JP6048945B1 - Rotary intermediate column - Google Patents

Abstract

An object of the present invention is to expand the degree of freedom of the installation position of a rotary intermediate pillar installed on a floor frame of a cargo carrier bed so that it can be applied to cargo vehicles of various structures. A rotary intermediate column (1) is provided on an intermediate column main body (6) installed on a floor frame (4) of a cargo carrier bed via a hinge and an outer surface (4a) of the floor frame (4). And a hook 9 formed with a second engagement recess 8, a rigid support link 13 connected to the intermediate pillar body via the link pin 10, and the intermediate pillar body and the support link 13 via the link pin 10. A lock arm 23 having a first lock lever 17 connected to the intermediate portion and a second lock release lever 21 on the rotation free end side, and a first engagement convex portion 25 moving in conjunction with the movement of the first lock lever. And a first lock mechanism 27 having a first engagement recess, a second engagement protrusion 29 connected to the second lock release lever 21, and a second lock mechanism 31 having a second engagement recess. It has. [Selection] Figure 4

Description

  The present invention relates to a rotary intermediate pole having a lock function installed on a cargo bed of a cargo vehicle.

  2. Description of the Related Art Conventionally, relatively large freight vehicles employ a structure in which an intermediate pillar is installed at an intermediate position of a long cargo bed at the front and rear, and the two halves before and after the intermediate pillar are connected and held and fixed. In addition, as the intermediate column, a rotary intermediate column as shown in Patent Documents 1 and 2 below is used. The rotary intermediate column is provided with a lock mechanism for holding and fixing the standing posture in which the intermediate column is raised on the loading platform.

  Among these, the lock mechanism disclosed in Patent Document 1 includes a hook disposed on the front side of a floor frame in a truck bed, a lock piece engaged with a recess provided on an upper surface side of the hook, and the lock A support link that is rotatably connected to the piece, has a lever that switches between a locked state and an unlocked state of the lock piece, and a notch from which the hook can protrude, and is connected to the intermediate column in a rotatable state. And a support structure for the lever provided in the space below the floor frame in the truck bed.

  Further, the lock mechanism disclosed in Patent Document 2 is rotatably attached to a holding body serving as an intermediate pillar, and is attached to the support functioning as a support link and the support so as to be freely rotatable. An actuating body having a locking member at one end and a lever body at the other end, a receiving member that is disposed on the front side of the cargo bed floor frame of the freight vehicle and engages with the locking member, and And a lock main body provided with an engagement element and a handle main body, and a lock receiving body that is installed in a lower space of the cargo bed floor frame of the freight vehicle and engages with the engagement element. Is disclosed.

Japanese Patent Laid-Open No. 11-198866 JP 2004-323003 A

However, in Patent Document 1, the lever support structure partially occupies the lower space of the floor frame in the truck bed, and in Patent Document 2, the locking receiver is the lower space of the cargo bed floor frame of the freight vehicle. Is partially occupied. Therefore, when a side guard, a fuel tank, a tire house, a tool box, etc. are present in the part, the intermediate pillar and its locking mechanism cannot be installed in the part. The degree of freedom of the installation position was narrowed.
In addition, the lock mechanisms disclosed in Patent Documents 1 and 2 both regulate the outward movement of the intermediate pillar, and the inward movement of the intermediate pillar is such that the bottom face of the intermediate pillar is in the loading platform. It regulates by contacting the upper surface of the edge of the floor frame. Therefore, when used for many years or when the frequency of use is high, there is a possibility of causing damage, deformation or malfunction of the intermediate column or floor frame.

Further, in the case of the lock mechanism disclosed in Patent Documents 1 and 2, the engagement state and the engagement release state between the lock piece and the hook, and the engagement state and engagement between the engagement element and the locking receiver. Since the unlocked state is difficult to visually recognize from the outside, there is a risk that the freight vehicle may run in a state where these lock mechanisms are not locked.
The present invention has been made on the basis of the above points. The purpose of the present invention is to install a rotary intermediate column having a lock mechanism on the loading platform of a freight vehicle. The intermediate pillar can be installed at various positions with a high degree of freedom, and the intermediate pillar and floor frame are damaged, deformed and operated by controlling the movement of the locked intermediate pillar both inside and outside with the lock mechanism. An object of the present invention is to improve the safety of the lock mechanism by reducing defects and enabling the lock state and unlock state of the lock mechanism to be easily visually confirmed from outside.

In order to achieve the above object, a rotary intermediate column according to claim 1 of the present invention is an intermediate column main body installed in a rotatable state via a hinge with respect to a floor frame of a cargo bed of a freight vehicle.
A hook provided to protrude outward from the outer surface of the floor frame, and having a first engagement recess on the upper surface side and a second engagement recess on the lower surface side;
A rigid support link connected to the intermediate pillar body via a link pin in a rotatable state, and having a window portion that avoids interference with the hook near the free rotation end;
A first lock lever that is pivotally connected to the intermediate column body and the support link via the link pin, and that pivots about the first pivot fulcrum is provided at the middle portion, and a pivot free end. A lock arm comprising a second unlocking member that moves in a direction toward and away from the second engagement recess on the side;
A first locking mechanism configured by including a first engagement convex portion that moves in conjunction with a movement of the first lock lever and a first engagement concave portion of the hook;
A second locking mechanism configured by including a second engaging convex portion of the second unlocking member and a second engaging concave portion of the hook,
The intermediate column main body, the hook, the support link, the lock arm, the first lock mechanism, and the second lock mechanism are configured to raise the intermediate column main body upward along the outer surface of the floor frame. The standing posture and the hanging posture in which the intermediate pillar main body is hung downward along the outer surface of the floor frame are configured not to be positioned in the lower space of the floor frame. It is a feature.

