ES2909800T3 - Angular and sofa adjustment tool - Google Patents

Abstract

Angular adjustment tool (3) equipped with a first member (1) and a second member (2) having a gear means (4) and an oscillating floating wedge member (6) having a toothed surface (7) that can be engaged with said gear means (4), and with respect to an angular adjustment tool with relative oscillating movement restricted to the opposite direction (B) of the relative oscillating movement allowed in a direction (A) of said second member (2 ) with respect to said first member (1), comprising free fastening means (10) that allow the fastening of the toothed surface (7) of said floating wedge member (6) to be freely maintained without contact with said means (4) of engagement during oscillating movement in said direction (A), wherein the non-contacting free holding means (10, 80) provides a wedge drive member (11, 81) which rotates along over a small angular interval by means of the frictional forces accompanying the rotation with the second member (2, 60), and configures a free state, without contact, in which the wedge drive member (11, 81) supports the toothed surface (7, 72) of the floating wedge member (6, 70) in a free state, without contact, with said engagement means (4, 66), by oscillating movement in a direction (A) of the second member (2, 60) with respect to the first member (1, 50), in addition to an engaged state of the toothed surface (7, 72) of the floating wedge member (6, 70) with the gear means (4, 66) and the surface (8, 58a) of wedge formed on the first side of the member (1, 50), by means of the oscillating movement in the opposite direction (B), in which the relative oscillating movement in the opposite direction (B) of the second member (2, 60) relative to the first member (1, 50) is constrained by the wedge effect of the floating wedge member (6, 70).

Description

DESCRIPTION

Angular and sofa setting tool

Field of invention:

The present invention relates to an angular adjustment tool according to the preamble of claim 1 and to a sofa according to the preamble of claim 8.

Prior art technology

Conventionally, there have been proposals for an angular adjustment tool that can oscillate a first member/a second member relative to one direction, and adjust the relative oscillation of the first member/second member in another direction by means of a wedge effect. of a floating wedge member (see patent reference 1).

Prior Art References

Patent References

First of all, as prior art, reference is made to Japanese Patent No. 5514753. Furthermore, reference is made to JP 2010008682 A. The angular adjustment tool known from this reference has a second member having a surface protruding to force the wedge member out of a mesh contact. But the wedge member remains immobile under the force of a spring. After further movement, a ratcheting noise cannot be avoided.

Furthermore, reference is made to EP 2805 642 A1 and EP 2253246 A1, from which only angular adjustment tools are known which function as indicated in relation to JP '682 A.

Patent Summary

Problems to be solved by the invention

Relative to the angle adjustment tools noted above, the floating wedge member is pressed all the time on an engagement member by biasing the spring-back force of a spring-back leaf spring member. For this reason, when the second member is rotated in one direction relative to the first member, and the floating wedge member slides on the gear means, the toothed surface of the floating wedge means collides with the gear means, generating a metallic noise.

For example, the sofa shown in Figure 10 of the present patent application has the headrest means 48 fixed to the upper edge of the backrest means 46 by means of an angular adjustment tool 3 . Next, on the occasion of adjusting the inclined angle of the headrest means 48, when there is a metallic noise generated from the angle adjustment tool in the ear of the person sitting on the seat means 47, there is a disadvantage in the sense of which is annoying to the ears.

Furthermore, the same applies even in the case of chairs, beds (of folding type) and the like. When the back or headrest means or tilted base means and the like are erected upright/subjected to a tilt, or the tilt angle of a tilted bed means is adjusted, when there is a generation of a metallic noise annoying since the angular adjustment tool axially supporting the swinging movement thereof, there is also a problem in that it is annoying to the ears.

Summary of the invention

In this sense, the present invention has as its object the provision of an angular adjustment tool that reduces the metallic noise generated associated with the oscillating movement.

Furthermore, another object of the invention is the provision of a sofa which performs an angular adjustment of the headrest means without generating a screeching sound to the ears of people sitting on it.

The object of the invention is achieved by the teaching of claim 1, which focuses on the features, which provide free, non-contact clamping means, which allow the clamping of the toothed surface of said floating wedge member to be held freely and without contact with said engagement means during oscillating motion in said direction (A), wherein the non-contact free holding means provides a wedge drive member which rotates over a small range angle by means of the frictional forces accompanying rotation with the second member, and configures a non-contact, free state in which the wedge drive member maintains the toothed surface of the floating wedge member in a free state, without contact, of said gear means, by means of oscillating movement in the direction of the second member with respect to the first member, in addition to a state of meshing of the toothed surface of the floating wedge member with the gear means and the wedge surface formed on the side of the first member, by means of the oscillating movement in the opposite direction, wherein the relative swinging motion in the opposite direction of the second member with respect to the first member is restricted by the wedge effect of the floating wedge member.

With respect to an angular adjustment tool of the present invention equipped with a first member, and a second member having a reciprocating axially supported engagement means, and a wedge member having a toothed surface engageable with said means gear, and said second member is oscillatable in one direction (A) relative to and with respect to said first member, and its relative oscillating movement in the other direction (B) is restricted.

Non-contact free holding means are provided which hold said toothed surface of said floating wedge member and said gear member freely, non-contact, during oscillating movement in said first direction (A).

Furthermore, said non-contact, free clamping means provides a wedge drive member which rotates through a small angular range by means of the frictional force accompanying rotation with said second member, and, by means of movement of oscillation in said direction (A) of said second member with respect to said first member, said wedge drive member causes said toothed surface of said floating wedge member not to contact said engagement means in a free, non-contacting state , and further, a configuration by oscillating at said small angular degree in said other direction (B), said floating wedge member is pressed between the wedge surface formed on said first side of the member, and said engagement means, in a configuration with the meshed state of said toothed surface of said floating wedge member with said engagement means, wherein the relative oscillation of said second member in said other direction (B) with respect to said first member is restrained by means of the wedge action of said floating wedge member.

Said non-contact free clamping means then provides a wedge drive member which rotates through a small angular range by means of frictional forces when rotating with said second member, and by oscillating said second member in said first direction (A) with respect to said first member, said wedge drive member maintaining said toothed surface of said floating wedge member in a free, non-contact, free and non-contact state with respect to said engagement means, further , a configuration in which by means of said oscillation through a small angular interval in said other direction (B), said floating wedge member is pushed between the wedge surface formed on said side of the first member, and said means gear, in the meshed state of said toothed surface of said floating wedge member and said engagement means, and by means of the wedge effect of said wedge member floating, relative oscillation of said second member in said other direction (B) with respect to said first member may be restricted.

Furthermore, said wedge drive member may have sliding means that generate said frictional force accompanying sliding rotation thereof on said second member.

