The movable member is locked and unlocked by the lock pin during the passage of the lock pin between the two cam plates due to the reciprocating motion performed by the movable member with respect to the fixed member.

  According to the present invention, a mechanism for locking or unlocking the movement of the movable member with respect to the fixed member can be easily formed.

The best mode of the present invention will be described below .

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a scalable TV (Television) system to which the present invention is applied (a system is a logical collection of a plurality of devices, regardless of whether or not the devices of each configuration are in the same casing. ) Is a perspective view showing a configuration example of an embodiment, and FIG. 2 is a side view showing a configuration example of a scalable TV system.

  In the example of FIG. 1, the scalable TV system 1 includes a stand 10 and nine television receivers 21-1 to 21-9 that can be attached to and detached from the stand 10.

  The television receivers 21-1 to 21-9 have the same configuration except that the branch numbers of the codes are different. Therefore, the following description will be given using the television receiver 21-1 as appropriate. However, the description is also applied to the description of the other television receivers 21-2 to 21-9.

  The stand 10 is provided with mounting portions 11-1 to 11-9 in 3 columns × 3 rows. Television receivers 21-1 to 21-9 are mounted on the mounting portions 11-1 to 11-9, respectively. For convenience of explanation, some of the mounting portions 11-1 to 11-9 are not shown in FIG. 1 or FIG.

  In other words, the leftmost column of the stand 10 is provided with a mounting portion 11-1, a mounting portion 11-4, and a mounting portion 11-7 in three stages, which are a television receiver 21-1 and a television receiver, respectively. The machine 21-4 and the television receiver 21-7 are mounted. The center row of the stand 10 is provided with a mounting portion 11-2, a mounting portion 11-5, and a mounting portion 11-8, which are not shown, in three stages, a television receiver 21-2 and a television receiver, respectively. A machine 21-5 and a television receiver 21-8 are mounted. In the rightmost column of the stand 10, a mounting portion 11-3, a mounting portion 11-6, and a mounting portion 11-9 (FIG. 2) are provided in three stages, which are a television receiver 21-3 and a television set, respectively. John receiver 21-6 and television receiver 21-9 are mounted.

  Note that the mounting portions 11-1 to 11-9 have the same configuration except that the branch numbers are different. Therefore, hereinafter, even if a description is given using a certain mounting part (for example, the mounting part 11-1), the description is also applied as an explanation of other mounting parts (for example, the mounting parts 11-2 to 11-9). Is done.

  In the example of FIG. 1, the mounting portion 11-1 is closed (fixed) so as to contact the stand 10. In this case, when the television receiver 21-1 (or the front surface of the mounting unit 11-1) mounted on the mounting unit 11-1 is pushed into the stand 10 by the user, the mounting unit 11-1 is 3, it is released from the stand 10, pushed out before the stand 10, and protrudes from the stand 10. Further, the mounting portion 11-1 protruding from the stand 10 is closed so as to be in contact with the stand 10 by being pushed again by the user toward the stand 10 side.

  By configuring the mounting portions 11-1 to 11-9 as described above, even if the television receivers 21-1 to 21-9 are more closely arranged as shown in FIG. As shown in FIG. 3, when the user pushes the mounting portion 11-1 toward the stand 10, the mounting portion 11-1 is released from the stand 10, pushed out before the stand 10, and attached to the stand 10. It will be in the state which protruded from the other television receiver 21 currently made. Thereby, the user can remove easily the television receiver 21-1 from the mounting part 11-1.

  In addition, the television receiver 21-1 is mounted on the mounting portion 11-1 that is released from the stand 10 and protrudes, and is pushed into the stand 10 again, so that the mounting portion 11-1 is shown in FIG. As shown, it is closed and secured to the stand 10.

  In the example of FIG. 3, the mounting unit 11-4 is again pushed into the stand 10 side without mounting the television receiver 21-4 on the mounting unit 11-4 released from the stand 10. The state fixed to the stand 10 is shown.

  As described above, the user can easily attach and detach the television receiver 21-1 from the mounting unit 11-1.

  Returning to FIG. 1, a speaker (not shown) that outputs the sound of the television receiver that constitutes the scalable TV system 1 is further provided below the third stage mounting portions 11-7 to 11-9 of the stand 10. ) Are respectively provided, and an electric box in which the electric system of the scalable TV system 1 (that is, the electric system of each column in the stand 10) is collected is stored below the racks 12-1 to 12-3. Boxes 13-1 to 13-3 are provided.

  Although not shown, in addition to the two outer supports, two supports are provided inside the stand 10, and in addition to the upper surface and the installation surface, a four-stage base is provided inside. As a result, a framework of 3 columns × 5 columns corresponding to the mounting portions 11-1 to 11-9, the racks 12-1 to 12-3, and the boxes 13-1 to 13-3 is configured. Yes.

  Therefore, in the following, when the stand 10 is individually described in relation to the mounting portions 11-1 to 11-9, the racks 12-1 to 12-3, and the boxes 13-1 to 13-3, the mounting is performed. The frames corresponding to the sections 11-1 to 11-9, the racks 12-1 to 12-3, and the boxes 13-1 to 13-3 are also referred to as stand frames 10-1 to 10-15, respectively.

  Here, the number of television receivers constituting the scalable TV system 1 is not limited to nine, and the arrangement of the television receivers constituting the scalable TV system 1 is also shown in FIG. As described above, the length × width is not limited to 3 × 3. In other words, the scalable TV system 1 can be configured by an arbitrary plurality of television receivers by changing the number of rows and stages of the mounting units, and constitutes the scalable TV system 1. Other arrangements of the television receivers may be, for example, vertical × horizontal 1 × 3, 2 × 3, 2 × 5, or the like.

  As described above, the scalable TV system 1 is a “scalable” system because an arbitrary number of television receivers can be arranged by arranging an arbitrary number of horizontal and vertical receivers. it can.

  The scalable TV system 1 is accompanied by a remote commander (not shown) that emits infrared IR (Infrared Ray), and the user operates the remote commander to change the reception channel, volume, and other various commands. Can be provided to each of the television receivers 21-1 to 21-9 of the scalable TV system 1. The infrared IR light receiving unit from the remote commander may be provided in one place in the scalable TV system 1 or may be provided for each of the television receivers 21-1 to 21-9.

  The remote commander is not limited to the one that performs infrared communication, and for example, a device that performs wireless communication such as BlueTooth (trademark) can be adopted.

  The television receivers 21-1 to 21-9 constituting the scalable TV system 1 are independent television receivers that operate independently, and are configured to be thin as shown in FIG. That is, each of the television receivers 21-1 to 21-9 includes a control block for determining a command from the remote commander, a signal processing block, a tuner, and the like. A display composed of a thin LCD (Liquid Crystal Display) or the like having a size of (inch) or 15 inches is provided.

  Therefore, even if the television receivers 21-1 to 21-9 are removed from the stand 10 and moved to other places, each of them functions as one television receiver. That is, the television receivers 21-1 to 21-9 each select a channel of a television broadcast signal received by an antenna (not shown) at a place where it is installed, and broadcast the selected channel. The content video is displayed on each display.

  On the other hand, in the scalable TV system 1, the television receivers 21-1 to 21-9 are mounted on the mounting portions 11-1 to 11-9, and the mounting portions 11-1 to 11-9 are mounted on the stand 10. When it is fixed to, it is possible to recognize its own arrangement position on the stand 10.

  Accordingly, the television receivers 21-1 to 21-9 attached to the stand 10 have one broadcast content video on their respective displays in accordance with the commands from the remote commander and the positions of the television receivers 21-1 to 21-9. Can be displayed large. Further, for example, only 2 × 2 of the television receivers 21-1 to 21-9 display a video of one broadcast content on its own display, and the other television receivers are different from each other. It is also possible to display the broadcast content video on its own display.

