JP5707221B2 - Reach forklift - Google Patents

Description

  The present invention relates to a reach type forklift.

  In general, a reach-type forklift (hereinafter referred to as “forklift”) is known as a vehicle used for carrying luggage. A forklift is equipped with a fork (claw) that handles luggage in front of the vehicle, a mast (support) that supports the fork so as to be movable in the vertical direction, and has two front wheels that are idle wheels and one rear wheel that is a steering wheel. I have. The rear wheels are steered wheels and are also drive wheels that are rotationally driven by a drive source such as a motor that drives the forklift. In many cases, one rear wheel is arranged close to one side surface (for example, the left side surface) of the rear of the forklift vehicle. In this case, auxiliary wheels are arranged on the other side surface (for example, the right side surface) on the rear side of the vehicle.

  The rear wheel and the auxiliary wheel are suspended from the body of the forklift via a link mechanism for the purpose of absorbing the swing in the roll direction of the body of the forklift (see, for example, Patent Document 1). In this way, even if the body of the forklift swings in the roll direction, the link mechanism absorbs the swing of the body in the roll direction, and the rear wheels and the auxiliary wheels are stably grounded on the road surface. Can do.

  Specifically, when the vehicle body of the forklift is viewed from the rear and the vehicle body rolls to the right side (when the lower end of the right side of the vehicle body approaches the road surface), the auxiliary wheel is pushed in the direction approaching the vehicle body. The movement of the auxiliary wheel relative to the vehicle body is transmitted to the rear wheel via the link mechanism described above, and the rear wheel moves away from the vehicle body. That is, the rear wheel moves in a direction pressed against the road surface. Conversely, when the vehicle body rolls to the left, the rear wheels are pushed in a direction approaching the vehicle body. The movement of the rear wheel with respect to the vehicle body is transmitted to the auxiliary wheel through the above-described link mechanism, and the auxiliary wheel moves in a direction to be pressed against the road surface. In this way, the rear wheels and the auxiliary wheels can be stably grounded on the road surface regardless of the roll of the vehicle body.

JP 2001-105818 A

  In the case of the forklift provided with the above-described rear wheel and auxiliary wheel, generally, a driver's seat on which an operator rides is provided above the auxiliary wheel. It is desirable that the floor (floor) of the driver's seat be as close to the road surface as possible (lower floor) in order to make it easy for operators to get on and off. As for the width in the left-right direction of the driver's seat, it is desirable that the length necessary for securing the floor area on which the boarded worker stands is secured.

However, the lowering of the driver's seat has a problem that it is difficult to realize the reach because the reach cylinder and the link mechanism described above need to be arranged below the floor of the driver's seat.
That is, in the case of the reach-type forklift as described in Patent Document 1 described above, a reach cylinder that moves a fork, a mast, and the like that handle a load in the front-rear direction with respect to the vehicle is provided. The reach cylinder is located on the lowermost side of the vehicle, on a center line extending in the front-rear direction of the vehicle, and at a predetermined height (fixed height) from the road surface. The above-described link mechanism is disposed on the upper side of the reach cylinder and below the floor surface of the driver seat, that is, between the reach cylinder and the floor surface of the driver seat. As described above, the floor height of the driver's seat of the forklift is determined after securing the height at which the reach cylinder is disposed from the road surface and the space in which the reach cylinder and the link mechanism are disposed. It was difficult to lower the floor.

  The shape of the lower link shown in FIG. 1 and FIG. 6 of Patent Document 1 is determined in consideration of design matters such as the arrangement of the shaft that becomes the center of rotation and the weight reduction of the lower link. This is set regardless of the above-mentioned lowering of the driver's seat.

  Moreover, the lower link arrange | positioned below the floor surface of a driver's seat among the above-mentioned link mechanisms is a link member arrange | positioned extending in the left-right direction of a vehicle, and is extended in the front-back direction in the center part in the left-right direction. The shaft member is supported so as to be swingable. An auxiliary wheel is arranged at the end of the lower link on the auxiliary wheel side, and a rear wheel is arranged at the end of the opposite rear wheel side.

  Since the center portion of the lower link to the end on the rear wheel side is disposed at the center of the vehicle, a reach cylinder is disposed below the vehicle. On the other hand, only the auxiliary wheel is disposed below the end of the lower link on the auxiliary wheel side. Therefore, the lower link is bent in a crank shape, the end on the auxiliary wheel side of the lower link is brought close to the road surface to lower the floor of the driver's seat, and the end on the rear wheel side is the road surface A method of securing a space for disposing the reach cylinder away from the position is also conceivable.

  However, when the lower link is bent in a crank shape, the width in the left-right direction at the driver's seat becomes narrow, and there is a problem that it is difficult to secure the floor area on which the boarded worker stands. In other words, in the area corresponding to the auxiliary wheel side end of the lower link, the floor of the driver's seat can be lowered, but in other areas, for example, the part where the lower link is bent into a crank shape, The floor cannot be lowered. As a result, the width in the left-right direction of the lowered floor portion of the floor surface of the driver's seat is reduced, making it difficult to secure the floor area on which the boarded worker stands.