Further, the rotary intermediate column according to claim 2 is an intermediate column main body installed in a rotatable state via a hinge with respect to the floor frame of the cargo bed of the freight vehicle,
A hook provided to protrude outward from the outer surface of the floor frame, and having a first engagement recess on the upper surface side and a second engagement recess on the lower surface side;
A rigid support link connected to the intermediate pillar body via a link pin in a rotatable state, and having a window portion that avoids interference with the hook near the free rotation end;
A first lock lever that is pivotally connected to the intermediate column body and the support link via the link pin, and that pivots about the first pivot fulcrum is provided at the middle portion, and a pivot free end. A lock arm having a second unlocking lever that swings about the second swing fulcrum on the side;
A first locking mechanism configured by including a first engagement convex portion that moves in conjunction with a movement of the first lock lever and a first engagement concave portion of the hook;
A second lock mechanism configured to include a second engagement convex portion connected to the second lock release lever via the second swing fulcrum and a second engagement concave portion of the hook. And comprising
The intermediate column main body, the hook, the support link, the lock arm, the first lock mechanism, and the second lock mechanism are configured to raise the intermediate column main body upward along the outer surface of the floor frame. The standing posture and the hanging posture in which the intermediate pillar main body is hung downward along the outer surface of the floor frame are configured not to be positioned in the lower space of the floor frame. It is a feature.

  According to a third aspect of the present invention, there is provided the rotary intermediate column according to the first or second aspect, wherein the support link accommodates the lock arm in a state where the intermediate column main body is in an upright posture. A recess is formed, and the front surface of the lock arm and the front surface of the support link are substantially flush with each other in a state where the lock arm is housed in the housing recess. .

  According to a fourth aspect of the present invention, there is provided the rotary intermediate column according to the first aspect, wherein the first engaging convex portion of the first lock lever is placed on the bottom of the receiving concave portion of the support link. A guide plate is provided that guides the second engaging convex portion of the second unlocking member to the second engaging concave portion of the hook while guiding the first engaging concave portion.

  According to a fifth aspect of the present invention, there is provided the rotary intermediate column according to the second aspect, wherein the first engaging convex portion of the first lock lever is placed on the bottom of the receiving concave portion of the support link. A guide plate is provided for guiding the second engaging convex portion connected to the second unlocking lever to the second engaging concave portion of the hook while guiding the first engaging concave portion. It is.

  The rotary intermediate column according to claim 6 is the rotary intermediate column according to any one of claims 1 to 5, wherein the swinging free end of the first lock lever is at the first swinging fulcrum. A swing spring that is always urged so as to be biased toward the bottom side of the support link is provided.

  The rotary intermediate column according to claim 7 is the rotary intermediate column according to any one of claims 1 to 6, wherein the second engagement is between the lock arm and the second engagement convex portion. A push spring that biases the convex portion to be biased toward the second engaging concave portion is provided.

  The rotary intermediate column according to claim 8 is the rotary intermediate column according to claim 2, wherein the second lock release lever is prevented from swinging or pulling down between the second lock release lever and the lock arm. A safety stopper is provided.

  The rotary intermediate column according to claim 9 is the rotary intermediate column according to any one of claims 1 to 7, wherein relative rotation between the support link and the lock arm is prevented. A safety stopper is provided.

  And the following effects are acquired by the said means. That is, according to the rotary intermediate column of the present invention, the rotary intermediate column is configured in the space below the floor frame in the cargo bed of the cargo vehicle in both the state where the intermediate column body is in the standing posture and the state where it is in the suspended posture. It is possible to prevent the intermediate column main body, the hook, the support link, the lock arm, the first lock mechanism, and the second lock mechanism from being located. Therefore, it is possible to install the rotary intermediate pillar at a free position without being affected by the position below the floor frame or the side guard, fuel tank, tire house, tool box, etc. arranged on the side of the floor frame. As a result, the degree of freedom of the installation position of the rotary intermediate pillar is expanded.

Further, in the present invention, hooks in which engagement concave portions are respectively formed on the upper surface side and the lower surface side are employed, and a first engagement convex portion that engages with each of these two types of engagement concave portions, and a second Two locking mechanisms are provided that allow the engaging convex portion to act from both above and below so as to sandwich the hook. Therefore, both the outward tilt and the inward tilt of the intermediate column main body are prevented by these two locking mechanisms, so the force applied to the bottom surface of the intermediate column and the top surface of the floor frame edge is weakened. It is possible to reduce the occurrence of breakage, deformation, and malfunction of the intermediate pillar or floor frame.
In addition, an accommodation recess for accommodating the lock arm is formed with respect to the support link, and the front surface of the lock arm and the front surface of the support link are substantially flush with the lock recess in the accommodation recess. In this case, the lock arm can be accommodated in a compact manner without projecting outward from the support link, and the aesthetic appearance of the rotating intermediate post when standing is improved. Further, since no step or depression is generated between the support link and the lock arm, there is no possibility that an object will be caught between them or a foreign object may be caught.

