JP2009100954A - Step device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To lift/lower a step board in a simple structure in a step device. <P>SOLUTION: The step device 10 having the step board 14 on which a person seated on the seat puts the feet, and a vertical slide mechanism 16, slidingly moving vertically the step board 14 is further provided with: a link 22 having one end rotationally connected to the step board 14 and having a predetermined length; a horizontal slide mechanism 24 horizontally slidingly moving the other end of the link 22; and moving control means 30 and 32 provided in the seat side and preventing the other end of the link 22 from being horizontally slidingly moved by the horizontal slide mechanism 24 at a predetermined lift position of the step board 14. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a step device, and more particularly to a step device suitable for raising and lowering a step plate on which a person sitting on a seat puts his / her foot in the vertical direction.

2. Description of the Related Art Conventionally, there is known a step device that can adjust the height of a step plate on which a person sitting on a seat in a wheelchair or the like places his / her foot (see, for example, Patent Document 1). The apparatus described in Patent Document 1 includes a fixed base provided on the seat side, an elevating base to which a step plate is attached, a screw shaft that moves the elevating base vertically with respect to the fixed base, and a screw shaft that rotates. And an electric motor. In this apparatus, the screw shaft is rotated by driving the electric motor, and the elevating base moves in the vertical direction with respect to the fixed base. Therefore, according to such an apparatus, the step plate can be moved up and down by driving with an electric motor.
JP 2007-68834 A

  However, in the apparatus described in Patent Document 1 described above, the step plate is moved up and down using an electric motor, so a space for mounting the electric motor and the screw shaft mechanism is required, and wiring to the power source and the electric motor is required. Alternatively, a controller for controlling the electric motor is required, and as a result, the total weight increases or the structure becomes complicated.

  The present invention has been made in view of the above-described points, and an object of the present invention is to provide a step device that realizes raising and lowering of a step plate with a simple structure.

  The above object is a step device including a step plate on which a person sitting on a seat puts his / her foot, and an up / down slide mechanism for sliding the step plate in the up / down direction, one end being on the step plate or the seat side. A link having a predetermined length that is rotatably connected, a horizontal slide mechanism that slides the other end of the link in the horizontal direction, and the other end of the link at a predetermined rising position or a predetermined lowering position of the step plate Is achieved by a step device comprising movement restriction means for restricting sliding movement in the horizontal direction by the horizontal slide mechanism.

  In the invention of this aspect, the other end of the link can be slid in the horizontal direction by the horizontal slide mechanism when the step plate is located at a position other than the predetermined ascending position or the predetermined descending position. When the step plate is located at the lowermost or uppermost position, the other end of the link is farthest in the horizontal position with respect to the connecting portion with the step plate or the seat side, and the link is inclined at the largest angle. From this state, when a force is applied upward or downward to the step plate or a force to reduce the inclination angle is applied to the link, the link rotates about the connecting portion with the step plate or the seat side, and the link Is horizontally slid by the horizontal slide mechanism so that the other end of the plate approaches the step plate or the connecting portion with the seat side in the horizontal direction position. Thereby, a step board raises or descends. Then, when the step plate is located at the predetermined ascending position or the predetermined descending position, the slide movement of the other end of the link is restricted, so that the step plate is not lifted or lowered, and the height position thereof is the predetermined ascending position or the predetermined position. Maintained in the lowered position. Therefore, according to the present invention, the elevation of the step plate can be realized with a simple structure.

  In the above-described step device, one end of the link may be rotatably connected to the step plate, and the movement restricting means may be provided on the seat side.

  Further, in this step device, the movement restricting means should be present when the horizontal position of the other end of the link with respect to the connecting portion between the link and the step plate is located at a predetermined lowered position. In a situation where the second position side is opposite to the first position side, the other end of the link may be restricted from sliding in the horizontal direction by the horizontal slide mechanism at a predetermined rising position of the step plate. .

  In the invention of this aspect, when the horizontal position of the other end of the link with respect to the connecting portion with the step plate is the first position side, the slide movement of the other end of the link is allowed and the step plate is allowed to move up and down. Is done. On the other hand, when the horizontal position of the other end of the link with respect to the connecting portion is the second position side, the sliding movement of the other end of the link is restricted, the step plate is prohibited from being raised and lowered, and the height position is the predetermined position. Maintained in the raised position. Therefore, according to the present invention, the elevation of the step plate can be realized with a simple structure.