  At this time, for example, even if any of the television receivers 21-1 to 21-9 is removed from the stand 10, each television receiver attached to the stand 10 is independent. Since the operation is performed, it is possible to display a command from the remote commander and an image corresponding to the position of the remote commander.

  Of course, the television receivers 21-1 to 21-9 attached to the stand 10 determine the commands from the remote commander, as in the case of the television receiver used alone, and are not shown. It is also possible to select a television broadcast signal channel received by the antenna with a built-in tuner and display the video of the broadcast content of the selected channel on each display as shown in FIG.

  4 and 5 are enlarged perspective views showing a detailed configuration example of the mounting portion 11-4 in FIG. In the example of FIG. 4, the mounting portion 11-4 that is released from the stand 10 (stand frame 10-4) and protrudes from the stand frame 10-4 is shown. In the example of FIG. 5, the stand frame is shown. The mounting portion 11-4 is shown in a state of being fixed so as to be in contact with 10-4.

  A monitor hook 31 for attaching the television receiver 21-4 to the stand 10 by hooking a monitor pipe 41 (FIG. 6) provided on the rear surface of the television receiver 21-4 to the mounting portion 11-4. The connector 32 for electrically connecting the electrical block of the television receiver 21-4 and the stand 10 (actually, the electrical box housed in the box 13-1) and the mounting portion 11- A monitor lock 33 is provided for fixing the lower portion of the television receiver 21-4 to the mounting portion 11-4 when 4 is fixed to the stand 10.

  As shown in FIG. 4, when the mounting portion 11-4 is released from the stand frame 10-4 and protrudes from the stand frame 10-4, the monitor hook 31 is used to detach the television receiver 21-4. The connector 32 and the monitor lock 33 are in an open state protruding in front of the mounting portion 11-4.

  When the television receiver 21-4 is mounted on the mounting portion 11-4 in the open state, and the mounting portion 11-4 on which the television receiver 21-4 is mounted is fixed to the stand frame 10-4, The monitor hook 31 and the monitor lock 33 fix the monitor pipe 41 of the television receiver 21-4 and the lower part of the television receiver 21-4, respectively.

  Thereby, the television receiver 21-4 is firmly fixed by the monitor hook 31 provided in the upper part of the mounting part 11-4 and the monitor lock 33 provided in the lower part of the mounting part 11-4.

  At this time, the connector 32 is connected to a connection connector provided in the television receiver 21-4, and is connected to the television receiver 21-4 mounted on the mounting portion 11-4, for example, an antenna (not shown). TV broadcast signals from, video and audio signals from video recorders, power, predetermined information, etc. are supplied. The predetermined information includes information on an arrangement position on the stand 10 and the like.

  Thereby, the television receiver 21-4 mounted on the mounting unit 11-4 can recognize its own arrangement position on the stand 10.

  On the other hand, as shown in FIG. 5, when the television receiver 21-4 is not attached and the attachment portion 11-4 is fixed to the stand frame 10-4, the monitor hook 31, the connector 32, and the monitor lock 33 will be in the closed state accommodated in the stand frame 10-4.

  Thereby, even if the television receiver 21-4 is not attached to the attachment portion 11-4, the monitor hook 31, the connector 32, and the monitor lock 33 do not protrude from the attachment portion 11-4. Therefore, the user's hindrance is also suppressed when viewing the video displayed on other television receivers.

  FIG. 6 is an enlarged side view illustrating a configuration example of the mounting unit 11-1 and the television receiver 21-1 in FIG. In the example of FIG. 6, the mounting portion 11-1 is released from the stand frame 10-1 and protrudes from the stand frame 10-1.

  A monitor pipe 41 is attached to the rear surface of the television receiver 21-1, and the television receiver 21-1 is hooked on the monitor hook 31 provided in the mounting portion 11-1. Is mounted on the mounting portion 11-1.

  One end portion of the pantograph mechanism 42 is attached to the stand frame 10-1, and the other end portion of the pantograph mechanism 42 is attached to the mounting portion 11-1. That is, the mounting portion 11-1 is connected to the stand frame 10-1 through the pantograph mechanism 42.

  The pantograph mechanism 42 moves the mounting portion 11-1 as a movable member from the stand frame 10-1 and the stand frame 10-1 as indicated by an arrow 43 with respect to the stand frame 10-1 as a fixed member. A position separated by a predetermined distance is configured to reciprocate in parallel.

  Therefore, the mounting portion 11-1 as the movable member released from the stand frame 10-1 as the fixed member closes or protrudes in parallel with the stand frame 10-1, that is, a parallel reciprocating motion. Will be able to do.

  6 corresponds to the lock cam portions 51-1 and 51-2 (FIG. 7) provided on the left and right sides of the lower portion of the mounting portion 11-1 on the stand frame 10-1 side, respectively. Lock pin portions 44-1 and 44-2 are provided.

  When the user pushes the mounting portion 11-1 released from the stand frame 10-1 and protruding into the stand frame 10-1 side, the lock pin portions 44-1 and 44-2 become the lock cam portion 51-1. And 51-2. Thereby, the mounting part 11-1 is fixed to the stand frame 10-1.

  Further, when the user further pushes the mounting portion 11-1 fixed to the stand frame 10-1 into the stand frame 10-1, the lock pin portions 44-1 and 44-2 are locked cam portions 51-1 and 51. -2. Thereby, the mounting part 11-1 is released from the stand frame 10-1.

  That is, the lock pin portions 44-1 and 44-2, together with the lock cam portions 51-1 and 51-2, fix and release the mounting portion 11-1 from the stand frame 10-1 (with respect to the stand frame 10-1). (Stopping and resuming the movement of the mounting portion 11-1).

  FIG. 7 is a perspective view showing a configuration example of the stand frame 10-1 of FIG. In practice, a cover (not shown) is attached to the back of the stand 10 so that the inside of the stand 10 (stand frames 10-1 to 10-15) cannot be seen.

  In the example of FIG. 7, the mounting portion 11-1 on which the television receiver 21-1 is mounted is fixed to the stand frame 10-1, and the pantograph mechanism 42 is housed inside the stand frame 10-1. It is shown.

  That is, in the stand frame 10-1, a lock cam portion 51-1 is provided at a position (lower left in the figure) corresponding to the lock pin portion 44-1 provided in the mounting portion 11-1. In this example, the lock pin portion 44-1 is fitted to the lock cam portion 51-1.

  In addition, although not shown in FIG. 7, the lock cam part 51-2 corresponding to the lock pin part 44-2 is also provided in the left-right symmetrical position in the stand frame 10-1. Details of the lock pin portions 44-1 and 44-2 and the lock cam portions 51-1 and 51-2 will be described with reference to FIG.

  In the example of FIG. 7, the pantograph mechanism 42 of FIG. 6 is composed of two symmetrical pantograph mechanisms 42-1, and a pantograph mechanism 42-2 (FIG. 8) for the purpose of improving rigidity. .

  The pantograph mechanism 42-1 is attached to one strut 61-1 side (left side in the figure) in the stand frame 10-1, and attached to the other strut 61-2 (FIG. 8) side in the stand frame 10-1. The pantograph mechanism 42-2 is connected via three shafts 62 to 64.

  Further, connecting members 72-1 and 72-2 for holding the thin shaft 71 are attached to the shaft 64. An upper end portion of an air cylinder 81 whose lower end portion is attached to the stand frame 10-1 is attached to and held by the thin shaft 71. Details of the air cylinder 81 will be described later with reference to FIG.

  Further, an upper end portion of a gas spring 82 having a lower end portion attached to the stand frame 10-1 is attached to the connecting member 72-2. Details of the gas spring 82 will be described later with reference to FIG.