Further, when a guide plate is provided on the bottom surface of the receiving recess of the support link, the engaging operation of the first engaging protrusion with respect to the first engaging recess when the first locking mechanism is locked, The engaging operation of the second engaging convex portion with respect to the second engaging concave portion when the second locking mechanism is locked becomes smooth.
Further, when a swing spring is provided to urge the swing free end of the first lock lever to the bottom side of the support link with respect to the first swing fulcrum, the first engagement convex portion is When the first engaging recess is not securely engaged, the first swing fulcrum moves outward by the urging force of the swing spring, so that the lock arm rotates around the link pin for support. The lock arm is lifted from the receiving recess of the link. Therefore, it is possible to easily determine whether or not the lock state of the first lock mechanism is reliably performed by checking whether or not the lock arm is lifted.

Further, when a pressing spring for biasing the second engaging convex portion toward the second engaging concave portion is disposed between the lock arm and the second engaging convex portion, the biasing force of the pressing spring is provided. As a result, the second engaging convex portion is pushed into the second engaging concave portion side and can smoothly shift to the locked state of the second locking mechanism.
When the second lock mechanism is unlocked, the second lock release lever is hooked with a finger to swing in a predetermined direction around the second swing support point, or the second lock release lever or the second lock release member By pulling down, the engagement state of the second engagement convex portion and the second engagement concave portion can be released, and the second lock mechanism can be easily shifted to the unlock state.

In addition, if a safety stopper is provided between the second lock release lever and the lock arm to prevent the second lock release lever from swinging or pulling down, the second lock release lever may be inadvertently operated or incomplete. It is possible to prevent a situation in which the lock of the second lock mechanism, which is caused by a lock posture or vibration during traveling of the freight vehicle, is released, and the safety of the rotary intermediate column of the present invention is improved.
In addition, when a safety stopper is provided between the support link and the lock arm to prevent relative rotation of the two, careless operation of the second unlocking lever, imperfect locking posture or freight vehicle It is possible to prevent a situation in which the lock of the second lock mechanism caused by vibration during traveling is released, and the safety of the rotary intermediate column of the present invention is improved.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the 1st Embodiment of this invention, and is a front view which shows a part of loading platform side surface of the freight vehicle to which the rotary intermediate pillar is applied. It is a figure which shows the 1st Embodiment of this invention and is a front view which shows the rotary intermediate | middle column of a standing posture. It is a figure which shows the 1st Embodiment of this invention and is a side view which shows the rotary intermediate | middle column of a standing posture. It is a figure which shows the 1st Embodiment of this invention and is a sectional side view which shows the rotary intermediate | middle column of a standing posture. It is a figure which shows the 1st Embodiment of this invention, and is a perspective view which shows the rotary intermediate | middle column of the state which flipped up the lock arm and the 1st lock lever upwards. It is a figure which shows the 1st Embodiment of this invention and is a sectional side view which shows the first operation procedure in the case of making the rotary intermediate | middle column of a standing posture transfer to a drooping posture. It is a figure which shows the 1st Embodiment of this invention and is a sectional side view which shows the next operation procedure in the case of making the rotary intermediate | middle column of a standing posture transfer to a drooping posture. It is a figure which shows the 1st Embodiment of this invention and is a sectional side view which shows the rotary intermediate | middle pillar of a drooping posture. It is a figure which shows the 2nd Embodiment of this invention and is a sectional side view which shows the rotary intermediate | middle column of a standing posture. It is a figure which shows the 2nd Embodiment of this invention, and is a sectional side view which shows the state in the middle of the transition which makes the rotary intermediate | middle pillar of a standing posture transfer to a drooping posture. It is a figure which shows the 2nd Embodiment of this invention, and is a perspective view which shows the safety stopper of a 2nd lock release lever. It is a figure which shows the 2nd Embodiment of this invention, and is a sectional side view which shows the state which cancel | released the safety stopper. It is a figure which shows the 2nd Embodiment of this invention, and is a sectional side view which shows the state which act | operated (locked) the safety stopper. It is a figure which shows other embodiment of this invention, and is a front view which shows the rotary intermediate | middle pillar of a standing posture. It is a figure which shows other embodiment of this invention, and is a side view which shows the rotary intermediate | middle column of a standing posture. It is a figure which shows other embodiment of this invention, and is a sectional side view which shows the rotary intermediate | middle column of a standing posture.

Hereinafter, the configuration of the rotary intermediate pillar of the present invention and the operation mode thereof will be specifically described by taking the first embodiment shown in FIGS. 1 to 8 and the second embodiment shown in FIGS. 9 and 10 as examples. explain.
As shown in FIG. 1, the rotary intermediate pillar 1 of the present invention has a relatively large freight vehicle T that is installed at a middle position of a front and rear long cargo bed 2 and attached to left and right side edges of the cargo bed 2. It is used for the purpose of holding and fixing in a state of being divided into two parts, front and rear.

(1) 1st Embodiment (refer FIGS. 1-8)
The rotary intermediate column 1 of the present invention includes an intermediate column main body 6 installed in a rotatable state with respect to a floor frame 4 of a loading platform 2 of a cargo vehicle T via a hinge 5, and an outer surface of the floor frame 4. 4a, a hook 9 provided with a first engagement recess 7 on the upper surface side and a second engagement recess 8 on the lower surface side, and the intermediate pillar via the link pin 10. A rigid support link 13 connected to the main body 6 in a rotatable state and having a window portion 11 formed to avoid interference with the hook 9 near the free end of rotation, and the intermediate via the link pin 10 A first lock lever 17 that is pivotally connected to the column body 6 and the support link 13 and that swings about the first swing fulcrum 15 is provided at an intermediate portion, and a second lock lever 17 is provided at the rotation free end side. A lock door provided with a second unlocking lever 21 that swings about a swing fulcrum 19. It is equipped with the arm 23, a.

