This application claims priority of Japanese Patent Applications No. 2021-162894 filed on Oct. 1, 2021. The contents of the applications are incorporated herein by reference in their entirety.
The present invention relates to a chair that is suitably utilized in an office or the like and in which a seat is tiltable.
For example, chairs in which a seat is tiltable are known from Japanese Unexamined Patent Application Publication No. 2009-82521 and Japanese Unexamined Patent Application Publication No. 2009-297319 (hereinafter referred to as Patent Documents 1 and 2).
Patent Document 1 describes a configuration in which a plurality of fluid bags are connected by a flow path and a seat is tilted when air moves.
Patent Document 2 describes a configuration in which a plurality of independent air cushions are covered with a cover member and fitted into a recess of a seat to provide a cushioning property to a person sitting in the chair.
In the configurations of Patent Documents 1 and 2, the seat can move freely by the cushioning effect. However, the degree of freedom of deformation of the seat is too high for a seated person to hold his or her posture on the seat, and therefore, the seated person needs to follow a movement of the seat rather than the seat following a movement of the seated person. As a result, the conventional seats are not designed suitably for supporting a movement of the seated person continuously changing his or her posture while the seated person balances his or her load.
To solve such a problem, it is conceivable to provide a chair including a curved rolling surface in at least one of an upper base unit and a lower base unit, and, in the chair, when the upper base unit rolls with respect to the lower base unit, a seat provided in the upper base unit swings (to the front, rear, left, and right).
However, if the rolling surface includes a region having a different curvature (including a case where the curvature of the rolling surface is uneven) such as a hole or a flat portion due to some reason, rattling or an undesirable noise due to the change in curvature is easily generated during an operation of the upper base unit and therefore, an operation of the seat.
Such a problem may also occur when adopting a configuration in which the seat rolls only in a front-rear direction or only in a left-right direction.
The present invention has been made by focusing on such a problem, and an object thereof is to realize an unprecedented chair in which movement of a seat by using a rolling surface can be smoothly performed.
The present invention adopts the following means to achieve such an object.
That is, a chair of the present invention includes an upper base unit and a lower base unit facing each other, and a seat that is provided in the upper base unit and swings when the upper base unit rolls with respect to the lower base unit, and at least one of the upper base unit and the lower base unit includes a rolling surface being curved. In the chair, a region having a different curvature exists in a part of the rolling surface, and an elastic member is interposed between the region having the different curvature and a corresponding region of an opposing surface.
According to such a configuration, the upper base unit can follow a movement of a seated person while rolling via the rolling surface, and thus, the seated person can easily find a weight balance while supporting his or her own weight, and can change his or her posture stably and continuously. At that time, even if a region having a different curvature exists in a part of the rolling surface, the elastic member interposed between the region of the rolling surface and a corresponding region of the opposing surface makes it possible to effectively prevent rattling and generation of an undesirable noise due to the change in curvature, during the operation of the upper base unit, and therefore, the operation of the seat.
In a specific aspect, the chair includes a connection member that connects the upper base unit and the lower base unit, and the region having the different curvature is a relief hole for inserting the connection member.
This is particularly effective in a case where the upper base unit swings in a direction of 360 degrees with respect to the lower base unit, and the relief hole is provided at three or more locations around a swing center.
A specific example of the connection member includes a rotation stop member that restricts a relative movement of the upper base unit and the lower base unit in a rotation direction.
Another specific example of the connection member includes a detachment stop member that restricts a separation between the upper base unit and the lower base unit.
Still another specific example of the connection member includes a constitution component of a braking mechanism that slows down a movement of a seat by a relative movement of two members.
Still another specific example of the connection member includes a return spring interposed between the upper base unit and the lower base unit and the return spring returns the upper base unit to a predetermined reference position with respect to the lower base unit.
In a preferable aspect, the elastic member is an elastic resin foam body interposed between the upper base unit and the lower base unit.
In another preferable aspect, the elastic member is an elastic sheet interposed between the upper base unit and the lower base unit.
The elastic member is preferably also provided with a relief hole.