  FIG. 8 is a side view showing a detailed configuration example of the pantograph mechanism 42-2.

  In the example of FIG. 8, description is made using the support 61-2 in the stand frame 10-1 and the pantograph mechanism 42-2 attached to the support 101-2 side frame 101-2 of the mounting portion 11-1. However, the pantograph mechanism 42-1 attached to the column 61-1 in the stand frame 10-1 and the frame 101-1 on the column 61-1 side of the mounting portion 11-1 is symmetrical with the pantograph mechanism 42-2. However, it has the same configuration as the pantograph mechanism 42-2 and performs the same operation.

  The support 61-2 in the stand frame 10-1 as a fixed member is provided with a rail 111 and an inner 112 that can move up and down on the rail 111 from the center to the lower end, and a mounting portion as a movable member The frame 101-2 of 11-1 is provided with a rail 121 and an inner 122 that can move up and down on the rail 121 from the center to the lower end.

  The pantograph mechanism 42-2 includes an arm 131 and an arm 132. The arm 131 and the arm 132 are connected using a parallel pin 133 and are configured to be rotatable about the parallel pin 133 as an axis. In addition, in order to improve the rigidity of a connection part, you may make it attach a bearing to the parallel pin 133. FIG.

  One fixed end of the arm 131 is attached to the upper end of the frame 101-2 using a parallel pin 141, and the other fixed end is connected to the inner 112 on the rail 111 provided in the column 61-2. 142 is attached.

  One fixed end of the arm 132 is attached to the upper end of the column 61-2 using a parallel pin 143, and the other fixed end is connected to the inner 122 on the rail 121 provided in the frame 101-2. 144 is attached.

  That is, since the inner 112 and the arm 131 are attached by the parallel pins 142, the arm 131 is rotatable about the parallel pins 142 with respect to the inner 112. The inner 112 moves up and down on the rail 111. It becomes movable. Similarly, since the inner 122 and the arm 132 are attached by the parallel pin 144, the arm 132 is rotatable with respect to the inner 122 about the parallel pin 144, and the inner 122 moves up and down on the rail 121. It becomes possible to move to.

  By configuring the pantograph mechanism 42-2 as described above, the frame 101-2 of the mounting portion 11-1 as the movable member is reciprocally moved and reciprocated with respect to the support post 61-2 as the fixed member. Can do exercise.

  Further, a pantograph mechanism 42-1 that enables the frame 101-1 of the mounting portion 11-1 as a movable member to reciprocate and move back and forth with respect to the support post 61-1 as a fixed member is a pantograph mechanism 42. -2 and left-right symmetry. Therefore, the stand frame 10-1 is connected to the left and right frames 101-1 and 101-2 of the mounting portion 11-1 via the two pantograph mechanisms 42-1 and 42-2. The movement of the mounting portion 11-1 can be balanced.

  In the example of FIG. 8, the arm 131 of the pantograph mechanism 42-2 is provided with a shaft holder 151 for holding the shaft 62 and a shaft holder 152 for holding the shaft 64. The shaft holders 151 and 152 of the arm 131 of the pantograph mechanism 42-2 hold the shaft 62 and the shaft 63 together with the shaft holders 151 and 152 provided in the same manner as the arm 131 of the pantograph mechanism 42-1. The mechanisms 42-1 and 42-2 are connected.

  The arm 132 of the pantograph mechanism 42-2 is provided with a shaft holder 153 for holding the shaft 63. The shaft holder 153 of the arm 132 of the pantograph mechanism 42-2 holds the shaft 62 and the shaft 63 together with the shaft holder 153 provided in the same manner as the arm 132 of the pantograph mechanism 42-1. And 42-2 are connected.

  Thereby, the rigidity of the pantograph mechanisms 42-1 and 42-2 is improved.

  By configuring the pantograph mechanisms 42-1 and 42-2 as described above, the mounting portion 11-1 as a movable member is supported on the left and right, and therefore, with respect to the stand frame 10-1 as a fixed member, Reciprocating motion can be performed in a stable state.

  Next, a gas spring attached to the pantograph mechanism 42-2 will be described with reference to FIG.

  FIG. 9 is a side view showing an example of attaching the gas spring 82 to the pantograph mechanism 42-2. In FIG. 9, not only the frame 101-2 of FIG. 8 but also the front plate 11-1a of the mounting portion 11-1 is shown as the mounting portion 11-1, and the stand frame 10-1 is shown in FIG. In addition to the eight struts 61-2, a strut fixing base 171 for fixing the struts 61-2 is also shown. Further, in the arm 132 of FIG. 9, the shaft holder 153 is omitted.

  A connecting member 72-2 is attached to the arm 131 of FIG. 9 via a shaft 64 held by a shaft holder 152.

  The gas spring 82 has a lower fixed end 82a fixed to the column fixing base 171 of the stand frame 10-1 by using a fixing member 172 on the back side of the connecting member 72-2 in the drawing, and the upper movable portion. The end 82b is fixed using a parallel pin 174 and attached to the pantograph mechanism 42-2.

  The fixed end 82a and the movable end 82b of the gas spring 82 are fixed using parallel pins 173 and 174, and can be freely angled with respect to the column fixing base 171 and the connecting member 72-2, respectively. Can be changed.

  The gas spring 82 has a stretching ability capable of stretching to a predetermined length by being filled with a gas such as nitrogen.

  When the gas spring 82 is contracted, the movable end 82b of the gas spring 82 moves upward in the figure due to the expansion capability of the gas spring 82, and attached to the movable end 82b of the gas spring 82 with this movement. The connecting member 72-2 is pushed upward.

  When the connecting member 72-2 is pushed up, the inner 112 attached to the arm 131 of the pantograph mechanism 42-2 and the inner 122 attached to the arm 132 are moved to the rail 111 and the rail 121 as indicated by the arrow u. At the same time, the fixed end of the arm 131 and the frame 101-2 of the mounting portion 11-1 attached to the fixed end using the parallel pin 141 move in the direction of arrow A.

  This operation is similarly performed in the pantograph mechanism 42-1. That is, when the connecting member 72-2 is pushed up, the inner 112 attached to the arm 131 of the pantograph mechanism 42-1 and the inner 122 attached to the arm 132 are moved along the rail 111 and the rail 121 by the arrow u. As shown in FIG. 6, each of the arms 131 moves upward, and at the same time, the fixed end of the arm 131 and the frame 101-1 of the mounting portion 11-1 attached to the fixed end using the parallel pin 141 move in the direction of arrow A.

  As described above, the mounting portion 11-1 is pushed forward (in the direction of arrow A) from the stand frame 10-1 and protrudes from the stand frame 10-1.

  On the other hand, for example, the user pushes the mounting portion 11-1 protruding from the stand frame 10-1 into the stand frame 10-1 (arrow B direction). When a force is applied in the direction of arrow B, the inner 112 attached to the arm 131 of the pantograph mechanisms 42-1 and 42-2, and the inner 122 attached to the arm 132, along the rail 111 and the rail 121, As indicated by the arrow d, the gas spring 82 is lowered, and at the same time, the movable end 82b of the gas spring 82 attached to the connecting member 72-2 is lowered, so that the gas spring 82 contracts.

  At this time, the lock pin portions 44-1 and 44-2 described above are fitted into the lock cam portions 51-1 and 51-2, respectively, and the mounting portion 11-1 is fixed to the stand frame 10-1. Therefore, the gas spring 82 is accommodated in the stand frame 10-1 in a contracted state.