  The present invention has been made to solve the above-described problem, and an object of the present invention is to provide a reach-type forklift that can secure the floor area of a driver's seat and can achieve both a lower floor surface. And

In order to achieve the above object, the present invention provides the following means.
The reach type forklift according to the first aspect of the present invention includes a drive unit having a drive wheel disposed on one side surface in the left-right direction of the vehicle and an auxiliary wheel disposed on the other side surface in the left-right direction of the vehicle. A caster unit that is supported in a swingable manner around a lower swing axis that extends in the left-right direction and extends in the front-rear direction of the vehicle at the end on one side, and has a caster unit at the end on the other side A caster arm that is supported so as to be movable relative to the vehicle in the up-down direction, and extends in the left-right direction, and can swing on the vehicle body around an upper swing axis extending in the front-rear direction of the vehicle at the other side end. An upper arm that is supported and supports the drive unit so as to be relatively movable in the vertical direction with respect to the vehicle main body at the end on one side surface, and in the horizontal direction In the center region, it is supported by the vehicle body so as to be swingable around the lower swing axis, and the end of one of the side faces mutually moves relative to the drive unit via the connecting portion. The other side end is transmitted to the caster unit and the caster arm relative to each other in the vertical direction, and swings around the lower swing axis. A lower arm that transmits the relative movement in the vertical direction between the drive unit, the caster unit, and the caster arm so that the relative movement in the vertical direction is reversed. At least part of the space between the side swing axis is recessed upwards and placed in the center of the lower part of the vehicle when the lower arm swings Upper reach cylinder extending in the front-rear direction is provided a recess that enters the interior with the, on the upper side of the lower arm in the vehicle body, a plate-shaped frame extending in the longitudinal direction and the lateral direction of the vehicle body is disposed The frame is provided with a notch for allowing at least a part of the lower arm swinging upward to avoid interference between the frame and the lower arm. .

  According to the reach type forklift of the present invention, by providing the recess in the lower arm, the reach cylinder enters the recess to avoid interference with the lower arm, and compared with the case where the recess is not provided. The lower arm can be arranged at a position close to the reach cylinder. In other words, the lower arm can be arranged below. Further, by providing the concave portion in the lower arm, the space height required when the lower arm, the reach cylinder, etc. are arranged in the left-right direction of the vehicle is reduced.

  In other words, it is necessary to secure a space (interference avoidance space) for avoiding interference (collision) between the lower arm such as the reach cylinder and the adjacent member on the upper and lower sides of the swinging lower arm. If the lower arm does not have a recess, the height of the reach cylinder, the lower interference avoidance space, the thickness of the lower arm, and the accumulated length of the upper interference avoidance space are the lower arm and reach cylinder placement. It becomes the necessary space height when doing. In contrast, in the present invention, a recess is provided in the lower arm so that the lower interference avoidance space and a part of the thickness of the lower arm are overlapped to reach the lower arm by the overlap amount. It can be arranged at a position close to the cylinder, and the space height necessary for arranging the lower arm, the reach cylinder and the like can be lowered.

Li Chishirinda is than one end of the lower arm, by being positioned close to the lower pivot axis, it is possible to shallow the depth of the depression in the recess to avoid interference with the reach cylinder. That is, the range in which the lower arm swings is narrower at the portion supported by the swing shaft than at one end of the lower arm. For this reason, the depth of the recess in the recess that avoids interference with the reach cylinder is also shallower when placed closer to the lower swing axis than when the reach cylinder is placed closer to one end. . In other words, it becomes easy to secure the thickness of the lower arm, and it becomes easy to secure the strength of the lower arm.

A reach-type forklift according to a second aspect of the present invention includes a drive unit having a drive wheel disposed on one side surface in the left-right direction of the vehicle and an auxiliary wheel disposed on the other side surface in the left-right direction of the vehicle. A caster unit that is supported in a swingable manner around a lower swing axis that extends in the left-right direction and extends in the front-rear direction of the vehicle at the end on one side, and has a caster unit at the end on the other side A caster arm that is supported so as to be movable relative to the vehicle in the up-down direction, and extends in the left-right direction, and can swing around the upper swing axis extending in the front-rear direction of the vehicle at the other side end An upper arm that is supported and supports the drive unit so as to be relatively movable in the vertical direction with respect to the vehicle main body at the end on one side surface, and in the horizontal direction In the center region, it is supported by the vehicle body so as to be swingable around the lower swing axis, and the end of one of the side faces mutually moves relative to the drive unit via the connecting portion. The other side end is transmitted to the caster unit and the caster arm relative to each other in the vertical direction, and swings around the lower swing axis. A lower arm that transmits the relative movement in the vertical direction between the drive unit, the caster unit, and the caster arm so that the relative movement in the vertical direction is reversed. At least part of the space between the side swing axis is recessed upwards and placed in the center of the lower part of the vehicle when the lower arm swings Upper reach cylinder extending in the front-rear direction together with the is provided a recess that enters the interior, wherein the upper side of the lower arm of a vehicle body, a plate-shaped frame extending in the longitudinal direction and the lateral direction of the vehicle is disposed on the frame It is desirable that a notch is provided to allow at least a part of the lower arm swinging upward to avoid interference between the frame and the lower arm.

Thus by providing a notch in the frame to be disposed above the lower arm, this notch, a portion of the lower arm swings upward, in particular allows the entry of the upper end of one end portion And the arrangement height of a lower arm becomes still lower by avoiding interference with a frame and a lower arm.

