FR2669371A1 - Device with a rod allowing slow rotation - Google Patents

Abstract

The invention relates to a device with a rod allowing slow rotation, in which a rod supports a second member which can rotate with respect to a first member. …<??>According to the invention, the rod possesses a hollow body which is locked to the first member (1), caps are inserted, from the outside, to the extreme portions of the body and are locked to the second member (2), a torsion bar (4) is fixed, at one end, to the body and at the other end, to one of the members forming caps, a viscous grease is enclosed between the body of the rod and the members forming caps and the hollow body of the rod and a member forming a cap are locked to the first and second members respectively, so that they cannot rotate, whereas the other member forming a cap is locked with a certain amount of play (7) allowing free displacement. …<??>The invention applies particularly to chests (cases, boxes) for make-up, for radio-cassettes, for a dashboard of a vehicle and the like. … …

Description

The present invention relates to a rod device allowing a

slow rotation that supports a

second rotary member relative to a first member.

The rod device allowing slow rotation can for example be used for a rotating support portion of a hinged device of a compact case for makeup, for radio cassettes for

a dashboard of a car and the like.

One such type of rod device allowing slow rotation consists of a rod 3 which supports a rotary member 1 which rotates relatively to a fixed member 2 as shown in figure 7c The rod 3 is approximately composed, as shown in FIGS. 7 and 8, of a hollow body 31, of members forming caps 32 and 33 inserted in rotation, from the outside of both sides of the body 31, of a torsion bar 4 blocked at an extreme hook portion 41 in the body 31 of the rod while the other hook portion 42 is locked in 1 cap member 33 and a viscous grease (not shown) enclosed between the body 31 of the rod and the forming members

caps 32 and 33.

The body 31 is provided with a shank having a stepped portion or small diameter portions 31b, where the cap members 32 and 33 are inserted, from the outside, and rotatably, are formed on both sides of. a larger diameter portion 31a and a slit-shaped hole 34 is formed in the longitudinal direction, the large diameter portion 31a being provided with a key protruding from the cap. cylinders having bottoms respectively, the internal and external diameters of each cylinder being respectively formed to be approximately the same as the external diameter of the small rod portion 31b and the external diameter of the large rod portion 31a Each of the forming members caps 32 and 33 es: respectively provided with a portion forming a key

which protrudes 37 and 38 at its outer circumference.

At the bottom of the cap member 33 is formed a concave slot 36 The cap members 32 and 33 are inserted, from the outside, on the portions 31b of small diameter, respectively, circular grooves 32a and 33a. cap members 32 and 33 being placed on circular ribs in each small diameter rod portion 31b, respectively, to pocket the fall of the cap member so that it

can be rotatably incorporated into the body 31 of the rod.

In this incorporated state, the torsion bar 4 is inserted into the hole 34 of the body 31, its hook portion 41 being locked at the hole 34 while its other hook portion 42 is locked in the concave slot 36 of the forming member. cap 33 and the viscous grease is trapped between the cap members 32, 33 and the

small diameter rod portions 31b, respectively.

The rod 3 thus formed is inserted into a pivot portion by raising the rotary member 1 to 900 relative to the fixed member 2 so that grooves (not shown) provided on each support portion of the rod of the rotary member 1 and the fixed member 2 can correspond By this insertion, the rod 3 is placed so that the large diameter portion 31 a of its body 31 is located in the bearing portion 21 of the fixed member 2 , that the cap members 32 and 33 are in the rotating support portions 11 and 12 of the rotary member, respectively, and then each key 35, 37 and 38 is inserted into grooves (not shown) which are formed on the bearing portion 21 and the supporting portions 11 and 12, respectively, thus the large diameter rod portion 31a and the cap members 32 and 33 are respectively attached to the bearing portion 21 and to the supporting portions in

rotation 11 and 12 in a non-rotating manner.

In the conventional slow rotation rod device thus constructed, a lifting torque is stored in the torsion bar 4 due to the rotation of the rotary member 1, from the neutral point b in the closing direction and the member rotary member 1 is fixed to the fixed member 2 with a suitable locking means at the fully closed point ao the lifting torque is maximum (see figure 9) When the locking means is released, the rotary member 1 rotates in the direction of opening due to the lifting torque of the torsion bar 4 At the moment of this rotation, a shear resistance of the viscous grease arises and the rotary member 1 turns slowly and it can be stopped at the neutral point b despite the load of bar couple

torsion 4.

Thus, the conventional slow-acting rotary shaft can perform slow operation efficiently in a Qt-1 area from the fully closed point a of component 1 to the neutral point b,

as shown in figure 10.