  As described above, the mounting portion 11-1 released from the stand frame 10-1 moves in the direction of arrow A from the stand frame 10-1 due to the extension capability of the gas spring 82. The movement speed at which the gas spring 82 moves in the direction of arrow A is largely caused by the expansion and contraction speed of the gas spring 82 while being affected by the weight of the member.

  Therefore, by attaching the gas spring 82 to the pantograph mechanism 42, the mounting portion 11-1 can be pushed out from the stand frame 10-1, but the pushing speed (that is, the movement of the mounting portion 11-1 in the direction of arrow A). It is difficult to control (speed).

  That is, the (piston rod) extension speed of the gas spring can be controlled by the cylinder diameter, piston rod diameter, gas amount and oil amount filled in the cylinder, but this control is set by the gas spring manufacturer, The user has no choice but to use a specification close to the desired requirement. However, when trying to select a gas spring to be actually used, it is often not the extension speed that the user wants to use, and it is difficult to adjust to a lower extension speed than the manufacturer's specifications.

  In addition, it is possible to cope with a configuration in which the extension speed is electrically adjusted, but there is a risk that the manufacturing cost increases.

  Therefore, in addition to the gas spring 82, an air cylinder 81 is attached to the pantograph mechanism 42 as shown in FIG.

  FIG. 10 is a side view showing an example of attaching the air cylinder 81 to the pantograph mechanism 42-2 of FIG.

  The air cylinder 81 has a lower fixed end 81a fixed to the column fixing base 171 of the stand frame 10-1 using a fixing member 181 on the front side of the connecting member 72-2 in the figure, and an upper movable end. 81b is fixed to the thin shaft 71 (FIG. 11) held by the connecting member 72-2 and attached to the pantograph mechanism 42-2.

  The fixed end 81a of the air cylinder 81 is fixed by using a parallel pin, and the movable end 81b is fixed by a thin shaft 71, which is respectively connected to the column fixing base 171 and the connecting member 72-2. You can change the angle freely.

  Since the air cylinder 81 acts as a reaction force against the extension capability (that is, the force in the extension direction) of the gas spring 82, by providing the air cylinder 81 in the pantograph mechanism 42-2, the extension speed ( The speed at which the mounting portion 11-1 moves in the direction of arrow A) can be reduced.

  Moreover, the air cylinder 81 actually has a speed control mechanism 201 as shown in FIG. 11, and the reaction force against the gas spring 82 can be adjusted by the speed control mechanism 201.

  In the example of FIG. 11, the air cylinder 81 is connected to the speed control mechanism 201 by a connecting pipe 202 via an air hole portion 81 c for taking in and out air from the outside. The hole 81c, the connecting pipe 202, and the air speed control mechanism 201 are inserted into and removed from the outside.

  FIG. 12 is a side view and a front view showing a detailed configuration example of the speed control mechanism 201.

  The speed control mechanism 201 includes a speed control main body 211 and a flow rate adjusting screw 212. The speed control main body 211 has an air inlet / outlet port 211a through which air is taken in / out through the hole 213 and an air inlet / outlet port 211b through which air is taken in / out of the connecting pipe 202 connected to the air hole 81c of the air cylinder 81 through the hole 213. Is provided.

  The flow rate of air passing through the speed control body 211 is adjusted by tightening the flow rate adjusting screw 212. By tightly tightening the flow rate adjusting screw 212, the flow rate of the air passing through the speed control body 211 is reduced, and the reaction force against the extending force of the air cylinder 81 is increased. Further, by loosely tightening the flow rate adjusting screw 212, the flow rate of the air passing through the speed control body 211 is increased, and the reaction force against the extending force of the air cylinder 81 is reduced.

  As described above, the internal pressure of the air cylinder 81 is adjusted, and the reaction force against the gas spring 82 is also adjusted.

  That is, returning to FIG. 10, when the extension speed of the gas spring 82 (the speed at which the mounting portion 11-1 moves in the direction of arrow A) is higher than the desired speed, the air flow rate of the speed control mechanism 201 is reduced. The reaction force of the air cylinder 81 is increased. Thereby, the moving speed to the arrow A direction of the mounting part 11-1 by the gas spring 82 can be reduced.

  On the other hand, when it is desired to increase the extension speed of the gas spring 82, the reaction force of the air cylinder 81 is decreased by increasing the air flow rate of the speed control mechanism 201. Thereby, the moving speed to the arrow A direction of the mounting part 11-1 by the gas spring 82 can be increased.

  Next, the operation of the pantograph mechanism 42 including the air cylinder 81 and the gas spring 82 will be described.

  For example, as shown in the example of FIG. 10, in a state where the mounting portion 11-1 is released from the stand frame 10-1, The extension capability of the gas spring 82 adjusted by the reaction force acts, and the mounting portion 11-1 protrudes from the stand frame 10-1 in the arrow A direction.

  Here, the user pushes the mounting portion 11-1 protruding in the arrow A direction from the stand frame 10-1 into the stand frame 10-1 (arrow B direction).

  When human power or the like is applied in the direction of arrow B, the inner 112 attached to the arm 131 of the pantograph mechanism 42-2 and the inner 122 attached to the arm 132 are moved to the arrow d along the rail 111 and the rail 121. As shown in the drawing, the movable end 81b of the air cylinder 81 attached to the connecting member 72-2 and the movable end 82b of the gas spring 82 are lowered simultaneously with the lowering of the inners 112 and 122, and the air The cylinder 81 and the gas spring 82 contract.

  As described above, as shown in FIG. 13, the arms 131 and 132 are folded and housed in the stand frame 10-1, and the mounting portion 11-1 is closed with respect to the stand frame 10-1.

  At this time, the mounting portion 11-1 is actually attached to the stand frame 10-1 by fitting the lock pin portions 44-1 and 44-2 to the lock cam portions 51-1 and 51-2. It is fixed (locked) to it.

  For example, the user pushes the mounting portion 11-1 fixed to the stand frame 10-1 further into the stand frame 10-1 side (arrow B direction), so that the lock pin portions 44-1 and 44-2 are moved. The lock cams 51-1 and 51-2 are disengaged. Thereby, the mounting part 11-1 is released from the stand frame 10-1.

  At this time, the movable end 82b of the gas spring 82 and the movable end 81b of the air cylinder 81 are moved in the direction of the arrow u (in the drawing) at a speed adjusted by the extension capability of the contracted gas spring 82 and the reaction force of the air cylinder 81. With this movement, the connecting member 72-2 attached to the movable end 81b of the air cylinder 81 and the movable end 82b of the gas spring 82 is pushed upward.

  When the connecting member 72-2 is pushed up, the inner 112 attached to the arm 131 of the pantograph mechanism 42-2 and the inner 122 attached to the arm 132 rise along the rail 111 and the rail 121, respectively. The fixed end of the arm 131 and the frame 101-2 of the mounting portion 11-1 attached to the fixed end using the parallel pin 141 move in the arrow A direction.

  This operation is similarly performed in the pantograph mechanism 42-1. That is, when the connecting member 72-2 is pushed up, the inner 112 attached to the arm 131 of the pantograph mechanism 42-1 and the inner 122 attached to the arm 132 are moved along the rail 111 and the rail 121 by the arrow u. As shown in FIG. 6, each of the arms 131 moves upward, and at the same time, the fixed end of the arm 131 and the frame 101-1 of the mounting portion 11-1 attached to the fixed end using the parallel pin 141 move in the direction of arrow A.

  As described above, the mounting portion 11-1 moves forward (in the direction of arrow A) from the stand frame 10-1 with the moving speed controlled by the extension capability of the gas spring 82 and the reaction force of the air cylinder 81 as shown in FIG. 10. ) To protrude from the stand frame 10-1.