Furthermore, the sofa of the present invention in which the headrest means is fixed by said angular adjustment tool on the upper edge of the backrest means, and allows the gradual oscillation of said headrest means in the vertical direction (A) and restrict the rocking motion in the tilt direction (B).

The configuration is one in which said angular adjustment tool is equipped with a gear means and a small gear member for use in adjustment having a toothed surface allowing engagement with said gear means, and where said gear means of headrests oscillate in said vertical direction (A), not only is said gearing means of said angular adjustment tool and said toothed surface caused to be in a free, non-contacting state, furthermore, said gearing means of said angular adjustment tool and said toothed surface are in an engaged state due to the retracting action at a specific small angle in the inclined direction (B), in a configuration to maintain the posture of said headrest.

Effects of the invention

By means of the angular adjustment tool of the present invention, by means of the engagement of the toothed surface of the floating wedge member with the engagement means, it allows the desired static angle of the first member/second member to be maintained securely without slippage. Then, when an angular adjustment of the first member/second member is made, the free, non-contact state is enabled, which keeps the toothed surface of the floating wedge member free and out of contact with the gearing means, and allows silent oscillation.

In other words, prevention of generation of a metallic noise generated by the impact of the floating wedge member on the gear means is enabled.

Furthermore, by the sofa of the present invention, prevention of generation of annoying noise to the ears of the person sitting on the seat means is enabled, and quiet swinging movement of the headrest means is enabled.

Brief description of the drawings

Figure 1: Cross-sectional side surface drawing depicting the first embodiment of the angular adjustment tool of the present invention.

Figure 2: Cross-sectional side surface drawing depicting the first embodiment of the angular adjustment tool of the present invention.

Figure 3: Cross-sectional side surface drawing depicting the first embodiment of the angular adjustment tool of the present invention.

Figure 4: Cross-sectional side surface drawing depicting the first embodiment of the angular adjustment tool of the present invention.

Figure 5: Cross-sectional side surface drawing depicting the first embodiment of the angular adjustment tool of the present invention.

Figure 6: Cross-sectional side surface drawing depicting the first embodiment of the angular adjustment tool of the present invention.

Figure 7: Exploded side surface drawing of the wedge drive member.

Figure 8: Drawing of a lateral surface in cross section in exploded view of the main parts. Figure 9: Drawing of a cross section at C - C in Figure 7.

Figure 10: Perspective drawing representing the sofa of the present invention.

Figure 11: Exploded side surface drawing of another wedge drive member.

Figure 12: Exploded perspective view when the main parts of the wedge driving member are viewed from the inner surface side.

Figure 13: Drawing of a cross section at D - D in Figure 11.

Figure 14: Perspective drawing representing the second embodiment of the angular adjustment tool of the present invention.

Figure 15: Exploded perspective view of the second embodiment.

Figure 16: Exploded perspective view of the second embodiment as seen from a different angle.

Figure 17: Perspective view of the opposite surface wall means of the second embodiment.

Figure 18: Perspective view showing the floating wedge member of the second embodiment.

Figure 19: Perspective view showing the wedge driving member of the second embodiment. Figure 20: Elevation view showing the wedge drive member of the second embodiment.

Figure 21: Perspective view showing another embodiment of the wedge drive member.

Figure 22: Elevation view showing another embodiment of the wedge drive member.

Figure 23: Partially exploded perspective view of the second embodiment in the cover removed state.

Figure 24: Partially exploded perspective view showing the state in which the opposite surface wall is removed in Figure 23.

Figure 25: Elevation view representing the assembled state of all the constituent parts.

Figure 26: Vertical cross-sectional drawing of the second embodiment.

Figure 27: Partial horizontal cross-sectional drawing of the second embodiment.

Fig. 28: Drawing of a side surface in cross section for explaining the method of operation of the second embodiment.

Figure 29: Drawing of a side surface in cross section to explain the mode of operation as a continuation of Figure 28.

Figure 30: Drawing of a side surface in cross section to explain the method of operation as a continuation of Figure 29.

Figure 31: Drawing of a side surface in cross section to explain the method of operation as a continuation of Figure 30.

Figure 32: Drawing of a side surface in cross section to explain the mode of operation as a continuation of Figure 31.

Best mode for carrying out the invention.

In the following, the present invention is explained in detail based on figures showing the embodiments.

As illustrated in Figure 1, the angle adjustment tool 3 of this embodiment has the first member 1 and the second member 2 having the engaging means 4, and the floating wedge member 6 having a toothed surface 7 that allows to engage with the gear means 4. Next, the first member 1 and the second member 2 are assembled in a manner that allows oscillation about the center of an axis L by means of the pivotally connected axis 24 .

The angular adjustment tool 3 of the present invention can be adapted to sofas, chairs, beds (lift style) and the like. More specifically, it can accommodate freely swinging pivot means of tilt/lift headrest means, backrest means, tiltable bed means and the like. When reference is made to a sofa earlier or later in this text, this means that it can also be any of the other devices indicated, such as a chair, a bed, etc., or even the freely oscillating pivot means of .. ., as indicated above.

Wedge member 6 has surface 7 on one side surface and has contact surface 9 on the other side surface. Said contact surface 9 preferably contacts a wedge surface preferably formed on the side of the first member 1. As illustrated in Figure 1, the floating wedge member 6 not only has a contact surface 9 that contacts, for example , with the wedge surface 8, in the engaged state also engage with the toothed surface 7 and the engagement means 4, so as to prevent the second member 2 from having an oscillating movement in the direction of the arrow B in the figure with respect to the first member 1.

The first member 1 preferably has the fixing means 18 integrated, for example with a pair of mutually opposite wall means 17 and 17. Not only is the pivotally connected shaft 24 inserted through the mutually opposite wall means 17 and 17, but also a wedge-shaped window means 5 is preferably formed. The wedge-shaped window means 5 preferably has an arcuate wedge surface 8, and preferably a shelter space 15 for storing the floating wedge member 6 in the separated state from the engagement means 4. The wedge-shaped window means 5 is formed so that the wedge surface 8 gradually approaches the engagement means 4. For this reason, a clockwise contracting wedge-shaped gap is formed in the side surface view of Figure 1 by means of the wedge surface 8 and the outer peripheral toothed surface of the gear means 4, and the floating wedge member 6 is disposed in a freely movable manner in this wedge-shaped space.

