ES2681823T3 - Adjustable angle joint - Google Patents

Abstract

An angle adjustable hinge comprising: a first member (1) holding a disc body (16) having a non-circular through hole (23) so that it rotates freely about an axis of oscillation (C), a portion non-circular shaft (20) for insertion into the through hole (23), and a second member (2) fixed to one end of the non-circular shaft portion (20), where the first member (1) and the second Member (2) are, by inserting the shaft portion (20) into the through hole (23), pivotally so that they oscillate relatively, and a gear portion (4) is formed from 1/3 to 1/4 of the peripheral edge portion of the disc body (16) and two protruding portions (28) are formed at the beginning and the end of the gear portion (4), a floating wedge member (6), of which one side is a toothed face (7) coupled to the gear portion (4) and another face is a contact face (9) for contacting a wedge face (8) formed in the side of the first member (1), where a relative oscillation of the first member (1) and the second member (2) in a first direction (B) is restricted in an engaged state where the contact face (9) contacts the face of wedge (8) and the toothed face (7) and the gear portion (4) are engaged, where the floating wedge member (6) is movable to separate from the gear portion (4) in a withdrawn state making oscillating the first member (1) and the second member (2) relatively in a second direction (A) to a lock release position (P0) to release engagement of the gear portion (4) and the toothed face (7 ), and where the first member (1) and the second member (2) oscillate relatively in the first direction (B) in the withdrawn state; wherein the adjustable angle joint further comprises a recovery means (10), which recovers the floating wedge member (6) from the withdrawn state to the state engaged with the gear portion (4) by a return action (M2) of a small predetermined angle (θ) in the second direction (A) during free oscillation (M1) where, during free oscillation (M1), the first member (1) and the second member (2) oscillate relatively in the first direction (B) from the lock release position (P0), characterized in that lower circular projections (24) protrude from the disc body (16) from the left and right sides thereof, and are held to rotate freely by a pair of facing plate portions (13) with the lower circular projections (24) inserted into the circular support holes (21) of the facing plate portions (13), arranged mutually parallel and fixed to a coupling portion (17) of the first me embro (1).

Description

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DESCRIPTION

Adjustable angle joint

The invention relates to an adjustable angle joint.

An earlier patent application, which was published after this priority date, is EP 2 767 188 A1. This document refers to an adjustable angle joint and a sofa.

Another document is US 2005/0046260 A1 referring to an adjustable angle joint provided with a first arm having a cover portion and a second arm connected to the first arm with the case portion for oscillating around a first axis and having a First portion of gear. The adjustable angle joint is also provided with a wedge-shaped window portion formed in the case portion of the first arm and a floating wedge member, arranged to move within the wedge-shaped window portion that has a face side shaped toothed face to engage with the gear portion and another side face shaped contact face to contact a wedge face on an outer side of the wedge-shaped window portion.

In a sofa S as shown in Fig. 13 and Fig. 14, an adjustable angle joint Z is used to recline a support portion 50 such as a headrest 48 and an armrest 49. The sofa S has a construction in that its posture is maintained at a desired angle of inclination by restricting the oscillation of the support portion 50 in one direction B by the adjustable angle joint Z, and the support portion 50 oscillates in another direction A with a sound click

The inventor of the present application has proposed many adjustable angle joints to maintain the angle of inclination of the support portion 50 with multiple stages (see Japanese Patent No. 4418519, for example).

In the adjustable angle joint described in Japanese Patent No. 4418519, a first member and a second member pivot to oscillate relatively, and the oscillation (in one direction) of the first member and the second member is restricted by a wedge function of a floating wedge member. The wedge function of the floating wedge member is canceled by adjusting the first member and the second member in a predetermined lock release position, and free oscillation (in one direction) of the first member and the second member becomes possible. When the wedge function of the floating wedge member is canceled once, the wedge function (locked state) cannot be recovered until the first member and the second member are set to a predetermined lock recovery position. That is, there is a disadvantage in that the posture of the first member and the second member cannot be maintained with the locked state in an intermediate position towards the oscillation from the blocking release position towards the blocking recovery position.

Conventionally, the sofa S shown in Fig. 13 and Fig. 14 is manufactured so that free oscillation is made possible when the headrest 48 or the armrest 29 is raised in an upright position (lock release position), then , the lock is recovered when the headrest 48 or armrest 49 tilts in a direction of the arrow B to a horizontal position (lock recovery position). With the recovery of the locked state, the inclined position can be maintained at a desired angle of inclination when the headrest 48 or the armrest 49 gradually rises in a direction of the arrow A.