The configuration that employs the rotation stop member is extremely useful when applied to a chair in which an arm is attached to the lower base unit and a seat is attached to the upper base unit.
The present invention has the configuration described above, and thus, it is possible to follow a free movement of a seated person via a rolling surface, and, even if the rolling surface includes a region having different curvature (including a case where the curvature of the rolling surface is uneven) such as a hole or a flat portion due to some reason, rattling and an undesirable noise can be suppressed. Thus, it is possible to provide a novel, useful chair that can appropriately support a movement of the seated person continuously changing his or her posture while balancing his or her load.
An embodiment of the present invention will be described below with reference to the drawings.
In the seat 1, a circumference of a seat main body 11 is covered with upholstery 12, and the seat 1 is attached to the movement mechanism 3 via a seat shell 13. The seat shell 13 includes an inner seat shell 131 attached to a bottom surface of the seat main body 11 and an outer seat shell 132 that backs up the inner seat shell 131 and secures the connection to the movement mechanism 3.
The leg 2 includes casters 22 at a lower end of a leg vane 21, and a leg support post 23 erected from a center portion of the leg vane 21, and the seat 1 is rotatably attached to an upper end side of the leg support post 23. The leg support post 23 can be extended and contracted by a gas spring mechanism GS illustrated in
As illustrated in
The movement mechanism 3 supports the upper base unit 31 movably with respect to the lower base unit 32, in the front-rear direction as illustrated in
As illustrated in
As illustrated in
The curved surface has a substantially partial spherical shape or a substantially arc-shaped cross section, in other words, the curved surface has a bowl-shape or a convex R-shape, and the upper base unit 31 may move in directions of 360 degrees including the front-rear, left-right, and diagonal directions, while rolling on the lower base unit 32. The curved surface may be implemented in various modes, such as a surface that is curved at a constant curvature, even at a position separated from a reference position N which is a contact position between the two base units 31 and 32 when no load is applied, a surface having a curvature that smoothly changes as the distance from the reference position N increases, a surface having different curvature in the front-rear and left-right directions, and a surface having different curvature between the front and the rear.
As illustrated in
As illustrated in
In the present embodiment, the high-elastic urethane foam is adopted, because high-elastic urethane foam has low temperature dependence and excellent durability. Needlessly to say, low-elastic urethane foam may be used for the elastic member, or a thin member such as an elastic sheet may be used.
When the upper base unit 31 receives a load and moves in any direction of 360 degrees including the front-rear, left-right, and diagonal directions with respect to the lower base unit 32, as illustrated in
Generally, it is conceivable to use, as the movement mechanism, a guide mechanism composed of a cam and a follower between an upper base unit and a lower base unit, and a link mechanism connecting the upper base unit and the lower base unit. Compared to such a structure, the movement mechanism 3 of the present embodiment utilizes the rolling surfaces 312a and 322a to realize an operation of the seat 1 in which a tilting movement component is larger than a horizontal movement component. The chair of the present embodiment that performs such an operation is particularly easy to use in a situation where a person frequently sits down and stands up from a seat.
The curvatures of the rolling surfaces 312a and 322a are set so that a gravity center position G of the seat 1 is lifted to G′ by the movement, as illustrated by a solid line and an imaginary line in
As illustrated in
In addition, in the upper base unit 31, the lower base unit 32, and the elastic member 33, first holes 31P to 33P for inserting a pin 341 constituting the first connection member 34 are opened along a first line L1, and second holes 31Q to 33Q for inserting a shaft 351 constituting the second connection member 35 are opened along a second line L2. The holes 31P, 32P, 33P, 31Q, 32Q, and 33Q prevent the pin 341 and the shaft 351 from interfering with the rolling surfaces 312a and 322a and the elastic member 33, and thus, are also referred to as “relief holes” herein.
The first connection member 34 is mainly composed of three of the pins 341, and the pins 341 are formed as an integral member with a flange unit 342. The pins 341 are inserted through the first hole 31P of the upper base unit 31 (that is, the first hole 31P of the seat receiver 311 and the first hole 31P of the upper base plate 312), the first hole 33P of the elastic member 33, and the first hole 32P of the lower base unit 32 (that is, the first hole 32P of the lower base plate 322), respectively, and the pins 341 are fastened from below by bolts (not illustrated) at positions where the pins 341 abut against the support base unit 321 constituting the lower base unit 32.