  Further, in the above-described step device, the horizontal slide mechanism is connected to the horizontally extending rail fixed to the seat side and the other end of the link, and is capable of sliding horizontally along the rail. It is good also as having a member.

  In the invention of this aspect, the horizontal movement of the other end of the link is realized by the horizontal movement of the horizontal movement member along the rail.

  Further, in the above-described step device, the movement restricting means is provided at substantially the same horizontal position with respect to the connecting portion between the link and the step plate, and the horizontal movement member protrudes on the rail on which the slide movement is performed. It is good also as having the protrusion part to perform and the stopper provided adjacent to the horizontal direction edge part of the said rail.

  In this aspect of the invention, when the step plate is located at the predetermined ascending position, the stopper restricts the sliding movement of the horizontal moving member such that the step plate descends from the predetermined ascending position, and the protrusions cause the step plate to be predetermined. Slide movement of the horizontal movement member that further rises from the raised position is restricted. For this reason, it can prevent that the height position of the step board located in a predetermined raising position becomes easy to change by disturbance.

  In the above-described step device, the step is provided with a horizontally extendable spring having one end fixed to the seat side or the step plate and the other end attached to the other end of the link. The expansion and contraction of the spring may be prohibited at a predetermined rising position or a predetermined lowering position of the plate, and the other end of the link may be restricted from sliding in the horizontal direction by the horizontal slide mechanism.

  In the invention of this aspect, when the step plate is located at a position other than the predetermined ascending position or the predetermined descending position, the other end of the link is slid in the horizontal direction by the horizontal sliding mechanism by allowing the spring to expand and contract. Is possible. On the other hand, when the step plate is located at the predetermined ascending position or the predetermined descending position, the expansion and contraction of the spring is prohibited, so that the sliding movement of the other end of the link is restricted. When such a restriction is made, the step plate is prevented from being raised and lowered, and its height position is maintained at the predetermined ascending position or the predetermined descending position. Therefore, according to the present invention, the elevation of the step plate can be realized with a simple structure.

  In the above-described step device, one end of the link is rotatably connected to the step plate, one end of the spring is fixed to the seat side, and the movement restricting means is a positioning provided on the seat side. It is good also as having a hole and the detachable positioning pin inserted in the said positioning hole through the other end of the said link.

  In this aspect of the invention, when the positioning pin is inserted into the positioning hole through the other end of the link, the expansion and contraction of the spring is prohibited, so that the sliding movement of the other end of the link is restricted and the step plate is not allowed to move up and down. Is done. Therefore, according to the present invention, the elevation of the step plate can be realized with a simple structure.

  In the above-described step device, the positioning hole includes a lower positioning hole into which the positioning pin is inserted through the other end of the link at a predetermined lowered position of the step plate, and the positioning pin at a predetermined raised position of the step plate. It is good also as having a raising positioning hole inserted through the other end of the said link.

  In the invention of this aspect, when the positioning pin is inserted into the lower positioning hole through the other end of the link, the expansion and contraction of the spring is prohibited, so that the sliding movement of the other end of the link is restricted and the step plate is lifted. It is forbidden. Further, when the positioning pin is inserted into the rising positioning hole through the other end of the link, the expansion and contraction of the spring is prohibited, so that the sliding movement of the other end of the link is restricted and the lowering of the step plate is prohibited. When the insertion of the positioning pin into the descending positioning hole or the ascending positioning hole is released, the spring expands and contracts to the balance position, so that the other end of the link slides and the step plate is raised and lowered. On the other hand, when the spring is forcibly expanded and contracted from the balance position and the positioning pin is inserted into the lower positioning hole or the upper positioning hole through the other end of the link, as described above, the step plate is prevented from moving up and down. Therefore, according to the present invention, the elevation of the step plate is realized with a simple structure.

  Further, in the above-described step device, the horizontal slide mechanism is connected to the horizontally extending rail fixed to the seat side and the other end of the link, and is capable of sliding horizontally along the rail. It is good also as having a member.

  In the invention of this aspect, the horizontal movement of the other end of the link is realized by the horizontal movement of the horizontal movement member along the rail.

  Furthermore, in the above-described step device, the spring slides the other end of the link in a predetermined horizontal direction by the horizontal slide mechanism at a position other than the predetermined ascent position of the step plate to move the step plate to the predetermined ascent position. It is good also as generating the spring force which raises toward.