However, when there is an excessive load (in the direction of the arrow B to restrict the oscillation) on the headrest 48 or the armrest 49, a clearance is generated in a fixed portion of the adjustable angle joint Z and a fixing member of the sofa S, or, the adjustable angle joint Z itself deforms plastically, the blockage cannot be recovered because the armrest 49 can interfere (contact) with a base portion 45 before reaching the blocking recovery position. Similarly, the lock may not recover because the headrest 48 may interfere (contact) with an upper end face of a backing portion 46. And it is also a problem that the locked state of the armrest 49 (the headrest 48) does not can be recovered if obstacles are placed in the base portion 45 (the upper end face of the backing portion 46).

Therefore, it is an object of the present invention to provide an adjustable angle joint with which the locked state recovers easily in a random position towards the free oscillation of the first member and the second member from the locked release position, and is Perform an angle adjustment at a desired intermediate position to maintain the adjustable angle joint posture.

This object is solved in accordance with the present invention by an adjustable angle joint that includes the features of claim 1. A more detailed embodiment is described in a dependent claim 2.

The present invention will be described with reference to the accompanying drawings, in which:

Fig. 1 is an exploded perspective view showing an embodiment of the present invention.

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Fig. 2 is a perspective view of one half of the product before the assembly is completed.

Fig. 3 is a cross-sectional view of Fig. 2.

Fig. 4 is a perspective view of a state mounted and used.

Fig. 5 is a cross-sectional view of Fig. 4.

Fig. 6A is a complete cross-sectional view of the adjustable angle joint of the present invention.

Fig. 6B is an enlarged cross-sectional view of a main portion of the adjustable angle joint of the present invention.

Fig. 7A is a complete cross-sectional view of the adjustable angle joint of the present invention.

Fig. 7B is an enlarged cross-sectional view of the main portion of the adjustable angle joint of the present invention.

Fig. 8A is a complete cross-sectional view of the adjustable angle joint of the present invention.

Fig. 8B is an enlarged cross-sectional view of the main portion of the adjustable angle joint of the present invention.

Fig. 9A is a complete cross-sectional view of the adjustable angle joint of the present invention.

Fig. 9B is an enlarged cross-sectional view of the main portion of the adjustable angle joint of the present invention.

Fig. 10A is a complete cross-sectional view of the adjustable angle joint of the present invention.

Fig. 10B is an enlarged cross-sectional view of the main portion of the adjustable angle joint of the present invention.

Fig. 11A is a complete cross-sectional view of the adjustable angle joint of the present invention.

Fig. 11B is an enlarged cross-sectional view of the main portion of the present invention.

Fig. 12A is a complete cross-sectional view of the angle joint

Fig. 12B is an enlarged cross-sectional view of the main portion of the present invention.

Fig. 13 is a perspective view of a sofa.

Fig. 14 is a perspective view of the sofa.

Fig. 15A is a front view showing an elastic portion.

Fig. 15B is a cross-sectional side view showing the elastic portion in an uncompressed state.

Fig. 15C is a cross-sectional view showing the elastic portion in a compressed state.

Preferred embodiments of the present invention will now be described with reference to the accompanying drawings.

An adjustable angle joint according to the present invention is used as a joint joint (connecting joint) of a sofa S having a headrest 48 and an armrest 49 as shown in the perspective view of Fig. 13 and Fig 14. On the sofa S shown in Fig. 13 and Fig. 14, a plurality of adjustable angle joints Z are arranged in a connecting portion of the headrest 48 and a backing portion 46, and in a connecting portion of an armrest portion 49 and a base portion 45 to adjust the inclination angles of the headrest 48 and the armrest 49 (support portions 50). The adjustable angle joint Z, not restricted to a sofa, can be used for a reclining bed.