With such a structure, for example, a relative position (distance L) between the flange unit 342 of the first connection member 34 and the support base unit 321 in
When the seat 1 swings in the front-rear direction as illustrated in
In the present embodiment, as illustrated in
As illustrated in
As described above, the second connection member 35 imparts a damper effect to the operation of the movement mechanism 3. Specifically, as illustrated in
Each of the shafts 351 is a bolt-shaped shaft having a large-diameter proximal end unit 351a at a lower end. In a state where the upper end side of the shafts 351 is inserted through the second hole 32Q of the support base unit 321 from the bottom surface side of the support base unit 321, the proximal end unit 351a is accommodated in a recessed unit 355a of a cocoon-shaped (see
As illustrated in
The shafts 351 protrude upward via the second hole 32Q of the lower base unit 32 (that is, the second hole 32Q of the support base unit 321 and the second hole 32Q of the lower base plate 322), the second hole 33Q of the elastic member 33 (not illustrated in
On the other hand, as illustrated in
The return spring 36 is arranged at a plurality of locations (three locations in the present embodiment) over a range of 180 degrees or more (for example, 270 degrees) around a center position (reference numeral O in
As described above, the second connection member 35 has a configuration in which the O-rings 353 made of a friction material are fitted between the shafts 351, which are columnar members, and the hole units 311b.
Specifically, as illustrated in
On the other hand, as illustrated in
An inner diameter of the O-rings 353 is chosen so that the O-rings 353 fit with the shafts 351 with a predetermined sliding resistance, and the predetermined sliding resistance is chosen so that a required damper effect can be obtained when the seat 1 swings. In the present embodiment, NBR rubber is used for the O-rings 353. However, the material is not limited thereto, and various materials may be adopted as the material for realizing the sliding resistance.
The shafts 351 are passed through the shaft holes 352 and fitted to the O-rings 353 from above, and the pressing tool 356 is pushed from above to fit the projecting unit 356b into the hole unit 311b. Thus, the O-rings 353 are pressed against the bottom wall 311a of the seat receiver 311 by the end unit 356a to realize the assembled state illustrated in
If the upper base unit 31 swings, as illustrated in
That is, the damper mechanism DM is arranged at a plurality of locations around a center position of the upper base unit 31 over a range of 180 degrees or more (for example, 270 degrees). Therefore, if the seat 1 moves in any direction of 360 degrees, the shafts 351 and the O-rings 353 operate while following the movement of the seat 1 and sliding relative to each other, and exert a damper action by a sliding resistance in both directions of an operation in which a distance between the upper base unit 31 and the lower base unit 32 is expanded or contracted.
In a chair having such a configuration, in a state where no seating load is applied, the gravity return mechanism GRM mentioned above attempts to return the chair to a position (reference position) where the center of gravity of the movable portion including the upper base unit 31, the seat 1, and the back 4 is lowest. At that time, a restoring force of the elastic member 33 and an auxiliary restoring force of the return spring 36 act together, and thus, the chair stops at the overall most stable position.
The seat 1 of the chair can swing from the reference position N in any direction of 360 degrees including the front-rear, left-right, and diagonal directions, when the upper base plate 312 performs a rolling operation with respect to the lower base plate 322.
In the rolling surfaces performing such a rolling operation, the upper base plate 312 and the lower base plate 322, which are surfaces facing each other, include the first holes 31P and 32P for passing the pins 341 constituting the first connection member as illustrated in
In the holes 31P, 32P, 31Q, 32Q, and the like, regions having different so-called curvatures are formed and the continuity of the rolling surfaces 312a and 322a is impaired. Therefore, if the upper base plate 312 constituting the upper base unit 31 rolls directly on the lower base plate 322 constituting the lower base unit 32, the upper base unit 31 is likely to rattle due to the change in the curvature. The rattling propagates as a rattling of the seat 1.