In other words, it is necessary to secure an upper avoidance space that avoids interference between the swinging lower arm and the frame, but by providing a notch in the frame, the upper interference avoidance space and the lower arm Part of the thickness can be overlaid. As a result, the height at which the lower arm is disposed can be further reduced by the amount of overlap.
In the second aspect of the present invention, the reach cylinder is preferably disposed on one end side of the lower arm rather than the center between the one end and the lower swing axis.
In this way, the reach cylinder is arranged closer to one end than the lower swing axis of the lower arm, so that the recess that avoids interference with the reach cylinder also approaches the other end. Therefore, it becomes easy to increase the depth of the recess in the recess, and it is easy to avoid interference between the lower arm and the reach cylinder. The thickness of the member necessary to ensure the strength of the lower arm becomes thinner as it approaches one end from the lower swing axis of the lower arm. Therefore, compared to the case where the concave portion is arranged near the lower swing axis of the lower arm, the concave portion is arranged at the other end, so that the depth of the concave portion is increased while ensuring the strength of the lower arm. It becomes easy to do.
In the first aspect or the second aspect of the invention, the lower arm comprises a pair of arm main bodies arranged at intervals in the front-rear direction, and a connection portion extending in the front-rear direction to connect the pair of arm main bodies. The part is preferably connected to the arm body at a position above the upper end of the recess.
By arranging the connection part that connects the pair of arm bodies arranged in parallel in this way above the upper end of the recess formed in the arm body, interference between the lower arm and the reach cylinder can be avoided more reliably. Can do.

  According to the reach type forklift of the present invention, by providing a recess in the lower arm, it is possible to avoid interference between the reach cylinder and the lower arm and to dispose the lower arm at a position close to the reach cylinder. Moreover, the space height required when arrange | positioning a lower arm, a reach cylinder, etc. over the left-right direction of a vehicle becomes low. Since the height from the road surface to the reach cylinder is fixed to a predetermined height, the floor surface of the driver's seat arranged on the upper side of the lower arm is secured and the floor surface is lowered. There is an effect that can be.

It is a mimetic diagram explaining the whole forklift concerning the embodiment. FIG. 2 is a schematic diagram illustrating the configuration of the drive unit, caster unit, and link mechanism in the forklift shown in FIG. FIG. 3 is a partially enlarged rear view illustrating the configuration of the lower arm in FIG. 2. It is a top view explaining the structure of the lower arm of FIG. It is a schematic diagram explaining the other Example in relative arrangement | positioning of a lower arm and a reach cylinder.

  A forklift (reach forklift) 1 according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a schematic diagram illustrating the overall configuration of a forklift 1 according to this embodiment, FIG. 1 (a) is a plan view, and FIG. 1 (b) is a side view.

  The forklift 1 according to this embodiment is used for transporting luggage, and is particularly used for cargo handling work in a factory, a warehouse, a freight station, a port, or the like. As shown in FIG. 1, the forklift 1 is mainly provided with a vehicle main body 10 on which a driver (occupant) rides and a cargo handling unit 20 that handles luggage.

FIG. 2 is a schematic diagram illustrating the configuration of the drive unit 30, the caster unit 40, and the link mechanism 50 in the forklift 1 of FIG.
As shown in FIG. 1, the vehicle main body 10 is provided with a front wheel 11 used for traveling the forklift 1, an outrigger 13 on which the front wheel 11 is disposed, and a driver seat 14 on which a driver gets. Further, as shown in FIG. 2, the vehicle body 10 includes a drive unit 30 having a rear wheel (drive wheel) 31 used for traveling of the forklift 1, a caster unit 40 having an auxiliary wheel 41, a drive unit 30, and a caster unit 40. A link mechanism 50 that connects the two, a reach cylinder 24 that moves the cargo handling unit 20 in the front-rear direction with respect to the vehicle body 10, and the like are provided.

  The front wheels 11 are a pair of wheels respectively disposed at the front end of the outrigger 13 as shown in FIGS. 1 (a) and 1 (b). In the present embodiment, description will be made by applying to an example in which the front wheel 11 is an idle wheel in which the direction of the rotation shaft is fixed with respect to the vehicle body 10.

  As shown in FIG. 2, the drive unit 30 is disposed at the left rear end inside the vehicle main body 10, and causes the forklift 1 to travel forward and backward, and to turn right and left. The drive unit 30 is supported so as to be rotatable about an axis extending in the vertical direction with respect to the vehicle body 10, and is rotated about the above-described axis by rotating the handle 15 of the driver's seat 14. As the drive unit 30 is rotated about the axis in this way, the forklift 1 performs a right turn or a left turn. The drive unit 30 is mainly provided with a rear wheel 31 that contacts the road surface and moves the forklift 1 as described above, and a drive unit body 32 that supports the rear wheel 31 and rotationally drives the rear wheel 31. Yes.

  The rear wheel 31 is a wheel that contacts the road surface at the left rear end of the vehicle main body 10 and is a driving wheel that is rotationally driven by a driving source such as a motor provided in the driving unit main body 32. Further, the rear wheel 31 is also a steered wheel that determines the traveling direction of the forklift 1 by rotating around the axis line extending in the vertical direction together with the drive unit 30.

  The drive unit main body 32 includes a drive source (not shown) such as a motor that generates a drive force for rotating the rear wheel 31, and a transmission unit such as a gear that transmits the rotational drive force generated by the drive source to the rear wheel 31. (Not shown) and the like are housed inside. The drive unit main body 32 is supported by the upper arm 51 and the connecting unit 53 of the link mechanism 50 so as to be movable relative to the vehicle main body 10 in the vertical direction.