In such a hinged device, it is necessary to improve the free stopping zone o the rotary member 1 can be stopped at any point in the zone L 2 from the dead center b to the point of total opening c while maintaining the maximum angle of rotation d L of the organ

rotary 1 to roughly 1350, as shown in Figure 9.

In this case, it is impossible to satisfy this condition by using the conventional rod device.

allowing slow rotation.

In other words, when the rotary member 1 is rotated from dead center b to the point of full opening c, the torsion bar 4 in the rod 3 is twisted in the neutral direction against the closing direction at the time of rotation. in the zone GL 1 described above, thus the torque is stored in the torsion bar 4 The stored torque is used for the return of the rotary member 1 in the direction of neutral b against the shear resistance of the viscous grease En consequence, he

it is impossible to stop the rotary member 1 at a point.

On the other hand, when the rotary member 1 is rotated through the full extents t L 1 eto G 2 using the torque of the torsion bar 4 by applying an initial torque to the torsion bar 4, the torque of the rotary member 1 coincides with the direction of action of the torque of the torsion bar 4 in the zone t 2 it is therefore impossible to stop the rotary member 1 only because

the shear strength of viscous grease.

Furthermore, the torsion bar 4 is retained in the direction of torsion, at the time of use, by deformation This problem arises from the fact that the angle of rotation in the zone c> L, 2 increases due to the

permanent deformation.

The present invention aims to remedy the above problem. It aims to provide a rod device allowing slow rotation which is used to pivotally support a part of a hinge device o the rotation angle of the organ. rotation exceeds neutral and allows a free stop zone to be reached, which allows the rotary member to rotate at a slow speed, due to the lifting torque of the torsion bar in the rotation zone within limits neutral point and this makes it possible to stop the rotary member at any point in the rotation zone

beyond its neutral point.

In order to solve the above problem, the invention is characterized in that the rod which rotatably supports a second member relative to a first member comprises: a hollow body locked in a non-rotatable manner to the first member; cap members inserted, from the outside, on an end portion of the body of the rod, rotatably and non-rotatably locked to the second member; a torsion bar, one end portion of which is locked to the above body of the rod while the other end portion is locked to the cap member; a viscous fat enclosed between the above body and the cap member; and the hollow body and a cap member are locked to the first and second members respectively and non-rotatably while the other cap member is locked with

a game allowing him a certain movement.

The stem body and the cap members are integrated with the first and second members respectively, one of the two rotating with the center of

the support portion rotating relative to the other.

This rotation is accomplished on the torsion zones in

negative and positive directions of the torsion bar.

In this case, the relative rotation of the first or the second member in the torsion zone in the positive direction

is accomplished by the torque of the torsion bar.

However, despite this torque load, the rotation is accomplished at a slow speed due to the shear resistance of the viscous grease trapped between the

stem body and cap-forming organs.

The relative rotation of the first or the second member in the initial zone where the torsion bar changes from the torsion in the positive direction to the torsion in the negative direction is accomplished in the rolling zone relating to the second or the first cap member or the body of the rod o the torsion bar has no relation to them given the load of the external force The organ rotated in this area has a small torque and when the load of the external force on this organ is released, it stops in any position due to the frictional resistance at the rotating support portion and the shear resistance of the viscous grease Furthermore, the relative rotation of the first or second member in the torsion zone in the negative direction of the torsion bar goes beyond the above rolling zone and enables the torsion of the torsion bar in a negative direction due to the load of the external force. rotary, if the load of the external force is no longer applied to it, can be stopped in any position by the fact that a synthetic force of the rotary member and the shear resistance of the viscous grease

balance with the torque of the torsion bar.

Thus, the relative rotation of the first or the second member in the torsion zone, in the negative direction of the torsion bar, is accomplished by the rolling zone. Consequently, it is possible that the torsion angle of the bar of torsion in negative direction is smaller and more than the whole zone of torsion in negative direction is towards the free stopping zone o the turned member can be stopped at any point due to

the release of external force.