adjustable angle joint of

Adjustable of the present invention. adjustable angle joint of

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As shown in Fig. 1 through Fig. 5, the adjustable angle joint of the present invention is provided with a first member 1 in which a disc body 16 having a through circular hole 23 is secured so that it can rotate freely around an oscillation axis C and a second member 2 of which a non-circular shaft portion 20 can be inserted in the through hole 23 on either side in the direction of the axis. The first member 1 and the second member 2 are connected so that they are relatively oscillating by inserting the shaft portion 20 into the through hole 23. In the present invention, the terms "non-circular" and "non-circularity" of the hole thru 23 and shaft portion 20 include configurations having concave convex and saw gears. And, (although not shown in the figures) it is also preferable to fix (so as not to rotate) the non-circular shaft portion 20 and the second member 2 as separate parts. And, it is also preferable to fix (detachably) the second member 2 to any of the ends of the non-circular shaft portion 20. A gear portion 4 is formed on a perimeter edge of the disk body 16, and a floating wedge member 6, of which one side is a toothed face 7 that engages the gear portion 4 and another side is a contact face 9 that contacts a wedge face 8 formed on the side of the first member 1.

The first member 1 is provided with a pair of plate portions 13 for securing the disc body 16 and a coupling portion 17 for attachment to the armrest portion 49 or the headrest portion 48. A circular support hole 21 and a window portion (wedge-shaped) 5 to form a wedge-shaped space to hold the floating wedge member 6 is formed through each of the plate portions 13. In addition, a small engagement boss 33 and a pivot shaft portion 27 of small diameter protrudes from an outer side of the facing plate portion 13. The window portion (wedge-shaped) 5 has the wedge face 8 with an arcuate shape to form a withdrawal space 25 for storing the floating wedge member 6 to separate it from the gear portion 4.

According to the invention, circular lower projections 24, insertable in the circular support holes 21, protrude from the right and left sides of the disc body 16. The gear portion 4 is formed for a range of between 1/3 to 1 / 4 of the peripheral edge of the disc body 16 (a range of the central angle between 90 ° and 120 °), and an overhanging portion (timing projection) 28 is formed on 2 points, namely a starting portion and a portion of end of the gear portion 4. The disc body 16 is held so that it rotates freely by means of the pair of facing plate portions 13 with the circular lower projections 24 inserted in the circular support holes 21, and the facing plate portions 13 are arranged mutually in parallel and fixed (riveted) to the fixing portion 17 with rivets 42.

The second member 2 has a fixing portion 18 for attachment to the fixing portion of the sofa 45 or the backing portion 46, and the non-circular shaft portion 20 protrudes from one end of the fixing portion 18. The portion of Tree 20 has a female threaded hole 44. A plurality of small holes 29 for bolts and screws are formed in the fixing portions 17 and 18.

The floating wedge member 6 is held within the wedge-shaped space formed with the pair of facing plate portions 13 (the window portions 5) and the gear portion 4, and both side end portions protrude (to the left and right) of the window portions 5. Preferably, between 13 and 20 gear teeth are arranged on the toothed face 7, and 40 or more (in a small step) gear teeth, preferably between 45 and 65 gear teeth, are formed in the gear portion 4 of the disc body 16. Thus, the number of stages of the angle adjustment may be greater than 40. A spring member (elastic) 26 for elastically pushing the floating wedge member 6 towards the portion gear 4 is disposed on the side of the contact face 9 (the side of the fixing portion 17) of the floating wedge member 6.

As shown in Figs. 6A and 6B, and Figs. 12A and 12B, in a coupled state in which the contact face 9 of the floating wedge member 6 and the toothed face 7 and the gear portion 4 are engaged, the relative oscillation of the first member 1 and the second member 2 in a address B is restricted (stopped). And, as shown in Figs. 9A and 9B, the first member 1 and the second member 2 oscillate relatively in another direction A to establish a blocking release position P0, and the floating wedge member 6 moves and separates from the gear portion 4 to reach a withdrawal state in which the coupling of the gear portion 4 and the toothed face 7 are thus released. In the withdrawal state shown in Figs. 10A and 10B, the first member 1 and the second member 2 can be swung relatively in the B direction. In the present invention, it is referred to as "free oscillation (M1)" when the blocking (oscillation restriction) of the first member is released. 1 and the second member 2 and the first member 1 and the second member 2 oscillate (relatively) in the B direction.

The adjustable angle joint of the present invention is provided with a recovery means 10 which recovers the floating wedge member 6 in the withdrawn state to the state coupled with the gear portion 4 by the return action M2 of the small predetermined angle 0 in the direction A during the free oscillation M1 where the first member 1 and the second member 2 in the blocking release position P0 oscillate relatively in the direction B, as shown in Figs. 11A and 11B.