Further, the rotary intermediate column 1 of the present invention is configured by including a first engagement convex portion 25 that moves in conjunction with the movement of the first lock lever 17 and the first engagement concave portion 7 of the hook 9. The second engagement convex portion 29 connected to the first lock mechanism 27 and the second lock release lever 21 via the second swing fulcrum 19 and the second engagement of the hook 9 And a second lock mechanism 31 configured by including the recess 8.
The intermediate column main body, the hook, the support link, the lock arm, the first lock mechanism, and the second lock mechanism are arranged so that the intermediate column main body 6 extends along the outer surface 4a of the floor frame 4. In the lower space 4c of the floor frame 4 in both the standing posture raised upward and the hanging posture in which the intermediate column body 6 is suspended downward along the outer surface of the floor frame 4. It is configured not to.

Further, in the rotary intermediate column 1A according to the first embodiment of the present invention, the intermediate column main body 6 has a cross-sectional groove shape in which the left and right side edges of a metal rectangular flat plate material are bent 90 ° outward. It is comprised by the member of.
A base plate 33 made of a metal flat plate material thicker than the wall thickness of the intermediate column body 6 is attached to the lower part of the center of the recess 6 a of the intermediate column body 6. A link base 35 having a hole portion 35a penetrating in the width direction B for horizontally supporting the link pin 10 is attached to the center upper portion of the base plate 33. The link base 35 is composed of a highly rigid metal block member.

Further, the above-described hook 9 is attached to the outer side surface 4a of the floor frame 4, and upper hinges 37 of the hinges 5L and 5R are provided on the left and right side edges of the base plate 33 above the hook 9. Is attached. Further, the lower hinge 39 connected to the upper hinge 37 by the hinge pin 38 so as to be rotatable is attached to the outer side surface 4a of the floor frame 4 described above.
The hook 9 is made of a metal block-like member having high rigidity. The first engaging recess 7 having a U-shaped groove as an example is formed on the upper surface side and the lower surface side of the hook 9. Second engaging recesses 8 are respectively formed.
Further, since the support link 13 functions as a reinforcing member that supports the intermediate column main body 6 described above, the support link 13 is formed by cutting out into a shape as shown in the figure using a highly rigid metal block-like member.

The support link 13 is formed with an accommodation recess 41 for accommodating the lock arm 23 described below in a state where the above-described intermediate column body 6 is in the standing posture shown in FIGS. And the window part 11 for receiving the hook 9 mentioned above is formed in the lower center of the bottom part of this accommodation recessed part 41 as an example as a square-window-like through-hole by which the corner part was processed round.
A hole 43a for receiving the link pin 10 is formed in the upper part of the side walls 43L and 43R provided so as to rise to the left and right with the accommodating recess 41 interposed therebetween so as to penetrate in the width direction B.

The lock arm 23 is a member having a size that can be accommodated in the receiving recess 41 of the support link 13. For example, the lock arm 23 is supported in a state where the left and right side edges of a rectangular metal plate material are received in the receiving recess 41 of the support link 13. It has a shape bent 90 ° so as to face the bottom side of the link 13.
In addition, a square window-like window 45 for avoiding interference with the hook 9 is formed in the center of the lock arm 23 near the free rotation end of the front plate 23a in the same manner as the window 11 of the support link 13 described above. Has been. Further, on the pivot base end side of the left and right side plates 47L and 47R of the lock arm 23, a hole 47a that similarly receives the link pin 10 is formed at a position where the shaft center coincides with the hole 35a of the link base 35 described above. ing.

Further, in the left and right side plates 47L and 47R of the lock arm 23, elongated holes 47b extending in the longitudinal direction of the lock arm 23 are formed at positions somewhat closer to the rotation free end than the holes 47a. The elongated hole 47 b is a hole for receiving a lock lever pin serving as the first swing fulcrum 15.
Then, in a state where the lock arm 23 configured in this way is housed in the housing recess 41 of the support link 13 described above, the front surface of the lock arm 23 and the front surfaces of the left and right side walls 43L and 43R of the support link 13 are almost The receiving recess 41 of the support link 13 is configured to be flush with the lock arm 23.

The first lock lever 17 includes a lock lever pin serving as the first swing fulcrum 15 described above at the swing base end of a rectangular plate-shaped lever body 17a that is somewhat thick and rigid, and the lever body 17a. As an example of engagement with the first engagement recess 7 of the hook 9 described above, the first free movement engagement end 25 is provided with a round bar-like first engagement protrusion 25.
Further, the first swing fulcrum 15 is a swirl spring constituted by a torsion coil spring as an example that constantly biases the swing free end of the first lock lever 17 to be biased toward the bottom side of the support link 13. 49A is provided.

  The first swing fulcrum 15 is supported by a slide bracket 51 that slides in the longitudinal direction of the lock arm 23 within the length range of the long holes 47b formed in the left and right side plates 47L and 47R of the lock arm 23 described above. The first lock lever 17 is swung between the slide bracket 51 and the lock arm 23 by urging the slide bracket 51 toward the free rotation end of the lock arm 23. An absorption spring 53 constituted by a compression coil spring is provided as an example for absorbing the displacement of the first swing fulcrum 15 due to the above.

