JP4532393B2 - Hinge - Google Patents

Description

  The present invention relates to a hinge capable of automatically turning a wing.

Conventionally, a hinge in which a wing attached to a shaft automatically pivots is well known. For example, the hinge disclosed in Japanese Utility Model Publication No. 63-173479 is of that kind. One of the pair of wings in the hinge has a pair of end sleeves formed at both upper and lower ends, and the other of the wings has an intermediate sleeve interposed between the pair of sleeves. A shaft inserted through these sleeves is divided into three shaft members arranged in a row. A pair of shaft members adjacent to each other among these divided shaft members is composed of a fixed shaft member and a movable shaft member, and a cam mechanism that enables automatic turning of the wings is formed on the opposing surfaces. Yes. The remaining shaft members are adjacent to the movable shaft member via the coil spring so that the pair of shaft members are in pressure contact with each other on the opposing surfaces.
Japanese Utility Model Publication No. 63-173479

  In the hinge disclosed in Patent Document 1, the fixed shaft member is attached to one of the sleeves at both ends of one of the pair of wings, and the intermediate sleeve in the other wing is attached to the fixed shaft member. There are cases where it is difficult to say that the attachment state of these wings to the fixed shaft member is unstable and has sufficient strength. For example, depending on the amount of the fixed shaft member entering the intermediate sleeve and how the hinge is used, the intermediate sleeve may come off the fixed shaft member, or loosening may occur between the fixed shaft member and the intermediate sleeve, causing the wing to turn. May not be smooth.

  In such a situation, an object of the present invention is to improve the durability of the hinge in which the wing automatically turns.

  In order to solve the above-described problems, the present invention is directed to a shaft having a first wing and a second wing that can pivot in a direction around the shaft, and the shaft includes the first and second wings. The hinge includes a cam mechanism that is inserted into a group of sleeves that are formed on each other and alternately arranged to enable the first and second wings to automatically turn.

  In this hinge, the present invention is characterized as follows. The first wing includes a first fixing sleeve and a second fixing sleeve positioned at both ends of the sleeve group, and at least one intermediate fixing sleeve positioned between the first and second fixing sleeves. At least three fixing sleeves. The second wing has at least two movable sleeves including a first movable sleeve adjacent to the first fixing sleeve and a second movable sleeve adjacent to the second fixing sleeve. The shaft includes a first shaft, a second shaft, and a third shaft interposed between the first and second shafts. The first shaft is fixed to the first fixing sleeve and enters the first movable sleeve so as to be slidable in the peripheral direction. The second shaft is fixed to the second fixing sleeve and enters the second fixing sleeve and the intermediate fixing sleeve adjacent to the second fixing sleeve via the second moving sleeve. And is slidable in the direction around the second movable sleeve. In the third shaft, a surface facing the second shaft forms a cam follower in the cam mechanism, while a surface facing the first shaft is interposed between the first shaft and the third shaft. Under the action of a spring means for urging toward the second shaft, and slidable in the circumferential direction and the axial direction of both the fixing sleeve and the movable sleeve. Is formed. The cam mechanism includes a cam formed by inclining a surface of the second shaft facing the third shaft with respect to an axis of the shaft, and the cam follower. The first movable sleeve enters the peripheral surface of the third shaft at a portion entering the first movable sleeve from the radial direction, and the third shaft is moved when the second wing turns. Drive means capable of following the cam with the cam follower by rotating around the shaft is formed, while the third shaft has the drive means entered into the peripheral surface, and A recess is formed that is guided by the driving means to enable the movement of the third shaft in the axial direction.

  In a preferred embodiment of the present invention, the driving means is formed by pins that penetrate the third shaft in the radial direction, and both ends of the pins are fixed to the movable sleeve.

  In the hinge according to the present invention, the second shaft is fixed to the second fixing sleeve of the first wing, the second movable sleeve of the second wing, and the second fixing sleeve via the second movable sleeve. The second movable sleeve of the second wing does not come off from the second shaft, and the second wing can always turn smoothly around the second shaft. This will improve the durability of the hinge.

  In this aspect of the invention in which the drive portion for rotating the third shaft is a pin that penetrates the third shaft in the radial direction, and both ends of the pin are fixed to the peripheral wall of the movable sleeve, the second wing is swiveled. Since the force when rotating the third shaft easily acts on the entire diameter of the third shaft, the rotation of the third shaft becomes smooth, and the rotation damages the pin and the third shaft. Less.

  The details of the hinge according to the present invention will be described with reference to the accompanying drawings.