  In the invention of this aspect, when the holding of the step plate at the predetermined lowered position is released, the other end of the link is slid in the predetermined horizontal direction by the horizontal slide mechanism by the spring force of the spring, and the step plate is predetermined. It is raised toward the raised position, and the rise of the step plate is stopped at the spring balance position. When the step plate is pressed downward from this state, a force against the spring force of the spring is applied, so that the other end of the link is slid in the direction opposite to the predetermined horizontal direction described above. When the step plate is held at the predetermined lowered position, the elevation of the step plate is restricted. Therefore, according to the present invention, the step plate can be lifted and lowered semi-automatically with a simple structure.

  According to the present invention, raising and lowering of the step plate can be realized with a simple structure.

  Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram of a main part of a vehicle including a step device 10 according to a first embodiment of the present invention. FIG. 2 shows a perspective view of the step device 10 of this embodiment. FIG. 3 is a perspective view of a horizontal slide mechanism provided in the step device 10 of the present embodiment. FIG. 4 is a diagram for explaining the operation of the step device 10 of this embodiment. FIG. 4A shows a situation where the step plate is located at a predetermined lowered position, and FIG. 4B shows a situation where the step plate is located at a predetermined raised position.

  In the present embodiment, the vehicle includes a seat 12 on which a person sits, a step plate 14 on which a person sitting on the seat 12 puts his / her foot, and a step device 10 that raises and lowers the step plate 14.

  The step device 10 includes a vertical slide mechanism 16 that slides the step plate 14 in the vertical direction. The vertical slide mechanism 16 includes two rails 18 that are fixed to the seat 12 side, that is, the vehicle main body side and extend in the vertical direction, and a slide block 20 that is slidable in the vertical direction along the rails 18 within the rail 18. have.

  The step plate 14 includes a step main body portion 14a that faces in the up-down direction and spreads horizontally, and a slide portion 14b that extends downward from one end of the lower surface of the step main body portion 14a. The above-described slide block 20 is fixed and connected to the slide portion 14b of the step plate 14. Accordingly, the movement of the step plate 14 is limited only in the vertical direction with respect to the seat 12 side by the sliding movement of the slide block 20 along the rail 18.

  Further, one end of the link 22 is connected to the vicinity of the center of the lower surface of the step body 14a. A connecting portion between one end of the link 22 and the step main body portion 14a is configured to be rotatable. Accordingly, the link 22 is rotatable with respect to the step main body portion 14a. The link 22 has a predetermined length in the longitudinal direction. This predetermined length corresponds to a change in height required for raising and lowering the step plate 14 as will be described later. Further, a through hole 25 penetrating in the same direction as the rotation shaft is provided near the center of the link 22 in the longitudinal direction. The through hole 25 is opened to a size that allows a human finger to be inserted.

  The step device 10 also includes a horizontal slide mechanism 24 that slides the other end of the link 22 in the horizontal direction. The horizontal slide mechanism 24 includes a rail 26 fixed to the seat side, that is, the vehicle main body side, and a roller 28 that can slide in the horizontal direction along the rail 26 in the rail 26. The rail 26 extends in the horizontal direction, has a horizontal length corresponding to the length of the link 22, and has a U-shaped cross section that sandwiches the roller 28 in the vertical direction. The roller 28 is rotatably connected to the other end of the link 22 via a shaft 29. Accordingly, the other end of the link 22 is limited only in the horizontal direction with respect to the sheet 12 side as the roller 28 slides along the rail 26.

  A stopper 30 that restricts the sliding movement of the roller 28 is provided adjacent to the horizontal end (the right end in FIG. 4) of the rail 26 of the horizontal slide mechanism 24. The stopper 30 is set so that its horizontal position is separated from the horizontal position of the connecting portion between one end of the link 22 and the step main body portion 14a by the diameter of the roller 28. The stopper 30 is a plate-like member that closes the opening of the rail 26 on which the roller 28 slides.

  The rail 26 is provided with a protrusion 32 in a U-shaped cross section that is a portion with which the roller 28 contacts. The protrusion 32 is provided to make it difficult for the roller 28 to slide along the rail 26, and its horizontal position is substantially the same as the horizontal position of the connecting portion between the one end of the link 22 and the step body 14 a. It is set to be the same. The height of the protrusion 32 is set to such an extent that the roller 28 can slide in the horizontal direction within the U-shaped section of the rail 26.

