The present invention relates to a seat recliner structure and a vehicle seat including the seat recliner.
To make a high-strength and high-rigidity seat with a weight reduction taken into consideration, an automobile seat having compact and thin recliners on its both sides is used. Recliners need to surely lock, have a small backlash, and be hardly broken at the time of collision.
As such a recliner, in Patent Document 1, the present applicant has proposed one achieving both a reduction in backlash and smooth movement by having grooves formed in its lock gear and guide bracket and having steel balls disposed in the grooves. In Patent Application No. 2019-70768, the present inventor has also proposed a recliner achieving a further reduction in backlash by having steel balls formed in a shape more easily fitting in grooves.
Patent Document 1: WO2017/043665
However, seat back frames have dimensional variations, and deterioration in the locking performance of a recliner may cause the generation of abnormal sound and the like. As for a lock failure due to variations of parts, providing play reduces the possibility of the occurrence of the lock failure. Providing the play, however, causes the generation of abnormal sound. It is often the case that this abnormal sound is not generated in a normal state but is generated during traveling on rough roads. Therefore, it is expected that in ordinary management, the abnormal sound can be controlled based on an index indicating the generation of abnormal sound. Further, if this index can be reflected in structure design by taking this index into consideration at a design stage, it may be possible to eliminate a cause of the failure in advance.
A seat frame of an automobile is one structure in which various press parts are welded. A back frame and a cushion frame are joined through recliners to constitute a seat frame. The press parts are made with high accuracy but welded structures have machining variations, and when they are assembled, various defects occur. Recliners made of thick plate parts and a frame made of a thin plate greatly differ in section modulus. The left and right recliners are made to synchronously function by a connecting rod. The connecting rod is elastically deformed by the accumulation of assembly variations to have a residual stress. This increases the sliding resistance of internal parts of the recliners to cause a synchronization failure that is a failure in synchronous locking of the left and right recliners or pseudo-locking that is a lock failure of one of the recliners.
The present invention was made in consideration of the above and has an object to provide a seat recliner structure that achieves a reduction in operation synchronization failure and the like of recliners on both sides of a seat frame to be capable of smoother operation despite variations in the dimensional accuracy of the seat frame, and to provide a vehicle seat including the seat recliner structure.
To solve the above problem, the present invention is a seat recliner structure including: recliners provided on a left side and a right side of a cushion frame and a back frame to recline the back frame relative to the cushion frame; and a connecting rod which connects the left and right recliners to synchronize the left and right recliners, wherein the left and right recliners have different backlashes, and the backlash of the driving-side recliner is smaller than the backlash of the driven-side recliner.
Further, the present invention provides the seat recliner structure, wherein the left and right recliners each have: a guide bracket and an internal gear which rotate relative to each other, one of which is attached to the cushion frame, and the other of which is attached to the back frame; and a plurality of lock gears which operate in a diameter direction between the guide bracket and the internal gear to separate from and approach each other and which include external teeth engageable with internal teeth of the internal gear, and
wherein the left and right recliners are different in the backlash depending on the presence or absence of a steel ball between any of the plurality of lock gears and the guide bracket.
Preferably, the recliner having the steel ball is relatively smaller in the backlash than the recliner not having the steel ball.
Further, the present invention provides the seat recliner structure, wherein the left and right recliners each have: a guide bracket and an internal gear which rotate relative to each other, one of which is attached to the cushion frame, and the other of which is attached to the back frame; and a plurality of lock gears which operate in a diameter direction between the guide bracket and the internal gear to separate from and approach each other and which include external teeth engageable with internal teeth of the internal gear,
wherein the left and right recliners each have a steel ball provided between any of the plurality of lock gears and the guide bracket, and
wherein the left and right recliners are different in the backlash depending on a difference in the shape of grooves provided in facing surfaces of the lock gear where the steel ball is disposed and the guide bracket.
Preferably, the backlash is relatively smaller as a circumferential-direction movement amount of the steel ball restricted by the grooves is smaller.
Preferably, a difference in clearance size between a lock gear between which and the guide bracket the steel ball is not provided, out of the plurality of lock gears, and at least one of surfaces, of the guide bracket and the internal gear, facing the lock gear further makes the backlashes different.
Further, the present invention provides the seat recliner structure,
wherein the left and right recliners are selected from those that are substantially equal in spring constants in linear change ranges of load-deflection characteristics both in a front-rear direction and a left-right direction, the load-deflection characteristics being indicated by the spring constants that are found from a relation between a load and a deflection amount which is measured at an input point of the load when a plate member is attached to a fixing jig through the recliner, and the load up to 50 N is applied in the front-rear direction and the left-right direction of the plate member to a position, of the plate member, 500 mm above a rotation center of the recliner, and
wherein the driving-side and driven-side recliners are selected based on determination that, when entire deflection amount change ranges of the load-deflection characteristics are compared, a recliner whose characteristics in the front-rear direction and the left-right direction both exhibit relatively the highest linearity has the smallest backlash, and as compared with the recliner having the smallest backlash, a recliner whose characteristic only in one of the front-rear direction and the left-right direction exhibits weak linearity has a relatively larger backlash and a recliner whose characteristics in the front-rear direction and the left-right direction both exhibit weak linearity has a still larger backlash.
