JP2014029181A - Hinge - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hinge capable of achieving buffering effect by a damper independently of a position of a slider, when a second coupling object is turned to a first coupling object in the closing direction.SOLUTION: A hinge 1 includes: a case 10 fixed to one of a first coupling object and a second coupling object; a cam block 20 turnably supported by the case 10, and fixed to the another of the first coupling object and the second coupling object; a slider 40 accommodated in an accommodation chamber 11 of the case movably in a direction to approach the cam block 20 and a direction to separate therefrom, and capable of being brought into contact with a cam surface 21 of the cam block 20; a pressing member 50 for pressing the slider 40 in the direction to approach the cam block 20; a damper 60; and an arm 70 which is turnably supported by the case 10, can be brought into contact with the cam surface 21 of the cam block 20, and further can be brought into contact with a rod portion 63 of a piston 62 of the damper 60.

Description

  The present invention relates to hinge technology.

Various techniques relating to a hinge that rotatably connects a second connection object to the first connection object are known.
The hinge is provided in an office machine (scanner, fax machine, copier, multifunction machine, etc.) configured to include a main body and an original pressure plate, and an original is placed on the main body (first connection object) of the office machine. There exists what connects a crimping plate (2nd connection object) so that rotation is possible (refer patent document 1).
The hinge includes a case, a cam block, a slider, a biasing member (winding spring), a damper, and an arm. The case is fixed to the main body of the office machine, and the cam block is a document of the office machine. Fixed to the crimping plate.
The hinge contacts the cam block by rotating the cam block when the hinge is rotated in the direction in which the original cover is closed (in the direction in which the rotation angle is reduced) with respect to the main body of the office machine. It rotates in the state and pushes the rod part of the piston of the damper, and the cam block turns and pushes the slider against the urging force of the urging member, and the buffering effect by the damper and the buffering effect by the urging member Are configured to occur.

JP 2011-247554 A

However, in the hinge, the arm is rotatably provided on the slider, and is pushed by the cam block when the cam block is rotated by rotating the document crimping plate in the closing direction with respect to the main body of the office machine. Depending on the position of the slider, the cam block may not contact the arm.
Therefore, in the hinge, even if the cam block is rotated by rotating the document crimping plate with respect to the main body of the office machine and the cam block is rotated, the arm cannot be rotated depending on the position of the slider. There are cases where the operation of pushing the rod part of the piston of the damper by the arm cannot be performed.
That is, with the hinge, even if the cam block is rotated by rotating the document crimping plate in the closing direction with respect to the main body of the office machine, the buffering effect by the damper may not occur depending on the position of the slider.

  The present invention has been made in view of the situation as described above, and when the second connection object rotates in the closing direction with respect to the first connection object, the buffering effect by the damper regardless of the position of the slider. It is an object of the present invention to provide a hinge capable of generating the above.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, in Claim 1, it is the hinge which connects a 2nd connection target object to a 1st connection target object rotatably, Comprising: A storage chamber is provided, The said 1st connection target object or the said 2nd connection target object A case that is fixed to either one, a cam block that includes a cam surface, is rotatably supported by the case, and is fixed to either the first connection object or the second connection object; A slider configured to be accommodated in a housing chamber of the case so as to be movable in a direction approaching the cam block and in a direction away from the cam block and configured to be able to contact a cam surface of the cam block; An urging member for urging in a direction approaching the block; a cylinder; and a piston arranged so that the rod portion protrudes from the cylinder. A damper configured to generate a buffering effect by moving the piston so that the projecting length from the solder is shortened, and is rotatably supported by the case and can contact the cam surface of the cam block And an arm configured to be able to come into contact with the rod portion of the piston of the damper, and when the second connection object rotates in a closing direction with respect to the first connection object, the cam The block rotates and rotates with the arm contacting the cam surface of the cam block to push in the rod portion of the piston of the damper, and the piston of the damper is the cylinder in the rod portion of the piston of the damper And the cam block rotates and pushes the slider in contact with the cam surface of the cam block, In which serial slider is configured to move in a direction away from the cam block.

