JP2008106504A - Fastener for double floor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fastener for a double floor, which hardly drops out, and which can inhibit the uplift of a panel during earthquakes. <P>SOLUTION: This fastener 32 comprises a bolt 34, a flange 36, an upper cylinder 38, a lower cylinder 40, a coil spring 42, a guide 44, and a lock nut 46. The bolt 34 comprises a head 48, a shaft 50, and a stopper 52. A top surface of the upper cylinder 38 abuts on the bottom of the flange 36. The upper cylinder 38 is loosely fitted into the lower cylinder 40. The coil spring 42 is housed between the bolt 34 and the lower cylinder 40. The lock nut 46 is equipped with a cut out portion 70 (engaging portion). The bolt 34 passes through the flange 36, the upper cylinder 38, the lower cylinder 40, the coil spring 42, the guide 44, and the lock nut 46. The bolt 34 is screwed into the hole 68 of the lock nut 46. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a fastener for a double floor. Specifically, the present invention relates to a fastener for fixing a support leg and a panel.

  Double floors are used in offices, precision equipment manufacturing factories, and clean rooms for large computers. An example of a double floor is disclosed in Japanese Patent Application Laid-Open No. 2002-256683. The double floor includes a large number of support legs standing on a slab at a predetermined interval, and a large number of panels placed on the top plate of the support legs. Various cables are accommodated in the space between the slab and the panel. This space may be used as a route for air conditioning.

  The panel is fixed to the top board. A fastener is used for fixing. FIG. 9A is a partial cross-sectional view showing a conventional fastener 2, and FIG. 9B is a side view thereof. The fastener 2 includes a pin 4, a tube 6, and a coil spring 8. The pin 4 has a head 10 at its upper end and a protrusion 12 in the vicinity of its lower end. The pin 4 passes through the cylinder 6. The cylinder 6 includes a flange 14, an upper portion 16 having a large inner diameter, and a lower portion 18 having a small inner diameter. The coil spring 8 is accommodated in the upper portion 16. The coil spring 8 is a compression spring. The upper end of the coil spring 8 is in contact with the head 10, and the lower end thereof is in contact with the lower part 18. The pin 4 also penetrates the coil spring 8.

  FIG. 10 is a plan view showing the top plate 20 of the support leg to which the fastener 2 of FIG. 9 is applied. On the top plate 20, corners of four panels are placed. The top plate 20 includes four openings 22. Each opening 22 includes two depressions 24.

FIG. 11 is a partial cross-sectional view showing a part of the double floor 26 in which the fastener 2 of FIG. 9 is used. FIG. 11 is a cross-sectional view seen from the direction of the arrow indicated by reference numeral A1 in FIG. In the construction of the double floor 26, as shown in FIG. 11A, the corner of the panel 28 is placed on the top plate 20, and the fastener 2 is placed in the hole 30 of the panel 28 and the opening 22 of the top plate 20. Is passed. The protrusion 12 of the fastener 2 passes through the recess 24 (see FIG. 10) of the opening 22. When the head 10 is pressed downward by a screwdriver, the coil spring 8 contracts and the pin 4 moves downward. With the head 10 pressed, the driver is turned and the pin 4 rotates. The angle of rotation is about 90 °. By the rotation, as shown in FIG. 11B, the projection 12 is positioned in the left-right direction. When the driver is removed, the coil spring 8 is restored. Due to the restoration, the pin 4 moves upward until the protrusion 12 contacts the lower surface of the top plate 20. FIG. 11C shows a state in which the protrusion 12 is in contact with the lower surface of the top plate 20. The coil spring 8 is not completely restored. The coil spring 8 biases the pin 4 upward. This urging force acts in the direction of narrowing the distance between the flange 14 and the protrusion 12. The panel 28 is fixed to the top plate 20 by this urging force.
JP 2002-256683 A

  In the fastener 2, the pin 4 needs to be rotated approximately 90 ° during construction. The rotation angle of the pin 4 is determined depending on the operator's intuition. If the rotation angle is insufficient or the angle is too large, the protrusion 12 is positioned near the recess 24. In this case, when vibration is repeatedly applied to the double floor 26 after a long period of use, the pin 4 gradually rotates, the position of the protrusion 12 coincides with the position of the recess 24, and the fastener 2 may fall off. .