  The rail 26 is provided with a protrusion 34 at a horizontal end (left end in FIG. 4) in a U-shaped cross section, which is a portion with which the roller 28 contacts. The protrusion 34 is provided to prohibit further sliding movement of the roller 28 along the rail 26, and is a leaf spring, for example. The height of the protrusion 34 is set to such an extent that the roller 28 can be sandwiched between the protrusion 26 and the inner wall in the U-shape of the cross section of the rail 26. In addition, the projection part 32 and the projection part 34 are good also as being comprised by the integrated member.

  Next, operation | movement of the step apparatus 10 of a present Example is demonstrated.

  In the step device 10 of the present embodiment, when the step plate 14 is positioned at the lowest position with respect to the vertical slide mechanism 16, the other end of the link 22 is horizontal with respect to the connecting portion with the step plate 14 by the horizontal slide mechanism 24. The link 22 inclines at the largest angle farthest in the direction (the predetermined lowered position shown in FIG. 4A). In this case, the roller 28 is sandwiched between the inner wall of the rail 26 and the protrusion 34 in the rail 26, so that the horizontal position of the other end of the link 22 is fixed and the link 22 rotates (the other end). Is only allowed to move further away in the horizontal direction with respect to the connecting portion).

  From this state, for example, when the step plate 14 is lifted by a rider's operation and an upward force is applied to the step plate 14, the other end of the link 22 is connected to the connection portion with the step plate 14 by the horizontal slide mechanism 24. As a result, the link 22 is slid in the horizontal direction so as to approach the position in the horizontal direction, and the link 22 rotates about the connecting portion with the step plate 14. Depending on the action of the upward force on the step plate 14, the link 22 can be rotated until it becomes a right angle with respect to the step plate 14, and the slide position of the other end of the link 22 has its horizontal position. It is possible to carry out until the horizontal position of the connecting portion with the step plate 14 is matched. That is, the step plate 14 can be positioned on the uppermost side with respect to the vertical slide mechanism 16 by being lifted from the predetermined lowered position.

  At this time, if the upward force on the step plate 14 is released before the horizontal position of the other end of the link 22 reaches the horizontal position of the connecting portion with the step plate 14, the other end of the link 22 Is returned to the original position by the action of the gravity of the step plate 14 and is slid in the horizontal direction by the horizontal slide mechanism 24 so as to be separated from the connecting portion with the step plate 14 in the horizontal direction. Will grow again. Therefore, at this time, unless an upward force is applied to the step plate 14, the step plate 14 is lowered by its own weight and reaches the predetermined lowered position again.

  On the other hand, after the horizontal position of the other end of the link 22 reaches the horizontal position of the connecting portion with the step plate 14, the stopper 30 side (shown in FIG. 4) is located near the center in the longitudinal direction of the link 22 by human operation. When a force is applied in the horizontal direction on the right side, the roller 28 gets over the protrusion 32 on the rail 26 and comes into contact with the stopper 30. In this case, the link 22 is rotated and inclined slightly more than the state perpendicular to the step plate 14, and the roller 28 is positioned in the horizontal direction by the stopper 30 and the protrusion 32. The sliding movement along the rail 26 at the other end of the link 22 is restricted.

  That is, the other end of the link 22 approaches the connecting portion with the step plate 14 by the horizontal slide mechanism 24 in the horizontal direction, so that the inclination angle of the link 22 is reduced and the roller 28 is stopped within the rail 26 by the stopper 30. , The sliding movement of the other end of the link 22 toward the stopper 30 is restricted, and the rotation of the link 22 is prohibited. Therefore, at this time, even if a person's foot is placed on the step board 14, the lowering of the step board 14 is prohibited, and the height position thereof is maintained at a predetermined ascending position as shown in FIG.

  Further, when a force is applied in the horizontal direction on the protrusion side (left side shown in FIG. 4) near the center in the longitudinal direction of the link 22 by a human operation from the state where the step plate 14 is located at the predetermined ascending position, the roller 28 is Get over the protrusion 32 on the rail 26 to the opposite side. In this case, the link 22 is slid in the horizontal direction by the horizontal slide mechanism 24 so that the other end of the link 22 is separated from the connecting portion with the step plate 14 in the horizontal direction by the rotational torque accompanying the gravity action of the step plate 14. Thus, the inclination angle of the link 22 is increased again. Therefore, at this time, the step plate 14 is lowered by its own weight and reaches the predetermined lowered position again.