  In Claim 2, When the rotation angle of the said 2nd connection target object with respect to a said 1st connection target object rotates in the direction which the said 2nd connection target object opens with respect to a said 1st connection target object, it increases. The second connection object is rotated in the closing direction with respect to the first connection object, and the rotation angle of the second connection object with respect to the first connection object is a predetermined time. The slider is configured so that the state in which the slider is in contact with the cam surface of the cam block is canceled and the movement of the slider in the direction away from the cam block is stopped when the moving angle is less than or equal to the moving angle. It is.

  The movement direction of the piston according to claim 3, wherein the arm moves so that a protruding length from the cylinder in the rod portion of the piston of the damper becomes shorter when the rod portion of the piston of the damper is pushed in. It is comprised so that it may move along.

  As effects of the present invention, the following effects can be obtained.

  That is, according to the present invention, when the second connection object rotates in the closing direction with respect to the first connection object, the buffering effect by the damper can be generated regardless of the position of the slider.

The front view which showed the hinge and office machine which concern on 1st embodiment of this invention. Similarly sectional drawing of a hinge (state in which rotation angle is larger than θ = 75 °). The top view of a hinge (state in which a rotation angle is larger than (theta) = 75 degrees) similarly. Sectional drawing of the slider of a hinge similarly. The top view of the slider of a hinge similarly. The top view of the arm of a hinge similarly. Similarly sectional drawing of a hinge (state in which rotation angle is θ = 75 °). Similarly sectional drawing of a hinge (state in which rotation angle is θ = 0 °). Sectional drawing of the hinge (state in which a rotation angle is larger than (theta) = 75 degrees) concerning 2nd embodiment of this invention. The top view of a hinge (state in which a rotation angle is larger than (theta) = 75 degrees) similarly. The top view of the arm of a hinge similarly. Sectional drawing of the slider of a hinge similarly. The top view of the slider of a hinge similarly. Similarly sectional drawing of a hinge (state in which rotation angle is θ = 75 °). Similarly sectional drawing of a hinge (state in which rotation angle is θ = 0 °).

  Next, the hinge 1 which concerns on 1st embodiment of this invention is demonstrated using FIGS. 1-8.

As shown in FIG. 1, the hinge 1 is provided in an office machine 90 that includes a main body 91 and a document crimping plate 92.
The office machine 90 refers to an apparatus such as a scanner, a fax machine, a copier, or a multifunction machine (an office machine 90 having a scanner function, a fax function, and / or a copy function).
The main body 91 of the office machine 90 is an embodiment of the first connection object according to the present invention. The main body 91 of the office machine 90 includes a control device, a printing device, a display device, and an input device.
The original cover 92 of the office machine 90 is an embodiment of the second connection object according to the present invention. The document pressing plate 92 of the office machine 90 includes a document reading tray before reading, an ADF (Auto Document Feeder), and a document reading tray after reading.

As shown in FIGS. 1 to 3, the hinge 1 includes a case 10, a cam block 20, a rotation pin 30, a slider 40, a biasing member 50, a damper 60, an arm 70, an arm pin 80, It comprises.
The hinge 1 has the case 10 fixed to the main body 91 of the office machine 90 and the cam block 20 fixed to the original pressing plate 92 of the office machine 90 so that the original pressing plate 92 can be rotated on the main body 91 of the office machine 90. Link.

The state in which the document crimping plate 92 of the office machine 90 is closed (relative to the main body 91) indicates a state in which the lower surface of the document crimping plate 92 is in contact with the upper surface of the main body 91.
Further, when the document crimping plate 92 of the office machine 90 is open (relative to the main body 91), the document crimping plate 92 rotates with respect to the main body 91, so This refers to a state in which the upper surfaces (the lower front end portion of the original cover 92 and the upper front end portion of the main body 91) are separated from each other.
The rotation angle θ of the original pressure plate 92 when the original pressure plate 92 of the office machine 90 is closed (more precisely, the rotation angle θ of the original pressure plate 92 with respect to the main body 91) is set to “0 °”. Assuming that the rotation angle θ increases (the value of the rotation angle θ becomes positive) when the pressure plate 92 rotates in the opening direction (the direction in which the lower surface of the original pressure plate 92 is separated from the upper surface of the main body 91). The rotation angle θ of the original cover 92 is defined.