  In the fastener 2, when a large upward force is applied to the panel 28 due to an earthquake, the coil spring 8 is compressed and the panel 28 may be lifted from the top plate 20.

  An object of the present invention is to provide a fastener that can be prevented from falling off and can prevent the panel from rising during an earthquake.

The fastener according to the present invention fixes the panel to the top plate by passing through the opening formed in the top plate of the support leg and the hole formed in the panel placed on the top plate. . This fastener is
(1) A flange that contacts the upper surface of the panel,
(2) An upper cylinder located below this flange,
(3) A lower cylinder that is loosely fitted to the upper cylinder and is positioned above the top plate,
(4) a spring for urging the upper cylinder upward with respect to the lower cylinder;
(5) A bolt that penetrates the upper and lower cylinders, and (6) a lock nut that is positioned below the lower cylinder and into which the bolts are screwed. The lock nut includes an engaging portion. The engaging portion engages with the top plate to prevent the bolt and the lock nut from rotating together when the bolt rotates. The bolt includes a stopper. This stopper rotates the bolt and the lock nut together by preventing the lock nut from moving downward when the bolt rotates in the reverse direction with the engaging portion not engaged with the top plate. In this fastener, the distance between the flange and the top plate contracts when the bolt rotates forward with the engaging portion engaged with the top plate, and the bolt reverses with the engaging portion engaged with the top plate. When rotated, the distance between the flange and the top plate extends.

  In this fastener, since the engaging portion engages with the top plate, the fastener does not loosen even after long-term use. This fastener is difficult to fall off. In this fastener, since the panel is pressed against the top plate by the bolt, the panel is unlikely to be lifted during an earthquake.

  Hereinafter, the present invention will be described in detail based on preferred embodiments with appropriate reference to the drawings.

  1A is a plan view showing a fastener 32 according to an embodiment of the present invention, FIG. 1B is a front view thereof, and FIG. 2 is a side view thereof. In FIG. 1B, a partial cross section is shown. The fastener 32 includes a bolt 34, a flange 36, an upper cylinder 38, a lower cylinder 40, a coil spring 42, a guide 44, and a lock nut 46. These members are made of a metal material.

  The bolt 34 includes a head 48, a shaft 50, and a stopper 52. The head 48 is tapered, and a groove 54 is cut on the upper surface. A screwdriver tip is fitted in the groove 54. A male thread is threaded on the lower part of the shaft 50. The stopper 52 is located near the lower end of the shaft 50. The stopper 52 is wider than the shaft 50. The stopper 52 is formed by crushing a part of the shaft 50. The stopper 52 may be formed by overlaying.

  The planar shape of the flange 36 is a circle. The flange 36 includes a tapered hole 58. The bolt 34 passes through the hole 58. The inner peripheral surface of the hole 58 is in contact with the outer peripheral surface of the head 48.

  The axial direction of the upper cylinder 38 is the vertical direction. The upper cylinder 38 is located below the flange 36. The upper surface of the upper cylinder 38 is in contact with the bottom of the flange 36. Bolts 34 pass through the upper cylinder 38. The inner diameter of the upper tube 38 is larger than the outer diameter of the bolt 34. The flange 36 may be integrated with the upper cylinder 38. The flange 36 may be integrated with the bolt 34.

  The axial direction of the lower cylinder 40 is the vertical direction. The inner diameter of the lower cylinder 40 is larger than the outer diameter of the upper cylinder 38. In the lower cylinder 40, the vicinity of the lower end of the upper cylinder 38 is inserted. The upper cylinder 38 can slide up and down with respect to the lower cylinder 40. In other words, the lower cylinder 40 is loosely fitted with the upper cylinder 38. The lower cylinder 40 has an annular bottom 60. The bolt 34 passes through the lower cylinder 40.