  The moving speed of the mounting portion 11-1 in the direction of the arrow A can be realized by other methods such as a gas damper and a friction sleep. However, the speed control by the extension capability of the gas spring 82 and the reaction force of the air cylinder 81 can be finely adjusted as compared with other methods, and the movement speed once adjusted is maintained for a long period. It is possible.

  As described above, the moving speed of the mounting portion 11-1 in the direction of the arrow A is controlled by the extension capability of the gas spring 82 and the reaction force of the air cylinder 81, so that the plurality of the scalable TV system 1 in FIG. It is possible to adjust the moving speed of the mounting portions 11-1 to 11-9 from the stand 10 so as to be substantially constant, and to maintain the adjustment over a long period of time.

  As a result, the user can safely and easily put the mounting portions 11-1 to 11-9 in front of the stand 10.

  FIG. 14 is a rear view showing an example of arrangement positions of the air cylinder 81 and the gas spring 82 in the stand frame 10-1. In addition, since the pantograph mechanisms 42-1 and 42-2 in the example of FIG. 14 are for clearly indicating only the positions, they are simply illustrated as rectangles for convenience of explanation.

  In the example of FIG. 14, connecting members 72-1 and 72-2 are attached to the shaft 64 held by the pantograph mechanism 42-1 and the pantograph mechanism 42-2 in order from the pantograph mechanism 42-1 side. Yes.

  The connecting member 72-1 and the connecting member 72-2 hold the thin shaft 71, and the movable end 81b of the air cylinder 81 is attached to the thin shaft 71. Further, the movable end 82b of the gas spring 82 is further attached to the connecting member 72-2 by a parallel pin 174.

  The arrangement relationship in FIG. 14 is an example, and the positions of the air cylinder 81 and the gas spring 82 may be reversed, and the arrangement interval can also be changed according to the speed adjustment. . Moreover, the attachment method to the pantograph mechanism 42-1 and the pantograph mechanism 42-2 is not limited to the above-described example.

  Further, the air cylinder 81 and the gas spring 82 are not limited to one configuration, but may be configured by increasing at least one of the air cylinder 81 and the gas spring 82 according to the speed adjustment degree. . That is, a plurality of air cylinders 81 may be configured for one gas spring 82, and conversely, a plurality of gas springs 82 may be configured for one air cylinder 81. Alternatively, a plurality of both may be configured.

  15 is a perspective view illustrating a configuration example of the mounting unit 11-1 and the stand frame 10-1, and FIG. 16 is a mounting unit in a state where the front plate 11-1a of the mounting unit 11-1 of FIG. 15 is removed. It is a perspective view which shows the structural example of 11-1 and the stand frame 10-1. Note that portions corresponding to those in FIG. 10 are denoted by corresponding reference numerals, and the description thereof will be repeated, and will be omitted as appropriate.

  A pantograph mechanism 42-1 is provided on the column 61-1 of the stand frame 10-1 shown in the front of the figure and the frame 101-1 of the mounting portion 11-1, and the stand frame shown in the back of the figure. A pantograph mechanism 42-2 is provided on the support 61-2 of 10-1 and the frame 101-2 of the mounting portion 11-1.

  The pantograph mechanisms 42-1 and 42-2 are connected to each other by holding the shaft 62, the shaft 64, and the shaft 63 respectively with shaft holders 151 to 153 installed therein. Thereby, the movable balance of the mounting part 11-1 and the improvement in rigidity are enhanced.

  A connecting member 72-2 is held on the shaft 64, and a movable end 81b of an air cylinder 81 is attached to the connecting member 72-2 via a thin shaft 71 so that the gas spring 82 can move. End 82b is attached using parallel pins 174.

  For example, as shown in the example of FIG. 15, in a state where the mounting portion 11-1 and the stand frame 10-1 are open (that is, a state where the mounting portion 11-1 is released from the stand frame 10-1). The user pushes the mounting portion 11-1 protruding in the arrow A direction from the stand frame 10-1 into the stand frame 10-1 side (arrow B direction).

  When human power or the like is applied in the direction of arrow B, the inner 112 attached to the arm 131 of the pantograph mechanisms 42-1 and 42-2 and the inner 122 attached to the arm 132 follow the rail 111 and the rail 121. The movable end 81b of the air cylinder 81 attached to the connecting member 72-2 and the movable end 82b of the gas spring 82 are lowered simultaneously with the lowering of the inners 112 and 122, respectively. The spring 82 contracts.

  As described above, as shown in FIG. 17, the arms 131 and 132 of the pantograph mechanisms 42-1 and 42-2 are folded, and the pantograph mechanisms 42-1 and 42-2 are housed in the stand frame 10-1. It will be in a state and the mounting part 11-1 will be closed with respect to the stand frame 10-1.

  At this time, the mounting portion 11-1 is actually attached to the stand frame 10-1 by fitting the lock pin portions 44-1 and 44-2 to the lock cam portions 51-1 and 51-2. It is fixed (locked) to it.

  On the other hand, as shown in FIG. 17, in a state where the mounting portion 11-1 is closed (that is, fixed) with respect to the stand frame 10-1, the user is mounted on the stand frame 10-1. By pushing the portion 11-1 into the stand frame 10-1 side (arrow B direction), the lock pin portions 44-1 and 44-2 are detached from the lock cam portions 51-1 and 51-2. Thereby, the mounting part 11-1 is released from the stand frame 10-1.

  At this time, the movable end 82b of the gas spring 82 and the movable end 81b of the air cylinder 81 move upward in the figure at a speed adjusted by the extension capability of the contracted gas spring 82 and the reaction force of the air cylinder 81. With this movement, the connecting member 72-2 attached to the movable end 81b of the air cylinder 81 and the movable end 82b of the gas spring 82 is pushed upward.

  When the connecting member 72-2 is pushed up, the inner 112 attached to the arm 131 of the pantograph mechanisms 42-1 and 42-2 and the inner 122 attached to the arm 132 are moved along the rail 111 and the rail 121, respectively. At the same time, the fixed end of the arm 131 and the frames 101-1 and 101-2 of the mounting portion 11-1 attached to the fixed end using the parallel pin 141 move in the arrow A direction.

  As described above, as illustrated in FIG. 15, the mounting portion 11-1 is pushed forward (in the direction of arrow A) from the stand frame 10-1 and protrudes from the stand frame 10-1.

  As described above, the movable speed of the mounting portion 11-1 with respect to the stand frame 10-1 can be controlled by the extension capability of the gas spring 82 and the reaction force of the air cylinder 81. The moving speeds of all the mounting portions 11-1 to 11-9 can be adjusted to be substantially constant.

  Accordingly, the user can safely and easily attach the television receiver 21-1 to the monitor hook 31 provided in the attachment unit 11-1, or the television receiver 21 attached to the attachment unit 11-1. -1 can be removed safely and easily.

  Next, with reference to FIG. 18, the locking mechanism provided in the mounting part 11-1 and the stand frame 10-1 will be described in detail.

  FIG. 18 is a top view of the mounting unit 11-1 to which the television receiver 21-1 is mounted and the stand frame 10-1 as viewed from directly above, in a state of protruding from the stand frame 10-1. In the example of FIG. 18, portions that are not necessary for the description of the lock mechanism of the stand frame 10-1 and the mounting portion 11-1 are omitted for convenience of description.

  The column fixing base 171 of the stand frame 10-1 in FIG. 18 is provided with a lock cam portion 51-1 on the column 61-1 side, and a lock cam portion 51-2 on the column 61-2 side. Yes.

  In addition, a power switch 221 having a metal piece 222 is attached to the column fixing base 171 of the stand frame 10-1 in the vicinity of the lock cam portion 51-2. The power switch 221 turns on the power state of the television receiver 21-1 while the metal plate 252 attached to the mounting portion 11-1 is in contact with the metal piece 222. That is, the power switch 221 detects that the television receiver 21-1 is attached to the stand 10, notifies the electric box housed in the box 13-1, and connects the television receiver via the connector 32. Power is supplied to 21-1.