The second member 2 preferably integrates the two panels of the gear panel means 45 and 45 with the fixing means 19. Next, the mutually parallel gear means 4 and 4 are inserted between the two opposite walls of the first member 1. They are formed so that they [rotate], for example, in an angular range of 100° ~ 120° around the center angle at the arc-shaped outer peripheral edge means of the gear panel means 45 and 45. Next, said toothed surface 7 and gear means 4 not only engage at two locations in the left-right horizontal direction, all the teeth of toothed surface 7 simultaneously mesh with gear means 4. The protrusion means 14 and 14 are arranged in the initial terminal means and the final terminal means of the gear means 4. The pivotally connected shaft 24 is inserted into the gear panel means 45 and 45. Now, the toothed surface 7 of the floating wedge member 6 may have 13 ~ 20 teeth formed thereon. Furthermore, the gear means 4 may have 40 or more teeth, more preferably 45 ~ 65 teeth formed therein. In this way, the angular adjustment means have 40 or more stages enabled therein.

As illustrated in Figure 2, the oscillating movement of the second member 2 in the (relative) direction of arrow A in the figure is enabled with respect to the first member 1. During the oscillating movement of the second member 2 in that direction A, the floating wedge member 6 is provided with free, non-contact holding means 10 which keep it non-contact with the engagement means 4.

The contactless, free clamping means 10 provides the wedge drive member 11 (operating plate) rotated in a small angular range about the axial center L, by means of the frictional force accompanied by the rotation of the second member 2.

The wedge drive member 11 has a hole means 21 through which the pivotally connected shaft 24 is inserted. In the state that the wedge driving member 11 is inserted between the gear panel means 45 and 45, the first member 1/second member 2 are pivotally integrated through the pivotally connected shaft 24.

As illustrated in Fig. 7, the opening window means 20 which maintains the wedge member 6 floating in a freely movable manner is formed in the wedge driving member 11. The opening window means 20 has an arcuate surface 22 on the outer side, as seen from the center point (axial center L) of the hole means 21, and preferably has a conical surface 23 forming an acute angle O , see, for example, Fig. 7, with a terminal edge of the surface 22 arcuate. The recessed means 25 is preferably formed on the outer side surface of the wedge drive member 11.

In Figures 1~6, a spring means, preferably a leaf spring member 16, between the first member 1 and the wedge drive member 11. When a leaf spring means or member is mentioned below, it can always be replaced by spring means. The leaf spring member 16 has a protrusion means 13 at the intermediate part in the long direction thereof, and both terminal means of the long direction are supported by the first member 1. The leaf spring member 16 is so arranged. such that it has the protruding means 13 opposite the recessed means 25 of the wedge drive member 11. For this purpose, as illustrated in Figures 1 and 2, the protruding means 13 slides continuously in the recessed means 25 to allow the wedge drive member 11 to be rotated, driven by means of the driving forces. friction on the second member 2. On the other hand, as illustrated in Figures 4 and 5, in the state where the protrusion means 13 is separated from the recessed means 25 and is pressed against the outer side surface of the member 11, the wedge driving member 11 is locked from being rotated by dragging frictional forces from the second member 2.

As illustrated in Figures 7 and 9, the wedge drive member 11 has frictional contact means 12 which generates a dragging frictional force due to the friction of the second member 2.

The wedge drive member 11 preferably consists of two side wall means 27 and 27 wherein said side wall means 27 and 27 are preferably further connected by means of connecting means 28 to a pair of connecting means 27 and 27. side wall. The friction contact means 12 forms, for example, a protruding shape (bulge shape) on the outer side of one or both of the side wall means 27 and 27 of the wedge driving member 11. Frictional contact means 12 preferably forms a tab-shaped cutout 29, for example, in an inverted C-shape from sidewall means 27 and 27, and this tab shape 29 is preferably formed so as to curve up in a leaf spring fashion (Figure 9). Alternatively, a pair of preferably parallel slits may be formed, and the inner side of the slits may have a triangular mound-shaped protrusion thereon (not shown in the figures). When the multiple friction contact means 12 are pressed against the inner surface of the gear panel means 45 and 45 of the second member 2 generating a dragging frictional force, the wedge driving member 11 is rotated together with the second member 2 by means of this dragging frictional force.

As illustrated in Figures 11~13, the outer annular wave-shaped means 32 may provide (multiple) intermittent arc-shaped grooves remaining on the peripheral edge of the holding means 21 which may be provided on the operating member 11 wedge shaped.

As illustrated in Figures 12 and 13, the outer annular wave-shaped means 32 can be cut by means of the (multiple) arc-shaped grooves 35 remaining intermittently in the remaining connecting means 30 of the connecting means 27 . side wall, and multiple protrusions 33 may be formed by, for example, bending the arcuate slits towards the inner side. The inner annular wave-shaped means 31 can be cut by means of the intermittent (multiple) arcuate groove 39 remaining in the connection means 38 of the protrusion means 33, and multiple friction contact means 12 are formed in shapes that they protrude outwardly swollen into projections on the inner side of the slits 39. The inner annular wave-shaped means 31 and the outer annular wave-shaped means 32 can be elastically deformed. As a result, the elastic deformation of the friction contact means 12 generates an appropriate drag friction force by being brought into elastically pressurized contact with the inner surface of the gear panel means 45 and 45 of the second member 2. in this way, the wedge drive member 11 rotates together with the second member 2 by means of this dragging frictional force.

Next, the operating method (effects) of the above-described angle adjustment tool of the present invention is explained.

As illustrated in Figures 1 and 2, the folding operation M ⁰ is performed by swinging the second member 2 in the direction of arrow A relative to the first member 1. As a result, the wedge drive member 11 rotates jointly (counterclockwise in the figure) with the second member 2 by means of the dragging frictional force. In this way, the floating wedge member 6 is moved to the upper end surface of the tapered surface 23 of the wedge drive member 11.

As a result, while the floating wedge member 6 is displaced towards the lower direction in the wedge-shaped window means 5 (the wedge shape), and oscillates in contact with the inclined induction surface 26 of the window means 5 wedge-shaped, and slightly shifts in the direction of separation from the gear means 4. The floating wedge member 6 is arranged to rest on the wedge surface 8 by the lower means of the wedge-shaped window means 5 (the wedge-shaped gap). As a result, a minute gap is generated between the toothed surface 7 and the gear means 4, causing a non-contact free state (see Figure 8). In the free, non-contact state, the floating wedge member 6 and the gear means 4 are not in contact, and the second member 2 quietly oscillates in the direction A, without generating any sound. The floating wedge member 6 is held by means of the tapered surface 23 of the wedge drive member 11 and the induction gradient surface 26 of the wedge shaped window means 5 and the wedge surface 8 and is preferably held in a substantially fan-shaped space. As long as there is a generation of the dragging frictional force of the second member 2 on the wedge driving member 11, the wedge driving member 6 is pressed from the upper side by the wedge driving member 11, and not meshes with gear means 4.