The recovery means 10 is provided with a ring member 12 which rotates against the facing plate portion 13 within a range of the predetermined small angle 0, an oscillating member 11, having an end 11a interconnectedly coupled to the ring member 12 and that oscillates freely within a predetermined angle range

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with an intermediate portion such as a bearing point and another end 11b is arranged so that it is pressed against the floating wedge member 6 in the withdrawn state, and a pressure fixing friction member 15, which has a fixing hole Non-circular 19 fixed to the shaft portion 20 to rotate together with the shaft portion 20, and having an elastic portion 14 that elasticly pushes the ring member 12 in an axial inner direction and slides over the member of ring 12.

In the withdrawal state shown in Figs. 10A and 10B, the floating wedge member 6 maintains the withdrawal state (held in a first position V1 in which the end 11b of the oscillating member 11 does not press the floating wedge member 6) during the free oscillation M1 of the first member 1 and the second member 2 in the direction B. By the return action M0 in the direction A shown in Figs. 11A and 11B, the ring member 12 is rotated by frictional force with the elastic portion 14 according to the predetermined small angle 0, and the oscillating member 11 (which moves to a second position V2 where the end 11b presses the member of floating wedge 6) moves the floating wedge member 6 (pushing it out of the withdrawal space 25) to engage the gear portion 4 and the toothed face 7.

As shown in Fig. 1, the ring member 12 is formed as a ring having a circular orifice portion 22 into which the shaft portion 20 is inserted, and a concave engagement portion 34 corresponding to the small projection 33 and an arc-shaped notch portion 32 is formed in the peripheral edge portion. The ring member 12 engages the small projection 33 towards the concave hitch portion 34 in a movable manner (with a backslash), and rotatable within the range of the small predetermined angle 0 around the axis of oscillation C as a fulcrum.

The oscillating member 11 is formed of high rigidity metal (or resin) with an approximately V-shape, and the end 11a (formed as a short cylindrical column) is fixed to the arc-shaped notch portion 32 engages so interconnected to the ring member 12. A pivot hole portion 31 is formed in an intermediate portion of the swinging member 11 to insert the pivot shaft portion 27. For example, the swinging member 11 pivots towards (the outer side face of) the facing plate portion 13 when the end 11a of the swinging member 11 moves up and down, and the corresponding other end 11b moves oppositely downward and upward in zigzag with the pivot shaft portion 17 as a support point.

As shown in Fig. 15A, the elastic portion 14 is formed as a ring, and a plurality of small convex portions 37 protrude from an end face. The elastic portion 14 is composed of an elastically deformable resin (or metal), and another end face of the elastic portion 14 is a sliding face 39 for sliding (pushing elastically in the axial interior direction in a mounted and used state described later) on ring member 12.

In Fig. 1, a pressure fixing friction member 15 is formed as a ring, and a plurality of small concave portions 38 corresponding to the small convex portions 37 of the elastic portion 14. The elastic portion 14 is fixed with the plurality of small convex portions 37 inserted in the small concave portions 38 to rotate (co-rotate) in a unified manner with the pressure fixing friction member 15. It is also preferable to form the elastic portion 14 in a unified manner with the member friction fixing pressure 15.

In a state of half a product shown in Figs. 2 and 3, the pressure fixing friction member 15 is disposed on an outer side on each ring member 12, and the elastic portion 14 contacts the outer face of the ring member 12. As shown in Fig. 15B , the sliding face 39 of the elastic portion 14 is arc-shaped in an uncompressed state. The pressure-adjusting friction member 15 is held by a cover member 40. The cover member 40 is composed of a pair of (two pieces) half resin cover bodies 41. An insertion pin and an insertion hole are formed in the half cover body 41 in corresponding mounting positions (see Fig. 1). The cover member 40 covers and stores in a very compact manner the pressure-adjusting friction members 15, the ring members 12, the oscillating member 11, the facing plate portions 13, the disk body 16, and the floating wedge 6.

In the assembled and used state shown in Figs. 4 and 5, the shaft portion 20 of the second member 2 is inserted through the through hole 23 and the fixing hole 19, a bolt 43 is screwed into the female thread hole 44 to insert the first member 1 into the second member 2. The bolt 43 is inserted into a washer 51. In the pressure fixing friction members 15, the elastic portions 14 are elastically deformed by compression of the bolt fixing force 43. As shown in Fig. 15C , the sliding face 39 of the elastic portion 14 becomes a flat face in the compressed and pressurized state to the ring member 12. That is, the pressure fixing friction members 15 elastically push the ring members 12 with the elastic portions 14 in the axial internal direction.