  Thus, according to the step device 10 of the present embodiment, the height position of the step plate 14 can be switched between the predetermined lowered position and the predetermined raised position. Specifically, the step plate 14 is switched from a predetermined lowered position to a predetermined raised position, the step plate 14 is lifted upward by a human operation, and then the link 22 standing substantially vertically is pulled horizontally to stop the other end. This can be realized by abutting on 30. Further, when the step plate 14 is switched from the predetermined ascending position to the predetermined descending position, the link 22 whose other end is in contact with the stopper 30 is pulled in the horizontal direction by a human operation, and the other end is slid to the projection 34 side. Can be realized.

  In this respect, in this embodiment, since it is not necessary to use an electric motor to realize the up and down movement of the step plate 14, inconvenience due to the use of this electric motor can be avoided, for example, The mounting space for the electric motor can be reduced, and the electric motor, wiring, and controller for controlling the electric motor can be eliminated. Therefore, according to the step device 10 of the present embodiment, the step plate 14 can be moved up and down with a simple structure without consuming electric power.

  In the present embodiment, when the step plate 14 is located at the predetermined ascending position, the other end of the link 22 slides toward the stopper 30 so that the step plate 14 descends as described above (FIG. 4B ) Is restricted / prohibited, but the slide movement toward the projection 34 side where the step plate 14 is raised by the projection 32 (left in FIG. 4B). (Slide movement in the direction) will be regulated and suppressed. For this reason, according to the step device 10 of the present embodiment, when the step plate 14 is positioned at the predetermined ascending position, the height position of the step plate is prevented from being easily changed due to body vibration caused by disturbance. It is possible.

  Further, in this embodiment, when the step plate 14 is located at the predetermined lowered position, the roller 28 is sandwiched between the inner wall of the rail 26 and the protrusion 34 in the rail 26, so that the roller 28 further exceeds the roller 28. The sliding movement is prohibited and the sliding movement of the roller 28 toward the stopper 30 is suppressed. That is, the roller 28 does not slide to the stopper side unless a certain amount of force is applied. For this reason, according to the step device 10 of the present embodiment, when the step plate 14 is located at the predetermined lowered position, it is possible to prevent the height position of the step plate from being easily changed due to the vibration of the vehicle body due to disturbance. It is possible.

  Further, in this embodiment, the step plate 14 is moved up and down manually, but in order to raise the step plate 14 from the predetermined lowered position to the predetermined raised position, a force in the horizontal direction is applied to the link 22. There is a need. Here, in the step device 10 of the present embodiment, a through hole 25 penetrating in the same direction as the rotation shaft is provided near the center of the link 22 in the longitudinal direction. Since this through hole 25 is opened to a size that allows human fingers to be inserted, inserting a finger into the through hole 25 makes it easy for a person to apply a force in the horizontal direction to the link 22. Become. Therefore, according to this embodiment, it is easy to manually slide the link 22 in the process of raising the step plate 14 to the predetermined ascending position.

  In the first embodiment, the stopper 30 and the protrusion 32 are connected to the "movement restricting means" described in the claims on the protrusion 34 side as viewed from the connecting portion of the link 22 and the step plate 14. The roller 28 is patented in the "first position" described in the claims in the horizontal direction, the horizontal position on the stopper 30 side as viewed from the connecting portion in the "second position" described in the claims. The protrusion 32 corresponds to the “horizontal moving member” recited in the claims, and the protrusion 32 corresponds to the “protrusion” recited in the claims.

  FIG. 5 is a perspective view of the step device 100 according to the second embodiment of the present invention. FIG. 6 is a perspective view of a main part of the horizontal slide mechanism provided in the step device 100 of the present embodiment. FIG. 7 shows a side view of the horizontal slide mechanism provided in the step device 100 of the present embodiment. FIG. 8 is a view showing a cross section AA of the horizontal slide mechanism shown in FIG. Moreover, FIG. 9 shows the figure for demonstrating the operation | movement in the step apparatus 100 of a present Example. FIG. 9A shows a situation where the step plate is located at a predetermined lowered position, and FIG. 9B shows a situation where the step plate is located at a predetermined raised position. 5 to 9, the same reference numerals are given to the same components as those shown in FIGS. 1 to 4, and the description thereof is omitted or simplified.