The invention will be better understood, and other objects, features, details and advantages thereof

will appear more clearly during the description

explanatory diagram which will follow made with reference to the appended schematic drawings given solely by way of example illustrating several embodiments of the invention, and in which: FIGS. 1 (a) and (b) show a rod of a device to rod allowing slow rotation according to the invention, FIG. 1 (a) being a view in longitudinal section and FIG. 1 (b) a view from the left side; FIGS. 2 (a), (b), (c), (d) and (e) show cross-sectional views of the above rod, Fig. 2 (a) being a sectional view taken along line aa, Fig. 2 (b) along line bb, Fig. 2 (c) along line cc, Figure 2 (d) along line d- d, and Figure 2 (e) along line ee; Figures 3 (a), (b) and (c) are respectively a front view, a side view and another side view of a hinged device attached to the rod above Figures 4 (a) and (b) show the operation of the above hinge device, Figure 4 (a) being a side view in neutral and Figure 4 (b) a side view in fully open condition Figure 5 is a central longitudinal sectional view corresponding to Figure 4 (a); Fig. 6 is a side view of another embodiment corresponding to Fig. 4 (a); Figure 7 is a perspective view of a hinge device used for the conventional rod device allowing slow rotation Figure 8 is an exploded longitudinal sectional view of the rod forming the rod device allowing slow rotation above ; Figures 9 (a), (b) and (c) respectively show a right side view of a cap member of the above rod, a longitudinal sectional view taken along line bb of the rod and a view on the left side of the other cap member; and Figure 10 is a side view which shows the

operation of the above hinge device.

The invention will now be described with reference to an embodiment of the present invention where the same elements as those of the prior art are indicated.

by the same reference numbers.

In Figures 1 and 2, the rod 3 of this embodiment consists of a hollow body 31 and cap members 32 and 33 which are inserted, from the outside, on both sides of the body 31 in a rotary manner. , with a torsion bar 4 of which a hooked end portion 41 is locked in the body 31 of the rod and its other hooked end portion 42 is locked in the cap member 33, a viscous grease 5 being trapped between the body 31 and

cap members 32 and 33.

The rod body 31 is formed of a stepped rod which is provided with small diameter portions 31b which receive the cap members 32 and 33 inserted from the outside, respectively, and rotatably on both sides of one. portion forming central rod of larger diameter 31 a This body 31 is crossed by a hole which consists of a slot 34 a which opens on one side of the body 31 and a circular hole 34 b which continues the hole 34 a and opens on the other side.In addition, a key 35 is provided on the outside of the

portion 3 la of large diameter.

The cap members 32 and 33 are in the form of cylinders having a bottom, each being inserted, from the outside, on the small diameter rod portions of the body 31 and a concave slot 36 is drilled in the bottom of the cap.

the cap member 33.

The outer diameters of the cap members 32 and 33 are the same as the diameter of the large diameter portion 31a of the body 31, the outer sides of the cap members 32 and 33 being

provided with keys 37 and 38, respectively.

The members forming caps 32 and 33 are rotatably placed on the body 31 by inserting them, from the outside,

on each portion of rod of smaller diameter 31 b.

The viscous grease 5 is applied to the outer surface of the small diameter portions 31b upon insertion of the cap members 32 and 33 and is enclosed between the cap members 32 and 33 and the small shank portions. diameter 31 b by insertion of caps 32 and 33, from the outside. In the assembled state, the torsion bar 4 is inserted into the hole in the body 31 and is incorporated into the shaft 3 by locking a hooked end portion 41 in the hole 34 a while the other end portion in hook 42 is locked in the concave slot 36 of the cap member 33 by pulling the other portion 42 outwards

body hole 31.

The rod 3 thus constructed forms a rod device allowing slow rotation by being attached to the rotating support portion of the hinge device.

60 that can be seen in figure 3.

The hinge device 60 is supported in such a way that the rotary member 1 can be rotated around the rod 3 relative to the fixed member 2 On one side of the rotary member 1, there is provided a support portion 11 of the shank which is traversed by the shank 3 The upper surface of the portion 11 is formed to be a tapered surface 12 while the upper end surface of the tapered surface 12 is formed to be

a stop surface 13.

Furthermore, on the fixed member 2, bearing portions 21 and 22 are formed in order to clamp the support portion 11 of the rod of the rotary member 1 while at the lateral end surface of the bearing portions 21 and 22 is formed an abutment surface 23 on which comes in

abutting the stop surface 13 of the rotary member 1.

In the hinge device 60, the rotary member 1 can assume the fully open state shown in FIG. 4 (b) where the rotation is retained by the abutment of the stop surface 13 against the surface 23 via the point death of Figure 4 (a) which is roughly vertical to

from the fully closed state of Figure 3 (c).

The angle of torsion o U from the fully closed state of the rotary member 1 to the fully open state is

in this case about 1350.

The rod 3 is inserted on the rotational support portion of the rotary member 1 at the neutral point of the member

rotary 1.