In other words, while the folding operation M ⁰ is performed, the floating wedge member 6 is held without causing a metallic noise, and the toothed surface 7 of the floating wedge member 6 and the gear means 4 are held in the state. free, no contact.

Next, as illustrated in Figure 3, during the folding operation M ⁰ , with the return operation M ¹ causing an oscillating movement in the direction of the arrow B of the second member 2 with respect to the first member 1, the wedge driving member 11 is rotated together with the second member 2 by means of the dragging frictional force (clockwise in the figure). The wedge drive member 11 pushes up the bottom end surface from the bottom of the floating wedge member 6 and the floating wedge member 6 is moved to the top of the wedge-shaped window means 5 (space with wedge-shaped), causing the meshed state of the toothed surface 7 of the floating wedge member 6 and the gear means 4. The floating wedge member 6 is progressively pushed into the narrowing space between the wedge surface 8 and the engagement means 4, restricting the oscillating movement of the second member 2 in the direction B by means of the wedge effect, maintaining the inclined angle of the first member 1 and the second member 2 (keeping them in a fixed state).

In the engaged state depicted in Figure 3, by the engagement of the toothed surface 7 of the floating wedge member 6 with the engagement means 4, a secure clamping and fixing of the inclined angle of the first member 1 on the second member is enabled. 2 without slippage.

Next, as illustrated in Fig. 4, when the second member 2 is further swung in the direction A by means of the folding operation M ⁰ , the final folded position P ⁰ in the vertical state is enabled. By these means, while the vertical means 14 is pressed against the upper end surface of the floating wedge member 6, the floating wedge member 6 is displaced into the shelter space 15 of the lower means of the wedge-shaped window means 5 (the wedge-shaped space). On this occasion, the wedge driving member 11 is pressed against the bottom end surface of the floating wedge member 6, and is further rotated from the non-contact state of Fig. 2 (counterclockwise in the figure). This state is called as retired state. In the retracted state, the floating wedge member 6 is stored in the shelter space 15, in addition to the rotation of the wedge drive member 11 being bound by means of the protrusion means 13 of the leaf spring member 16. Therefore, even if the second member 2 is swung in the direction B, the wedge driving member 11 does not rotate together with it due to the binding of the spring member 16. As a result, the engagement release state of the gear means 4 and the tooth surface 7 is maintained, and the second member 2 can be swung in the direction B relative to the first member 1.

Next, as illustrated in Fig. 5, when the second member 2 is subjected to a swinging movement in the direction B by means of the unfolding operation M ² , and immediately before assuming the final unfolded position P ¹ ( see Figure 6), the second member 2 becomes linear with respect to the first member 1, the protrusion means 14 of the other direction contacts the bottom end surface of the floating wedge member 6.

Next, as illustrated in Figures 5 and 6, when the second member 2 is slightly and strongly pressed in the direction B, the protrusion means 14 is pressed against the bottom end surface of the floating wedge member 6, and the floating wedge member 6 is moved so as to be pushed in the upper direction from the shelter space 15 . On this occasion, along with the displacement of the floating wedge member 6, due to the upper end surface of the floating wedge member 6 being pushed upward toward the tapered surface 23 of the wedge driving member 11, and the driving member 11 wedge drive is rotated clockwise in the diagram. The wedge drive member 11 is released from the bound state by means of the leaf spring member 16 and rotates together with the second member 2 as a result of the frictional force, displacing the floating wedge member 6 to the top of the legs. wedge-shaped window means 5 (wedge-shaped gap), to a state in which the toothed surface 7 of the floating wedge member 6 and the gear means 4 are in mesh.

The angular adjustment tool described above, and as illustrated in Figure 10, fixes the headrest means 48 by means of the angular adjustment tool 3 on the upper edge of the backrest means 46, allowing the progressive oscillation of the headrests. headrest means 48 towards the vertical direction A and adjusting the oscillation thereof towards the inclined direction B in a manner suitable for adaptation to a sofa.

As illustrated in Figure 8, the angular adjustment tool 3 is equipped with the gear means 34, and the small gear means 34 (floating wedge member 6) for use in adjustment having the toothed surface 37 that allows meshing with the gear means 34.

In Fig. 10, when the headrest means 48 is swung in the vertical direction A, the engagement means 34 of the angular adjustment tool 3 and the toothed surface 37 are held in a non-contact, free state. Then, the engagement state of the gearing means 34 of the angle adjusting tool 3 with the toothed surface 37 is enabled by a back operation of a specific small angle to the inclined direction B, in a configuration to hold the posture. of the headrest means 48.

The present invention may now be subjected to design modifications, for example by eliminating the wedge-shaped window means 5 and, for example, using instead a panel-shaped member and the like which presses the contact surface 9 of the floating wedge member 6.

Furthermore, the wedge driving member 11 need not have the opening window means 20, and may be shaped to have a pair of contact surfaces above and below pressing the upper end surface/lower end surface of the member. 6 floating wedge, and may employ a panel-shaped member and the like, so that the design or dimensional relationships can be freely modified.

As described above, the angular adjustment tool of the present invention provides the first member 1 and the second member 2 having the engagement means 4, and the floating wedge member 6 having the tooth surface 7 fixedly fixed. oscillating and pivoting that allows the engagement with the gear means 4, allowing the relative oscillation movement of the second member 2 in a first direction A with respect to the first member 1 and with respect to the angular adjustment tool that restricts the oscillation movement relative in the other direction B. Next is the provision of the non-contact, free clamping means 10 which keeps the toothed surface 7 of the floating wedge member 6 and the engagement means 4 free from each other, without contact, during oscillating movement in a direction A. Due to this, the meshing of the toothed surface 7 of the floating wedge member 6 with the gear means 4 allows the est Stationary mounting of the first member 1/second member 2 at the desired angle and safely and without slipping. Furthermore, during the angular adjustment of the first member 1/second member 2, the toothed surface 7 of the floating wedge member 6 and the engagement means 4 can be released to the non-contact state and can be held in a free, non-contact state, which allows a silent oscillation movement. In other words, prevention of the generation of so-called metallic noise generated by the collision of the floating wedge member 6 with the gear means 4 is enabled.