The present invention further provides a vehicle seat including a seat recliner structure for reclining a back frame relative to a cushion frame,
wherein the seat recliner structure is the above-described seat recliner structure.
According to the present invention, since the backlash of the driving-side recliner is smaller than the backlash of the driven-side recliner, it is possible to enhance the synchronization of the movements of the left and right recliners, thereby enabling smoother operation despite variations in the dimensional accuracy of the seat frame including the cushion frame and the back frame.
The present invention will be hereinafter described in more detail based on embodiments illustrated in the drawings.
The seat recliner structure 10 includes recliners 11, 12 arranged on the left and right and a connecting rod 13 connecting shaft portions of the left and right recliners 11, 12. Out of the left and right recliners 11, 12, one is a driving side to which driving members such as an operation lever, a motor, and so on are connected, and the other is a driven side. In this embodiment, the recliner 11 is the driving side and the recliner 12 is the driven side. The driving-side recliner 11 and the driven-side recliner 12 are different in backlash. The backlash of the driving-side recliner 11 is smaller than the backlash of the driven-side recliner.
To make the driving-side recliner 11 and the driven-side recliner 12 satisfy such a condition, three recliners having relatively small to large backlashes (the recliner with a small backlash will be referred to as “High”, the recliner with a middle-level backlash as “Middle”, and the recliner with the largest backlash as “Low”) were checked. The recliners illustrated in
The recliner: High, which has the structure proposed in Patent Application No. 2019-70768 by the present applicant, has steel balls 27 disposed between the guide bracket 21 and the two lock gears 23a, 23b (lock gear A) facing each other at an interval of 180 degrees as illustrated in
Friction between the guide bracket 21 and the lock gears 23a, 23b (lock gear A) is rolling friction due to the steel balls 27, and friction between the lock gears 23a, 23b (lock gear A) and the internal gear 22 is entirely sliding friction. Incidentally, friction between the lock gears 23c, 23d (lock gear B) and the guide bracket 21 or the internal gear 22 is entirely sliding friction.
The recliner: Middle has the structure disclosed in Patent Document 1 (WO2017/043665). As illustrated in
In the recliner: Low, no steel ball is disposed between the guide bracket 21 and the four lock gears 23a to 23d as illustrated in
As described above, the recliner: High and the recliner: Middle are common in that the steel balls 27 are disposed between the guide bracket 21 and the two lock gears 23a, 23b (lock gear A) out of the four lock gears, but they are different in the shape of the grooves 21b, 23e to control the circumferential-direction movement amount of the steel balls 27, and further, preferably are different in the size of the clearance between the other two lock gears 23c, 23d (lock gear B) and the internal gear 22, whereby the recliner: High and the recliner: Middle are designed such that the former has a smaller backlash than the backlash of the latter. Further, in the recliner: High and the recliner: Middle, since the steel balls 27 are disposed, the two lock gears 23a, 23b (lock gear A) have substantially no backlash (a very small backlash) with the facing surfaces of the internal gear 22 and the guide bracket 21. On the other hand, the recliner: Low has no steel ball, preferably has the clearances between the four lock gears 23a to 23d and the facing surfaces of the internal gear 22 and the guide bracket 21, thereby being designed to have a larger backlash than those of both the recliner: High and the recliner: Middle.
Measurement of Load-Deflection Characteristics of Recliner
Measurement of Load-Deflection Characteristics Using Rigid Frame
The load-deflection characteristics are measured as illustrated in
Lockability confirmation is done by subjective determination based on the confirmation of whether or not the left and right recliners lock synchronously. A lever is attached to the connecting rod and is operated in the unlocking direction to unlock the recliners on both sides. In this state, the hand is taken off the lever, and it is confirmed whether the left and right recliners synchronously lock at the time of re-locking.
To know a reference of an input, a load is input by a push pull gauge and an accurate load is read with a load cell. The displacement is measured with a dial gauge.
Measurement of Load-deflection Characteristics of Recliners
As described above, as for the characteristic indicated by the spring constant found from a relation of a load and the deflection amount measured at the input point of the load when the load up to 50 N was applied in the front-rear and left-right directions to the position 500 mm above the rotation center of the recliner, both the front-rear direction and left-right direction characteristics of the recliner: High having the smallest backlash had a relatively smaller change in the spring constant in the middle than the characteristics of the other two recliners: Middle and recliner: Low and had the highest linearity in the entire deflection amount change ranges. Note that whether the linearity is high or low is thus determined based on the degree of the change in the middle of the gradient of the graph indicating the spring constant (the size of the nonlinear range) in the graph represented by the load-deflection characteristic, and as the degree of the change is smaller, the linearity is determined as being higher. In the recliner: Middle with the second smallest backlash, the spring constant in the left-right direction is similar to that in the recliner: High, but its front-rear spring characteristic is a combined nonlinear spring characteristic having a nonlinear range where the spring constant becomes small in the middle range of the deflection amount change. However, it has such a characteristic that the spring constant in the range where the linear spring characteristic is exhibited, other than the middle range, is similar to that in the recliner: High. The recliner: Low having the largest backlash exhibits a combined nonlinear spring characteristic both in the front-rear direction and in the left-right direction, and a deflection amount range where the spring constant in the left-right direction is 1 N/mm or less occupies about ⅓ of the entire left-right deflection amount.
