JP2003192089A - Container connection tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a container connection tool which can be easily assembled with a small number of components. <P>SOLUTION: A rotation axis insertion hole 5 and a handle insertion hole 6 are formed in a connection tool body 1. A rotation axis 11 that has cones 12 and 13 on its top and bottom ends is inserted within the rotation axis insertion hole 5. The handle axis 16a of the handle 16 for rotation operation of the rotation axis 11 is inserted within the handle insertion hole 6. The simplification of the assemble of the container connection tool is intended by inserting a coil spring 20 into a spring insertion hole 21 formed on the rotation axis and that penetrates through in radial direction to press the handle axis 16a in outer direction by the single coin spring 20 in conjunction with to make the rotation axis 11 return rotate until each cone spring 12 and 13 becomes an engagement position by restored elasticity caused by the transformation of the coil spring 20 to reduce the number of the components. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a container connecting tool for connecting stacked upper and lower containers.

[0002]

2. Description of the Related Art Generally, in the case of transporting a large number of containers by ship, a container connecting tool is installed between the containers at each stage of the containers stacked in multiple stages, the upper and lower containers are connected by the container connecting tool, and after the containers are stacked. , The upper container is fixed by bridging a fastener that can be tightened with a turnbuckle between the upper container and the deck metal fitting attached to the deck.

As the above-mentioned container connecting tool, the actual fair 5-2
The one described in No. 3514 is conventionally known.
This container connector is provided with an upper cone and a lower cone above and below the connector body, and each cone is provided between an engagement position and an engagement position by swinging a handle supported by the connector body. I am trying to rotate it.

When the containers are connected by using the above-mentioned container connecting tool, the upper cones are engaged with the engaging holes of the corner fittings provided at the corners of the lower surface of the container in the suspended state of the container, and the container is attached to the lower surface of the container. Place the container with the connector attached on top of the previously loaded container, and engage it when the lower cone enters the engaging holes of the corner fittings provided at the four corners of the upper surface of the lower container. When the lower cone is rotated toward the disengagement position by contact with the inner peripheral edge of the hole and the lower cone is completely fitted in the engagement hole, the lower cone is rotated to the engagement position by the elasticity of the spring. It is made to engage with the engaging hole.

When loading and unloading containers,
Swing the handle, pull up the upper container with the lower cone disengaged from the engagement hole, lower the container to a position where the operator can operate the handle, and then swing the handle to move the upper cone. The engaging hole is disengaged and the container connector is removed from the container.

By the way, in the conventional container connector, the upper cone or the lower cone is pivoted to the disengagement position by pivoting the handle to the right or left, so that the handle is pivoted from the pivot direction. When disengaging the lower cone without knowing which of the upper and lower cones is disengaged, the upper cone may be disengaged due to an erroneous operation of the handle. In particular, the handle is often misoperated when the container connector is used upside down.

In this case, since the container connecting tool remains on the upper surface side of the lower container by loading and unloading the upper container, it is necessary to get on the lower container and remove the container connecting tool, which is very troublesome. is there.

Further, when a plurality of containers are stacked in multiple stages, each of the container connectors is arranged at a high place, and the handle of the container connector arranged at the high place is rocked horizontally from the deck. Since the lower cone is disengaged, there is a problem that an operating force cannot be effectively applied to the lever, the operability is poor, and a dedicated operating metal fitting is required for operating the handle.

In order to solve the above-mentioned problems, the applicant of the present application rotatably provided a handle having a lateral lever portion on the connector body and rotated the rotary shaft by pulling down the lever portion of the handle. We have already proposed a container connector that disengages the lower cone of the connector body and pushes up the lever to rotate the rotating shaft in the opposite direction to disengage the upper cone. (Japanese Patent Laid-Open No. 10-291585).