Next, the method of use (function) of the adjustable angle joint described above in the present invention is described.

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In the coupled state shown in Figs. 6A and 6B, the toothed face 7 of the floating wedge member 6 is coupled to the gear portion 4, and the contact face 9 contacts the face 8 to restrict (stop) the relative oscillation of the first member 1 and the second member 2 in the B direction. The following explanation assumes the condition that the second member 2 is coupled to the sofa fixing portion, the first member 1 is coupled to the armrest portion 49 or the headrest portion 48, and the first member 1 swings against the second member 2 (fixed).

Next, as shown in Figs. 7A and 7B, when the first member 1 swings in the direction A, the floating wedge member 6 moves slightly within the window portion 5, and the contact face 9 separates from the wedge face 8 to form a small hollow d. When the first member 1 swings farther in the direction A, the inclined guide face 35 of the floating wedge member 6 mounts the inclined portion 36 of the window portion 5, the serrated face 7 of the floating wedge member 6 is separated from the gear portion 4 according to the gap d, and the toothed face 7 passes over the portion 4 with a clicking sound. Even if the first member 1 is swung in the direction B against the second member 2, the oscillation is restricted (stopped) by the wedge function of the floating wedge member 6, and the posture of the first member 1 is maintained (it is maintained fixed). Although the rotational force acts on the ring member 12 in the direction of the arrow N (counterclockwise in the figures) against the facing plate portion 13 by a frictional force with the elastic portion 14 (the member of pressure-fixing friction 15) in the oscillation in the direction A, the ring member 12 engages (against the facing plate portion 13) by the small projection 33 that contacts the concave portion (hook) 34.

As shown in Figs. 8A and 8B, when the first member 1 is swung further in the direction A, the toothed face 7 repeatedly passes over the gear portion 4, and an overhanging portion 28 disposed at an end portion of the gear portion 4 contacts with the floating wedge member 6.

As shown in Figs. 9A and 9B, when the first member 1 is swung further in the direction A to a blocking release position P0 in the state in which the protruding portion 28 contacts the floating wedge member 6, the floating wedge member 6 is pushed by the projecting portion 28 and moved to the withdrawal space 25 for storage, and the toothed face 7 is separated from the gear portion 4 (a withdrawal state is performed). In this case, the other end 11b of the oscillation member 11 is pushed by the floating wedge member 6 and swung. This position is the first position V1. The oscillating member 11 oscillates to the first position V1, the end 11a pushes the ring member 12, and the ring member 12 rotates in the direction of the arrow R (clockwise in the figures) only the small angle 0.

In the withdrawal state, the floating wedge member 6 is stored within the withdrawal space 25, and the engagement of the toothed face 7 and the gear portion 4 is released. Therefore, the lock is released (oscillation restriction ) in the direction B, and the free oscillation of the first member 1 in the direction B is made possible.

Next, as shown in Figs. 10A and 10B, when the first member 1 is in the free oscillation M1 in the direction B, the ring member 12, although receiving rotational force in the direction of the arrow R by the frictional force of the elastic portion 14, is stopped by the small projection 33 that contacts the concave portion (latch) 34. That is, during the free oscillation M1 of the first member 1 in the direction B, the oscillating member 11 is held in the first position V1 and maintains the posture without oscillation, and the floating wedge member 6 is maintained in the withdrawal state.

In Figs. 11A and 11B, when the return action M2 is carried out in the direction A according to the small predetermined angle 0 during the free oscillation M1 of the first member 1 in the direction B, the ring member 12, which receives a rotational force in the direction of the arrow N (counterclockwise in the figures) due to the frictional force of the elastic portion 14, it rotates. The oscillating member 11, whose end 11a is pushed by the rotating ring member 12, oscillates. This position is the second position V2. The oscillating member 11 pushes the floating wedge member 6 with the other end 11b to remove it from the withdrawal space 25. The floating wedge member 6 pushed out of the withdrawal space 25 is pressed against the gear portion 4 by the spring member 26, and the coupled state in which the toothed face 7 is engaged to the gear portion 4 (returning to the locked state) is realized.