  Normally, one end of the metal piece 222 is attached to the power switch 221 so as to be arranged at the position of the dotted line in FIG. 18, but the metal plate 252 installed in the mounting part 11-1 Pressed to the position of the solid line. At this time, since the metal piece 222 has elasticity, it generates a force to return to the dotted line position.

  On the other hand, the monitor pipe 31 of the television receiver 21-1 is attached to the monitor hook 31 provided on the front plate 11-1a of the attachment unit 11-1 in FIG.

  A storage unit 241 for storing a substrate of the television receiver 21-1 is attached to the rear surface of the television receiver 21-1, and the monitor pipe 41 is connected by connecting members 242-1 to 242-4. It is attached to the back surface of the storage unit 241 and the television receiver 21-1 so as to protrude from the back surface.

  Lock pin portions 44-1 and 44-2 are attached to the front frame 11-1a on the side of the stand frame 10-1 at positions corresponding to the lock cam portions 51-1 and 51-2 provided on the column fixing base 171. Protruding portions 251-1 and 251-2 are provided. That is, the lock pin portions 44-1 and 44-2 are attached to the protruding portions 251-1 and 251-2, respectively.

  Further, the projection 251-2 touches the metal piece 222 at a position corresponding to the metal piece 222 of the power switch 221 when the mounting portion 11-1 is closed by the stand 10, so that the television receiver A metal plate 252 for detecting that the machine 21-1 is mounted on the stand 10 is attached.

  Here, in a state where the mounting portion 11-1 is released from the stand frame 10-1, as described above with reference to FIG. The extension capability of the spring 82 is acting, and the mounting portion 11-1 protrudes from the stand frame 10-1 in the arrow A direction. Here, the user pushes the mounting portion 11-1 protruding in the arrow A direction from the stand frame 10-1 into the stand frame 10-1 (arrow B direction).

  When a force is applied in the direction of arrow B, the pantograph mechanisms 42-1 and 42-2 are housed in the stand frame 10-1, and as shown in FIG. 10-1 is closed.

  At this time, the lock pin portions 44-1 and 44-2 attached to the protruding portion 251-1 and the protruding portion 252-2 are respectively connected to the lock cam portions 51-1 and 51-2 provided on the column fixing base 171. Mated. Thereby, the movement to the arrow A direction of the mounting part 11-1 which is a movable member is stopped (locked).

  At the same time, the metal plate 252 attached to the protruding portion 252-2 pushes the metal piece 222 of the power switch 221 into the position indicated by the solid line in FIG. Correspondingly, the metal piece 222 tries to return to the position of the dotted line in FIG. 18, and the metal piece 222 and the metal plate 252 continue to contact each other.

  Thereby, while the mounting unit 11-1 is closed with respect to the stand frame 10-1 (that is, while the mounting unit 11-1 is fixed to the stand frame 10-1), the television receiver 21-1 is installed. The power supply state is always kept ON.

  When the mounting portion 11-1 is closed with respect to the stand frame 10-1, that is, by the lock pin portions 44-1 and 44-2 and the lock cam portions 51-1 and 51-2, the mounting portion 11-1 When the user's movement is stopped (locked), the user further pushes the mounting portion 11-1 fixed to the stand frame 10-1 into the stand frame 10-1 side (arrow B direction), thereby The pin portions 44-1 and 44-2 are detached from the lock cam portions 51-1 and 51-2, respectively. Thereby, the mounting part 11-1 is released from the stand frame 10-1.

  At this time, as described above with reference to FIG. 10, the pantograph mechanisms 42-1 and 42-2 are moved to the stand frame 10 at a speed adjusted by the extension ability of the pulling 82 that has contracted and the reaction force of the air cylinder 81. Extruded from -1. Thereby, as shown in FIG. 18, the mounting portion 11-1 is pushed forward (in the direction of arrow A) from the stand frame 10-1 and protrudes from the stand frame 10-1.

  At the same time, the metal plate 252 attached to the protruding portion 252-2 moves away from the metal piece 222 of the power switch 221, and the metal piece 222 returns to the dotted line position. Thereby, since the metal piece 222 is released from contact with the metal plate 252, the power of the television receiver 21-1 is turned off.

  As described above, the power ON / OFF switching of the television receiver 21-1 is performed by opening / closing the mounting unit 11-1 to the stand frame 10-1, that is, the lock pin units 44-1 and 44-2. The lock cam portions 51-1 and 51-2 are locked and released.

  Therefore, the user can lock or unlock the mounting unit 11-1 only by pushing the mounting unit 11-1 into the stand frame 10-1, and accordingly, the television receiver 21-1 can be unlocked. Can be turned on or off.

  This eliminates the need for the user to switch the power on or off of the television receiver 21-1 and to worry about forgetting to turn off the power.

  Next, the lock mechanism will be described in detail. FIG. 20 illustrates a detailed configuration example of the lock cam portion 51-2 provided on the column fixing base 171 of the stand frame 10-1. In the example of FIG. 20, the left side in the figure is the mounting portion 11-1 direction.

  The lock cam portion 51-2 includes a cam plate fixing base 311, a cam plate 312, and a cam plate 313.

  A cam plate mounting base 321 is provided on the cam plate fixing base 311. The cam plate mount 321 has a lock pin 351 (FIG. 21) of the lock pin portion 44-2 provided on the mounting portion 11-1 on the cam mounting table 321 on the mounting portion 11-1 side which is a movable member. It has a slope 321a formed so as to be easy.

  The cam plate 312 is attached to the cam plate fixing base 311 using a cantilever pin 322 on the stand frame 10-1 side which is a fixing member, and the cam plate 313 is attached to the stand frame 10-1 side. The holding pin 323 is used to attach the cam plate fixing base 311. The cam plate 312 and the cam plate 313 are configured to be rotatable about the cantilever pin 322 and the cantilever pin 323, respectively, in view of the performance of the cantilever pin.

  The cam plate 313 is attached to the cam plate fixing base 311 so that the contact surface 313a is in contact with the cam mount 321 due to its own weight, and the cam plate 312 is The contact surface 321a is attached to the cam plate fixing base 311 so as to be stationary in a state where it is in contact with the cam mounting base 321.

  The cam plate 312 is formed with a notch 331 for holding a lock pin 351 on which a force in the left direction (the mounting portion 11-1 direction) is acting. The cam plate 313 is formed with notches 332 and 333 for holding a lock pin 351 on which a force in the right direction in the drawing (in the direction of the stand frame 10-1) acts.

  FIG. 21 illustrates a detailed configuration example of the lock pin portion 44-2 in FIG. In the example of FIG. 21, the right side in the drawing is the direction of the stand frame 10-1.

  The lock pin portion 44-2 includes a lock pin 351 and a lock pin mounting plate 352. The lock pin 351 is attached to one end of the lock pin attachment plate 352, and the lock pin attachment plate 352 is attached to the movable member by a cantilever pin 353 on the other end side.

  In the lock pin mounting plate 352, one end portion to which the lock pin 351 is attached is held at a position P1 substantially parallel to the other end portion unless a force is applied. It is configured to be rotatable at a position P2 counterclockwise about the holding pin 353 and a position P3 clockwise about the cantilever pin 353.

  In the example of FIG. 21, the lock pin 351 is provided on the back side of the lock pin mounting plate 352 in the figure, but depending on the configuration of the lock mechanism, on the front side of the lock pin mounting plate 352 in the figure. You may make it provide.

  Next, the action of the force on the lock pin portion will be described with reference to FIG. 22, and the operation of the lock pin portion and the lock cam portion will be further described with reference to the process diagrams of FIGS.