  1 and 2 are a front view and a bottom view of the hinge 1. The hinge 1 has a shaft 2, and a first wing 3 and a second wing 4 that can pivot in a direction around the shaft 2. The first wing 3 includes an upper end sleeve 6 that is intermittently arranged in the vertical direction in FIG. 1, a lower end sleeve 7, and an intermediate sleeve 8 that is positioned between the sleeves 6 and 7. In FIG. 1, the second wing 4 includes an upper sleeve 11 positioned between the upper end sleeve 6 and the intermediate sleeve 8, and a lower sleeve 12 positioned between the lower end sleeve 7 and the intermediate sleeve 8. The first and second wings 3 and 4 are formed with through holes 13 and 14 for screwing them to a door or a fixed frame (not shown).

  FIG. 3 is a cross-sectional view taken along the line III-III in FIG. 2, but the shaft 2 is shown as a side view, not a cross-sectional view, and is partially broken. The shaft 2 is inserted through a group of sleeves consisting of an upper sleeve 6, an upper sleeve 11, an intermediate sleeve 8, a lower sleeve 12, and a lower sleeve 7 that are in close contact with each other in a tandem state, and is positioned above the figure. It includes a first shaft 21, a second shaft 22 located below the figure, and a third shaft 23 interposed between these shafts 21 and 22, and between the first shaft 21 and the third shaft 23 A coil spring 24, which is a spring means, is provided. The first shaft 21 is fixed to the upper end sleeve 6 by a fixing means 26 comprising a screw or a press-fit pin and extends to the upper sleeve 11, and the inner peripheral surface of the upper sleeve 11 goes around the peripheral surface of the first shaft 21. It can slide in the direction. The second shaft 22 is fixed to the lower end sleeve 7 by fixing means 27 made of screws or press-fit pins, and extends through the lower sleeve 12 to the intermediate sleeve 8. The lower sleeve 12 can slide in the circumferential direction on the peripheral surface of the second shaft 22, but the intermediate sleeve 8 does not move relative to the second shaft 22. The third shaft 23 extends across the upper sleeve 11 and the intermediate sleeve 8, and the third shaft 23 penetrates the third shaft 23 in the radial direction in a portion that fits in the upper sleeve 11. An oval through-hole 28 having a long diameter is formed in the direction of the axis C common to 7, 8, 11, and 12. Pins 29 are inserted into the through holes 28, and both ends of the pins 29 are fixed to the upper sleeve 11 (see FIG. 5). The third shaft 23 in such a state is slidable in the circumferential direction with respect to the inner peripheral surface of the intermediate sleeve 8, and the upper and lower sides of the figure with respect to the inner peripheral surface of the intermediate sleeve 8 and the upper sleeve 11. It can slide in the direction. The vertical movement of the third shaft 23 is guided in the vertical direction when the wall surface of the through hole 28 contacts the pin 29, and stops when the top or bottom of the through hole 28 contacts the pin 29.

  In FIG. 3, the upper end surface 32 of the second shaft 22 and the lower end surface 33 of the third shaft 23 are opposed to each other, are inclined at the same angle with respect to the axis C, and are in close contact with each other in a slidable state. Yes. The coil spring 24 urges the third shaft 23 downward in the drawing to press the lower end surface 33 against the upper end surface 32.

  4 is a view when the second wing 4 is turned clockwise by 90 ° in FIG. 2, that is, downward, and FIG. 5 is a cross-sectional view taken along the line VV in FIG. 2 is shown as a side view rather than a cross-sectional view.

  4 and 5, when the hand is placed on the second wing 4 in FIG. 2 and rotated 90 ° clockwise, the upper sleeve 11 slides around the first shaft 21, while the lower sleeve 12 The second shaft 22 is slid around the shaft 22, and the third shaft 23 is driven by the pins 29 fixed to the upper sleeve 11 at both ends, and rotates around the axis C inside the intermediate sleeve 8. The third shaft 23 rises while compressing the coil spring 24 of FIG. 3 by rotating while climbing the inclined upper end surface 32 of the second shaft 22 which is the cam surface with the lower end surface 33 serving as a cam follower, The state shown in FIG. 5 is obtained. When the second wing 4 in this state is released, the third shaft 23 biased downward by the restoring force of the compressed coil spring 24 is tilted while rotating counterclockwise. The second wing 4 can be automatically returned to the state shown in FIGS.

  Although not shown, the third shaft 23 acts in the same manner as in FIGS. 4 and 5 even when the second wing 4 is turned in FIG. 2 and turned counterclockwise. The swung second wing 4 can be automatically returned to the state shown in FIGS.