As shown in FIG. 2 or FIG. 3, the case 10 of the hinge 1 is a box-shaped member, and is formed in a substantially rectangular tube shape with a bottom that opens to the side.
The case 10 includes a storage chamber 11, a support portion 12, a first pin hole 13, and a second pin hole 14.

The storage chamber 11 of the case 10 of the hinge 1 is configured by the inside space of the rectangular cylinder (the space inside the case 10 upper plate, lower plate, both side plates, and the bottom plate).
The storage chamber 11 of the case 10 is configured to store the slider 40, the biasing member 50, and the damper 60.

The support portion 12 of the case 10 of the hinge 1 supports the cam block 20 and the arm 70.
The support portion 12 of the case 10 is configured with portions formed so that both side plates of the case 10 protrude leftward from the opening of the storage chamber 11.

The first pin holes 13 of the case 10 of the hinge 1 are disposed in the respective support portions 12 of the case 10.
The first pin holes 13 of the case 10 are formed so as to penetrate both side plates of the case 10 in the front-rear direction. The first pin hole 13 of the case 10 is configured to allow the rotation pin 30 to be inserted.

The second pin holes 14 of the case 10 of the hinge 1 are disposed in the respective support portions 12 of the case 10. The second pin hole 14 of the case 10 is disposed to the right of the first pin hole 13 (on the bottom plate side of the case 10). The second pin hole 14 of the case 10 is disposed below the first pin hole 13 (on the lower plate side of the case 10).
The second pin hole 14 of the case 10 is formed so as to penetrate both side plates of the case 10 in the front-rear direction. The second pin hole 14 of the case 10 is configured such that an arm pin 80 can be inserted.

The cam block 20 of the hinge 1 is rotatably supported by the case 10 (supporting portion 12 of the case 10).
The cam block 20 includes a cam surface 21 and a through hole 24.
The cam block 20 is arranged so that the cam surface 21 is located on the left side of the storage chamber 11 of the case 10 (outside of the storage chamber 11 of the case 10).

The cam surface 21 of the cam block 20 of the hinge 1 is disposed at the lower part of the cam block 20.
The cam surface 21 of the cam block 20 is a smooth curved surface and is configured by the lower right surface of the cam block 20.
The cam surface 21 of the cam block 20 includes an arm side cam surface 22 and two slider side cam surfaces 23.

The arm-side cam surface 22 of the cam block 20 of the hinge 1 is configured to be able to contact the arm 70 when the rotation angle of the document pressing plate 92 with respect to the main body 91 of the office machine is larger than 75 °.
The arm-side cam surface 22 of the cam block 20 is a convex curved surface.

The slider-side cam surface 23 of the cam block 20 of the hinge 1 is configured to be able to contact the slider 40.
The slider-side cam surface 23 of the cam block 20 is disposed on the front and back (both sides) of the arm-side cam surface 22, respectively. The slider-side cam surface 23 of the cam block 20 is positioned closer to the storage chamber 11 side of the case 10 than the arm-side cam surface 22 in a state where the rotation angle of the document pressing plate 92 with respect to the main body 91 of the office machine is larger than 75 °. To be formed.
The slider-side cam surface 23 of the cam block 20 is a concave curved surface.

The through hole 24 of the cam block 20 of the hinge 1 is disposed at the front portion of the cam block 20.
The through hole 24 of the cam block 20 is formed so as to penetrate the cam block 20 in the front-rear direction.
The through hole 24 of the cam block 20 is configured such that the rotation pin 30 can be inserted.

The cam block 20 of the hinge 1 is rotatably supported by the case 10 by inserting a rotation pin 30 into the through hole 24 of the cam block 20 and the first pin hole 13 of the case 10.
The cam block 20 is configured to be rotatable with respect to the case 10 with the rotation pin 30 as a rotation axis.