In Figs. 12A and 12B, the coupled state is realized, in which the toothed face 7 of the floating wedge member 6 is coupled to the gear portion 4 and the contact face 9 contacts the wedge face 8, the function of wedge of the floating wedge member 6 to stop the oscillation of the first member in the B direction. As described above, the locked state is easily recovered in random positions during the free oscillation of the first member 1 from the locked release position P0 to the direction B, the oscillation of the first member 1 is restricted in a desired intermediate inclined position to maintain the posture, and an angle adjustment is initiated by an oscillation from the intermediate inclined position to the direction A.

The present invention can be modified. For example, if you don't have the window portion (wedge-shaped) 5, you can use a plate piece member, etc. instead to press the contact face 9 of the floating wedge member 6. And the design and dimensions of the cover member 40 can be modified.

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And the number of gear teeth of the toothed face 7 and of the gear portion 4 may be greater or lesser than the numbers described above depending on the cases. And the procedure for forming the gear teeth can be freely selected from several plastic (press), pressure molding, roulette work, etc.

Especially, the oscillating member 11 can be freely modified as long as the member 11 is interconnected to move the floating wedge member 6 in an opposite direction (clockwise) to push it out (remove or remove) from the withdrawal state together with the rotation of the ring member 12 (counterclockwise) a small angle 0 of Figs. 10A and 10B to Figs. 11A and 11B.

And the tree portion 20 is formed as a regular hexagonal column, and the through hole 23 is also regular hexagonal to correspond to the tree portion 20 in the figures. The shaft portion 20 and the through hole 23 can adopt various polygonal configurations and others as long as they are not circular and fit together.

As described above, the adjustable angle joint of the present invention can cause the floating wedge member 6 to effectively engage the gear portion 4 to block the first member 1 and the second member 2 by a simple operation of a slight return movement in the direction A in a random position as a free oscillation in the direction B from the lock release position P0 because the first member 1 that holds the disk body 16 having the through hole 23 is not provided circular to rotate freely around the axis of rotation C, the non-circular shaft portion 20 to be inserted into the through hole 23, and the second member 2 fixed to one end of the non-circular shaft portion 20; the first member 1 and the second member 2 are pivoted so that they oscillate relatively by inserting the shaft portion 20 into the through hole 23, the gear portion 4 is formed in the peripheral edge portion of the disk body 16 ; the floating wedge member 6 is provided, one of whose sides is the toothed face 7 coupled to the gear portion 4 and another face is the contact face 9 for contacting the wedge face 8 formed on the side of the first member 1 ; a relative oscillation of the first member 1 and the second member 2 is made in the restricted direction B in the coupled state in which the contact face 9 contacts the wedge face 8 and the toothed face 7 and the gear portion 4 are coupled, the withdrawal state, in which the floating wedge member 6 moves to separate from the gear portion 4 by oscillating the first member 1 and the second member 2 relatively in another direction A towards the lock release position P0 for releasing the coupling of the gear portion 4 and the toothed face 7, and the first member 1 and the second member 2 are swung relatively in the direction B in the withdrawn state; and the recovery means 10 is provided, which recovers the floating wedge member 6 from the withdrawal state to the state coupled with the gear portion 4 by the return action M2 of a small predetermined angle 0 in the direction A towards the free oscillation M1 in which the first member 1 and the second member 2 oscillate relatively in the direction B from the lock release position P0. That is, after the release of the coupling of the floating wedge member 6 and the gear portion 4, the coupling of the floating wedge member 6 and the gear portion 4 is recovered by the recovery means 10 to restrict the oscillation of the first member 1 and the second member 2 and an angle adjustment can be initiated from the previous posture so that the first member 1 and the second member 2 form predetermined lock recovery position. Thus, the support portion 50 can be safely maintained with an intermediate tilt posture of a desired tilt angle with a simple operation in an intermediate position between the final standing posture (lock release position) and the final raid posture ( blocking recovery posture) of the support portion 50 of the sofa S. That is, the disadvantage is resolved that the locked state of the support portion 50 of the sofa S cannot be recovered, and an adjustment of angle of the support portion 50.