  In the present embodiment, the step device 100 includes a horizontal slide mechanism 102. The horizontal slide mechanism 102 includes a rail 26 and a roller 28. A stopper 104 is provided adjacent to the horizontal end of the rail 26 of the horizontal slide mechanism 102 (the right end in FIG. 9). One end of a spring 106 is attached and fixed to the stopper 104. The other end of the spring 106 is fixedly attached to a roller 28 that is slidable along the rail 26.

  The spring 106 can be extended or contracted along the rail 26 from its natural length, and generates a spring force corresponding to the slide position of the roller 28 with respect to the stopper 104. Specifically, the step plate 14 has a predetermined value. A tension that generates a spring force that balances the horizontal component force acting on the other end of the link 22 due to the gravitational action of the step plate 14, that is, a spring force that stops the roller 28 with respect to the stopper 104 when it is in the raised position. It is a spring.

  A shaft 29 that connects the other end of the link 22 and the roller 28 includes a bolt that connects the link 22 and the roller 28 in the axial direction. The bolt 29 has a hollow portion having a hole penetrating in the axial direction. Also, a through-hole penetrating in the axial direction (hereinafter referred to as a descending-side through-hole) is formed in the side wall of the rail 26 where the shaft portion of the roller 28 faces the axial direction when the step plate 14 is located at the predetermined lowered position. When the step plate 14 is located at a predetermined raised position while the step plate 14 is open, a through-hole penetrating in the axial direction (hereinafter referred to as a rising-side through-hole) is formed on the side wall where the shaft portion of the roller 28 faces in the axial direction. ) 108 is open. Each of these through holes 108 has a diameter equivalent to the diameter of the hollow portion of the shaft 29 provided in the link 22 or the roller 28.

  A detachable positioning pin 110 can be inserted into the hollow portion of the bolt 29. The positioning pin 110 has an axial length slightly longer than the sum of the axial thickness of the link 22, the axial thickness of the roller 28 and the thickness of the side wall of the rail 26.

  Next, the operation of the step device 100 of this embodiment will be described.

  In the step device 100 of the present embodiment, when the step plate 14 is positioned at the lowest position with respect to the vertical slide mechanism 16, the other end of the link 22 is horizontal with respect to the connecting portion with the step plate 14 by the horizontal slide mechanism 102. The link 22 is inclined farthest in the direction at the largest angle (a predetermined lowered position shown in FIG. 9A). In this case, the spring 106 generates a large spring force that extends beyond the natural length and pulls the roller 28 toward the stopper 104, but the positioning pin 110 is moved by the human operation via the other end of the link 22 and the roller 26. The horizontal position of the other end of the link 22 is fixed, and the rotation of the link 22 is prohibited. Therefore, the person can insert the positioning pin 110 into the other end of the link 22, the roller 28, and the descending through hole 108, thereby maintaining the height position of the step plate 14 at the predetermined lowered position.

  From this state, when the insertion of the positioning pin 110 into the descending through hole 108 is released by a human operation, the other end of the link 22 is connected to the step plate 14 by the horizontal slide mechanism 102 by the spring force of the spring 106. The link 22 is slid in the horizontal direction so as to approach the horizontal position, and the link 22 rotates about the connecting portion with the step plate 14. Depending on the action of the spring force by the spring 106, the link 22 may rotate to a position where the spring force of the spring 106 and the horizontal component force acting on the other end of the link 22 due to the gravity action of the step plate 14 are balanced. It is possible, and the sliding movement of the other end of the link 22 can be performed until the balance occurs. That is, the step plate 14 can be automatically lifted with respect to the vertical slide mechanism 16 by the spring force of the spring 106 by releasing the insertion of the positioning pin 110 at the predetermined lowered position. When this occurs, it is located at a predetermined raised position as shown in FIG.

  When the step plate 14 is positioned at the predetermined ascending position, the positioning pin 110 can be inserted into the ascending-side through hole 108 of the rail 26 via the other end of the link 22 and the roller 28. When the insertion is performed, the horizontal position of the other end of the link 22 is fixed, and the rotation of the link 22 is prohibited. Therefore, when the person inserts the positioning pin 110 into the other end of the link 22, the roller 28, and the ascending-side through hole 108, the height position of the step plate 14 can be maintained at the predetermined ascending position.