In the above container connector, the upper cone is disengaged by pushing up the lever portion provided on the handle, and the lower cone is disengaged by pulling it down, so that the lever portion swings. It is easy to know which of the upper and lower cones is disengaged, and the handle is less likely to be erroneously operated. Further, since the engagement of the cone is released by pushing up and pulling down the lever portion, a dedicated operation metal fitting is not required for operating the lever portion, and for example,
It has a feature that the lever portion can be operated by the operation metal fitting having a simple structure in which the hook is provided at the tip of the rod, and the operability at the time of attaching and detaching the container connecting tool can be improved.

Further, in the previously proposed container connector, since the handle is movably supported in the axial direction and the handle is urged outward by the spring, the handle can be secured when the upper and lower containers are bound. There is no inconvenience that the lever part of the hindrance interferes with the lashing and the container can be firmly lashed.

[0012]

By the way, in the already proposed container connector, two springs, a spring for returning and rotating the rotary shaft and a spring for pushing the handle outward, are provided in the connector body. Since it is built in, the number of parts is large, it takes time and effort to assemble, and there are some points to be improved in order to facilitate the assembly.

Further, when the rotary shaft is rotated by swinging the lever portion of the handle, the end surface of the upper cone rotates in a state of being in surface contact with the upper end surface of the protrusion provided on the connector body, and Since the spring for returning and rotating the rotating shaft is the tension coil spring, the rotating shaft rotates in contact with the inner peripheral surface of the shaft insertion hole. For this reason, the rotational resistance of the rotary shaft is large, and a relatively large operating force is required for operating the steering wheel, and there are still points to be improved in order to reduce the operating force.

An object of the present invention is to provide a container connector which can rotate a rotary shaft with a small operation force and has a small number of parts and which can be easily assembled.

[0015]

In order to solve the above-mentioned problems, according to the present invention, substantially rectangular engaging holes provided in corner fittings of a container are provided above and below a flange arranged between the upper and lower containers. And a connector main body provided with a positioning protrusion that fits snugly with the rotary shaft insertion hole that penetrates from the upper end face of the upper protrusion to the lower end face of the lower protrusion, and has the upper and lower ends described above. A rotating shaft having a first cone and a second cone engageable with the peripheral edge of the engaging hole, and a handle insertion hole penetrating the rotating shaft insertion hole from the outer peripheral surface of the flange so as to be slidably inserted. A handle shaft having a handle shaft and a lever portion provided laterally on the outer end of the handle shaft, and a spring insertion hole formed in the rotary shaft and penetrating in the radial direction, so that the handle is directed outward. Push While, deformed by the rotation of the rotary shaft, first by the restoring elastic due to the deformation, the second
Coil springs for rotating both ends of the cone so as to return and rotate the rotary shaft from the outer peripheral surface of the protruding portion facing the cone to the engaging position facing outward, and rotation about the shaft center of the handle shaft as the rotary shaft. This is because the rotation transmission mechanism is used for transmission to the.

According to the above construction, it is possible to apply an outward pressing force to the handle with a single coil spring, and to return the rotating shaft rotated by the handle operation. Therefore, the number of parts is smaller than that of the container connector in which the elastic force of each spring is applied to the handle and the rotating shaft, and the assembling of the container connector can be facilitated.

Further, since the coil spring is inserted in the spring insertion hole formed in the rotary shaft and penetrating in the radial direction, the coil spring does not press the rotary shaft against the inner circumference of the rotary shaft insertion hole. Therefore, the rotation resistance of the rotating shaft is small, and the rotating shaft can be smoothly rotated.

Here, as the rotation transmission mechanism, an L-shaped arm is provided at the inner end of the handle shaft, and the tip of the arm is inserted into a long guide hole in the axial direction provided on the outer periphery of the rotary shaft. Can be adopted.