The second lock release lever 21 is formed by bending a metal flat plate material into a shape as shown in the figure, like the lock arm 23 described above. The second lock release lever 21 is formed by extending a rectangular flat plate-like front surface portion 21a, a swinging free end of the front surface portion 21a, a bent portion having a bent portion in the middle, and the left and right sides of the front surface portion 21a. Side plate portions 55L and 55R formed by bending the side edges of the inner side by 90 ° inward, and the left and right side plate portions 55L and 55R receive the lock release lever pin serving as the second swing fulcrum 19 and are horizontal. A hole 55a is formed for support.
In addition, on the inner side of the left and right side plate portions 55L and 55R, as an example, a second engagement convex portion 29 made of a somewhat thick rectangular flat plate member whose tip is processed to be round is similarly second. It is connected in a swingable state via a lock release lever pin serving as a swing fulcrum 19.

Further, the rotation free end of the front plate 23a of the lock arm 23 is bent inward, and is provided integrally with the bent portion 23b of the front plate 23a and the second engaging convex portion 29 described above. Between the guide shafts 57L and 57R, a pushing spring 59 is provided that urges the second engaging convex portion 29 to be biased toward the second engaging concave portion 8 of the hook 9.
In addition, the bottom of the housing recess 41 of the support link 13 guides the first engagement protrusion 25 of the first lock lever 17 to the first engagement recess 7 of the hook 9 and the second lock release lever 21. The second engaging convex portion 29 connected to the hook 9 functions as a guide plate 61 that guides the second engaging convex portion 29 to the second engaging concave portion 8 of the hook 9.

Next, the operation mode of the rotary intermediate column 1A according to the present embodiment configured as described above will be specifically described together with the operation procedure of the rotary intermediate column 1A based on FIG. 4 and FIGS. explain.
(A) At the time of transition to the hanging posture When the rotary intermediate column 1A is in the standing posture, the first engaging convex portion 25 is engaged with the first engaging concave portion 7 on the upper surface side of the hook 9 as shown in FIG. The second engagement convex portion 29 is engaged with the second engagement concave portion 8 on the lower surface side of the hook 9, and both the first lock mechanism 27 and the second lock mechanism 31 are in a locked state.

In this state, the intermediate column body 6 is vertically raised on the upper surface 4 b of the side edge of the floor frame 4, and the support link 13 and the lock arm 23 are rotated downward to be parallel to the intermediate column body 6. It is supported by a drooping posture. Further, since the lock arm 23 is housed in the housing recess 41 of the support link 13, it keeps a flat appearance without protruding outward.
In this state, when a force F that tries to fall outward acts on the intermediate column main body 6, the first engagement convex portion 25 comes into contact with the first engagement concave portion 7, so that the intermediate column main body 6 is moved outward. The fall is prevented. On the other hand, when a force R that tries to fall inward acts on the intermediate column main body 6, the second engagement convex portion 29 comes into contact with the second engagement concave portion 8, so that the intermediate column main body 6 falls inward. Is prevented.

Next, when the rotary intermediate column 1A in the standing posture is shifted to the hanging posture, the finger is hooked on the finger hooking portion 21b of the second lock release lever 21, and pulled to the front as shown in FIG. The release lever 21 is swung clockwise in the figure, or the second lock release lever 21 is pulled downward to release the engagement state between the second engagement convex portion 29 and the second engagement concave portion 8, and the second The lock mechanism 31 is set to the unlocked state.
When the lock arm 23 is pulled upward in this state as shown in FIG. 7, the lock arm 23 rotates clockwise around the link pin 10 in the drawing, and the first engagement convex portion 25 and the first The engaged state with the first engaging recess 7 is released, and the first lock mechanism 27 is also in the unlocked state.

When the lock of the first locking mechanism 27 is released, the intermediate column main body 6 can be rotated outward of the loading platform 2 around the hinge pin 38 of the hinge 5. , Transition to the hanging posture shown in FIG.
In this state, the support link 13 and the lock arm 23 are positioned inward of the intermediate column main body 6, and the lock arm 23 has a compact form accommodated in the accommodation recess 41 of the support link 13 as described above. I keep it.

(B) At the time of transition to the standing posture On the other hand, when the rotary intermediate column 1A in the hanging posture shown in FIG. 8 is shifted to the standing posture shown in FIG. 4, the intermediate column body 6 is illustrated with the hinge pin 38 of the hinge 5 as the center. 8 is rotated clockwise to the upright posture shown in FIG.
At this time, as shown in FIG. 7, the lock arm 23 is in a state of being lifted from the housing recess 41 of the support link 13 by the urging force of the swing spring 49A.

In this state, when the lock arm 23 is rotated counterclockwise around the link pin 10 in the drawing, the first lock lever 17 is rotated clockwise around the first swing fulcrum 15. Thus, the first engagement convex portion 25 at the tip of the lever main body 17a of the first lock lever 17 is guided while sliding on the surface of the guide plate 61 and reaches the first engagement concave portion 7 as shown in FIG. The first lock mechanism 27 is locked when engaged.
Further, when the lock arm 23 is further rotated and reaches the position shown in FIG. 6 parallel to the support link 13, the second engagement convex portion 29 receiving the urging force upward by the push spring 59 becomes the lower surface of the hook 9. The second engaging mechanism 29 is engaged with the second engaging recess 8 as shown in FIG. 4, and the second locking mechanism 31 is reached. Will also be locked.