In other words, the body 31 and the cap members 32 and 33 are respectively attached to the rotary member 1 and to the fixed member 2 by vertically raising the rotary member 1 to bring the holes into agreement with the groove. key which are respectively provided on the bearing portions 21 and 22 of the fixed member 2 and the support portion of the rod 11 of the rotary member 1, the rod 3 is inserted into the hole and the key is inserted 37 of the cap member 32, the key 35 of the rod 31 and the key 38 of the cap member 33 in the groove of the bearing portion 22, the groove of the portion 11 for supporting the rod and the groove of the bearing portion 21, respectively The grooves of the bearing portions 21 and 22 formed on the fixed member 2 are drilled to correspond to the shape of the keys 37 and 38 of the members forming caps 32 and 33 By fixing the bearing portions 21 and 22 to the keys 37 and 38, the members forming caps 32 and 33 are attached to the

support portions 21 and 22 in a non-rotating manner.

Furthermore, the groove on the support portion 11 of the rotary member 1 is formed, as shown in Figure 5, leaving a clearance portion 7 to allow free movement or rolling of the rotary member 1 in the direction A (direction of opening) in the groove corresponding to the key 35 which is formed at the large diameter rod portion 31 a of the body 31 As a result, the body 31 (its portion 31 a), the key 35 of which is inserted into the groove of the support portion 11 locks to the support portion 11 with the clearance portion 7 remaining as it is, so the rotary member 1 can travel

the play portion 7 without any relation to the body 31.

The operation of this embodiment will be

now described.

The locking state of the large diameter rod portion 31a of the body 31 and of the support portion 11 of the rotary member 1, when the latter is placed in neutral (Figure 4 (a)), is locked by leaving the clearance portion 7 in the support portion 11 such

which is.

When the rotary member 1 is rotated from neutral to the closing direction (direction B in figure 5), the body 31 rotates in the direction C shown in figure 2 (c) together with the rotary member 1. the rotation of the body 31 in the direction C, accompanied by the rotation of the rotary member 1 in the closing direction, a hooked end portion of the torsion bar 4 is twisted in the positive direction and the energy which rotates the rotary member 1 in the opening direction 1 1 is stored By this, the fully closed state shown in Fig. 3 is obtained (c) In this fully closed state, the rotary member 1 maintains its fully closed state by suitable means locking device (not shown). On the other hand, when the locking of the rotary member 1 in the fully closed state is released, the rotary member 1 rotates in the opening direction due to the torque of the torsion bar 4. The rotation, at this time, undergoes shear resistance of viscous grease, so it is achieved slowly despite the torque load of the torsion bar 4 The rotary member 1 stops near neutral in Figure 4 (a) At this time, the torsion bar 4 is in an unloaded state The rotation of the rotary member 1 in the opening direction

after that is carried out manually.

First, an external force is applied to the rotary member 1 which stops near neutral to rotate in the opening direction This rotation becomes a rotation of the rotary member 1 in the direction A which can be see figure 5 and the rotary member 1 moves freely in the clearance portion 7 of the support portion 11 This bearing is retained by the fact that the wall 7a of the clearance portion 7 abuts against the key 35, as shown by the double dot-dash line in Fig. 5 In the rotation of this rotary member 1, as the rotation of the body 31 is not accompanied, the torsion bar 4 is not twisted and retains the unloaded state As a result, the rotary member 1 can be stopped in any position due to the release of the external force. This is due to the fact that the above angle of rotation k 3 of the rotary member 1 is about 300 and the torque of the rotary member 1 is also small As a result, the rotation of the rotary member 1 can be stopped by the sole friction of the support portion 11 and the portion of

large diameter 31 a.

Furthermore, the rotary member 1 is brought to the fully open state (Figure 4 (b)) by applying an external force to rotate it in the open direction (direction A in Figure 5). the member 1 during this time accompanies the rotation in direction D of the body 31 of the rod in FIG. 2 (c) which is accomplished by twisting the bar 4 in a negative direction against the tendency to rotate the member rotary 1 in the closing direction In addition, the rotary member 1 can be stopped in any position, from

makes the release of external force.

This is due to the fact that the above angle of rotation çL 4 of the rotary member 1 is about 150, which does not cause a torque for the return of the rotary member 1 to neutral even if the torsion corresponding to the angle of rotation is added to the torsion bar 4 Consequently, this torque is balanced with the force of the torque of the rotary member 1 and the shear resistance of the viscous grease therefore the member

rotary 1 can be stopped in any position.

Moreover, as the angle of torsion of the bar 4 in the negative direction decreases at this time, the permanent deformation of the torsion bar 4 in

negative direction does not occur.