As shown in FIGS. 2 to 5, the slider 40 of the hinge 1 is configured to be able to contact the cam surface 21 (slider side cam surface 23) of the cam block 20.
The slider 40 is a box-shaped member, and is formed in a substantially rectangular tube shape with a bottom that opens to the right.
The slider 40 has the bottom plate of the slider 40 facing the cam block 20 and the outer surface of the slider 40 contacts the inner surface of the case 10 (the upper and lower plates of the case 10 and the inner surfaces of both side plates). It is accommodated in the accommodation chamber of the case 10 so as to come into contact.
The slider 40 is configured to be movable in a direction approaching the cam block 20 and a direction away from the cam block 20.
The slider 40 includes a rod hole 41 and a contact portion 42.

The rod hole 41 of the slider 40 of the hinge 1 is configured such that the rod portion 63 of the piston 62 of the damper 60 is inserted.
The rod hole 41 of the slider 40 is disposed substantially at the center of the bottom plate of the slider 40.
The rod hole 41 of the slider 40 is configured to penetrate in the left-right direction.

The contact portion 42 of the slider 40 of the hinge 1 is configured to contact the cam block 20 (the slider-side cam surface 23 or the upper and lower surfaces of the slider-side cam surface 23 in the cam block 20).
The abutting portion 42 of the slider 40 is disposed substantially at the center of the slider 40 in the vertical direction.
The contact portion 42 of the slider 40 is formed so as to protrude leftward (cam block 20 side) from the bottom plate before and after the rod hole 41.
The contact portion 42 of the slider 40 is configured with a smooth curved surface on the left side (cam block 20 side).

As shown in FIG. 2 or FIG. 3, the biasing member 50 of the hinge 1 is a winding spring, and is configured to bias the slider 40 in a direction (leftward) approaching the cam block 20.
The urging member 50 is accommodated in the storage chamber 11 of the case 10. One end (right end) of the urging member 50 abuts on the inner surface of the bottom plate of the case 10 via a force adjusting member (not shown), and the other end (left end) is inside the bottom plate of the slider 40. It arrange | positions so that it may contact | abut.
Note that the urging force adjusting member adjusts the magnitude of the urging force of the urging member 50 (the force with which the urging member 50 elastically deformed in the compression direction tries to return to its original shape).
The urging member 50 urges the slider 40 in a direction approaching the cam block 20 to abut against the slider-side cam surface 23 of the cam block 20 so that the urging member 50 rotates in the opening direction with respect to the case 10. The cam block 20 is energized.

The damper 60 of the hinge 1 is a fluid damper device including a cylinder 61 and a piston 62.
The damper 60 is configured by filling a cylinder 61 with silicon oil, which is a kind of incompressible fluid. The damper 60 is configured by disposing the piston 62 so that the rod portion 63 of the piston 62 protrudes leftward from the cylinder 61 and the body portion (not shown) of the piston 62 is positioned in the cylinder 61. The damper 60 is configured such that a piston 62 is provided so as to be movable in the axial direction substantially coaxially with the cylinder 61.

The damper 60 of the hinge 1 applies an external force to the rod portion 63 of the piston 62 and moves the piston 62 so that the protruding length of the rod portion 63 of the piston 62 from the cylinder 61 is shortened by the viscous resistance of silicon oil. A reaction force (force that pushes back the piston 62) is generated, and a buffering effect is generated.
When the external force applied to the rod portion 63 of the piston 62 is released after the piston 62 has been moved so that the protruding length of the rod portion 63 of the piston 62 from the cylinder 61 is shortened, The piston 62 is configured to move so that the protruding length of the rod portion 63 of the piston 62 from the cylinder 61 is increased by the biasing force of a return spring (not shown).

The damper 60 of the hinge 1 is fixedly disposed in the storage chamber 11 of the case 10.
The damper 60 is disposed so that the cylinder 61 is positioned inside the slider 40 and the biasing member 50.
The damper 60 is disposed so that the rod portion 63 of the piston 62 is inserted into the rod hole 41 of the slider 40 and protrudes outside the slider 40 (cam block 20 side).
The damper 60 is disposed so that the arm-side cam surface 22 of the cam block 20 is positioned on the axis of the piston 62.