And according to the rotary intermediate pillar 1A according to the present embodiment configured as described above, the lower space 4c of the floor frame 4 is not used in both the standing posture and the hanging posture. When installing the rotary intermediate column 1A on the loading platform 2, the rotary intermediate column 1A is installed at a free position without worrying about the position of the tire house 63, the fuel tank 65, the side guard or the tool box (not shown), etc. It becomes possible to do.
Further, two types of first engagement recesses 7 and second engagement recesses 8 formed on a single hook 9 with an outward force F and an inward force R applied to the intermediate column main body 6, and these Since it is supported by two types of lock mechanisms 27 and 31 composed of a first engagement convex portion 25 and a second engagement convex portion 29 that engage with the intermediate pillar main body 6 and the floor frame 4. Such force can be reduced to reduce these breakage, deformation and malfunction.
In addition, the locked state and unlocked state of the first lock mechanism 27 and the second lock mechanism 31 can be confirmed by the presence or absence of the lock arm 23 rising relative to the housing recess 41 in the support link 13. It becomes easy to confirm whether or not the lock mechanism 27 and the second lock mechanism 31 are securely locked, and the safety of the lock mechanisms 27 and 31 is improved.

(2) Second embodiment (see FIGS. 9 to 13)
The rotary intermediate column 1B according to the second embodiment basically has the same configuration as the rotary intermediate column 1A according to the first embodiment described above, and the first lock mechanism 27 is provided. And the second lock mechanism 31 is partially changed.
Therefore, the description of the same configuration as the first embodiment is omitted here, and the difference between the first lock mechanism 27 and the second lock mechanism 31 that is different from the first embodiment is as follows. A description will be given focusing on the difference in operation mode.

First, in the present embodiment, the first engagement convex portion 25 is not provided at the distal end portion of the first lock lever 17 as in the first embodiment, but the guide plate 61 of the support link 13. It is provided at the tip of a guide rod 69 slidably supported by a guide sleeve 67 provided above.
Specifically, an engagement fitting 73 that engages with the shaft portion 71 provided at the distal end portion of the first lock lever 17 is provided at the distal end portion of the round rod-shaped guide rod 69, and the engagement fitting 73 is provided on the outer peripheral surface thereof. On the other hand, the first engaging convex portion 25 is attached by welding or the like.

Therefore, in the present embodiment, the first engagement convex portion 25 is configured to move only in the direction along the longitudinal direction of the support link 13 regulated by the guide sleeve 67 and the guide rod 69.
Further, as an example, a stopper 75 having a cylindrical sleeve shape is provided on the upper portion of the guide rod 69, and the first embodiment configured by a compression coil spring between the stopper 75 and the guide sleeve 67. Is provided with a swing spring 49B having a different structure.

  Further, as shown in FIGS. 9 to 13, a safety stopper 77 is provided between the second lock release lever 21 and the lock arm 23 to prevent the second lock release lever 21 from swinging or pulling down. First, the front surface portion 21a and the finger hook portion 21b of the second lock release lever 21 are separated into separate members, and as an example provided on the finger hook portion 21b, a claw-like locking portion 79 is engaged with the bent portion 23b of the lock arm 23. It is configured to be switchable between a stopped state and a released state.

  Specifically, a pair of left and right swing arms 81L and 81R are attached to the front surface portion 21a of the second lock release lever 21, and the lower part thereof is rotatable with respect to the lock release lever pin 19 that is the second swing support point. A compression spring 83 that is slidably held in the axial direction and is urged so as to be always biased rightward in the drawing is disposed between one swing arm 81L and the second engagement convex portion 29. At the same time, a locking portion 79 protruding from the lock release lever pin 19 to the bent portion 23b side of the lock arm 23 is provided. Further, a locking pin 85 is fixed to the upper portion in the same direction as the unlocking lever pin 19, and the tip side of the locking hole portions 87 </ b> A and 87 </ b> B drilled in the side plate portion 55 </ b> R of the second unlocking lever 21. It is configured to be locked to either one.

  The safety stopper 77 having such a configuration can prevent the second lock mechanism 31 from being unlocked due to an inadvertent operation of the second lock release lever 21 or the like. That is, as shown in FIGS. 11 and 12, if the locking pin 85 is locked in the locking hole 87A on the release side, the locking portion 79 is locked to the bent portion 23b of the lock arm 23. The second unlocking lever 21 is hooked in the clockwise direction in the drawing by placing a finger on the finger hooking portion 21b of the second unlocking lever 21 or pulling it toward the front, or lowering the second unlocking lever 21 downward. The engagement state between the second engagement convex portion 29 and the second engagement concave portion 8 can be freely manipulated by pulling it down.

  On the other hand, as shown in FIG. 11 (indicated by a two-dot chain line) and FIG. 13, after the second locking mechanism 31 is locked, the locking pin 85 is locked in the locking hole 87B on the locking side. Then, even if it is going to operate the finger hook part 21b of the 2nd lock release lever 21, since the latching | locking part 79 is the state latched by the bending part 23b of the lock arm 23, it is comprised so that it cannot operate.

  Even when the rotary intermediate pillar 1B according to the second embodiment configured as described above is employed, the same operations and effects as those of the first embodiment described above can be achieved. In the case of the present embodiment, the lock arm 23 and the support link 13 are connected via the first lock lever 17, so that the first engagement convex portion 25 becomes the first engagement concave portion 7. When the lock arm 23 is not engaged, the lock arm 23 is prevented from jumping or ramping, and the safety of the rotary intermediate column 1B is improved.