  The caster unit 40 is disposed at the right rear end inside the vehicle main body 10 and is disposed below the driver's seat 14 and supports the vehicle main body 10 together with the front wheels 11 and the rear wheels 31 so as to be able to travel. The caster unit 40 includes an auxiliary wheel 41 that is a wheel in contact with the road surface, a caster arm 42 that supports the auxiliary wheel 41 so as to be movable relative to the vehicle body 10 and the lower arm 52, and an auxiliary wheel 41. A caster spring 43 that elastically supports relative movement is mainly provided.

  The auxiliary wheel 41 is a wheel that rotates as the forklift 1 travels, and is supported so as to be rotatable about an axis extending in the vertical direction with respect to the caster arm 42. In the present embodiment, the description will be made by applying to an example in which the auxiliary wheel 41 is configured by a pair of wheels, but the auxiliary wheel 41 may be configured by one wheel and is not particularly limited.

  The caster arm 42 supports the auxiliary wheel 41 so as to be rotatable around the above-described axis, and supports the auxiliary wheel 41 so as to be movable relative to the vehicle body 10 in the vertical direction. The caster arm 42 is formed in a substantially V shape or a substantially U shape in a top view, and the swing shaft 56 of the link mechanism 50 is inserted into a through hole provided in a pair of end portions. Therefore, the caster arm 42 is supported so as to be swingable about a swing shaft (lower swing axis) 56, and the auxiliary wheel 41 moves in the vertical direction by the swing of the caster arm 42. The auxiliary wheel 41 is attached to the approximate center of a caster arm 42 formed in a substantially V shape or a substantially U shape.

  The caster spring 43 is a coil spring disposed between the caster arm 42 and the lower arm 52. Between the auxiliary wheel 41, the caster arm 42, and the lower arm 52, the movement of the two from one to the other is performed. It tells from one to the other. Furthermore, the caster spring 43 absorbs a rapid movement by expanding and contracting when this movement is transmitted.

  Specifically, the caster spring 43 is disposed between an end portion of the caster arm 42 to which the auxiliary wheel 41 is attached and an end portion through which the swing shaft 56 is inserted. The caster spring 43 is arranged such that one end is disposed on the upper surface of the caster arm 42 and the other end is in contact with the lower surface of the end of the lower arm 52. In addition, a protrusion 44 that protrudes upward from the caster arm 42 in a truncated cone shape is disposed inside the caster spring 43, and the position of the caster spring 43 is defined by the protrusion 44.

  The link mechanism 50 supports the drive unit 30 so as to be movable relative to the vehicle body 10 in the vertical direction, and supports the caster unit 40 together with the caster arm 42 so as to be movable relative to the vehicle body 10 in the vertical direction. It is. Further, the link mechanism 50 is configured so that the vertical movement of the drive unit 30 with respect to the vehicle body 10 and the vertical movement of the caster unit 40 are moved in opposite directions. The link mechanism 50 is mainly provided with an upper arm 51, a lower arm 52, and a connecting portion 53.

  The upper arm 51 is a member that is disposed above the link mechanism 50 and that is disposed on the side of the driver's seat 14 and supports the drive unit 30 so as to be movable relative to the vehicle body 10 in the vertical direction. The upper arm 51 mainly includes a pair of prismatic members that extend in the left-right direction of the vehicle body 10 and are arranged side by side in the front-rear direction.

  The upper arm 51 is attached to the end of the drive unit 30 so as to be rotatable with respect to the connecting portion 53 with the connecting portion 53 sandwiched in the front-rear direction. On the other hand, the end of the upper arm 51 on the caster unit 40 side is swingably attached to the vehicle body 10 via a pair of upper brackets 17B formed in a plate shape by the upper link shaft 54. In other words, both ends of the upper link shaft 54 are supported by the pair of upper brackets 17B. The upper arm 51 swings around an upper link shaft (upper swing axis) 54 and rotates relative to the connecting portion 53 and the drive unit 30 to support the drive unit 30 so as to be relatively movable in the vertical direction.

FIG. 3 is a partially enlarged rear view illustrating the configuration of the lower arm 52 of FIG. FIG. 4 is a top view for explaining the configuration of the lower arm 52 of FIG.
The lower arm 52 is a member that is disposed below the link mechanism 50 and below the driver's seat 14, and is a member that transmits movement of the drive unit 30 and the caster unit 40 in the vertical direction to each other. As shown in FIGS. 2 to 4, the lower arm 52 is mainly provided with an arm main body 52 </ b> A, a contact portion 52 </ b> B, a connection portion 52 </ b> C, and a recess 52 </ b> D.

  The arm main body 52A is a pair of prismatic members that extend in the left-right direction of the vehicle main body 10 and are arranged side by side in the front-rear direction. The caster unit 40 and the connecting portion 53 are disposed inside the pair of arm main bodies 52A and 52A. The pair of arm main bodies 52A and 52A has a swing shaft (lower swing) with respect to the vehicle main body 10 via a pair of lower brackets 17C formed in a plate shape by a swing shaft 56 at the center in the left-right direction. (Axis) 56 is supported to be swingable. In other words, both ends of the swing shaft 56 are respectively supported by a pair of lower brackets 17 </ b> C disposed below the frame 17. Further, end portions on the drive unit 30 side (end portions on one side surface) of the pair of arm main bodies 52 </ b> A and 52 </ b> A are rotatably attached to the connecting portion 53 by the lower link shaft 55.