In this embodiment, it is possible to form the area of rotation in the opening direction after the dead center of the rotary member 1 as an area

free stop.

Another embodiment will be described as follows. This other embodiment relates to the case where the hinged device is different from that which precedes. There, the rod 3 is attached to the pivotal support portion of the hinge device 6 (Fig. 7) which has been described in the conventional art.In this case, the cap members 32 and 33 and the body 31 are respectively attached. to the support portions 11, 12 of the rotary member 1 and to the bearing portion 21 of the fixed portion 2 The groove of the bearing portion 21 formed on the fixed member 2 at this time is drilled to a shape corresponding to the key 35 of the body 31, this body 31 being fixed to the bearing portion 21 in a non-rotating manner by inserting the key 35 in the groove of the

support portion 21.

Furthermore, a groove of a support portion of the rod formed on the rotary member 1, is formed as shown in FIG. 6 by causing a clearance portion 7 to protrude where the rotary member 1 can move freely in the shaft. direction A (direction of opening of the rotary member 1) at the location of the key corresponding to the key 38 of the cap member 33 For this purpose, the cap member 33 for inserting the key 38 in the groove of the support portion 11 is attached to this portion 11 with the clearance portion 7 which

remains when the rotary member 1 is placed in neutral.

Furthermore, the groove of the other support portion 12 of the rod may be drilled to correspond to the key 37 of the member forming the cap 32 or else be formed so as to protrude into the clearance portion of the groove of the support portion 12 as in the case of the support portion 11 of the rod above In the first case, the cap member 32 is attached to the support portion of the rod 12 while in the latter case the cap member 32 is attached to the supporting portion of the rod 12 leaving the clearance portion of the portion 12 of the rod as it is The fixed state of the latter case is the same as in the case of the body 31 of the rod (rod portion 31 a of large diameter) and of the rod support portion 11 of the

figure 5.

In this embodiment, the rotary member 1 moves freely in the play portion of the support portion 11 without torsion of the bar 4 over an extent of d-3 which can be seen in Figure 5 while in the OL zone 4 of FIG. 1, the rotary member 1 rotates in the opening direction, twisting the bar 4 in a negative direction which accompanies the rotation of the member forming the cap 33 At this moment, the free stop of the rotary member 1 in the QG area 3, when the cap member 32 is attached to the support portion 12 in a non-rotatable manner, is achieved by the shear resistance of the viscous grease enclosed between the cap member 32 and the small diameter rod portion 31b of the rod body and the frictional force between the cap member 33 and the support portion 11 On the other hand, when the cap eye 32 is attached to the support portion 12 of the rod leaving the clearance portion, the free stop above in the zone 3 is obtained by the frictional force caused between the members forming the caps

32 and 33 and each support portion 12.

Furthermore, the free stop in the area o & 4 is obtained in the same way as in the embodiment

above.

Moreover, also in this embodiment, the viscous grease can be enclosed between the cap members 32 and 33 and the support portions 12 and 11 of the rod. In this case, the free stop in the area Dû 3 has shear strength

viscous fat.

Thus, as also in this embodiment, the torsion bar 4 is twisted in the negative direction after the rotary member has passed the rolling or free zone, the angle of torsion of the bar 4 in the negative direction decreases, and there is no deformation

permanent torsion bar 4.

As described above, according to this invention, it is possible to rotate the rotary member relative to the stationary member by the spring force of the torsion bar and the shear strength of the viscous grease. has a slow speed at

from the completely closed state to neutral and it is also possible to obtain a rotating zone in the opening direction after the neutral position where the torsion bar is turned in the negative direction which allows to obtain a good device forming a hinge.

On the other hand, in the area of rotation in the opening direction, after neutral, as the torsion bar is twisted in the negative direction due to the rolling area, the angle of torsion decreases and the permanent deformation of the bar. twist does not

not produce which keeps conventional endurance.

Claims (1)

R E V E N D I C A T I O N Rod device allowing slow rotation, of the type where a rod supports a second rotating member relative to a first one, characterized in that it comprises a hollow rod body (31) attached to the first member; cap members (32, 33) inserted from the outside to the ends of the hollow body and locked to the second member; a torsion bar (4) locked at one end to the body of the rod and at the other end to one of the cap members; a viscous fat (5) enclosed between the body of the rod and the cap members; and in that the hollow body and a cap member are locked to the first and second members respectively in a non-rotatable manner while the other cap member is locked by being provided with a certain clearance (7) allowing free movement.