In this specification, the driving-side recliner 11 and the driven side recliner 12 are selected based on the comparison among recliners that, in the load-deflection characteristics both in the front-rear direction and the left-right direction, are substantially equal in spring constants (within ±20% in terms of a spring constant value) in the entire deflection amount change ranges in the case where the linear spring characteristics are exhibited in the entire deflection amount change ranges, or are substantially equal in spring constants in the ranges where the linear spring characteristics are exhibited, except the middle deflection amount ranges (nonlinear ranges) where the spring constants become small in the case where the combined nonlinear spring characteristics are exhibited. At this time, one whose characteristics both in the front-rear direction and the left-right direction exhibit relatively the highest linearity in the entire deflection amount change ranges (exhibit a relatively small change in the spring constant in the middle ranges) is defined as having the smallest backlash. Then, as compared with the characteristics of the recliner having the smallest backlash, one exhibiting the combined nonlinear spring characteristic only in one of the front-rear direction and the left-right direction (the front-rear direction in this example) is defined as having a relatively larger backlash and one exhibiting the combined nonlinear spring characteristic both in the front-rear direction and the left-right direction is defined as having a relatively still larger backlash. Then, the driving-side recliner 11 and the driven-side recliner 12 are selected from the compared recliners using such criteria.
Measurement of Load-Deflection Characteristics Using Rigid Frame
A hysteresis loss was 7 N. Under the condition where the left-right direction variation was +3 mm, a weak combined nonlinear spring characteristic was exhibited, and a hysteresis loss was 20 to 47 N. Under the condition where the left-right direction variation was −3 mm, a weak combined nonlinear spring characteristic was exhibited under the conditions except the condition of the downward fanning type, and a linear spring characteristic was exhibited under the condition of the downward fanning type. A hysteresis loss was 22 to 47 N.
Table 2 shows the results of the confirmation of the lockability. In the High-High combination, neither the driving side nor the driven side was locked in the case of the parallelogram I type and II type under the +3 mm and −3 mm variation conditions. In the High-Middle combination, the driving side was not locked in the case of the parallelogram I pattern under the +3 mm variation condition and in the case of the parallelogram II type under the −3 mm variation condition.
In the High-Low combination, under the nominal condition, the spring characteristic in the front-rear direction was a combined nonlinear spring characteristic, and abnormal sound was generated when an input was larger than expected, for example, during traveling on a rough road. The left and right recliners synchronously locked even if the hysteresis loss was 40 N and thus there was no problem in the lockability. Therefore, the High-Low combination was the most effective in terms of the lockability.
The High-High combination exhibited a linear spring characteristic and did not generate abnormal sound. However, as for the lockability, a lock failure occurred when the frame became a parallelogram under the conditions where the left-right direction variation was +3 mm and −3 mm. The curvature of the connecting rod could not absorb the variation, the cam and the lock gears inclined, and the frictional force of the guide bracket and the lock gears became large to increase sliding resistance. Finally, the tooth tips of the internal gear and tooth tips of the lock gears abut on each other, causing a phenomenon that the gears were difficult to engage.
In the case of the recliner: High-High, it is necessary to provide play for absorbing the eccentricity of the left and right recliners when the connecting rod is designed. The play is play between the shaft or the cam and the connecting rod. It is also necessary to consider absorbing the variation by the curvature, using the elasticity of the connecting rod.
It has been also found out that the above spring characteristic evaluation method is capable of catching the possibility of the generation of abnormal sound that is not normally generated and is appropriate as an evaluation method.
In the case of the structure having the recliners on both sides, it has also been found out that making the spring characteristics of the driving side and the driven side different, preferably, making the backlash of the driving-side recliner smaller than the backlash of the driven-side recliner as in the above is effective for absorbing the variation of the back frame and reducing an operation synchronization failure.
Being made of iron parts, the recliner generated abnormal sound at its metal contact portion when it became a combined nonlinear spring with a small spring constant at a balanced point.
By measuring the load-deflection characteristics in the front-rear direction and the left-right direction, it was possible to identify a spring characteristic causing the generation of the abnormal sound. As the backlash is larger, larger abnormal sound is generated, but it is thought to be possible to ensure lockability while avoiding the abnormal sound if a connecting rod with a low flexural rigidity and a high torsional rigidity can be designed to absorb the eccentricity of the left and right recliners.
The use of a recliner having a backlash in the left-right direction involves a possibility of the generation of abnormal sound when part accuracy increases. A possible measure for this is to eliminate the backlash of the driven-side recliner by making a residual stress forcibly act on the frame.
Number | Date | Country | Kind |
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2019-103399 | May 2019 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/021539 | 6/1/2020 | WO | 00 |