The pair of arm main bodies 52A and 52A are connected by a contact portion 52B and a connection portion 52C extending in the front-rear direction of the vehicle main body 10.
The contact portion 52B is a member formed in a plate shape that connects the pair of arm main bodies 52A and 52A at the end portion on the caster unit 40 side (the end portion on the other side surface). In the present embodiment, description will be made by applying to an example in which the contact portion 52B is connected to the upper ends of the pair of arm main bodies 52A and 52A. The lower surface of the contact portion 52B is a surface with which the upper end of the caster spring 43 of the caster unit 40 comes into contact.

  The connecting portion 52C is a member formed in a plate shape that connects the pair of arm main bodies 52A and 52A between the swing shaft 56 and the lower link shaft 55. The present embodiment is applied to an example in which the connecting portion 52C is connected to the upper center of the recess 52D (the lower surface of the arm main body 52A) at the substantially vertical center of the pair of arm main bodies 52A and 52A. explain.

  In this way, the connection portion 52C that connects the pair of arm main bodies 52A and 52A is disposed above the upper end of the recess 52D formed in the arm main body 52A, so that the interference between the lower arm 52 and the reach cylinder 24 can be ensured. Can be avoided. Note that the position where the connecting portion 52C is connected to the arm main body 52A is not particularly limited as long as it is above the upper end of the recess 52D.

  The joint between the connecting portion 52C and the arm main body 52A is a curved surface that smoothly connects the outer surface of the connecting portion 52C and the outer surface of the arm main body 52A. The curvature of this curved surface is set to a larger value than that of a conventional lower arm that is not provided with the recess 52D. By doing in this way, it can suppress that a stress concentrates on the connection part 52C and 52 A of arm main bodies. Particularly, when the recess 52D is provided in the arm main body 52A as in the lower arm 52 of the present embodiment, the stress is particularly concentrated in the region where the recess 52D is provided in the arm main body 52A, that is, the region where the connection portion 52C is connected. Therefore, the effect of relaxing stress concentration by increasing the curvature of the joint is likely to appear.

  The recess 52D is a recess formed in the pair of arm bodies 52A and 52A in the lower arm 52, and avoids contact between the arm body 52A and the reach cylinder 24 disposed close to each other. The recess 52D is formed between the swing shaft 56 and the lower link shaft 55 on the lower surface of the pair of arm bodies 52A, 52A so as to be recessed upward. In the present embodiment, the concave portion 52D will be described as applied to an example in which the upper end of the concave portion 52D is recessed so as to reach the center in the vertical direction of the arm main body 52A.

  The position of the upper end of the recess 52D, that is, the depth of the recess is set so that the reach cylinder 24 and the lower arm 52 do not interfere when the lower arm 52 swings most toward the reach cylinder 24 (at the maximum swing). It is set (so that a gap of a predetermined interval remains). The maximum swing is when the drive unit 30 is moved most downward relative to the vehicle body 10, specifically, the lower relative movement is caused by a stopper that restricts the lower relative movement of the drive unit 30. It is a time when it is restricted. When the relative movement of the drive unit 30 is limited to the stopper, the rear wheel 31 of the drive unit 30 gets stuck in the hole, or the forklift 1 turns left and the vehicle body 10 rolls right (tilts right). It is. In addition, the swing angle of the lower arm 52 at the maximum swing is the maximum swing angle that takes into account the change in angle due to wear of the rear wheel 31 and the auxiliary wheel 41 and the change in angle due to an error in the mounting position due to replacement. It has been.

  The recess 52D will be described with reference to an example in which the end on the caster unit 40 side extends to the vicinity of the swing shaft 56 and the end on the drive unit 30 side extends to the vicinity of the lower link shaft 55. It should be noted that the depth of the recess 52D and the position of the end on the caster unit 40 side and the end on the drive unit 30 side determine the space required for securing the strength required for the lower arm 52 and avoiding contact with the reach cylinder 24. There is no particular limitation as long as it is determined within a range in which ensuring is compatible.

  As shown in FIG. 2, the connecting portion 53 is a member disposed between the upper arm 51 and the lower arm 52, and is also a member such as a bracket attached to the drive portion main body 32 of the drive unit 30. The connecting portion 53 is a member disposed on the side of the driver's seat 14 and is a plate-like member extending in the vertical direction of the vehicle main body 10, and is attached to the upper end portion so as to support the driving portion main body 32. ing. The connecting portion 53 and the upper arm 51 are connected at the upper end of the connecting portion 53 so as to be rotatable around an axis extending in the front-rear direction of the vehicle body 10. Further, the connecting portion 53 and the lower arm 52 are rotatably connected around the lower link shaft 55 at the lower end of the connecting portion 53.

A drive portion spring 57 is disposed between the connecting portion 53 and the vehicle body 10.
The drive portion spring 57 applies an urging force in the vertical direction to the drive unit 30 and the connecting portion 53, particularly an urging force that presses the drive unit 30 against the road surface. The drive part spring 57 is a coil spring whose axis extends in the vertical direction, and a lower end thereof is disposed in contact with an upper end of the connecting part 53. The upper end of the drive part spring 57 is attached to an attachment part 57 </ b> A fixed to the vehicle body 10. The attachment portion 57A is provided with an adjustment mechanism for adjusting the urging force by the drive portion spring 57.