Furthermore, the non-contact, free clamping means 10 provides the wedge drive member 11 which is rotated through a small angular range by means of the dragging frictional force with the second member 2, and by means of the oscillating movement of the second member 2. first member 1 into second member 2 in direction A, wedge drive member 11 releases toothed surface 7 of floating wedge member 6 from engagement means 4 to allow a free, non-contact state. Furthermore, due to the thrust of the floating wedge member 6 between the wedge surface 8 formed on one side of the first member 1 and the gear means 4, resulting from the oscillating movement in a small angular interval in the other direction B, it is allowed the state of engagement of the toothed surface 7 of the floating wedge member 6 with the engagement means 4, in a configuration that restricts the relative oscillating movement of the second member 2 in the other direction B relative to the first member 1 by means of the wedge action of the floating wedge member 6. As a result, by means of the engagement of the toothed surface 7 of the floating wedge member 6 with the engagement means 4, and the maintenance of the desired angle of posture of the first member 1/second member 2 is enabled safely and without slipping . Furthermore, while the second member 2 is swinging in the first direction A, the toothed surface 7 of the floating wedge member 6 and the gear means 4 are released to the non-contact state and can be securely held in the free, non-contact state. .

Furthermore, because the wedge drive member 11 has the friction contact means 12 which generates a dragging frictional force by rubbing against the second member 2, the wedge drive member 11 The wedge securely rotates together with the second member 2, allowing the toothed surface 7 of the floating wedge member 6 and the engagement means 4 to be switched from the non-contact, free state to the engaged state. The first member 1 and the second member 2 are allowed to oscillate with an appropriate frictional resistance force.

In addition, the sofa of the present invention fixes the headrest 48 by means of the angular adjustment tool 3 to the upper edge of the backrest means 46, and in a sofa allowing the oscillation of the headrest means 48 in the vertical direction A and restricts oscillation in direction B. Then, the angular adjustment tool 3 is equipped with the gear means 34, and the small gear member 36 for use in adjustment having the toothed surface 37 that allows the mesh with the gear means 34, and during the swinging movement of the headrest means 48 in the vertical direction A, the gear means 34 of the angular adjustment tool 3 and the toothed surface 37 are kept in a free state, without contact . Furthermore, a state of meshing of the gearing means 34 of the angular adjustment tool 3 with the toothed surface 37 is enabled, by a small specific angular return operation of the headrest in the inclined direction B, and the configuration allows maintenance of the posture of the headrest means 48. Therefore, prevention of generation of unpleasant noise in the ears during swinging movement of the head restraint means 48 in the vertical direction A is enabled, and silent swinging movement of the head restraint means 48 is enabled.

The second embodiment of the angular adjustment tool 3 of the present invention, as shown in Figures 14 to Figure 32, is equipped with the first member 50, the second member 60, the oscillating wedge member 70 and the means 180 non-contact free clamping, and the first and second covers 90 and 92, and can be oscillated as an integrated unit centered on the axial center L.

As illustrated in Figures 15 and 16, the first member 1 described above keeps the fixing means 51 and one end of the fixing means 51 described above fastened in an interleaved manner, in addition to providing a pair of fixing means 52 and 53. opposite wall parallel to each other. Next, the facing and opposite wall means 52 and 53 are firmly fixed to said fixing means 51 by means of rivets 54 and 54.

However, the fastening method is not limited to the rivet fastening described above and, for example, can be fixed using bolts and nuts or by welding. In addition, either one of the facing and opposite wall means 52 and 53 or the fixing means 51 may be machined to have one press-fit boss means, and the other may be provided with an installation hole for integration of the wall. same.

The opposite wall means 52 and 53 described above are formed in mirror symmetry with respect to each other, and not only the axis hole 56 is provided in one, but also the protruding position adjusting pin 57 is provided on the other. inner facing surface of the other (Figure 17). Opposite facing wall means 52 and 53 then provide wedge-shaped window means 58 between the shaft hole 56 described above and the position adjusting pin 57. Now, the position adjusting pin 57 described above may be formed by machining to protrude, or it may be formed by fixing a separate metal pin.

As illustrated in Figure 27, the position adjusting pin 57 described above is arranged to be positioned respectively at the same axial center of the pair of opposing wall means 52 and 53. Then, the position adjusting pin 57 described above prevents vibration of the wedge driving member 81 described above by guiding the leaf spring member 83 of the wedge driving member 81 described later. Furthermore, position adjustment of the wedge drive member 81 is enabled by interlocking with the leaf spring member 83 described above.

The wedge-shaped window means 58 described above, as illustrated in Figure 17, has an arcuate wedge-shaped surface 58a. Then, the wedge surface 58a described above is formed so as to gradually approach the engagement means 66 of the second member 60 described later (FIG. 25). In addition, the wedge-shaped window means 58 described above has a retracting space 58b for the purpose of storing the floating wedge member 70 in a separate state from the engagement means 66. Furthermore, the wedge-shaped window means 58 described above forms the inclined induction surface 58c in continuity with the retraction space 58b described above.

Furthermore, as illustrated in Fig. 25, a wedge-shaped shrinkage gap is formed along the clockwise direction by means of an outer peripheral toothed surface of the gear means 66 and the surface 58a wedge The floating wedge member 70 described below is freely movable and can be assembled in the wedge-shaped space described above.

The second member 60 described above, as illustrated in Figures 15 and 16, provides the fixing means 61 and a pair of gear plate means 62 and 63 which are parallel and opposite each other sandwiched by one end of the means 61 fixation described above. Next, plate means 62 and 63 gear are fixed and secured to the fixing means 61 described above by means of rivets 64 and 64. However, the fixing method is not limited to the fixing method described above, for example, and they can be fixed by bolts and nuts or by welding. Further, a protruding mounting protrusion is provided on either one of the fixing means 61 or the gear plate means 62 and 63, and the mounting hole may be provided on the other for integration thereof.

The gear plate means 62 and 63 described above are formed in mirror symmetry with respect to one another, and each have axial holes 65 and 65 for the purposes of inserting the pivot shaft 94 therethrough. Further, the gear plate means 62 and 63 described above form the gear means 66 in the range of 100° to 120° of the central angle in an arc-shaped outer peripheral edge means at an end side thereof. Furthermore, protrusion means 67 for use in exerting downward pressure is provided in the leading edge means of the engagement means 66 described above. Further, protrusion means 68 for use in exerting upward pressure is provided on the end terminal means of the gear means 66 described above.

Next, the two gear plate means 62 and 63 of the second member 60 are inserted between the opposite wall means 52 and 53 of the first member 50 described above, and are swingably connected via the pivot shaft 94 described further. ahead.

In this embodiment, it is disclosed that each of the first and second members 50 and 60 is formed of three constituent part plates, but is not necessarily limited thereto. For example, the first and second members 50 and 60 described above may superimpose two mirror-symmetrically formed constituent parts and may integrate the same by welding, riveting, bolting and nut fixing, or by the use of fit protrusions thereon.