  23 to 26, the operations of the lock pin portion 44-2 and the lock cam portion 51-2 are shown as states S1 to S10 representing the progress of the operation states of the lock pin portion 44-2 and the lock cam portion 51-2. It explains using. 22 to 26, in order to show the operation of the lock pin 351, the lock pin mounting plate 352 is shown in a transparent state. In FIGS. 22 to 26, reference numerals of parts that are not necessary for description are omitted as appropriate.

  As shown in FIG. 22, the mounting portion 11-1 as a movable member provided with the lock pin portion 44-2 is configured as shown in FIG. 10 unless a force is applied in the direction of arrow B by human power or the like. The force in the direction of arrow A is always applied by the extension capability of the gas spring 82 described above with reference to FIG.

  First, the locking operation will be described with reference to FIGS.

  For example, the user pushes and moves the mounting portion 11-1, which is a movable member, toward the stand frame 10-1 side (arrow B direction). In accordance with the movement of the mounting portion 11-1, the lock pin portion 44-2 also moves in the arrow B direction. A lock cam portion 51-2 is provided on the column fixing base 171 of the stand frame 10-1 before the lock pin portion 44-2 moves.

  At the stage where the mounting portion 11-1 is closed to the stand frame 10-1 (that is, the mounting portion 11-1 moves in the direction of arrow B), as shown in the state S1 in FIG. 351 rides on the cam plate mount 321 along an inclination 321 a formed on the cam plate mount 321. At this time, the cam plate 312 is stationary with the contact surface 312a in contact with the cam mount 321 due to its own weight, and the cam plate 313 has the contact surface 313a with the cam mount 321 due to its own weight. Still in contact with

  Further, when the mounting portion 11-1 moves in the arrow B direction, the lock pin 351 moves along the upper surface of the cam plate mounting base 321 as shown in the state S2, and the cam plate 312 is moved. Then, the surface 312b of the cam plate 312 is pushed up as shown in the state S3.

  At this time, the cam plate 312 rotates counterclockwise by the amount of the lock pin 351 with the cantilever pin 322 as an axis. Correspondingly, the inclined surface 331a of the notch 331 of the cam plate 312 pushes up the inclined surface 332a of the notch 332 of the cam plate 313, and the cam plate 313 rotates clockwise around the cantilever pin 323 in the drawing. The cam plate 313 is stationary while the contact portion 313b is in contact with the cam mount 321.

  That is, the contact portion 313b prevents the cam plate 313 from rotating too much, and after the lock pin 351 finishes contacting the cam plate 312, the contact surface 313a is brought into contact with the cam rest 321 by its own weight. Return to state. At this time, the positions of the cam plate 312 and the cam plate 313 are not necessarily limited to the positional relationship in which the inclined surface 331a pushes up the inclined surface 332a.

  Further, when the mounting portion 11-1 moves in the arrow B direction, the lock pin 351 finishes contact with the cam plate 312 as shown in the state S4 in FIG. 24, and as shown in the state S5. , It collides with a notch 332 formed in the cam plate 313. Since the notch 332 is formed so as to hold the lock pin 351 moving in the arrow B direction, the movement of the lock pin 351 is stopped by holding the notch 332.

  At this time, the cam plate 312 pushed up by the lock pin 351 returns to the original state where the contact surface 312a is brought into contact with the cam plate mounting base 321 by its own weight as shown in the state S6 of FIG. Returning, the cam plate 313 pushed up by the cam plate 312 also returns to the original state where the contact surface 313a comes into contact with the cam plate mounting base 321 due to its own weight.

  Here, for example, the user once releases the hand from the mounting unit 11-1. Correspondingly, when the force in the arrow B direction is no longer applied to the mounting portion 11-1, the lock pin 351 is moved to the state S7 by the force in the arrow A direction that always acts on the lock pin portion 44-2. As shown, it moves upward along the surface 331 a of the cam plate 312 and is held stationary by being held by a notch 331 formed in the cam plate 312.

  In other words, the cam plate 312 is in a state of being brought into contact with the cam plate mounting base 321 by the contact surface 312a and being stationary due to its own weight, so that the path along which the lock pin 351 has moved is blocked by the cam plate 312. Accordingly, the lock pin 351 cannot return the route that has been moved, passes through the inclined surface 331 a of the notch 331, and is guided to the notch 331.

  The notch 331 is formed so as to hold the lock pin 351 on which a force in the direction of arrow A acts, and the force of the lock pin 351 in the direction of arrow A is held by the notch 331 of the cam plate 312. As a result, the state S7 is maintained.

  As a result, the lock pin 351 held in the notch 331 of the cam plate 312 is in a locked state, and the mounting portion 11-1 that is a movable member is fixed (locked) to the stand frame 10-1. That is, the lock pin 351 is fitted into the notch 331 of the cam plate 312 and locked to the cam plate 312 only by the application of a force in the arrow B direction by the user.

  Next, the unlocking operation will be described with reference to FIG.

  In the locked state shown in the state S7 in FIG. 25, for example, the user pushes the mounting portion 11-1 further into the stand frame 10-1 side (arrow B direction). When the mounting portion 11-1 is pushed into the stand frame 10-1, the lock pin 351 moves upward along the inclined surface 333a of the notch 333 of the cam plate 313 as shown in the state S8 of FIG. .

  That is, the lock pin 351 is released from being held by the notch 331 of the cam plate 312.

  At this time, the lock pin 351 held in the notch 331 of the cam plate 312 comes into contact with the inclined surface 333a of the cam plate 313 by the force in the direction of the arrow B, passes through the inclined surface 333a as it is, and is cut. Guided to the notch 333.

  On the other hand, at this time, in the notch 331 of the cam plate 312, the inclined surface 333 b formed on the opposite side of the inclined surface 331 a is pushed up by the lock pin 351 that moves on the inclined surface 333 a of the cam plate 313.

  Further, when the mounting portion 11-1 is pushed into the stand frame 10-1, the lock pin 351 collides with the notch 333 of the cam plate 313 as shown in the state S9.

  The notch 333 is formed to hold the lock pin 351 on which a force in the direction of arrow B is applied. At this time, the notch 333 of the cam plate 313 is pushed by the force in the direction of arrow B received from the lock pin 351, and the cam plate 313 attempts to rotate clockwise around the cantilever pin 323. The contact portion 313b comes to a standstill in contact with the cam mount 321. Thereby, the lock pin 351 is held by the notch 333 of the cam plate 313 and stops.

  At this time, the inclined surface 333b of the cam plate 312 is released from the pushing-up of the lock pin 351, and the contact surface 313a returns to the state in contact with the cam rest 321 by its own weight.

  Here, the user once releases the hand from the mounting portion 11-1. Correspondingly, when the force applied by the user in the direction of the arrow B is released, the lock pin 351 is moved to the state S10 by the force in the direction of the arrow A always acting on the lock pin portion 44-2. As shown in FIG. 4, the contact surface 313a moves in the direction of arrow A along the upper surface 312c of the cam plate 312 in a state where the contact surface 313a is in contact with the cam mount 321 and moves away from the lock cam portion 44-2.

  As described above, the lock pin 351 is released from being locked (fitted) by the lock cam portion 44-2, and the mounting portion 11-1 is released from the stand frame 10-1. That is, the lock by the lock cam portion 44-2 of the lock pin 351 is released only by applying a force in the direction of the arrow B once.

  Next, the shape and positional relationship of the cam plate 312 and the cam plate 313 will be described in more detail with reference to the above operation.