  The coil spring 42 is accommodated between the bolt 34 and the lower cylinder 40. The upper end of the coil spring 42 is in contact with the lower end of the upper cylinder 38. The lower end of the coil spring 42 is in contact with the annular bottom 60. The coil spring 42 is a so-called compression spring. At the time of compression, the coil spring 42 urges the upper cylinder 38 upward with respect to the lower cylinder 40.

  The guide 44 includes a disk 62 and a pair of legs 64. The disk 62 is in contact with the lower end of the lower cylinder 40. The disk 62 has a hole 66. A female thread is threaded on the inner peripheral surface of the hole 66. Bolts 34 are screwed into the holes 66. The legs 64 are suspended from the disk 62.

  The lock nut 46 is located below the guide 44. The lock nut 46 has a hole 68. A female thread is threaded on the inner peripheral surface of the hole 68. Bolts 34 are screwed into the holes 68. The lock nut 46 includes a notch portion 70 (engagement portion). A step is formed on the upper surface of the lock nut 46 by the notch 70. Legs 64 are fitted into the notches 70.

  FIG. 3 is a plan view showing a top plate 72 to which the fastener 32 of FIG. 1 is applied. On the top plate 72, corners of four panels 74 are placed. The top plate 72 has four openings 76. The position of the opening 76 coincides with the position of the hole 78 (detailed later) of the panel 74. The opening 76 includes two projecting portions 80 disposed to face each other.

  FIG. 4 is a front view showing a part of a double floor 82 in which the fastener 32 of FIG. 1 is used. The double floor 82 includes a support leg 84, a panel 74, and a fastener 32. The support leg 84 is erected on the slab 86. On the slab 86, a large number of support legs 84 are erected at predetermined intervals. The panel 74 is bridged between the adjacent support legs 84. The corner of the panel 74 is placed on the top plate 72. The panel 74 includes a hole 78 penetrating vertically at a corner. As described above, the position of the hole 78 coincides with the position of the opening 76 in plan view. The fastener 32 passes through the hole 78 and the opening 76. The panel 74 is fixed to the top plate 72 by the fastener 32.

  Hereinafter, a method of fixing the panel 74 to the top plate 72 will be described with reference to FIGS. 5 (a) and (b), FIGS. 6 (c) and (d), FIGS. 7 (e) and (f) and FIGS. 8 (g) and (h) are denoted by reference numeral A2 in FIG. It is sectional drawing seen from the direction of the arrow. The positional relationship between the lock nut 46 and the opening 76 when the fastener 32 is passed through the hole 78 and the opening 76 is shown in FIG. The lock nut 46 is inserted into the opening 76 without being obstructed by the top plate 72. Most of the lock nut 46 is exposed from the opening 76 as shown in FIG. A portion of the lock nut 46 is in the opening 76. A leg 64 is further inserted into the opening 76. By fitting the leg 64 and the opening 76, the center position of the fastener 32 matches the center position of the opening 76. The disk 62 is in contact with the upper surface of the top plate 72. Due to this contact, further downward movement of the fastener 32 is prevented. The lock nut 46 is in contact with the stopper 52. Accordingly, the lock nut 46 cannot move downward with respect to the bolt 34. In this specification, the state shown in FIG. 5A is referred to as “origin”.

  The tip of the driver is fitted into the groove 54 of the head 48 (see FIG. 1), and the head 48 is pressed downward by the driver. By this pressing, the coil spring 42 contracts, and the bolt 34, the flange 36, the upper cylinder 38, and the lock nut 46 move downward. The lock nut 46 is separated from the top plate 72 by the movement. The driver is rotated backward while the head 48 is pressed. The rotation angle from the origin is about 20 ° to 60 °. Since the stopper 52 prevents the lock nut 46 from moving downward, the lock nut 46 is also rotated in reverse by the reverse rotation of the bolt 34. In other words, the lock nut 46 rotates together with the bolt 34. The state after the co-rotation is shown in FIGS. 5B and 5B '.