The floating wedge member 70 described above, as illustrated in Figure 18, has contact surface 71 on one side of the surface thereof, and has serrated surface 72 on the other side of surface thereof. The contact surface 71 described above, as illustrated in Figure 28, contacts the wedge surface 58a formed on the side of the first member 50. Then, when the floating wedge member 70 contacts that contact surface 71 with the wedge surface 58a, in addition to when the toothed surface 72 and the gear means 66 mesh, the oscillating movement of the second member 60 with respect to the first member 50 in the direction of arrow B in the figure is inhibited by the wedge effect.

Now, as illustrated in Figure 24, there are multiple, preferably five or six, teeth formed on the toothed surface 72 of the floating wedge member 70. This toothed surface 72 and gearing means 66 mesh at two locations in the left and right horizontal direction, in addition to preferably simultaneously meshing all the teeth of the toothed surface 72 and gearing means 66.

Further, for example, 13 to 20 teeth are formed on the tooth surface 72 of the floating wedge member 70, and more than 40 teeth, more preferably between 45 and 65 teeth, may be formed on the gear means 66. In this way, the number of angular adjustment stages is enabled with 40 or more stages.

The non-contact, free clamping means 80 described above, as illustrated in Figures 15 and 16, provides the wedge drive member (operating plate) 81 rotated in a small angular range about the axial center L by means of the drag friction force with the second member 60.

The wedge driving member 81 described above, as illustrated in Figures 19 and 20, is struck by press machining from a sheet metal plate, and is formed by bending. Next, the wedge driving member 81 has opening window means 82 provided in the center thereof, and a pair of leaf spring members 83 and 83 provided on one side of said opening window means 82, and the axial hole 84 provided on the other side of said opening window means 82. Furthermore, said wedge driving member 81 is swingably supported in the inserted state between the gear plate means 62 and 63, together with the second member 60.

The opening window means 82 described above is adapted to keep the floating wedge member 70 freely movable, and has an arcuate surface 82a on the outer side thereof when viewed from the center point (the center L). The arcuate surface 82a described above has a conical surface 82b formed at an acute angle O at a terminal edge thereof. Furthermore, the arcuate surface 82a described above provides a stepped means 82c at the other terminal edge thereof.

The leaf spring member 83 described above provides a vertical slit along the other side edge means of the wedge drive member 81 described above, and forms substantially right-angled cutouts that fold upward. As a result, both of the long direction terminal means of the leaf spring members 83 are connected to the wedge driving member 81.

Furthermore, the leaf spring members 83 described above have the protrusion means 83a protruding outwardly from the middle of the long direction thereof. So, the members 83 The leaf springs described above form a recessed means 83b which serves as a tie to the basal means on one side of the boss means 83a described above. By locking the recessed means 83b of the position adjusting pin 57 for ligation purposes, the position of the wedge drive member 81 is restricted from being rotated by the dragging frictional forces of the second member 60. In addition , the leaf spring members 83 described above form the recessed means 83c for use in guiding in the other side of the direction towards the boss means 83a described above. When the locating pin 57 is located in the recessed means 83c for use in guiding, as described above, while the leaf spring members 83 are being guided to the locating pin 57 described above, wedge drive member 81 is rotated together with second member 60 by means of dragging frictional forces.

Now, the position adjusting pin 57 described above can be guided into the recessed means 83c for use in the guiding described above, and need not normally be in sliding contact.

Furthermore, the leaf spring members 83 described above need not be provided as a pair of springs, and there may be only one on one side.

The shaft hole 84 described above serves the purpose of inserting the pivot shaft 94 therethrough, which is described below. Next, an annular wave-shaped means 85 is provided in the peripheral edge means of said axial hole 84, as the sliding contact means. The annular waveform media 85 has multiple raised media 85a. Said raised means 85a provide (multiple) non-continuous arch-shaped grooves 85c, which leave the remaining connection means 85b in the peripheral edge means of the axial hole 84, in addition, the inner lateral parts of said arc-shaped grooves 85c arc are formed in a curve in the direction of the thickness of the plate.

Then, because said wave-shaped annular means 85 is movable and elastically deformable, the raised means 85 elastically and under pressure comes into contact with the inner direction surface of the year plate means 62 and 63 of the second. member 60. As a result, an optimum drag friction force is generated between the wedge driving member 81 and the second member 60. As a result, the wedge driving member 81 and the second member 60 are rotated in unison by means of of said dragging frictional forces.

Now, as illustrated in Figures 21 and 22, the wedge drive member 81 described above may provide an annular sliding contact means 86 and the inner peripheral edge means of said annular means 85 wave-shaped. By arranging the annular-shaped sliding contact means 86, the wave-shaped annular means 85 described above is strengthened, which not only improves its longevity, but has the benefit that the sliding action is smoother and more stable. steady.

Furthermore, the wedge driving member 81 is not limited to the embodiments described above, and by providing punch holes and slits in a sheet of a metal plate, the opening window means 82 and the axial hole 84 in the other side of said opening window means 82, and the leaf spring member 83 and the other direction side of said opening window means 82 can be formed by cutting machining.

The first and second covers 90 and 92 serve the purpose of preventing the floating wedge member 70 described above from falling. Then, the first and second covers 90 and 92 not only have the facial shapes that cover the outer peripheral surface of the opposite wall means 52 and 53 of said first member 50, but also provide each of the axial holes 91 and 93 .

Next, the method of assembling the constituent parts described above is explained.

The wedge drive member 81 is inserted and positioned between the integrated year plate means 62 and 63 of the second member 60. Then those gear plate means 62 and 63 and the wedge drive member 81 are inserted. and are positioned between the opposing wall means 52 and 53 of the first member 50. Furthermore, after the first cover 90 is positioned in the opposing wall means 52, the pivot shaft 94 is inserted and locked into the holes 91, 56 , 65, 84, 65, 56 axis. Floating wedge member 70 is then inserted from wedge-shaped window means 58 of opposite wall means 53 to opening window means 82 and wedge-shaped window means 58 of wall means 52 . opposite surface wall. Next, the axial hole 93 of the second cover 92 engages the pivot shaft 94, preventing the floating wedge member 70 from falling. Finally, by closing both ends of the pivot shaft 94, the constituent parts described above are integrated together.

Next, the method of using the angle adjustment tool 3 of the second embodiment is explained.

As illustrated in Figure 28, when the second member 60 is inclined in the direction of arrow B with respect to the first member 50, the engagement state of the toothed surface 72 of the wedge member 70 is enabled. floating with gear means 66. Furthermore, the floating wedge member 70 is pushed into the gradually narrowing space formed between the wedge surface 58a and the engagement means 66. As a result, the floating wedge member 70 cannot swing in the direction B of the second member 60 by means of the wedge effect, and the angle of inclination between the first member 50 and the second member 60 is maintained (held fixed).