In the container connector according to the present invention,
It has a stopper slidably inserted in a stopper insertion hole that penetrates through the upper and lower surfaces of the flange, and when the stopper is in the descending stop state, the stopper pin provided on the outer periphery of the stopper and the protrusion provided on the outer periphery of the rotary shaft The rotating shaft is prevented from rotating toward the disengagement position where the upper cone is housed within the outer peripheral surface of the protrusion, and the stopper is pushed into the stopper insertion hole to release the rotation stopper. By providing a stop mechanism, when the container connecting tool is connected to the corner metal fittings on the lower surface of the upper container,
Since the stopper pin faces the protrusion in the circumferential direction of the rotation shaft and can prevent the rotation shaft from rotating in the direction in which the upper cone is disengaged, the container connector is dropped during the transfer of the container. Can be prevented.

Further, by providing an arcuate bulging portion in line contact with the end face of the corresponding cone at the opening end of the rotary shaft insertion hole, each cone is rotated when the rotary shaft is rotated by operating the handle. Since it rotates in line contact with the bulging portion, the rotation resistance is small, and the rotary shaft can be rotated by a small operating force.

In this case, each bulged portion can be rotated by a smaller operating force by making point contact with the outer circumference of the rotary shaft.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

As shown in FIGS. 1 and 4, the connector main body 1 is provided with a positioning first projection 3 on the upper side of a flange 2 arranged between the upper and lower containers C ₁ and C _{2 and} has a lower position. The second protrusion 4 is provided on the side.

The first projecting portion 3 and the second projecting portion 4 are sized so as to fit almost exactly into the substantially rectangular engaging holes a provided in the corner fittings A of the containers C ₁ and C ₂ . .

The connector body 1 has a rotary shaft insertion hole 5 penetrating from the upper surface of the first projecting portion 3 to the lower surface of the second projecting portion 4, and a handle penetrating from the outer peripheral surface of the flange 2 to the rotary shaft inserting hole 5. An insertion hole 6 and a spring accommodating hole 7 are formed at a position displaced from the inner end of the handle insertion hole 6 by 180 ° in the circumferential direction of the handle insertion hole 6. Further, the connector body 1 has a stopper insertion hole 8 penetrating the upper and lower surfaces of the flange 2,
A vertically elongated pin hole 9 is formed to connect the stopper insertion hole 8 and the rotary shaft insertion hole 5 to each other.

As shown in FIG. 2, the connector main body 1 is divided along a plane including the axes of the rotary shaft insertion hole 5 and the handle insertion hole 6, and the bolt 10 shown in FIG. They are connected to each other by tightening the nuts.

A rotary shaft 11 is inserted into the rotary shaft insertion hole 5 and rotatably supported, and a first cone 12 and a second cone 13 are provided at the upper and lower ends of the rotary shaft 11.

The first cone 12 and the second cone 13 have a pyramid portion 15 having a rounded tip on a base plate portion 14 in which the pair of side surfaces are inclined in opposite directions with the central portion as a boundary.
And the base plate portion 14 is sized to fit within the outer peripheral surfaces of the first protruding portion 3 and the second protruding portion 4.

Further, the first cone 12 and the second cone 13
Are arranged such that their longitudinal directions are out of phase with each other in the circumferential direction of the rotary shaft 11.

The rotating shaft 11 is rotated by the handle 16. The handle 16 is provided with a lever portion 16b at the end of the handle shaft 16a, and the protrusion 1 is provided at the end of the lever portion 16b.
6c is provided, and the handle shaft 16a is inserted into the handle insertion hole 6 and slidably and rotatably supported.

A rotation transmission mechanism 17 for transmitting the rotation of the handle 16 to the rotary shaft 11 is provided between the handle 16 and the rotary shaft 11. The rotation transmission mechanism 17 includes the rotation shaft 1
1 has a guide hole 18 that is long in the axial direction, and the handle shaft 1
With the L-shaped arm 19 provided at the inner end of 6a facing downward,
Insert the tip into the guide hole 18 and
When rotating 6, the inner surface of the guide hole 18 is pressed by the tip of the L-shaped arm 19 to rotate the rotating shaft 11.