On the other hand, in the present embodiment, the elastic member 33 is interposed between the above-described region in one of the upper base unit 31 and the lower base unit 32 and a corresponding region in the other one of the upper base unit 31 and the lower base unit 32. The elastic member 33 lowers the stability when opening peripheral edges of the holes 31P, 31Q, and the like existing in the rolling surface 312a of the upper base unit 31 abut against the rolling surface 322a of the lower base unit 32 facing the rolling surface 312a, and lowers the stability when opening peripheral edges of the holes 32P and 32Q existing in the rolling surface 322a of the lower base unit 32 abut against the rolling surface 312a of the upper base unit 31 facing the rolling surface 322a. That is, the elastic member 33 facilitates rolling between the rolling surfaces 312a and 322a at a place where the curvature of the rolling surfaces 312a and 322a changes and smooths the change of the curvature. Needlessly to say, even in a place where no hole is formed, and also a place where the surface of the rolling surfaces 312a and 322a is irregular or deteriorated, the elastic member has an effect of reducing the rattling caused by the irregular or deteriorated surface.
As illustrated in
Therefore, in the present embodiment, as illustrated in
Specifically, grooves 312x and 322x extending along the outer peripheral edges 312z and 322z and opening in opposite directions are provided in the vicinity of the outer peripheral edges 312z and 322z of the swinging surfaces 312a and 322a facing each other, and in the cover member 6, deformable strips 61 and 62 are attached to edge portions of the stretchable sheet material 60. As illustrated in
For example, the stretchable sheet material 60 is formed by using a material obtained by knitting polyester fibers. In the present embodiment, the stretchable sheet material 60 is sewn or formed into a cylindrical shape, and the strips 61 and 62 made of resin and having an annular thin plate shape are integrally provided at the upper end and the lower end of the stretchable sheet material 60. The size and elasticity of the stretchable sheet material 60 are chosen so that no wrinkles are generated when the gap is most narrow and so that the stretchable sheet material 60 does not hinder the operation of the swinging surface when the gap is widened. The relationship between the grooves 312x and 322x and the strips 61 and 62 is one-to-one, and each of the strips 61 and 62 corresponds to the entire area of one of the grooves 312x and 322x, and the strips 61 and 62 are provided having a length that surrounds the grooves 312x and 322x. Needlessly to say, the material of the stretchable sheet material 60 is not limited to the above-described materials, and various materials such as cloth, upholstery, woven fabric, and knitted items can be used, as long as the material can be stretched and contracted and covers the inside. The stretchable sheet material 60 that can hide the inside is used, but the stretchable sheet material 60 may be a material through which the inside is slightly visible.
As illustrated in
As illustrated in
As illustrated in
As described above, the chair of the present embodiment includes the upper base unit 31 and the lower base unit 32 facing each other, and the seat 1 that is provided in the upper base unit 31 and swings when the upper base unit 31 rolls with respect to the lower base unit 32, and the upper base unit 31, which is at least one of the upper base unit 31 and the lower base unit 32, includes the rolling surface 312a being curved. In the chair, a region having a different curvature exists in a part of the rolling surface 312a, and the elastic member 33 is interposed between the region having the different curvature and a corresponding region of an opposing surface.
According to such a configuration, the upper base unit 31 can follow the movement of the seated person while rolling via the rolling surface 312a, and thus, the seated person can easily find a weight balance while supporting his or her own weight, and can change his or her posture stably and continuously. At that time, even if a region having a different curvature exists in a part of the rolling surface 312a, the elastic member 33 interposed between the region of the rolling surface 312a and a corresponding region of the opposing surface makes it possible to effectively prevent rattling and generation of an undesirable noise due to the change in curvature, during the operation of the upper base unit 31, and therefore, the operation of the seat 1.
Specifically, the first and second connection members 34 and 35 that connect the upper base unit 31 and the lower base unit 32 are provided, and regions having different curvatures are formed by the relief holes 31P, 32P, 31Q, and 32Q for inserting the first and second connection members 34 and 35.