  In the hinge 1 configured as above, the first shaft 21 and the second shaft 22 fixed to the first wing 3 are respectively the upper sleeve 11 and the lower sleeve 12 of the second wing 4. Has entered. In addition, in the second shaft 22, the lower sleeve 12 is sandwiched between the lower end sleeve 7 and the intermediate sleeve 8 of the first wing 3 adjacent thereto, so that the second wing 4 is related to the shaft 2. It does not move in the axial direction and does not come off the second shaft 22. Therefore, the second wing 4 is not detached from the first shaft 21. Such a hinge 1 is excellent in durability, and the first and second wings 3 and 4 are always smoothly turned.

  In the present invention, the first wing 3 has three fixing sleeves 6, 7, 8 and the second wing 4 has two movable sleeves 11, 12. It is also possible to implement with a hinge in which the first wing 3 has a plurality of intermediate sleeves and the second wing 4 has three or more movable sleeves. Also in such a hinge, the upper sleeve 6 and the lower sleeve 7 provided on the first wing 3 are used as fixing sleeves for fixing the first shaft 21 and the second shaft 22, respectively. The intermediate sleeve can be used only for inserting the shafts 21 and 22, or can be used for fixing the shafts 21 and 22. The upper sleeve 11 provided on the second wing 4 and adjacent to the upper end sleeve 6 and the lower sleeve 12 adjacent to the lower end sleeve 7 are respectively connected to the fixed first shaft 21 and second shaft 22. Used as a movable sleeve that slides. The lower sleeve 12 at that time is also positioned between the lower end sleeve 7 and the intermediate sleeve in the first wing 3 so as not to be detached from the second shaft 22. Further, in the present invention, the pin 29 as a driving means for the third shaft 23 can be replaced with a protrusion protruding from the inner peripheral surface of the upper sleeve 11 toward the third shaft 23, and a through hole in the third shaft 23. 28 can be replaced with a recess formed in the peripheral surface of the third shaft 23 so as to allow the protrusion to enter. However, in the present invention, both the recess and the through hole 28 are treated as a recess on the peripheral surface of the third shaft 23.

  According to the present invention, it is possible to manufacture a highly durable hinge in which the wing automatically turns.

The top view of a hinge. The bottom view of the hinge of FIG. III-III sectional view taken on the line of FIG. The same figure as FIG. 2 when turning a wing. VV sectional view taken on the line of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hinge 2 Shaft 3 1st wing 4 2nd wing 6 1st fixing sleeve (upper sleeve)
7 Second fixing sleeve (lower end sleeve)
8 Intermediate fixing sleeve (intermediate sleeve)
11 First movable sleeve (upper sleeve)
12 Second movable sleeve (lower sleeve)
21 1st shaft 22 2nd shaft 23 3rd shaft 24 Energizing means (coil spring)
28 Recessed part (through hole)
29 Drive means (pin)
32 cam 33 cam follower C-axis

Claims (2)

A shaft and a first wing and a second wing pivotable in a direction around the shaft, wherein the shaft is inserted into a group of sleeves formed alternately in the first and second wings. In the hinge including a cam mechanism that enables automatic turning of the first and second wings,
The first wing includes a first fixing sleeve and a second fixing sleeve positioned at both ends of the sleeve group, and at least one intermediate fixing sleeve positioned between the first and second fixing sleeves. Having at least three fixing sleeves, including
The second wing has at least two movable sleeves including a first movable sleeve adjacent to the first fixed sleeve and a second movable sleeve adjacent to the second fixed sleeve;
The shaft includes a first shaft, a second shaft, and a third shaft interposed between the first and second shafts, and the first shaft is fixed to the first fixing sleeve. The first movable sleeve is slidably entered in the circumferential direction, and the second shaft is fixed to the second fixed sleeve, and the second movable sleeve and the second movable sleeve are connected to each other. Through the intermediate fixing sleeve adjacent to the second fixing sleeve and is slidable in a direction around the second movable sleeve, and the third shaft is opposed to the second shaft. While the surface forms a cam follower in the cam mechanism, the surface facing the first shaft is interposed between the first shaft and urges the third shaft toward the second shaft. It is in effect under the unit, and wherein for any and the fixing sleeve of the movable sleeve is slidably formed in the direction about the axial direction of the sleeves,
The cam mechanism includes a cam formed by inclining a surface of the second shaft facing the third shaft with respect to an axis of the shaft, and the cam follower,
The first movable sleeve enters the peripheral surface of the third shaft at a portion entering the first movable sleeve from the radial direction, and the third shaft is moved when the second wing turns. Drive means capable of following the cam with the cam follower by rotating around the shaft is formed, while the third shaft has the drive means entered into the peripheral surface, and The hinge is characterized in that a recess is formed which is guided by a driving means to enable the movement of the third shaft in the axial direction.   The hinge according to claim 1, wherein the driving means is formed by pins penetrating the third shaft in a radial direction thereof, and both ends of the pins are fixed to the movable sleeve.

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