  The reach cylinder 24 is a hydraulic cylinder disposed in the center of the lower surface of the vehicle body 10 so as to extend in the front-rear direction of the vehicle body 10. The height, which is the distance from the reach cylinder 24 to the road surface, is fixed at a predetermined height. The end of the piston in the reach cylinder 24 is attached to the cargo handling part 20, and the cylinder tube is fixed to the vehicle body 10. The cylinder of the reach cylinder 24 is partitioned into two spaces by a piston, and the piston of the reach cylinder 24 is separated from the cylinder tube by selecting the above-mentioned space for supplying the oil pressurized by the pressure increasing means such as a hydraulic pump. It protrudes or is pulled into the cylinder tube. Due to the movement of the piston, the cargo handling section 20 is pushed out (reached out) in front of the vehicle main body 10 or pulled (reached in) to the vehicle main body 10.

  As shown in FIGS. 1A and 1B, the outrigger 13 is a pair of arm-like members provided on the lower front side of the vehicle main body 10. It is arranged extending in parallel toward the front. A cargo handling section 20 is disposed between the pair of outriggers 13 and 13, and the cargo handling section 20 is movable between the pair of outriggers 13 and 13 in the front-rear direction.

  The driver's seat 14 is a place where the driver gets into the forklift 1 and operates the forklift 1 in a standing posture. The driver's seat 14 is provided at the right rear end of the vehicle body 10 and is provided with a handle 15 for steering the rear wheel 31 described above. In addition, an operation unit 16 such as a lever for operating the cargo handling unit 20 is provided in the driver's seat 14.

  Below the driver's seat 14, as shown in FIG. 2, a frame 17 and a lower cross member 17 </ b> A constituting the vehicle body 10 are arranged. The frame 17 is a plate-like member that is formed in a substantially rectangular shape and is disposed below a region on the drive unit 30 side of the floor surface of the driver's seat 14 (hereinafter referred to as “floor plate 14 </ b> A”). A rear end portion of the vehicle body 10 in the frame 17 is fixed to a rear end frame extending in the left-right direction at the rear end of the vehicle body 10. The front end of the vehicle main body 10 in the frame 17 is fixed to a central frame that extends in the left-right direction at the center of the vehicle main body 10. The rear end frame and the center frame constitute the vehicle body 10 together with other constituent members. Of the edge of the frame 17 on the drive unit 30 side, a notch portion 18 into which the arm body 52A that swings upward enters is formed in a portion of the lower arm 52 that faces the arm body 52A. The notch 18 is a recess formed in a slit shape extending from the edge of the frame 17 toward the caster unit 40 side.

  The lower cross member 17A is a plate-like member disposed on the side surface of the driver's seat 14 on the drive unit 30 side. The lower cross member 17A has a lower end extending to the floor plate 14A and an upper end extending to the upper bracket 17B. An upper bracket 17B is disposed on the front end surface and the rear end surface of the upper end of the lower cross member 17A. In the frame 17, a floor plate 14A and a lower cross member 17A are disposed above, and a lower bracket 17C is disposed below. Since the floor plate 14A and the lower cross member 17A are arranged above, it is difficult to move the arrangement position of the frame 17 upward.

  The cargo handling unit 20 is mainly provided with a fork 21 used for loading luggage, a lifting body 22 to which the fork 21 is attached, and a mast 23 in which the fork 21 and the lifting body 22 move in the vertical direction. .

  The fork 21 is a pair of arm-like members provided on the front surface of the elevating body 22, and is arranged so as to extend in parallel from the left and right ends of the lower end of the front surface of the elevating body 22 toward the front. The fork 21 is inserted into an insertion hole of a pallet formed in a substantially rectangular parallelepiped shape on which a load is placed, and lifts or lowers only the pallet or the pallet on which the load is placed.

  The elevating body 22 supports the fork 21 and is movable up and down along the mast 23 by an elevating cylinder (not shown) arranged between the elevating body 22 and the mast 23. .

  The mast 23 is a pair of columnar members arranged in parallel and facing each other, and is arranged extending in the vertical direction. Further, the pair of masts 23 and 23 are supported by the fork 21 and the lifting body 22 disposed between them so as to be vertically movable.

Next, the operation of the link mechanism 50 of the forklift 1 having the above configuration will be described with reference to FIG.
For example, when the forklift 1 turns to the right while moving forward, the vehicle main body 10 rolls to the left and the drive unit 30 is pushed into the vehicle main body 10. In other words, the drive unit 30 moves upward relative to the vehicle body 10. At this time, the upper arm 51 of the link mechanism 50 supports the drive unit 30 while the end on the drive unit 30 side swings upward about the upper link shaft 54.

  Further, the connecting portion 53 attached to the drive unit 30 moves upward as the drive unit 30 moves. Then, the end on the drive unit 30 side of the lower arm 52 rotatably connected to the connecting portion 53 also moves upward. At this time, the upper part of the lower arm 52 on the side of the drive unit 30 in the arm main body 52 </ b> A enters the notch 18 of the frame 17.

  When the end of the lower arm 52 on the connecting portion 53 side moves upward, the lower arm 52 swings about the swing shaft 56, and the end of the lower arm 52 on the caster unit 40 side faces downward in the opposite direction. Moving. The downward movement of the end of the lower arm 52 on the caster unit 40 side is transmitted to the caster arm 42 via the caster spring 43, and the caster arm 42 swings about the swing shaft 56, and the auxiliary wheel 41 is moved. The attached end moves downward. As a result, the auxiliary wheel 41 moves relatively downward with respect to the vehicle body 10. In other words, it protrudes downward from the vehicle body 10, and the auxiliary wheel 41 can continue to keep contact with the road surface.