As shown in FIG. 2, FIG. 3, or FIG. 6, the arm 70 of the hinge 1 is rotatably supported by the case 10 (the support portion 12 of the case 10).
The arm 70 is configured to be able to contact the cam surface 21 (arm-side cam surface 22) of the cam block 20 and to be able to contact the rod portion 63 of the piston 62 of the damper 60.
The arm 70 includes a contact portion 72 and a through hole 71.

The contact portion 72 of the arm 70 of the hinge 1 is disposed on the upper portion of the arm 70.
The contact portion 72 of the arm 70 is a convex curved surface and is configured by the upper right surface of the arm 70.

The through hole 71 of the arm 70 of the hinge 1 is disposed at the lower part of the arm 70.
The through hole 71 of the arm 70 is formed so as to penetrate the arm 70 in the front-rear direction.
The through hole 71 of the arm 70 is configured such that the arm pin 80 can be inserted.

The arm 70 of the hinge 1 is rotatably supported by the case 10 by inserting an arm pin 80 into the through hole 71 of the arm 70 and the second pin hole 14 of the case 10.
The arm 70 is configured to be rotatable with respect to the case 10 with the arm pin 80 as a rotation axis.

The arm 70 of the hinge 1 is disposed inside the support portions 12 of the case 10. The arm 70 is disposed inside both contact portions 42 of the slider 40. The arm 70 is disposed such that the upper portion (contact portion 42) is located between the arm-side cam surface 22 of the cam block 20 and the rod portion 63 of the piston 62 of the damper 60. The arm 70 is disposed such that the upper portion (abutting portion 42) is positioned between the slider-side cam surfaces 23 of the cam block 20.
The arm 70 has an upper left surface (surface on the cam block 20 side) in contact with the cam surface 21 (arm side cam surface 22) of the cam block 20 and an abutting portion 42 of the rod portion of the piston 62 of the damper 60. It arrange | positions so that 63 may be contact | abutted.

As shown in FIG. 2, FIG. 7, or FIG. 8, the hinge 1 is in the direction in which the document pressing plate 92 (second connection object) is closed with respect to the main body 91 (first connection object) of the office machine 90 ( When the cam block 20 is rotated in a direction in which the rotation angle is reduced, the cam block 20 is rotated, and the arm 70 is rotated in a state where the arm 70 is in contact with the arm-side cam surface 22 of the cam block 20. The rod part 63 is pushed in, and the piston 62 is configured to move so that the protruding length from the cylinder 61 in the rod part 63 of the piston 62 is shortened against the urging force of the return spring.
Further, when the hinge 1 is rotated in the direction in which the document crimping plate 92 (second connection object) is closed with respect to the main body 91 (first connection object) of the office machine 90, the cam block 20 is rotated and the cam 1 is rotated. The slider 40 that contacts the slider-side cam surface 23 of the block 20 is pushed in, and the slider 40 moves in a direction away from the cam block 20 against the urging force of the urging member 50.
When the hinge 1 is rotated in the direction in which the document pressing plate 92 is closed with respect to the main body 91 of the office machine 90, the arm 70 is rotated and the slider 40 is moved, so that the shock absorbing effect by the damper 60 and the biasing member 50. And a buffering effect.

As described above, in the hinge 1, the arm 70 is rotatably supported by the case 10, so that the document pressing plate 92 is closed with respect to the main body 91 of the office machine 90 (in a direction in which the rotation angle is reduced). When rotating, regardless of the position of the slider 40, the arm 70 can be rotated while being in contact with the arm-side cam surface 22 of the cam block 20, and the rod portion 63 of the piston 62 of the damper 60 can be pushed in. .
Therefore, in the hinge 1, when the original cover 92 is rotated in the closing direction with respect to the main body 91 of the office machine 90, a buffering effect by the damper 60 can be generated regardless of the position of the slider 40.