  From this state, even if the insertion of the positioning pin 110 into the ascending-side through hole 108 is released by a human operation, the step plate 14 does not move up and down as it is, but for example, it is pressed by a human foot. When the step plate 14 is pressed downward, the other end of the link 22 is separated from the connecting portion with the step plate 14 by the horizontal slide mechanism 102 in the horizontal direction, and the link 22 is inclined. When the positioning pin 110 is inserted into the lower side through-hole 108 of the rail 26 through the other end of the link 22 and the roller 28 by a human operation when the step plate 14 is positioned at the predetermined lowering position, the link 22 The horizontal position of the other end is fixed and the rotation of the link 22 is prohibited, so that the height position of the step plate 14 is maintained at the predetermined lowered position.

  Thus, according to the step device 100 of the present embodiment, the height position of the step plate 14 can be switched between the predetermined lowered position and the predetermined raised position. Specifically, the step plate 14 can be raised from a predetermined lowering position by the spring force of the spring 106 after the insertion release operation from the lower side through hole 108 of the positioning pin 110, and the step plate 14. The maintenance to the predetermined ascending position can be realized by inserting the positioning pin 110 into the ascending-side through hole 108. Further, the step plate 14 can be lowered from the predetermined raised position by pressing the step plate 14 downward against the spring force of the spring 106, and maintaining the step plate 14 at the predetermined lowered position. Can be realized by an operation of inserting the positioning pin 110 into the descending through hole 108.

  In this respect, in this embodiment, since it is not necessary to use an electric motor to realize the up and down movement of the step plate 14, inconvenience due to the use of this electric motor can be avoided, for example, The mounting space for the electric motor can be reduced, and the electric motor, wiring, and controller for controlling the electric motor can be eliminated. Therefore, according to the step device 100 of the present embodiment, the step plate 14 can be moved up and down with a simple structure without consuming electric power.

  When the step plate 14 is located at a predetermined lowered position or a predetermined raised position, the positioning pin 110 is inserted into the lower side through hole 108 or the upper side through hole 108 of the rail 26 so that the step plate 14 moves up and down. Is prohibited. For this reason, when the step plate 14 is located at the predetermined lowered position and at the predetermined raised position, it is possible to prevent the height position of the step plate from being easily fluctuated due to body vibration caused by disturbance. It is.

  Further, in this embodiment, the step plate 14 is moved up and down manually. However, in order to raise the step plate 14 from the predetermined lowered position to the predetermined raised position, the step plate 14 is moved to the lower side through hole 108 of the positioning pin 110. It is sufficient to perform an operation of releasing the insertion of the step plate. After the releasing operation, the step plate 14 can be raised to a predetermined upper position by the spring force of the spring 106. In order to lower the step plate 14 from the predetermined raised position to the predetermined lowered position, the step plate 14 is appropriately stepped on from above with the foot, and the insertion operation of the positioning pin 110 into the rising side through hole 108 is performed. Is enough. Therefore, according to the step device 100 of the present embodiment, the step plate 14 can be lifted and lowered semi-automatically while realizing a simple structure.

  In the second embodiment, the descending side through hole 108 and the ascending side through hole 108 and the positioning pin 110 are included in the “movement restricting means” recited in the claims, and the descending side through hole 108 and the ascending side through hole are included. The hole 108 is described in the “Positioning hole” described in the claims, the descending through hole 108 is described in the “Descending positioning hole” described in the claims, and the rising through hole 108 is described in the claims. Each of them corresponds to a “rising positioning hole”.

  In the second embodiment, a tension spring is used as the spring 106. However, the present invention is not limited to this, and a compression spring may be used.

  By the way, in the first and second embodiments described above, a structure in which the vertical slide mechanism 16 extends downward from the lower surface of the step main body portion 14a of the step plate 14 is employed, but upward from the upper surface of the step main body portion 14a. It is good also as employ | adopting the structure extended.

  In the first and second embodiments described above, the horizontal slide mechanism 24 is provided only below the step plate 14, but two or more horizontal slide mechanisms 24 may be provided in parallel.

  In the first and second embodiments described above, the step-up / down position of the step plate 14 is switched to two stages of a predetermined ascending position and a predetermined descending position. However, the present invention is not limited to this. The elevation position may be switched between three or more stages. For example, in the first embodiment, a plurality of stoppers that can regulate the slide movement of the roll 28 in the horizontal slide mechanism 24 are provided at predetermined intervals in the extending direction of the rail 26, and one functioning stopper is selected. Also good. Further, in the second embodiment, a plurality of through holes 108 provided on the side wall of the rail 26 are provided at predetermined intervals in the extending direction of the rail 26, and one of the through holes 108 into which the positioning pins 110 are inserted is selected. It is good.