  When the pressing of the head 48 is released, the bolt 34, the flange 36, the upper cylinder 38, and the lock nut 46 move upward by the restoring force of the coil spring 42. By this movement, the upper surface of the lock nut 46 partially abuts against the lower surface of the top plate 72 as shown in FIGS. By this contact, further upward movement of the bolt 34, the flange 36, the upper cylinder 38 and the lock nut 46 is prevented.

  When the driver further rotates in the reverse direction, the bolt 34 rotates in the reverse direction. The lock nut 46 rotates with the bolt 34 while rubbing against the top plate 72. At the stage where the rotation angle of the lock nut 46 from the origin becomes approximately 90 °, the position of the notch portion 70 coincides with the position of the overhang portion 80 as shown in FIG. Since the coil spring 42 urges the lock nut 46 upward, the bolt 34, the flange 36, the upper cylinder 38 and the lock nut 46 are instantaneously moved further upward due to the matching of the positions. At this stage, as shown in FIG. 6 (d), the lower surface of the overhang 80 fits into the notch 70. In other words, the lock nut 46 is engaged with the top plate 72. During this instantaneous movement, a “click” sound is generated and transmitted to the operator's ear. At the same time, an impact is transmitted to the worker's hand. From this sound and impact, the operator recognizes the fitting of the overhang 80 into the notch 70.

  The worker who has confirmed the insertion turns the driver forward. The bolt 34 rotates forward by the forward rotation. Since the lock nut 46 is engaged with the top plate 72, the lock nut 46 does not rotate together even if the bolt 34 rotates forward. Accordingly, the bolt 34 moves downward with respect to the lock nut 46 by forward rotation. By this movement, the flange 36 and the upper cylinder 38 also move downward. By the forward rotation of the bolt 34, the distance between the flange 36 and the top plate 72 contracts. Eventually, the flange 36 comes into contact with the upper surface of the panel 74 as shown in FIG. By this contact, the panel 74 is firmly fixed to the top plate 72. Thus, the double floor 82 is completed.

  In the state shown in FIG. 7 (e), the lock nut 46 is engaged with the top plate 72. Therefore, even if vibration is applied to the double floor 82, the bolt 34 does not loosen. Even if this fastener 32 is used for a long period of time, it does not fall off. Even if an upward force is applied to the panel 74 due to an earthquake or the like, the panel 74 does not rise from the top plate 72 unless the bolt 34 is deformed.

  When the double floor 82 is disassembled, the bolt 34 is rotated in the reverse direction in the state shown in FIG. Since the lock nut 46 is engaged with the top plate 72, the lock nut 46 does not rotate together even when the bolt 34 rotates in the reverse direction. By reverse rotation, the bolt 34 moves upward with respect to the lock nut 46. At the same time, the flange 36 and the upper cylinder 38 also move upward. By this movement, the distance between the flange 36 and the top plate 72 is extended. When the stopper 52 comes into contact with the lock nut 46, the reverse rotation of the bolt 34 is prevented. The fastener 32 returns to the state shown in FIGS. 6 (d) and 6 (d ').

  The head 48 is pressed downward by a driver. By this pressing, the coil spring 42 contracts, and the bolt 34, the flange 36, the upper cylinder 38, and the lock nut 46 move downward. The lock nut 46 is separated from the top plate 72 by the movement. The driver is rotated backward while the head 48 is pressed. Since the stopper 52 prevents the lock nut 46 from moving downward, the lock nut 46 is also rotated in reverse by the reverse rotation of the bolt 34. In other words, the lock nut 46 rotates together with the bolt 34. The state after the co-rotation is shown in FIGS. 7 (f) and 7 (f '). The rotation angle of the lock nut 46 from the origin is about 110 ° to 160 °.