As shown in FIG. 2, FIG. 7, or FIG. 8, the hinge 1 rotates in the direction in which the document crimping plate 92 closes with respect to the main body 91 of the office machine 90, and the document crimping plate 92 rotates relative to the main body 91. A configuration in which the contact portion 42 of the slider 40 contacts the surface above the slider-side cam surface 23 of the cam block 20 when the angle becomes equal to or less than a predetermined rotation angle (rotation angle θ = 75 °). Is done.
The hinge 1 is further in a direction in which the original cover 92 is closed with respect to the main body 91 of the office machine 90 in a state where the contact portion 42 of the slider 40 is in contact with the surface above the slider-side cam surface 23 of the cam block 20. When rotated, the slider 40 is configured not to approach the cam block 20 and not to be separated from the cam block 20.
The hinge 1 rotates in the direction in which the document crimping plate 92 (second connection target) closes with respect to the main body 91 (first connection target) of the office machine 90, and the rotation angle of the document crimping plate 92 with respect to the main body 91. Is less than a predetermined rotation angle (rotation angle θ = 75 °), the state where the contact portion 42 of the slider 40 contacts the slider-side cam surface 23 of the cam block 20 is eliminated, and the slider 40 is configured to stop moving in a direction away from the cam block 20.

Thus, in the hinge 1, when the original cover 92 is rotated in the closing direction with respect to the main body 91 of the office machine 90, the rotation angle of the original cover 92 with respect to the main body 91 is set to a predetermined rotation angle ( In a state where the rotation angle is larger than θ (75 °), a buffering effect by the damper 60 and a buffering effect by the urging member 50 are produced, but the rotation angle of the document pressing plate 92 relative to the main body 91 of the office machine 90 is a predetermined angle. In the state of the rotation angle or less (rotation angle θ = 75 °), the force for moving the slider 40 against the urging force of the urging member 50 is not applied to the slider 40, and the buffering effect by the urging member 50 is exerted. It does not occur (the only buffering effect that occurs is due to the damper 60).
Therefore, according to the hinge 1, the buffering effect of the hinge 1 as a whole can be reduced from the middle of the operation of rotating the document crimping plate 92 in the closing direction with respect to the main body 91 of the office machine 90.
Further, in the hinge 1 configured as described above, by setting the urging force of the urging member 50 and the urging force of the return spring of the damper 60, the rotation angle of the document pressing plate 92 with respect to the main body 91 of the office machine 90 can be changed. In a state where the rotation angle is larger than a predetermined rotation angle (rotation angle θ = 75 °), the rotation angle of the document pressure-bonding plate 92 with respect to the main body 91 is maintained, and the rotation angle of the document pressure-bonding plate 92 with respect to the main body 91 of the office machine 90 is maintained. Is not more than a predetermined rotation angle (rotation angle θ = 75 °), the document pressing plate 92 is configured to automatically rotate in the closing direction with respect to the main body 91 due to its own weight. You can also.

The document pressing plate 92 of the office machine 90 may be configured not to include a document storage tray before reading, an ADF (Auto Document Feeder), and a document storage tray after reading.
The hinge 1 has the case 10 fixed to the document crimping plate 92 of the office machine 90, the cam block 20 fixed to the main body 91 of the office machine 90, and the document crimping plate 92 pivoted to the main body 91 of the office machine 90. You may comprise so that it may connect.

Next, the hinge 1 which concerns on 2nd embodiment of this invention is demonstrated using FIGS. 9-15.
In addition, description of the hinge 1 which concerns on 2nd embodiment is abbreviate | omitted suitably about the part of the structure similar to the hinge 1 which concerns on 1st embodiment, and focuses on a different part from the structure of the hinge 1 which concerns on 1st embodiment. explain.

As shown in FIGS. 9 to 11, the through hole 71 of the arm 70 of the hinge 1 is formed in a long hole shape extending from the lower part of the arm 70 toward the upper part. The through hole 71 of the arm 70 is a piston of the damper 60 in a state where the arm pin 80 is inserted into the through hole 71 of the arm 70 and the second pin hole 14 of the case 10 and the arm 70 is rotatably supported by the case 10. It is comprised so that it may extend in the direction which intersects 62 moving directions.
The arm 70 extends in a direction in which the through hole 71 of the arm 70 extends (damper) in a state where the arm pin 80 is inserted into the through hole 71 of the arm 70 and the second pin hole 14 of the case 10 and is rotatably supported by the case 10. It is configured to be movable (so as to wobble) in a direction that intersects the moving direction of 60 pistons 62.