  In the first and second embodiments described above, one end of the link 22 is rotatably connected to the step plate 14, and the rails 26 of the horizontal slide mechanisms 24, 102 are fixed to the seat side, that is, the vehicle body side. However, the present invention is not limited to this, and one end of the link is rotatably connected to the seat side, that is, the vehicle body side, and the rails 26 of the horizontal slide mechanisms 24 and 102 are fixed to the step plate 14. Also good. In this case, one end of the spring 106 is fixed to the step plate 14.

It is a principal part block diagram of a vehicle provided with the step device which is 1st Example of this invention. It is a perspective view of the step apparatus of a present Example. It is a perspective view of the horizontal slide mechanism with which the step apparatus of a present Example is provided. It is a figure for demonstrating the operation | movement in the step apparatus of a present Example. It is a perspective view of the step apparatus which is 2nd Example of this invention. It is a principal part perspective view of the horizontal slide mechanism with which the step apparatus of a present Example is provided. It is a side view of the horizontal slide mechanism with which the step apparatus of a present Example is provided. It is the figure showing the AA cross section of the horizontal slide mechanism shown in FIG. It is a figure for demonstrating the operation | movement in the step apparatus of a present Example.

Explanation of symbols

10, 100 Step device 12 Sheet 14 Step plate 16 Vertical slide mechanism 22 Link 24, 102 Horizontal slide mechanism 26 Rail 28 Roller 30, 104 Stopper 32, 34 Protrusion 106 Spring 108 Through hole 110 Positioning pin

Claims (10)

A step device comprising a step plate on which a person sitting on a seat places his / her foot, and an up / down slide mechanism for sliding the step plate in the up / down direction,
A link having a predetermined length, one end of which is rotatably connected to the step plate or the sheet side;
A horizontal slide mechanism for sliding the other end of the link in the horizontal direction;
A movement restricting means for restricting the other end of the link from sliding in the horizontal direction by the horizontal slide mechanism at a predetermined ascending position or a predetermined descending position of the step plate;
A step device comprising: One end of the link is rotatably connected to the step plate,
The step device according to claim 1, wherein the movement restricting unit is provided on a seat side.   In the movement restricting means, the horizontal position of the other end of the link with respect to the connecting portion between the link and the step plate is opposite to the first position side that should be present when the step plate is located at a predetermined lowered position. 3. The step according to claim 2, wherein the second end of the link is restricted from being slid in the horizontal direction by the horizontal slide mechanism at a predetermined rising position of the step plate. apparatus.   The horizontal slide mechanism includes a horizontally extending rail fixed to the seat side, and a horizontal moving member connected to the other end of the link and slidable in the horizontal direction along the rail. The step device according to claim 2 or 3.   The movement restricting means is provided at substantially the same horizontal position with respect to the connecting portion between the link and the step plate, and a protrusion that protrudes on the rail on which the horizontal moving member slides, The step device according to claim 4, further comprising a stopper provided adjacent to the horizontal end. One end is fixed to the seat side or the step plate and the other end is attached to the other end of the link.
The movement restricting means prohibits expansion and contraction of the spring at a predetermined ascending position or a predetermined descending position of the step plate and restricts the other end of the link from sliding in the horizontal direction by the horizontal sliding mechanism. The step device according to claim 1 or 2. One end of the link is rotatably connected to the step plate,
One end of the spring is fixed to the seat side,
The step device according to claim 6, wherein the movement restricting unit includes a positioning hole provided on a seat side and a detachable positioning pin inserted into the positioning hole through the other end of the link.   The positioning hole includes a lower positioning hole where the positioning pin is inserted through the other end of the link at a predetermined lowered position of the step plate, and the positioning pin is inserted through the other end of the link at a predetermined raised position of the step plate. The step device according to claim 7, further comprising a raised positioning hole.   The horizontal slide mechanism includes a horizontally extending rail fixed to the seat side, and a horizontal moving member connected to the other end of the link and slidable in the horizontal direction along the rail. The step device according to claim 7 or 8.   The spring has a spring force that causes the other end of the link to slide in a predetermined horizontal direction by the horizontal slide mechanism at a position other than a predetermined ascent position of the step plate to raise the step plate toward a predetermined ascent position. The step device according to claim 6, wherein the step device is generated.

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