  When the pressing of the head 48 is released, the bolt 34, the flange 36, the upper cylinder 38, and the lock nut 46 move upward by the restoring force of the coil spring 42. As a result of this movement, a part of the upper surface of the lock nut 46 comes into contact with the lower surface of the top plate 72 as shown in FIGS. By this contact, further upward movement of the bolt 34, the flange 36, the upper cylinder 38 and the lock nut 46 is prevented.

  When the driver further rotates in the reverse direction, the bolt 34 rotates in the reverse direction. The lock nut 46 rotates with the bolt 34 while rubbing against the top plate 72. When the rotation angle of the lock nut 46 from the origin becomes approximately 180 °, the entire contour of the lock nut 46 is located inside the opening 76 as shown in FIG. Since the coil spring 42 urges the lock nut 46 upward, the bolt 34, the flange 36, the upper cylinder 38 and the lock nut 46 are instantaneously moved further upward. This state is shown in FIG. The operator recognizes this movement by the sound and impact generated during the instantaneous movement. In this state, the fastener 32 can be pulled out from the opening 76 and the hole 78 without being obstructed by the top plate 72. The panel 74 becomes free from the support leg 84 when the fastener 32 is pulled out.

  Attachment and removal of the fastener 32 is easy and does not require operator skill. Furthermore, no dedicated tool is required for installation and removal.

  The fastener according to the present invention can be applied to various double floors.

Fig.1 (a) is the top view by which the fastener concerning one Embodiment of this invention was shown, FIG.1 (b) is the front view. FIG. 2 is a side view illustrating the fastener of FIG. 1. FIG. 3 is a plan view showing a top plate to which the fastener of FIG. 1 is applied. FIG. 4 is a front view showing a part of a double floor in which the fastener of FIG. 1 is used. FIG. 5 is an explanatory diagram showing the construction of the double floor of FIG. FIG. 6 is an explanatory diagram showing the construction of the double floor of FIG. FIG. 7 is an explanatory diagram showing the construction of the double floor of FIG. FIG. 8 is an explanatory diagram showing the construction of the double floor of FIG. FIG. 9A is a partial cross-sectional view showing a conventional fastener, and FIG. 9B is a side view thereof. FIG. 10 is a plan view showing a top plate of a support leg to which the fastener of FIG. 9 is applied. FIG. 11 is a partial cross-sectional view showing a part of a double floor in which the fastener of FIG. 9 is used.

Explanation of symbols

32 ... Fastener 34 ... Bolt 36 ... Flange 38 ... Upper cylinder 40 ... Lower cylinder 42 ... Coil spring 44 ... Guide 46 ... Lock nut 48 ... Head 52 ... Stopper 60 ... Annular bottom 70 ... Notch 72 ... Top plate 74 ... Panel 76 ... Opening 78 ... Hole 80 ... Overhang 82 ... Double floor 84 ... Support legs

Claims (1)

A fastener for a double floor that passes through an opening formed in a top plate of a support leg and a hole formed in a panel placed on the top plate and fixes the panel to the top plate. ,
A flange that contacts the top surface of the panel,
An upper cylinder located below this flange,
A lower cylinder that is loosely fitted to the upper cylinder and is located above the top plate,
A spring for urging the upper cylinder upward with respect to the lower cylinder;
Bolts that pass through the upper and lower cylinders and a lock nut into which the bolts are screwed are provided below the lower cylinders.
This lock nut has an engagement part that prevents the bolt and lock nut from rotating together when the bolt rotates by engaging with the top plate,
The bolt includes a stopper that rotates the bolt and the lock nut together by preventing the lock nut from moving downward when the bolt rotates in the reverse direction when the engaging portion is not engaged with the top plate. And
When the bolt rotates forward with the engagement part engaged with the top plate, the distance between the flange and the top plate shrinks,
A fastener configured to extend the distance between the flange and the top plate when the bolt rotates in the reverse direction with the engaging portion engaged with the top plate.

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