  First, the shape of the cam plate 312 and the position of the cantilever pin 322 that fixes the cam plate 312 are such that the lock pin 351 can pass through the cam plate mounting base 321 as shown in the state S3 of FIG. When the lock pin 351 is held by the notch 332 of the cam plate 313 as shown in the state S6 of FIG. 25, the initial state (that is, the contact surface 313a is placed on the cam mount) The shape and the position return to the state in contact with 321).

  The shape of the cam plate 312 and the positional relationship between the cam plate 312 and the cam plate 313 are shown by the arrow A that always acts when the force in the arrow B direction is no longer applied, as shown in the state S7 of FIG. The lock pin 351 is shaped to be held by the notch 331 due to the force in the direction, and when the force in the arrow B direction is no longer applied as shown in the state S10 in FIG. The lock pin 351 moves and moves in the arrow A direction along the upper surface 312c of the cam plate 312 due to the acting force in the arrow A direction.

  On the other hand, the shape of the cam plate 313 and the position of the cantilever pin 323 that fixes the cam plate 313 are held by the notch 332 by the lock pin 351 moving in the arrow B direction as shown in the state S6 of FIG. Thus, the shape and position cannot be moved rearward (right side in the figure) from the notch 332, and the lock pin 351 collides with the notch 333 of the cam plate 313 as shown in the state S9 of FIG. When this occurs, the lock pin 351 that moves in the direction of arrow B is held by the notch 333, and has a shape and position that cannot be moved rearward from the notch 333.

  The shape of the cam plate 313 and the positional relationship between the cam plate 312 and the cam plate 313 are as follows when the mounting portion 11-1 is pushed again in the arrow B direction in the locked state, as shown in state S8 of FIG. In addition, the lock pin 351 has such a shape and positional relationship that it pushes up the inclined surface 333 a of the cam plate 313.

  As described above, the two cam plates are formed so as to have a predetermined shape, and are arranged in a predetermined positional relationship to constitute the lock cam portion 51-2. That is, the lock cam portion 51-2 corresponding to a conventional cam groove is configured by forming two cam plates having a predetermined shape and arranging them at a predetermined position. Therefore, it can be formed more easily than the conventional complicated cam groove.

  In the above description, the lock cam portion 51-2 provided on the column 61-2 side and the lock pin portion 44-2 corresponding to the lock cam portion 51-2 have been described. However, the lock cam portion 51-1 provided on the column 61-1 side is described. Is configured as shown in FIG.

  FIG. 27 shows a detailed configuration example of the lock cam portion 51-1 of FIG.

  Similarly to the lock cam portion 51-2, the lock cam portion 51-1 in FIG. 27 includes a cam plate fixing base 311, a cam plate 312, and a cam plate 313. The lock cam portion 51-2 in FIG. They are only different, and basically have the same configuration with left-right symmetry, and the description thereof will be omitted.

  Further, the lock pin portion 44-1 corresponding to the lock cam portion 51-1 is different from the lock pin portion 44-2 in FIG. 21 only in the left and right, and basically has the same configuration that is symmetrical to the left and right. Therefore, the description is omitted.

  As described above, by configuring the lock pin portion 44-2 and the lock cam portion 51-2, it is possible to lock and unlock only by applying a single force in the direction of arrow B both when locked and when unlocked. Can do.

  Accordingly, the user can easily fix or remove the mounting portion 11-1 from the stand frame 10-1.

  In the above description, the stand 10 to which the television receivers 21-1 to 21-9 are mounted has been described. However, if the stand 10 is equipped with a display, a display device may be used. It may be.

  Moreover, the pantograph mechanism provided with the air cylinder and the gas spring and the lock mechanism described above are not applied only to the stand on which the television receiver in the scalable TV system 1 is mounted, but move relative to the fixed member. Any device provided with a movable member can be applied to other devices.

It is a perspective view which shows the structural example of one Embodiment of the scalable TV system to which this invention is applied. It is a side view which shows the structural example of the external appearance of the scalable TV system of FIG. It is a perspective view which shows the structural example of the external appearance of the scalable TV system of the state by which the mounting part 11-1 of FIG. 1 was extruded from the stand. It is an expansion perspective view which shows the structural example of the mounting part 11-4 of FIG. 1 released from the stand and protruding from the stand. It is an expansion perspective view which shows the structural example of the mounting part 11-4 of the state fixed to the stand. FIG. 2 is an enlarged side view illustrating a configuration example of a mounting unit and a television receiver in FIG. 1. It is a perspective view which shows the structural example which looked at the stand frame corresponding to the mounting part with which the television receiver of FIG. 6 is mounted | worn from back. It is a side view which shows the detailed structural example of the pantograph mechanism of FIG. It is a side view which shows the example of attachment of the gas spring to the pantograph mechanism of FIG. It is a side view which shows the example of attachment of the air cylinder to the pantograph mechanism of FIG. It is a side view which shows the detailed structural example of the air cylinder of FIG. It is the side view and front view which show the detailed structural example of the speed control mechanism of FIG. It is a side view which shows the structural example of the pantograph mechanism of FIG. 10 in the state where the mounting part was closed with respect to the stand frame. It is a rear view which shows the example of the arrangement position of the air cylinder and gas spring in a stand frame. It is a perspective view which shows the structural example of a mounting part and a stand frame. FIG. 16 is a perspective view illustrating a configuration example of a mounting unit and a stand frame in a state where a front plate of the mounting unit of FIG. 15 is removed. It is a perspective view which shows the structural example of the mounting part and stand frame of the state in which the mounting part was closed with respect to the stand frame. It is a top view which shows the example of a structure of the mounting part of the state protruded from the stand frame, and a stand frame. It is a top view which shows the structural example of the mounting part and stand frame of the state in which the mounting part was closed with respect to the stand frame. It is a perspective view which shows the detailed structural example of the external appearance of the lock cam part of FIG. It is a perspective view which shows the detailed structural example of the external appearance of the lock pin part of FIG. It is a figure explaining the effect | action of the force to a lock pin part. It is process drawing explaining operation | movement of a lock pin part. It is process drawing explaining operation | movement of a lock pin part. It is process drawing explaining operation | movement of a lock pin part. It is process drawing explaining operation | movement of a lock pin part. FIG. 19 is a perspective view showing another detailed configuration example of the appearance of the lock cam portion of FIG. 18.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Scalable TV system, 10 stands, 10-1 Stand frame, 11-1 thru | or 11-9 mounting part, 21-1 thru | or 21-9 Television receiver, 42, 42-1, 42-2 Pantograph mechanism, 44- DESCRIPTION OF SYMBOLS 1,44-2 Lock pin part, 51-1, 51-2 Lock cam part, 61-1, 61-2 support | pillar, 62 thru | or 64 shaft, 81 Air cylinder, 82 Gas spring, 201 Speed control mechanism, 221 Power switch, 222 metal piece, 252 metal plate, 311 cam plate fixing base, 312, 313 cam plate, 321 cam mount, 322, 323 cantilever pin, 331 to 333 notch, 351 lock pin, 352 lock pin mounting plate, 353 piece Holding pin

Claims (3)

A display stand to which at least one display device is attached,
A fixing member fixed at a predetermined position of the main body;
A movable member that moves relative to the fixed member and is detachable from the display device;
Two cam plates installed in a predetermined positional relationship on one of the fixed member and the movable member;
The movable member is locked and unlocked in the course of passing between the two cam plates by reciprocating movement of the movable member with respect to the fixed member, which is installed on the other of the fixed member and the movable member. A display stand comprising: a lock pin for performing the operation.   The two cam plates are configured in a shape and positional relationship in which the movable member can be locked or unlocked by only one reciprocating motion by the lock pin.
  The display stand according to claim 1.   The two cam plates are installed on the fixing member,
  The lock pin is installed on the movable member.
  The display stand according to claim 1.

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