The lever portion 16b of the handle 16 is turned sideways in the engaged state in which both ends of the first cone 12 and the second cone 13 project outward from the outer peripheral surfaces of the projecting portions 3 and 4 facing the cone. And the lever part 1
The rotation of the rotary shaft 11 by pushing up 6b causes the first cone 12 to be rotationally displaced to the disengagement position in which the first cone 12 is entirely accommodated within the outer peripheral surface of the first protrusion 3. In addition, the rotation of the rotating shaft 11 by pulling down the lever portion 16b causes the second cone 13
Is rotationally displaced to an engagement releasing position where the whole is housed within the outer peripheral surface of the second protrusion 4.

As shown in FIGS. 1 and 3, a coil spring 20 is housed in the spring housing hole 7.
The coil spring 20 has an L-shaped bent piece 20a at one end, and the bent piece 20a is housed in a notch 7a formed on one side of the inner circumference of the closed end of the spring housing hole 7, and the notch is formed. The edge of the tip of the bent piece 20a is engaged with the side surface of the portion 7a, and the engagement prevents the one end from moving in the axial direction.

The other end of the coil spring 20 is inserted into a spring insertion hole 21 formed in the rotary shaft 11 and penetrating in the radial direction. The coil spring 20 causes the handle shaft 16a of the handle 16 to face outward. Pressed.

The coil spring 20 is composed of the rotating shaft 1
1 is elastically deformed when it is rotated, and due to the restoring elasticity due to the deformation, both ends of the first cone 12 and the second cone 13 project outward from the outer peripheral surfaces of the projecting portions 3 and 4 facing the respective cones. The rotary shaft 11 is rotated back to the position.

In the state where the first cone 12 and the second cone 13 are held in the engagement position by the coil spring 20, the lever portion 16b of the handle 16 is held in the sideways state.

The handle 16 is temporarily fixed to both positions where the first cone 12 and the second cone 13 are disengaged by a temporary fixing mechanism 22 shown in FIG. 6 provided between the handle 16 and the rotary shaft 11.

The temporary fixing mechanism 22 is provided with a pair of notches 23, 23 at substantially central positions on both side surfaces of the guide hole 18,
The handle 16 and the rotary shaft 11 are temporarily fixed by engaging the tip of the arm 19 with each notch 23.

The rotation shaft 11 is prevented from rotating by the rotation stop mechanism 24 shown in FIGS. 3 and 4 from the engaged position to the disengaged position of the cone arranged on the upper side thereof.

In the rotation stopping mechanism 24, the stopper 25 is slidably inserted into the stopper insertion hole 8 and a stopper pin 26 inserted into the pin hole 9 is provided on the outer periphery of the stopper 25, and the outer periphery of the rotating shaft 11 is provided. The surface is provided with a first protrusion 27 and a second protrusion 28 that face the stopper pin 26 in the circumferential direction of the rotary shaft 11 at the positions where the stopper pin 26 contacts both ends of the pin hole 9, respectively.

Here, the stopper 25 is the stopper pin 2
When the flange 6 contacts the both ends of the pin hole 9, the flange 2
The end portion of the rotary shaft 1 is projected to the upper surface or the lower surface of the rotary shaft 1 and the stopper 25 is pushed into the stopper insertion hole 8 so that the stopper pin 26 can move relative to the first protrusion 27 or the second protrusion 28.
The position of the rotary shaft 11 is displaced in the axial direction of 1, and the rotation stopper of the rotary shaft 11 is released.

The handle shaft 1 of the handle 16
The rotation angle of 6a is limited by the contact of the rear end of the arm 19 with the wall surface 29 provided in the connector body 1, and the tip of the arm 19 is located slightly before the arm 19 contacts the wall surface 29. The notch 23 is adapted to be engaged (see FIG. 1).

As shown in FIGS. 1 and 2, four arcuate bulges 30 are formed at 90 ° intervals at the upper and lower open ends of the rotary shaft insertion hole 5, and each bulge is formed. 30 is in line contact with the end faces of the first cone 12 and the second cone 13, and is in point contact with the outer periphery of the rotary shaft 11.