  Conversely, when the forklift 1 turns leftward while moving forward, the vehicle main body 10 rolls to the right and the caster unit 40 is pushed into the vehicle main body 10. In other words, the caster unit 40 moves upward relative to the vehicle body 10. At this time, the caster arm 42 swings about the swing shaft 56, and the end portion to which the auxiliary wheel 41 is attached moves upward.

  The movement of the caster arm 42 is transmitted to the end of the lower arm 52 on the caster unit 40 side via the caster spring 43. The lower arm 52 swings about the swing shaft 56, the end on the caster unit 40 side moves upward, and the end on the drive unit 30 side moves downward. At this time, at least the upper end of the reach cylinder 24 enters the recess 52D of the lower arm 52, so that collision (interference) with the lower arm 52 is avoided.

  When the end of the lower arm 52 on the drive unit 30 side moves downward, the connecting portion 53 connected to the lower arm 52 so as to be rotatable also moves downward. At the same time, the drive unit 30 attached to the connecting portion 53 also moves relatively downward with respect to the vehicle body 10. In other words, the rear wheel 31 protrudes downward from the vehicle main body 10 and can keep contact with the road surface.

  According to the link mechanism 50 described above, the recess 52D is provided in the lower arm 52, thereby avoiding interference between the reach cylinder 24 and the lower arm 52, and compared with the case where the recess 52D is not provided. The arm 52 can be arranged at a position close to the reach cylinder 24. In other words, the lower link shaft 55 and the swing shaft 56 can be disposed below. Since the height at which the reach cylinder 24 is disposed is fixed in advance, the floor plate 14A of the driver's seat 14 disposed above the lower arm 52 can be lowered. Further, since the space height required when the lower arm 52, the reach cylinder 24, etc. are arranged in the left-right direction of the vehicle body 10 can be reduced, the floor plate 14A of the driver's seat 14 interferes with the lower arm 52. Therefore, it is not necessary to provide a protruding portion that avoids the problem, and the floor area of the driver's seat 14 can be secured.

  That is, it is necessary to secure an interference avoidance space for avoiding interference (collision) between the lower arm 52 such as the reach cylinder 24 and the adjacent member on the upper and lower sides of the swinging lower arm 52. When the recess 52D is not provided in the lower arm 52, the height of the reach cylinder 24, the lower interference avoidance space, the thickness of the lower arm 52, and the length obtained by stacking the upper interference avoidance space are the link mechanism 50. And the space height required when the reach cylinder 24 is arranged. On the other hand, in the present embodiment, the lower arm 52 is provided with a recess 52D, and the above-described lower interference avoidance space and a part of the thickness of the lower arm 52 are overlapped, so that only the overlapping amount is obtained. The lower arm 52 can be disposed at a position close to the reach cylinder 24, and the space height required when the lower arm 52 and the reach cylinder 24 are disposed can be reduced.

  Since the reach cylinder 24 is disposed closer to the swing shaft 56 than the end of the lower arm 52 on the drive unit 30 side, the depth of the recess 52D that avoids interference with the reach cylinder 24 is made shallower. be able to. That is, the range in which the lower arm 52 swings is narrower in the vicinity of the swing shaft 56 than the end of the lower arm 52 on the drive unit 30 side. Therefore, the depth of the recess 52D that avoids interference with the reach cylinder 24 is also set closer to the swing shaft 56 than when the reach cylinder 24 is placed closer to the end on the drive unit 30 side. It becomes shallower. In other words, it becomes easy to secure the thickness of the lower arm 52, and the strength of the lower arm 52 is easily secured.

  A notch 18 is provided in the frame 17 so that a part of the lower arm 52 swinging upward, in particular, the upper end of the arm body 52A near the end on the drive unit 30 side can be entered into the notch 18. By avoiding the interference between the frame 17 and the lower arm 52, the arrangement height of the frame 17 can be further reduced.

  That is, it is necessary to secure an upper avoidance space for avoiding interference between the lower arm 52 and the frame 17, but by providing the frame 17 with the notch 18, the upper interference avoidance space and the lower arm are provided. A part of the thickness of 52 can be overlaid. As a result, the height at which the frame 17 is disposed can be further reduced by the amount of overlap.

FIG. 5 is a schematic diagram for explaining another embodiment in the relative arrangement of the lower arm 52 and the reach cylinder 24.
As in the above-described embodiment, the reach cylinder 24 may be disposed in the vicinity of the swing shaft 56 in the lower arm 52, or the lower arm 52 is moved toward the drive unit 30 as shown in FIG. Accordingly, the reach cylinder 24 may be disposed near the end of the lower arm 52 on the drive unit 30 side, and is not particularly limited.

  Here, the fact that the reach cylinder 24 is arranged in the vicinity of the swing shaft 56 means that the reach is closer to the swing shaft 56 than the center between the end of the lower arm 52 on the drive unit 30 side and the swing shaft 56. It means that the cylinder 24 is arranged. Similarly, the fact that the reach cylinder 24 is arranged in the vicinity of the end on the drive unit 30 side means that the reach cylinder 24 is arranged on the drive unit 30 side than the above-mentioned center.