In other words, in the engaged state illustrated in Figure 28, as a result of the engagement between the toothed surface 72 of the floating wedge member 70 and the engaging means 66, there is no slippage of the second member 60, and the slope angle between the first member 50 and the second member 60 are securely held.

Conversely, when the second member is oscillated in the direction of arrow A, as illustrated in Figure 29, the wedge drive member 81 begins to rotate in unison with the second member 60 as a result of the forces of drag friction generated based on the spring forces of the annular waveform means 85 . As a result, the floating wedge member 70 is displaced in the downward direction in the wedge-shaped window 58 . Next, the upper end surface of the floating wedge member 70 is pressed towards the conical surface 82b of the wedge drive member 81. As a result, the floating wedge member 70, while in sliding contact with the induction gradient surface 58c of the wedge-shaped window means 58, is slightly displaced in the direction away from the engagement means 66. The floating wedge member 70 is then displaced from the wedge surface 58a at the bottom of the wedge-shaped window means 58. As a result, a minute gap is generated between the toothed surface 72 and the engagement means 66, and the floating wedge member 70 assumes the free, non-contacting state (FIG. 29). In the free, non-contact state, the floating wedge member 70 is supported via the three points of the induction gradient surface 58c of the wedge-shaped window means 58, the conical surface 82b of the drive member 81 wedge, and stepped means 82c. In the free, non-contact state, because there is no contact between the floating wedge member 70 and the gear means 66, no unpleasant clanking sound is generated, and the second member 60 silently oscillates in the direction of arrow A. .

Furthermore, although dragging frictional forces are generated between the wedge drive member 81 and the second member 60, because the floating wedge member 70 is pushed up by the wedge drive member 81, there is no meshing of toothed surface 72 with engagement member 66 .

In other words, while the swing operation of the second member 60 in the direction of arrow A is being performed, the floating wedge member 70 is held without generating a strong metallic noise, and the toothed surface 72 of the floating wedge member 70 and the gear means 66 is kept in the non-contact state.

As illustrated in Fig. 30, when the second member 60 is further swung in the direction of arrow A, and the upper end surface of the floating wedge member 70 is pressed by the boss means 67 for use in pressing downward in one direction, the member 81 not only rotates in unison, but the floating wedge member 70 presses down on the wedge drive member 81. As a result, the protrusion means 83a of the leaf spring member 83 provided in the wedge driving member 81 rides on the position adjusting pin 57. As a result, the position adjusting pin 57 is locked in the recessed means 83b for use in locking. Then, the bottom end surface of the floating wedge member 70 is stored in the retraction space 58b to assume the retracted state.

In the retracted state, the floating wedge member 70 is stored in the retraction space 58, in addition to which the recessed means 83b for use in locking the leaf spring member 83 locks on the position adjustment pin 57 . For this reason, even if the second member 60 is swung in the direction B as a result of the elastic force of the leaf spring member 83 locking the position adjusting pin 57, the non-engaging state of the locking means 66 is maintained. gear with toothed surface 72. As a result, the wedge drive member 81 does not rotate in unison, and the second member 60 is allowed to freely oscillate in direction B relative to the first member 50.

Next, as shown in Figure 32, when the second member 60 is swung in the direction of arrow B, just before the second member 60 becomes straight with respect to the first member 50, the means 68 of protrusion for use in pushing up contact the bottom end surface of the floating wedge member 70.

Then, when the second member 60 is swung slightly with force in the direction of arrow B, the protruding means 68 for use in pushing up pushes up the bottom end surface of the floating wedge member 70, displacing the member. floating wedge 70 from space 58b retracted upwards. At that time, along with the displacement of the floating wedge member 70, the upper end surface of the floating wedge member 70 presses upwardly on the conical surface 82b of the wedge driving member 81. As a result, the wedge drive member 81 rotates clockwise in Figure 32 about the center of the axial center L. As a result, the locked state of the lowered means 83b for use in locking the leaf spring member 83 and the position adjusting pin 57 is released, and the position adjusting pin 57 moves to the lowered means 83b. for use in guiding the leaf spring member 83. Then, as a result of the frictional forces between the wedge drive member 81 and the second member 60, these rotate in unison. As a result, the floating wedge member 70 moves to the top of the wedge-shaped window means 58 (wedge-shaped gap), and the toothed surface 72 of the floating wedge member 70 and the gear means 66 they assume the engaged state.

Now, in this embodiment, the position of the straight line state (180°) of the second member 60 with respect to the first member 50 is the final deployed position, but is not necessarily limited thereto. By appropriate selection of the central angle range provided for the engagement means 66, for example, the second means 66 can have a final deployed position that positions it so as to form an angle of 120° with respect to the first member 50.

Next, when the second member 60 is oscillated once more in the direction of arrow A, the wedge drive member 81 begins to rotate in unison with the second member 60 as a result of dragging frictional forces based on the spring force of the annular waveform means 85 . As a result, the floating wedge member 70 moves downwardly in the wedge-shaped window means 58. Next, the upper end surface of the floating wedge member 70 is pressed against the conical surface 82b of the wedge drive member 81. As a result, the floating wedge member 70, while in sliding contact with the induction gradient surface 58c of the wedge-shaped window means 58, moves slightly in the direction away from the engagement means 66. As a result, because the floating wedge member 70 is disposed away from the wedge surface 58a by the lower means of the wedge-shaped window 58, a minute gap is generated between the toothed surface 72 and the gear means 66 , and, once again, the floating wedge member 70 assumes the free, non-contacting state (FIG. 29). Therefore, unpleasant metallic noise is not generated. Then, when the second member 60 is swung in the direction of arrow B, the toothed surface 72 of the floating wedge member 70 and the gear means 66 mesh. Furthermore, the floating wedge member 70 is pushed into the taper formed between the wedge surface 58a and the engagement means 66. As a result, the oscillation of the floating wedge member 70 is prevented in the direction B of the second member 60 by means of the wedge effect, and the inclined angle of the first member 50 with the second member 60 is maintained (held fixed) and returns. to the state illustrated in Figure 28.

Preferably, the wedge-shaped member in one or all of the described embodiments is not subject to a spring force forcing the wedge member into an engaged state with the engagement means 4.

Also preferably, the wedge member is subjected to a frictional force so as not to freely move to a different position. The frictional force may be created at one or both end faces of the wedge member 6 . In the second described embodiment, this may be achieved, for example, by a frictional force between one or both of said end faces with one or both of the other means 90 and 92. Although not described in detail, one or both of said end faces cover may also be present in the first embodiment.

industrial utility

The drive adjustment tool of the present invention is limited by the appended claims and can be used on furniture other than sofas.