Such relief holes 31P, 32P, 31Q, and 32Q contact the opposing surface only in the periphery of the hole and there is no contact in the inside of the hole, and thus the relief holes 31P, 32P, 31Q, and 32Q tend to form stabilization points, which cause rattling or the like. In contrast, if the elastic member 33 is interposed at such a position, no highly stable state is created between the periphery of the hole and the opposing surface, and the change in the contact state is smoothed, and thus it is possible to attenuate occurrence of rattling and undesirable noise. Thus, the connection members 34 and 35 can be arranged in a part of the rolling surfaces 312a and 322a, and thus the degree of freedom in design is improved.
In particular, the upper base unit 31 swings in a direction of 360 degrees with respect to the lower base unit 32, and the relief holes 31P, 32P, 31Q, and 32Q are provided at three or more locations around the swing center.
In a case where such a configuration is used and the seat 1 moves in a direction of 360 degrees including the front-rear, left-right, and diagonal directions, if the connection members 34 and 35 are provided in an outer periphery of the upper base unit 31 and the lower base unit 32 to avoid interference with the rolling surfaces 312a and 322a, the entire mechanism including the connection members 34 and 35 is very large when viewed in a plan view. In contrast, in the configuration of the present embodiment, the connection members 34 and 35 can be arranged in a part of the rolling surfaces 312a and 322a and do not need to be arranged on the outside, and thus it is possible to avoid an unnecessarily increase in the size of the components of the mechanism including the connection members 34 and 35 when viewed in a plan view. In other words, the size of the rolling surfaces 312a and 322a can be increased as much as possible within an allowable range.
The pins 341 constituting the first connection member 34 of the present embodiment are rotation stop members that restrict a relative movement of the upper base unit 31 and the lower base unit 32 in a rotation direction, and may be passed through the rolling surfaces 312a and 322a to obtain an appropriate arrangement of the rotation stop members.
The pins 341 constituting the first connection member 34 of the present embodiment are also detachment stop members that restrict a separation between the upper base unit 31 and the lower base unit 32, and may be passed through the rolling surfaces 312a and 322a to obtain an appropriate arrangement of the detachment stop members.
The shafts 351 constituting the second connection member 35 of the present embodiment are constitution components of the damper mechanism DM which is a braking mechanism that slows down the movement of the seat 1 by a relative movement between two members, and may be passed through the rolling surfaces 312a and 322a to obtain an appropriate arrangement of the damper mechanism DM.
The third connection member 36 of the present embodiment is a return spring interposed between the upper base unit 31 and the lower base unit 32 to return the upper base unit 31 to the predetermined reference position N with respect to the lower base unit 32, and may be passed through the rolling surfaces 312a and 322a to obtain an appropriate arrangement of the return spring 36.
In the present embodiment, an elastic resin foam body interposed between the upper base unit 31 and the lower base unit 32 is employed as the elastic member 33.
With such a configuration, it is possible to impart an appropriate thickness to the elastic resin foam body, and, for example, by selecting a proper elastic resin foam body from various materials, including an elastic resin foam body having low resilience and an elastic resin foam body having high resilience, it is possible to easily impart various characteristics such as a cushioning effect and a delay effect.
Needless to say, as the elastic member, an elastic sheet may be interposed between the upper base unit 31 and the lower base unit 32, and thereby, the space between the rolling surfaces 312a and 322a can be flattened and the space between the upper base unit 31 and the lower base unit 32 can be compact.
In the present embodiment, the elastic member 33 is also provided with the relief holes 33P and 33Q, and thus, the space between the upper base unit 31 and the lower base unit 32 can be sufficiently filled with the elastic member 33, except for the relief holes 33P and 33Q.
In the present embodiment, the arms 5 are attached to the lower base unit 32 and the seat 1 is attached to the upper base unit 31. When the upper base unit 31 rotates with respect to the lower base unit 32, a positional relationship between the seat 1 and the arms 5 changes. However, if the rotation stop member 34 mentioned above is employed, it is possible to maintain an appropriate state of the chair.
The embodiment of the present invention has been described, and a specific configuration of each unit is not limited to that in the embodiment described above and various modifications are possible without departing from the gist of the present invention.
Number | Date | Country | Kind |
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2021-162894 | Oct 2021 | JP | national |