The container connector shown in the embodiment has the above structure, and FIGS. 1 and 4 show a state in which the upper and lower containers C ₁ and C ₂ are connected to each other by the container connector. That is, the first protruding portion 3 is inserted into the engagement hole a in the lower surface of the upper container C ₁ , and the first cone 12 has its first
Both ends project outward from the outer peripheral surface of the projecting portion 3 and engage with the engaging holes a.

The second projecting portion 4 is provided on the lower container C ₂
The second cone 13 is inserted into the engaging hole a on the upper surface of the second cone 13, and both ends of the second cone 13 project outward from the outer peripheral surface of the second protruding portion 4 to engage with the engaging hole a.

In the engaged state of the first cone 12 and the second cone 13, the lever portion 16b of the handle 16 is in a horizontal state, the stopper 25 is pushed into the stopper insertion hole 8, and the stopper pin 26 is in the first position. 1 protrusion 27
And the position is displaced in the axial direction of the rotary shaft 11 with respect to the second protrusion 28.

Containers C ₁ and C ₂ stacked in multiple stages
In the above, the container C ₁ on the upper stage side is fixed by a fastening tool slantingly extended between the engagement hole b on the outer peripheral surface of the lower corner metal fitting A and the deck metal fitting attached to the deck.

Here, as shown in FIG. 5, the fastening tool includes a rod 40 having a hook 41 at its tip, and the rod 40.
The hook 41 of the rod 40 is engaged with the engaging hole b on the outer peripheral surface of the corner fitting A, and the rod 40 is axially tightened by tightening the turnbuckle. The upper container C ₁ is pulled and fixed.

Since the handle 16 of the container connecting tool projects outwardly from the outer peripheral surfaces of the containers C ₁ and C ₂ during the tightening of the above-mentioned fastener, the rod 40 should come into contact with the lever portion 16b of the handle 16. Is extremely large.

At this time, since the handle shaft 16a of the handle 16 is slidably supported in the axial direction and is pushed outward by the coil spring 20, the handle 16 is pushed by the rod 40 when the rod 40 is tightened. Being moved inward. Therefore, there is no inconvenience that the rod 40 is bent, and the linear tension of the rod 40 can fix the container C ₁ on the upper stage side very firmly.

When loading and unloading the upper container C ₁ , after removing the fasteners, the lever portion 1 of the handle 16 is removed.
Pull down 6b. By pulling down the lever portion 16b, the rotating shaft 11 rotates in the engagement releasing direction in which the second cone 13 is housed within the outer peripheral surface of the second protruding portion 4.

Here, when the rotary shaft 11 is rotated by pulling down the lever portion 16b, the tip of the arm 19 is guided by the guide hole 1
The rotating shaft 11 is pushed up by the contact with the rotating shaft 11.
Therefore, since the upper first cone 12 is rotated, the upper first cone 12 is formed on the upper opening end of the rotary shaft insertion hole 5.
It rotates in a non-contact state with respect to 0. Also, the rotating shaft 11
Rotates with its outer circumferences in point contact with the bulging portion 30 and the end face of the second cone 13 on the lower side in line contact with the lower bulging portion 30.

Therefore, the rotational resistance of the rotary shaft 11 is small, and the rotary shaft 11 can be rotated by an extremely small operating force.

When the handle 16 is rotated to a position where the tip of the L-shaped arm 19 fits into the notch 23, the second cone 13 is entirely disengaged in the outer peripheral surface of the second protrusion 4. The handle 16 is temporarily fixed by the engagement between the tip of the arm 19 and the notch 23, and the second cone 13 is held in the disengaged state.

[0055] At this time, the first cone 12 is in a state to engage the engaging hole a of the upper side container C _1, by pulling the upper-side container C _1, pulling the container connector with its upper side container C ₁ is, the second cone 13 and the second projecting portion 4 is pulled out from the engagement hole a of the lower side container C _1, the upper and lower container C _1, C ₂ are separated.