  Furthermore, in the present embodiment, the use of the safety stopper 77 allows the second lock to be generated due to inadvertent operation of the second lock release lever 21, incomplete locking posture, vibration during traveling of the cargo vehicle T, or the like. The situation that the mechanism 31 is unlocked can be prevented, and the safety of the rotary intermediate column 1B is improved.

(3) Other embodiments (see FIGS. 14 and 15)
The rotary intermediate column 1 of the present invention is not limited to those of the above-described two embodiments, and can be changed within the gist of the present invention.
For example, as shown in FIGS. 14 and 15, it is possible to provide a safety stopper 89 between the support link 13 and the lock arm 23 to prevent the relative rotation of both. Incidentally, in the rotary intermediate column 1C shown in FIGS. 14 and 15, the hole 91 and the hole 93 that coincide with each other in the state in which the lock arm 23 is housed in the housing recess 41 of the support link 13 are replaced by the left and right side walls 43L of the support link 13. 43R and left and right side plates 47L and 47R of the lock arm 23, respectively, and a safety stopper 89 constituted by a stopper pin 95 penetrating these holes 91 and 93 is employed.

A head 95 a having an outer diameter larger than the inner diameters of the holes 91 and 93 is formed at one end of the stopper pin 95, and a retaining pin 97 is inserted into the other end of the stopper pin 95. A hole 95b is formed.
Also, the rotary intermediate column 1C having such a configuration can exhibit the same operations and effects as the rotary intermediate column 1A of the first embodiment and the rotary intermediate column 1B of the second embodiment described above. Further, in the present embodiment, the lock of the second lock mechanism 31 caused by careless operation of the second lock release lever 21, incomplete lock posture or vibration during travel of the cargo vehicle T is released. Can be prevented, and the safety of the rotary intermediate column 1C is improved.

(4) Still another embodiment (see FIG. 16)
Further, as shown in FIG. 16, a second unlocking member 22 that moves toward and away from the second engaging recess 8 is provided on the rotation free end side of the lock arm 23. It is possible to provide the 2nd engagement convex part 29 in a front-end | tip part. In the rotary intermediate pillar 1D shown in FIG. 16, the second unlocking member 22 is formed by bending a metal flat plate material into an L shape as shown. The second unlocking member 22 includes a rectangular flat plate-shaped front surface portion 22a and a finger hook portion 22b protruding inwardly at the lower end portion, and has a somewhat thick rectangular flat plate shape with a rounded tip. It is being fixed to the 2nd engagement convex part 29 comprised by the member with the screw part 22c. The second unlocking member 22 and the second engaging convex portion 29 may be formed integrally, and the finger hooking portion 22b may be formed so as to protrude outward.

Further, the rotation free end of the front plate 23a of the lock arm 23 is bent inward, and is provided integrally with the bent portion 23b of the front plate 23a and the second engaging convex portion 29 described above. Between the guide shafts 57L and 57R, a pushing spring 59 is provided that urges the second engaging convex portion 29 to be biased toward the second engaging concave portion 8 of the hook 9.
In addition, the bottom of the receiving recess 41 of the support link 13 guides the first engaging protrusion 25 of the first lock lever 17 to the first engaging recess 7 of the hook 9 and the second unlocking member 22. The second engaging convex portion 29 connected to the hook 9 functions as a guide plate 61 that guides the second engaging convex portion 29 to the second engaging concave portion 8 of the hook 9.

  Also, the rotary intermediate column 1D having such a configuration can exhibit the same operations and effects as those of the rotary intermediate columns 1A to 1C of the above-described embodiments. Since the finger hooking portion 22b of the unlocking member 22 is put on a finger and pulled downward to release the engagement state between the second engagement convex portion 29 and the second engagement concave portion 8, the lock can be achieved with a simple structure. In addition to being able to switch between the state and the unlocked state, there is an effect of preventing a situation in which the lock of the second lock mechanism 31 is released due to an inadvertent operation or an incomplete locking posture.

In addition, the rotary intermediate pillar 1 of the present invention can be installed in pairs on the left and right of the loading platform of the freight vehicle T, or a plurality of sets can be installed. Further, when the processing accuracy and assembly accuracy of the lock arm 23, the first lock lever 17, and the hook 9 are high, the long hole 47b formed in the lock arm 23 is a circle that simply supports the first swing fulcrum 15. It is also possible to use a hole having a shape.
Further, a finger is put on the finger hooking portion 21b of the second unlocking lever 21, and the second unlocking lever 21 is pulled downward to release the engagement state between the second engaging convex portion 29 and the second engaging concave portion 8. It is also possible.
Furthermore, in addition to using the bottom of the support link 13 as a guide plate 61, a guide plate 61 separate from the support link 13 can be attached to the bottom of the support link 13.

  The rotary intermediate pillar of the present invention can be used in the field of manufacturing a large-scale freight vehicle with a long freight vehicle and the transportation using the large freight vehicle. The present invention has applicability when it is desired to provide a rotary intermediate pole that can be applied to various types of freight vehicles with a degree of freedom in position.