The arm 70 of the hinge 1 includes a protrusion 73.
The protrusion 73 of the arm 70 is formed in a columnar shape.
The protruding portion 73 of the arm 70 is disposed on the upper portion of the arm 70. The projecting portion 73 of the arm 70 is disposed on the left side (cam block 20 side) of the contact portion 72. The protruding portion 73 of the arm 70 is configured to protrude in the front-rear direction (the support portion 12 side of the case 10) from the left and right centers of the front and rear surfaces of the arm 70.

  As shown in FIG. 9, FIG. 10, FIG. 12, or FIG. 13, the slider 40 of the hinge 1 includes a guide portion 43 and a guide groove 44.

The guide portion 43 of the slider 40 of the hinge 1 is arranged at the substantially upper and lower center of the slider 40.
The guide portion 43 of the slider 40 is formed so as to protrude leftward (cam block 20 side) from the contact portion 42 before and after the rod hole 41.
The guide portion 43 of the slider 40 is configured such that the surface of the guide portion 43 on the rod hole 41 side and the surface of the contact portion 42 on the rod hole 41 side are flush with each other.

The guide groove 44 of the slider 40 of the hinge 1 moves the piston 62 of the damper 60 when the cam block 20 rotates and the arm 70 rotates and the arm 70 pushes the rod portion 63 of the piston 62 of the damper 60. The arm 70 is guided so that the arm 70 moves along the direction (the moving direction of the piston 62 when the rod 62 of the piston 62 moves so that the protruding length from the cylinder 61 becomes short).
The guide groove 44 of the slider 40 is formed on the surface of the contact portion 42 and the guide portion 43 on the rod hole 41 side. The guide groove 44 of the slider 40 is formed at the substantially vertical center of the contact portion 42 and the guide portion 43. The guide groove 44 of the slider 40 has a groove shape along the moving direction of the piston 62 of the damper 60 (the moving direction of the piston 62 when the rod 62 of the piston 62 moves so that the protruding length from the cylinder 61 becomes short). Formed. The guide groove 44 of the slider 40 is formed so that the protrusion 73 of the arm 70 can be disposed.

Here, in the conventional hinge, when the original pressing plate rotates in the closing direction with respect to the main body of the office machine and the arm pushes the rod part of the damper piston, the arm hits the rod part of the damper piston. The arm rotates while causing the displacement of the contact position.
In other words, in the conventional hinge, the direction of the force applied from the arm to the damper piston when the arm pushes the rod portion of the damper piston when the original pressure plate rotates relative to the main body of the office machine and closes. The arm rotates while changing.
In the conventional hinge, when the deviation width of the position of the arm that contacts the rod portion of the damper piston is large and the change width of the force applied from the arm to the damper piston is large, If the malfunction of the piston occurs when the rod is pushed by the arm and the piston of the damper moves due to the rotation of the original crimping plate in the closing direction, There is a case of being caught and not moving).

In the hinge 1, as shown in FIG. 9, FIG. 14, or FIG. 15, the document crimping plate 92 rotates with respect to the main body 91 of the office machine 90 in the closing direction, and the arm 70 is on the arm side of the cam block 20. When the rod portion 63 of the piston 62 of the damper 60 is pushed in contact with the cam surface 22, the arm 70 rotates while moving in the direction in which the long hole extends (vertical direction).
In the hinge 1, the original pressure plate 92 is rotated in the closing direction with respect to the main body 91 of the office machine 90, and the arm 70 is rotated in a state of being in contact with the arm side cam surface 22 of the cam block 20. When the rod part 63 of the piston 62 is pushed in, the guide groove 44 of the slider 40 (the moving direction of the piston 62 when the damper 60 moves so that the protruding length of the rod part 63 of the piston 62 from the cylinder 61 becomes short). The arm 70 moves to the case 10 side.