When the upper container C ₁ is pulled up, the stopper 25 descends due to its own weight and the stopper pin 2
6 is received at the lower end of the pin hole 9, and its tip end faces the second protrusion 28 in the circumferential direction of the rotary shaft 11.

When the upper container C ₁ is lifted and conveyed, the lever portion 16b of the handle 16 is temporarily stopped in the pulled-down state, and the first cone 12 is held in a state of being engaged with the engagement hole a. There is no inconvenience that the container connector will fall off from the container C ₁ .

When the upper container C ₁ is transported, the lever portion 16b is temporarily brought into contact with an obstacle to release the engagement between the tip portion of the arm 19 and the cutout portion 23, and the elasticity of the coil spring 20 causes the first cone 12 to move. Even if the rotating shaft 11 rotates in the direction of disengagement of the rotating shaft 11, since the stopper pin 26 of the stopper 25 faces the second protrusion 28 in the circumferential direction of the rotating shaft 11, And the second protrusion 28
Is stopped by the abutment of.

[0059] Therefore, the first cone 12 is held in engagement with the engaging hole a of the upper side container C _1, the occurrence of inconvenience that the container connector falls out from the upper side the container C ₁ is none Yes, and extremely safe.

The container connector is unloaded from the upper container C ₁ after the upper container C ₁ is unloaded.

When removing the container connecting tool, the lever portion 16b is turned sideways, and then the stopper 25 is pushed up so that the stopper pin 26 is moved relative to the second protrusion 28.
After shifting the position in the axial direction of 1, the lever portion 16b is further pushed up.

By pushing up the lever portion 16b, the rotary shaft 11 rotates in the direction in which the first cone 12 is disengaged, and the handle 16 is rotated to a position where the tip end portion of the arm 19 engages with the cutout portion 23. And the handle 16 and the rotary shaft 1 by the engagement of the tip of the arm 19 and the notch 23.
1 is temporarily fixed, and the first cone 12 has the first protrusion 3
The disengaged state is such that the whole is accommodated within the outer peripheral surface of the.

Therefore, the container connecting tool is lowered by its own weight, the first cone 12 and the first projecting portion 3 come out from the engaging hole a of the upper container C ₁ , and the container connecting tool is removed.

When stacking the containers, the first cone 12 is disengaged by pushing up the lever portion 16b, and then the first projecting portion 3 is inserted into the engaging hole a on the lower surface of the container C ₁ that has been lifted. Insert the 1st cone 1
2 is completely inserted into the engaging hole a, the lever portion 16
b is pulled down and returned to the horizontal state, and the first cone 12 and the second cone 13 are brought into the engaged state. Then, the container C ₁ is placed on the container C ₂ previously loaded,
The second protrusion 4 is inserted into the engagement hole a of the lower container C ₂ .

When the second cone 13 is inserted into the engagement hole a, the second cone 13 is rotated in the disengagement direction due to the contact between the inner periphery of the engagement hole a and the cone portion 15 of the second cone 13. ,
When the second cone 13 is completely inserted into the engagement hole a, the restoring elasticity of the coil spring 20 allows the second cone 13 to be completely inserted.
Is returned to the engagement state and engages with the engagement hole a.

When connecting the containers as described above, the container connecting device is such that the first cone 12 is on the lower side and the second cone 1 is on the lower side.
3 may be turned upside down and used.

Even when the container connector is used upside down, the lower first cone 12 is disengaged by pulling down the lever portion 16b, and the upper second cone 13 is engaged by pushing up the lever portion 16b. It will be canceled.

Further, when the upper container C ₁ is unloaded, the stopper 25 descends by its own weight, and the stopper pin 26 faces the first protrusion 27 in the circumferential direction of the rotary shaft 11, so that the lever portion 16b is laterally oriented. Since it cannot be pushed up from the state, the container connecting tool is kept connected to the upper container C ₁ and there is no danger of dropping.

[0069]

As described above, according to the present invention, the handle is outwardly pressed by the single coil spring, and the rotary shaft is rotated and returned to the state where the cones are in the engaging positions. As a result, the number of parts can be reduced and the assembling of the container connector can be facilitated.