And the joint is compact with the parts stored in the cover member 40, the floating wedge member 6 can maintain the state of withdrawal during free oscillation M1 in the direction B without any functional error, and the gear portion 4 and the serrated face 7 can be coupled by a certain movement of the floating wedge member 6 by the return action M2 in the direction A because the first member 1 is provided with a pair of facing plate portions 13 to hold the disc body 16; the recovery means 10 is provided with the ring member 12 which rotates towards the facing plate portion 13 within a range of the small predetermined angle 0, the oscillating member 11, whose end 11a is interconnectedly coupled with the ring member 12 and is oscillating with an intermediate portion as a support point within a predetermined angular range and another end 11b is arranged to be pressed against the floating cup member 6 in the withdrawn state, and the frictional pressure fixing member 15, which it has the non-circular fixing hole 19 to which the shaft portion 20 is fixed and the elastic portion 14 which rotates in a unified manner with the shaft portion 20 and pushes elastically in an axial inner direction and slides over the ring member 12; and in the withdrawal state, the floating cup member 6 maintains the withdrawal state during the free oscillation M1 of the first member 1 and the second member 2 in the direction B, the ring member 12 rotates the small predetermined angle 0 by the frictional force with the elastic portion 14 by the return action M2 in the direction A, and the oscillating member 11 moves the floating wedge member 6 to engage the gear portion 4 and the serrated face 7.

Claims (2)

5 10 fifteen twenty 25 30 35 40 Four. Five fifty 55 1. An adjustable angle joint comprising: a first member (1) holding a disc body (16) having a non-circular through hole (23) so that it rotates freely around an oscillation axis (C), a non-circular shaft portion (20) for its insertion in the through hole (23), and a second member (2) fixed to one end of the non-circular tree portion (20), where the first member (1) and the second member (2) are, by inserting the shaft portion (20) into the through hole (23), pivoting so that they oscillate relatively, and a gear portion (4) is formed in 1/3 to 1/4 of the peripheral edge portion of the disc body (16) and two protruding portions (28) are formed at the beginning and end of the gear portion (4), a floating wedge member (6), of which one side is a serrated face (7) coupled to the gear portion (4) and another face is a contact face (9) for contacting a wedge face (8) formed on the side of the first member (1), where a relative oscillation of the first member (1) and the second member (2) in a first direction (B) is restricted in a coupled state where the contact face (9) contacts the wedge face (8) and the serrated face (7) and the gear portion (4) are coupled, where the floating wedge member (6) is movable to separate from the gear portion (4) in a withdrawn state by swinging the first member (1) and the second member (2) relatively in a second direction (A) until a lock release position (P0) to release the engagement of the gear portion (4) and the toothed face (7), and where the first member (1) and the second member (2) oscillate relatively in the first direction (B) in the withdrawal state; where the adjustable angle joint further comprises a recovery means (10), which recovers the floating wedge member (6) from the withdrawal state to the state coupled with the gear portion (4) by a return action (M2) of a small predetermined angle (0) in the second direction (A) during the free swing (M1) where, during the free swing (M1), the first member (1) and the second member (2) oscillate relatively in the first direction (B) from the lock release position (P0), characterized by of the disc body (16) protruding lower circular projections (24) from the left and right sides thereof, and is maintained to rotate freely by means of a pair of facing plate portions (13) with the lower circular projections (24) inserted in the circular support holes (21) of the facing plate portions (13), arranged mutually parallel and fixed to a coupling portion (17) of the first member (1). 2. The adjustable angle joint described in claim 1, wherein: the first member (1) is provided with the pair of facing plate portions (13) to hold the disk body (16); the recovery medium (10) is provided with a ring member (12) that rotates towards the facing plate portion (13) within a range of the small predetermined angle (0); an oscillation member (11), whose end (11a) is interconnectedly coupled to the ring member (12) and is oscillating with an intermediate portion as a support point within a predetermined angular range and another end (11b) is arranged to be pressed against the floating wedge member (6) in the withdrawal state, and a pressure fixing friction member (15), which has a non-circular fixing hole (19) to which the shaft portion (20) and an elastic portion (14) that rotates in a unified manner with the portion of shaft (20) and which elastically pushes in an axial internal direction and sliding on the ring member (12); Y In the withdrawal state, the floating wedge member (6) maintains the withdrawal state during the free oscillation (M1) of the first member (1) and the second member (2) in the first direction (B), the member of Ring (12) rotates the small predetermined angle (6) by frictional force with the elastic portion (14) by the return action (M2) in the second direction, and the oscillating member (11) moves the floating wedge member (6) to couple the gear portion (4) and the toothed face (7).