DESCRIPTION OF SYMBOLS 1 Rotating intermediate | middle pillar 2 Carriage 3 Lift 4 Floor frame 4a Outer side surface 4b Upper surface 4c Lower space 5 Hinge 6 Intermediate pillar main body 6a Recess 7 First engagement recess 8 Second engagement recess 9 Hook 9a Inclined surface 10 Link pin 11 Window Part 13 Support link 15 First swing fulcrum (lock lever pin)
17 First lock lever 17a Lever body 19 Second swing fulcrum (lock release lever pin)
21 2nd lock release lever 21a Front part 21b Finger part 22 Second lock release member 22a Front part 22b Finger part 22c Screw part 23 Lock arm 23a Front plate 23b Bending part 25 First engagement convex part 27 First lock mechanism 29 Second engaging projection 31 Second lock mechanism 33 Base plate 35 Link base 35a Hole 37 Upper hinge 38 Hinge pin 39 Lower hinge 41 Housing recess 43 Side wall 43a Hole 45 Window 47 Side plate 47a Hole 47b Slot 49 Swing spring 51 Slide bracket 53 Absorption spring 55 Side plate portion 55a Hole portion 57 Guide shaft 59 Push-in spring 61 Guide plate 63 Tire house 65 Fuel tank 67 Guide sleeve 69 Guide rod 71 Shaft portion 73 Engagement fitting 75 Stopper 77 Safety stopper 79 Engagement Stop (locking claw)
81 swing arm 83 compression spring 85 locking pin 87 locking hole 89 safety stopper 91 hole 93 hole 95 stopper pin 95a head 95b hole 97 retaining pin T cargo vehicle B width direction F (outward ) Force R (inward) force

Claims (9)

An intermediate pillar body installed in a rotatable state via a hinge with respect to the floor frame of the cargo carrier bed;
A hook provided to protrude outward from the outer surface of the floor frame, and having a first engagement recess on the upper surface side and a second engagement recess on the lower surface side;
A rigid support link connected to the intermediate pillar body via a link pin in a rotatable state, and having a window portion that avoids interference with the hook near the free rotation end;
A first lock lever that is pivotally connected to the intermediate column body and the support link via the link pin, and that pivots about the first pivot fulcrum is provided at the middle portion, and a pivot free end. A lock arm comprising a second unlocking member that moves in a direction toward and away from the second engagement recess on the side;
A first locking mechanism configured by including a first engagement convex portion that moves in conjunction with a movement of the first lock lever and a first engagement concave portion of the hook;
A second locking mechanism configured by including a second engaging convex portion of the second unlocking member and a second engaging concave portion of the hook,
The intermediate column main body, the hook, the support link, the lock arm, the first lock mechanism, and the second lock mechanism are configured to raise the intermediate column main body upward along the outer surface of the floor frame. The standing posture and the hanging posture in which the intermediate pillar main body is hung downward along the outer surface of the floor frame are configured not to be positioned in the lower space of the floor frame. Features a rotating intermediate pillar. An intermediate pillar body installed in a rotatable state via a hinge with respect to the floor frame of the cargo carrier bed;
A hook provided to protrude outward from the outer surface of the floor frame, and having a first engagement recess on the upper surface side and a second engagement recess on the lower surface side;
A rigid support link connected to the intermediate pillar body via a link pin in a rotatable state, and having a window portion that avoids interference with the hook near the free rotation end;
A first lock lever that is pivotally connected to the intermediate column body and the support link via the link pin, and that pivots about the first pivot fulcrum is provided at the middle portion, and a pivot free end. A lock arm having a second unlocking lever that swings about the second swing fulcrum on the side;
A first locking mechanism configured by including a first engagement convex portion that moves in conjunction with a movement of the first lock lever and a first engagement concave portion of the hook;
A second lock mechanism configured to include a second engagement convex portion connected to the second lock release lever via the second swing fulcrum and a second engagement concave portion of the hook. And comprising
The intermediate column main body, the hook, the support link, the lock arm, the first lock mechanism, and the second lock mechanism are configured to raise the intermediate column main body upward along the outer surface of the floor frame. The standing posture and the hanging posture in which the intermediate pillar main body is hung downward along the outer surface of the floor frame are configured not to be positioned in the lower space of the floor frame. Features a rotating intermediate pillar.   The support link is formed with an accommodating recess for accommodating the lock arm in a state where the intermediate pillar body is in an upright posture, and the front surface of the lock arm is accommodated in the state where the lock arm is accommodated in the accommodating recess. The rotary intermediate post according to claim 1 or 2, wherein a front surface of the support link is configured to be substantially flush with each other.   At the bottom of the receiving recess of the support link, the first engaging convex portion of the first lock lever is guided to the first engaging concave portion of the hook, and the second engaging convex portion of the second unlocking member is provided. The rotary intermediate column according to claim 1, further comprising a guide plate that guides the second guide recess to the second engagement recess of the hook.   The first engagement convex portion of the first lock lever is guided to the first engagement concave portion of the hook and is connected to the second lock release lever at the bottom portion of the support recess of the support link. The rotary intermediate column according to claim 2, wherein a guide plate is provided to guide the mating convex portion to the second engaging concave portion of the hook.   2. A swing spring that constantly urges the first rocking fulcrum so that the rocking free end of the first lock lever is biased toward the bottom side of the support link is provided. The rotary intermediate pillar in any one of -5.   A push spring is provided between the lock arm and the second engagement convex portion to urge the second engagement convex portion so as to be biased toward the second engagement concave portion. The rotary intermediate pillar according to any one of claims 1 to 6.   The rotary intermediate column according to claim 2, wherein a safety stopper is provided between the second lock release lever and the lock arm to prevent the second lock release lever from swinging or pulling down.   The rotary intermediate pillar according to any one of claims 1 to 7, wherein a safety stopper is provided between the support link and the lock arm to prevent relative rotation of both.

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