Explanation of reference numbers

1. First member

2. Second member

3. Angle adjustment tool

4. Gear Media

6. Floating wedge media

7. Serrated surface

8. Wedge surface

10. Non-Contact, Free State Retaining Media

11. Wedge driving member (operating plate)

12. Friction means

16. Leaf spring member

17. Opposite Wall Media

18. Fixation means

. orifice media

. Surface

. conical surface

. connected shaft

. discounted media

. Sidewall Media

. means of connection

. Tongue shaped cutout

. gear media

. Small gear member for use in control

. toothed surface

. backup media

. headrest media

. first member

. fixing media

. Opposite Wall Media

. Opposite Wall Media

. shaft hole

. Position adjustment pin

. Wedge Shaped Window Media

a. wedge surface

b. shrink space

. Wedge Shaped Window Media

. Induction gradient surface

. second member

. fixing media

. gear plate media

. gear plate media

. rivets

. shaft hole

. gear media

. Protrusion means for use to press down. Protrusion means for use to press up. floating wedge member

. contact surface

. toothed surface

80. Non-Contact Free Restraint Means

81. Wedge Drive Member

82. Opening window media

82nd arched surface

82b. conical surface

82c. staggered media

83. Leaf Spring Member

83rd extrusion media

83b. Lowered media for use in blocking

83c. Lowered media for use in guiding

84. Shaft hole

85. Waveform Annular Media (Sliding Contact Media) 86. Sliding Contact Annular Media

90. First cover

91. Shaft hole

92. Second cover

93. Shaft hole

94. Pivot shaft

L. Axial center

A. One direction (vertical direction)

B. Other direction (inclined direction)

O. Acute angle

Claims (8)

1. Angular adjustment tool (3) equipped with a first member (1) and a second member (2) having a gear means (4) and an oscillating floating wedge member (6) having a surface (7) toothed meshable with said gearing means (4), and with respect to an angle setting tool with relative oscillating motion restricted to the opposite direction (B) of the permitted relative oscillating motion in a direction (A) of said second member (2) with respect to said first member (1), comprising free clamping means (10) allowing the clamping of the toothed surface (7) of said floating wedge member (6) to be freely maintained without contact with said gear means (4) during the oscillating movement in said direction (A), wherein the contactless, free clamping means (10, 80) provide a wedge drive member (11, 81) which rotates through a small angular range by means of the forces of friction that accompany the rotation with the second member (2, 60), and configures a free state, without contact, in which the wedge drive member (11, 81) supports the toothed surface (7, 72) of the member (6, 70) of floating wedge in a free state, without contact, with said gear means (4, 66), by oscillating movement in a direction (A) of the second member (2, 60) with respect to the first member (1,50), in addition to a geared state of the toothed surface (7, 72) of the member (6, 70) of cu floating wedge with the gear means (4, 66) and the wedge surface (8, 58a) formed on the first side of the member (1, 50), by means of the oscillating movement in the opposite direction (B), in in that the relative oscillating movement in the opposite direction (B) of the second member (2, 60) with respect to the first member (1,50) is restricted by means of the wedge effect of the floating wedge member (6, 70) . 2. Angular adjustment tool (3) according to claim 1, characterized in that said non-contact, free clamping means (10) provide a wedge drive member (11) which rotated over a small angular range by means of of the frictional force that accompanies the rotation with said second member (2), and by means of the oscillation movement in said direction (A) of said second member (2) with respect to said first member (1) said member (11 ) wedge drive causes said toothed surface (7) of said floating wedge member (6) to be in a free, non-contacting, and free and non-contacting state with said engagement means (4), and further by oscillating at said small angular degree in said other direction (B), said floating wedge member (6) is pressed between the wedge surface (8) formed on said side of the first member (1) and said means (4 ) of gear, and in the configuration with the geared state of said surface toothed surface (7) of said floating wedge member (6) with said engagement means (4), restraining relative oscillating movement in said other direction (B) of said first member (1) and said second member ( 2) is enabled by means of the wedge effect of said floating wedge member (6). Angular adjustment tool (3) according to one of claims 1 or 2, wherein said non-contact free clamping means (80) provides a wedge drive member (81) which is rotated in a small range angular by means of the frictional forces accompanying rotation with said second member (60), and configures a free, non-contacting state, in which said wedge drive member (81) maintains said toothed surface (72) of said floating wedge member (70) in a free, contactless state with respect to said engagement means (66) by oscillating motion in said first direction (A) of said second member (60) with respect to said first member (50), as well as an engaged state of said toothed surface (72) of said floating wedge member (70) with said engagement means (66) biasing said floating wedge member (70) between said engaging means (66). gear and the wedge surface (58a) formed on said side or of the first member (50), by oscillating movement in said other direction (B), wherein the relative oscillating movement in said other direction (B) of said second member (60) with respect to said first member (50) is constrained by the wedge effect of said floating wedge member (70). Angular adjustment tool (3) according to one of the preceding claims, wherein said wedge drive members (11, 81) have friction means (12, 85) that generate frictional forces accompanying said rotation while in sliding contact with said second member (2, 60). Angular adjustment tool (3) according to one of the preceding claims, characterized in that the wedge member (6) is not subjected to an elastic force to achieve the engagement state. Angular adjustment tool (3) according to one of the preceding claims, characterized in that the member (6) is subjected to a frictional force to restrict the free movement of the wedge member (6). Angular adjustment tool (3) according to one of the preceding claims, characterized in that the oscillating floating wedge member (6) is pivotally connected, preferably by means of free clamping means (10). 8. Sofa characterized by a configuration that fixes headrest means (48) by means of the angular adjustment tool (3) claimed in any one of claims 1 to 4 on the upper edge of the backrest means (46), and with respect to to the sofa that allows a progressive oscillation movement of said headrest means (48) in the vertical direction (A) and the restriction of the oscillation movement thereof in the inclined direction (B), said angular adjustment tool (3) is equipped with gear means (34), and a small gear member (36) for use in adjustment having a toothed surface (37) that allows to engage with said means (34). ) gear, and when said headrest means (48) is oscillated in said vertical direction (A), said gear means (34) of said angular adjustment tool (3) and said toothed surface (37) are held in a free, non-contacting state, and by a retraction operation to a specific small angular degree to said inclined direction (B) said means (34) for engaging said angular adjustment tool (3) and said surface (37) are caused to ) toothed are in an engaged state, maintaining the posture of said headrest (48).