In this way, the arm 70 of the hinge 1 closes the document pressing plate 92 (second connection object) with respect to the main body 91 (first connection object) of the office machine 90 (the direction in which the rotation angle decreases). And when the rod part 63 of the piston 62 of the damper 60 is pushed in, the rod 62 of the piston 62 of the damper 60 is moved so that the protruding length from the cylinder 61 becomes short. It is configured to move along the moving direction.
Therefore, in the hinge 1, when the arm 70 pushes the rod portion 63 of the piston 62 of the damper 60 when the original crimping plate 92 rotates in the closing direction with respect to the main body 91 of the office machine 90 ( When the arm 70 rotates in the direction in which the document pressing plate 92 closes with respect to the main body 91 of the office machine 90 and pushes the rod portion 63 of the piston 62 of the damper 60, the arm 70 follows the moving direction of the piston 62 of the damper 60. As compared with those that do not move), the deviation width of the position of the arm 70 that contacts the rod portion 63 of the piston 62 of the damper 60 can be reduced.
In the hinge 1, the original crimping plate 92 is rotated in the closing direction with respect to the main body 91 of the office machine 90, and the arm 70 pushes the rod portion 63 of the piston 62 of the damper 60 as compared with the conventional one. Thus, the change width of the direction of the force applied from the arm 70 to the piston 62 of the damper 60 can be reduced.
Therefore, according to the hinge 1, the document crimping plate 92 (second connection object) is rotated in the closing direction (in the direction in which the rotation angle decreases) with respect to the main body 91 (first connection object) of the office machine 90. It is suppressed by the movement operation failure of the piston 62 when it moves and is pushed by the arm 70 and moves so that the protrusion length from the cylinder 61 in the rod portion 63 of the piston 62 of the damper 60 is shortened. Can do.

DESCRIPTION OF SYMBOLS 1 Hinge 10 Case 11 Accommodating chamber 20 Cam block 21 Cam surface 30 Rotating pin 40 Slider 50 Energizing member 60 Damper 61 Cylinder 62 Piston 63 Rod part 70 Arm 80 Arm pin

Claims (3)

A hinge for pivotally connecting the second connection object to the first connection object,
A case provided with a storage chamber and fixed to either the first connection object or the second connection object;
A cam block that includes a cam surface, is rotatably supported by the case, and is fixed to either the first connection object or the second connection object;
A slider configured to be accommodated in the housing chamber of the case so as to be movable in a direction approaching the cam block and in a direction away from the cam block, and configured to come into contact with a cam surface of the cam block;
A biasing member that biases the slider in a direction approaching the cam block;
A cylinder and a piston arranged so that the rod portion protrudes from the cylinder, and a buffering effect is generated by moving the piston so that a protruding length from the cylinder in the rod portion of the piston is shortened A damper configured to, and
An arm that is rotatably supported by the case, is configured to be able to contact a cam surface of the cam block, and can be contacted to a rod portion of a piston of the damper;
Comprising
When the second connection object rotates in the closing direction with respect to the first connection object,
The cam block is rotated, the arm is rotated in a state of being in contact with the cam surface of the cam block, and the rod portion of the piston of the damper is pushed in. The piston of the damper is in the rod portion of the piston of the damper. While moving so that the protruding length from the cylinder becomes shorter,
The cam block is configured to rotate and push the slider in contact with the cam surface of the cam block, and the slider moves in a direction away from the cam block.
Hinge. The rotation angle of the second connection object with respect to the first connection object is defined as increasing when the second connection object rotates in the opening direction with respect to the first connection object,
The second connection object rotates in the closing direction with respect to the first connection object, and the rotation angle of the second connection object with respect to the first connection object becomes equal to or less than a predetermined rotation angle. When the slider is in contact with the cam surface of the cam block, the state in which the slider moves away from the cam block is stopped.
The hinge according to claim 1. The arm moves along the moving direction of the piston when the rod part of the piston of the damper moves in such a manner that the protruding length from the cylinder in the rod part of the piston of the damper becomes shorter when the rod part of the piston of the damper is pushed in. Composed of,
The hinge according to claim 1 or 2.

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