  As described above, the reach cylinder 24 is disposed close to the end of the lower arm 52 on the drive unit 30 side, so that the recess 52D may be provided at least in the vicinity of the end on the drive unit 30 side. It becomes easy to increase the dent depth. That is, it becomes easy to avoid interference between the lower arm 52 and the reach cylinder 24. The thickness of the member necessary to ensure the strength of the lower arm 52 decreases as it approaches the end on the drive unit 30 side from the vicinity of the swing shaft 56 in the lower arm 52, as shown by the dotted line in FIG. . Therefore, as compared with the case where the recess 52D is provided in the vicinity of the swing shaft 56 in the lower arm 52, the recess 52D is provided at the end on the drive unit 30 side, thereby ensuring the strength of the lower arm 52 and the recess in the recess 52D. It becomes easy to increase the depth.

  DESCRIPTION OF SYMBOLS 1 ... Forklift (reach type forklift), 10 ... Vehicle main body, 14 ... Driver's seat, 17 ... Frame, 18 ... Notch part, 20 ... Cargo handling part, 24 ... Reach cylinder, 31 ... Rear wheel (drive wheel), 30 ... Drive unit, 40 ... Caster unit, 41 ... Auxiliary wheel, 51 ... Upper arm, 52 ... Lower arm, 52A ... Arm body, 52C ... Connector, 52D ... Recess, 53 ... Connector,

Claims (4)

A drive unit having drive wheels disposed on one side surface in the left-right direction of the vehicle body;
A caster unit having an auxiliary wheel disposed on the other side surface in the left-right direction of the vehicle body;
Extending in the left-right direction and supported on the vehicle body so as to be swingable around a lower swing axis extending in the front-rear direction of the vehicle body at the end portion on the one side surface side. A caster arm that supports the caster unit so as to be movable relative to the vehicle body in the vertical direction;
The vehicle body is supported by the vehicle body so as to be swingable around the upper swing axis extending in the front-rear direction at the other side surface end and extending in the left-right direction, and the drive unit is supported at the one side surface end. An upper arm that is supported so as to be relatively movable in the vertical direction with respect to the vehicle body;
It extends in the left-right direction, and is supported by the vehicle body so as to be swingable about the lower swing axis in the central region, and the end on the one side is connected to the drive unit via a connecting portion. The relative movement in the vertical direction of the drive unit is mutually transmitted, and the relative movement in the vertical direction of the caster unit and the caster arm is mutually transmitted between the caster unit and the caster arm at the end portion on the other side surface. By swinging around the lower swing axis, the relative movement in the vertical direction is mutually reversed so that the relative movement in the vertical direction is reversed between the drive unit, the caster unit and the caster arm. A lower arm to transmit,
With
At least part of the lower arm from the one end to the lower swing axis is recessed upward, and is disposed at the lower center of the vehicle body when the lower arm swings. And a recess into which the upper end of the reach cylinder extending in the front-rear direction enters is provided.
The reach cylinder, than the middle between the lower pivot axis and the end portion of the one side surface side of the lower arm, characterized in that arranged on the lower pivot axis side Li over Ji-powered forklifts. A drive unit having drive wheels disposed on one side surface in the left-right direction of the vehicle body;
A caster unit having an auxiliary wheel disposed on the other side surface in the left-right direction of the vehicle body;
Extending in the left-right direction and supported on the vehicle body so as to be swingable around a lower swing axis extending in the front-rear direction of the vehicle body at the end portion on the one side surface side. A caster arm that supports the caster unit so as to be movable relative to the vehicle body in the vertical direction;
The vehicle body is supported by the vehicle body so as to be swingable around the upper swing axis extending in the front-rear direction at the other side surface end and extending in the left-right direction, and the drive unit is supported at the one side surface end. An upper arm that is supported so as to be relatively movable in the vertical direction with respect to the vehicle body;
It extends in the left-right direction, and is supported by the vehicle body so as to be swingable about the lower swing axis in the central region, and the end on the one side is connected to the drive unit via a connecting portion. The relative movement in the vertical direction of the drive unit is mutually transmitted, and the relative movement in the vertical direction of the caster unit and the caster arm is mutually transmitted between the caster unit and the caster arm at the end portion on the other side surface. By swinging around the lower swing axis, the relative movement in the vertical direction is mutually reversed so that the relative movement in the vertical direction is reversed between the drive unit, the caster unit and the caster arm. A lower arm to transmit,
With
At least part of the lower arm from the one end to the lower swing axis is recessed upward, and is disposed at the lower center of the vehicle body when the lower arm swings. And a recess into which the upper end of the reach cylinder extending in the front-rear direction enters is provided.
A plate-like frame extending in the front-rear direction and the left-right direction of the vehicle main body is disposed above the lower arm of the vehicle main body,
To the frame is to allow at least a portion of the entrance of the lower arm swings upward, characterized in that notches for avoiding interference with the said frame lower arm is provided Li over Ji-powered forklifts. The reach cylinder is arranged at an end portion on the one side surface side from a center between the end portion on the one side surface side of the lower arm and the lower swing axis. The reach type forklift according to claim 2 . The lower arm is composed of a pair of arm main bodies arranged at intervals in the front-rear direction, and a connection portion that extends in the front-rear direction and connects the pair of arm main bodies,
The reach type forklift according to any one of claims 1 to 3, wherein the connecting portion is connected to the arm main body at a position above the upper end of the recess.

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