Further, by providing an arcuate bulging portion in line contact with the end face of the cone at the opening end of the rotary shaft insertion hole, it is possible to reduce the rotational resistance during rotation of the rotary shaft, which is small. The rotary shaft can be rotated by operating force.

Furthermore, since the bulging portion is in point contact with the outer periphery of the rotary shaft, the rotational resistance is further reduced, and the rotary shaft can be rotated by a smaller operating force.

[Brief description of drawings]

FIG. 1 is a vertical sectional front view showing an embodiment of a container connector according to the present invention.

FIG. 2 is a plan view of the container connector shown in FIG.

FIG. 3 is a cross-sectional plan view of the container connector shown in FIG.

FIG. 4 is a vertical sectional front view of the container connector shown in FIG.

FIG. 5 is a vertical cross-sectional front view showing the lashing state of the upper container.

FIG. 6 is a vertical sectional side view showing a loading / unloading state of the upper container.

[Explanation of symbols]

1 Connector body 2 flange 3 first protrusion 4 Second protrusion 5 Rotating shaft insertion hole 6 Handle insertion hole 8 Stopper insertion hole 11 rotation axis 12 first cone 13 Second cone 16 handles 16a handle shaft 16b lever part 17 Rotation transmission mechanism 18 Guide hole 19 L-shaped arm 20 coil spring 24 Non-rotating mechanism 25 stopper 26 Stopper pin 27 First protrusion 28 Second protrusion 30 bulge

Claims (6)

[Claims] 1. A connector main body having positioning protrusions, which are fitted almost exactly into a substantially rectangular engaging hole provided in a corner fitting of a container, above and below a flange arranged between the upper and lower containers. And a first cone and a second cone which are inserted into a rotary shaft insertion hole penetrating from an upper end surface of the upper protruding portion to a lower end surface of the lower protruding portion, and which are engageable with peripheral portions of the engaging hole at upper and lower ends. And a handle shaft slidably inserted into a handle insertion hole penetrating the rotary shaft insertion hole from the outer peripheral surface of the flange, and the lever portion is laterally provided at the outer end of the handle shaft. And a handle provided with a spring insertion hole formed in the rotary shaft and penetrating in the radial direction to press the handle toward the outside, and deformed by the rotation of the rotary shaft.
A coil spring that causes both ends of each of the first and second cones to return and rotate the rotary shaft to the engaging position facing outward from the outer peripheral surface of the protruding portion facing the cone by the restoring elasticity due to the deformation, and the handle shaft. And a rotation transmission mechanism that transmits rotation about the axis of the rotation axis to the rotation axis. 2. A stopper, which is slidably inserted into a stopper insertion hole penetrating the upper and lower surfaces of the flange,
When the stopper is in the descent-stopped state, the stopper pin provided on the outer periphery of the stopper faces the protrusion provided on the outer periphery of the rotation shaft in the circumferential direction, and the upper cone is directed to the disengagement position where it is housed within the outer peripheral surface of the protrusion. The container connector according to claim 1, further comprising: a rotation stopping mechanism that prevents the rotation shaft from rotating and releases the rotation stopping by pushing the stopper into the stopper insertion hole. 3. The container connector according to claim 1, further comprising a temporary fixing mechanism for temporarily fixing the rotation shaft at a position where the first cone and the second cone are rotationally displaced to the disengagement position. 4. The rotation transmission mechanism is configured such that an L-shaped arm is provided at an inner end portion of a handle shaft, and a tip end portion of the arm is inserted into an axially long guide hole provided at an outer periphery of the rotation shaft. The container connector according to any one of claims 1 to 3. 5. The container connector according to claim 1, wherein an arcuate bulging portion that is in line contact with an end surface of a corresponding cone is provided at an opening end of the rotary shaft insertion hole. 6. The container connector according to claim 5, wherein the bulging portion is in point contact with the outer periphery of the rotating shaft.