KR101647092B1 - A Support for coil-shape weight which can accomodate the coil-shape weight bidirectionally - Google Patents

Abstract

The present invention relates to a coiled heavy object support capable of loading a coiled heavy object, comprising: a body extending back and forth along a longitudinal direction; A transverse support disposed on an upper surface of the body so as to support and support the coiled heavy object in a state in which the transverse direction intersecting the longitudinal direction of the body and the central axes of the coiled heavy object are arranged side by side; And a longitudinal support disposed on the upper surface of the main body so as to support and support the coiled heavy object in a state in which the longitudinal direction of the main body and the central axis of the coiled heavy object are arranged side by side .
According to the present invention, the storing direction of the coil-shaped heavy object can be selected in the lateral direction or the longitudinal direction according to the length of the coil-shaped heavy object to be stored, so that the inner space of the container is not wasted.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a co-

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a coiled heavy object support, and more particularly, to a coiled heavy object support which can select a storage direction of a coiled heavy object in accordance with a length of a coiled heavy object to be stored, .

The weight of a coil-like heavy material (R) having a weight of several to several tens tons, such as hot coils produced by heating a metal such as steel to a recrystallization temperature or higher and rolling it, is 15 to 30 tons (ton). Therefore, in the case of land transportation, the trailer for coil is used or the coil is bound to the flat trailer. In the case of marine transportation, bulk ship is used or stored in a container for cargo transportation. Transportation.

In the case of bulk shipping, there is an advantage in that it does not require the use of freight containers. However, most of the bulk carriers' operations are irregular, so it is difficult to comply with deadlines of freight operations and the fluctuation of freight rates of bulk carriers Container freight is increasing due to container freight rate cuts due to recent increase in container freight volume.

However, even in the case of transporting the coiled heavy object (R) by using the container ship, the load carrying the coiled heavy object (R) by the ship motion such as rolling and pitching of the ship occurring during the sea transportation There is a problem that the dunnage breaks or the container is often damaged. This problem leads to breakage of other cargoes in the container, so that a dry container, which is a container for general goods, Is used as a dunnage from shipping companies to shipping items to be avoided.

Of course, there is a method of using a coil dedicated container. However, in the case of a coil dedicated container, since only the coil type heavy object (R) can be carried, the coil can be unloaded from the destination because the other cargo can not be loaded, There is still a problem in that the fare is increased accordingly.

In order to solve such a problem, a coil support support for a container which can effectively transport the coil-like heavy material R without using a coil dedicated container has been used.

In the case of the conventional coil support for a container, it is general to arrange the central axis CR of the coil-like heavy object R side by side only in the longitudinal direction of the container or in the transverse direction perpendicular thereto. That is, as shown in FIG. 2, the coil-shaped heavy object R is disposed only in the longitudinal direction or the coil-shaped heavy object R is disposed only in the lateral direction as shown in FIG.

However, in the case of storing the coil-shaped heavy material R only in one direction as described above, in the case of the coil-like heavy material R having a specific length, the coil-shaped heavy material R in the longitudinal direction, R and the number of the coil-shaped heavy objects R stored when the coil-like heavy object R is placed in the lateral direction are different from each other and the space of the container is wasted according to the direction of the coil- .

Further, in the conventional coil support for a container, when the coiled heavy object R is housed in the container using the forklift in a state in which the coiled heavy object R is held, the load is applied to the lower surface of the coil support There was also a problem of scratching and severely damaging the floor of this container.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a coiling machine capable of selecting a storing direction of a coiled heavy object in a lateral direction or a longitudinal direction according to a length of a coiled heavy object to be stored, So as to provide an improved coiled heavy object support structure.

According to an aspect of the present invention, there is provided a coiled heavy object support for loading a coiled heavy object, comprising: a body extending back and forth along a longitudinal direction; A transverse support disposed on an upper surface of the body so as to support and support the coiled heavy object in a state in which the transverse direction intersecting the longitudinal direction of the body and the central axes of the coiled heavy object are arranged side by side; And a longitudinal support disposed on the upper surface of the main body so as to support and support the coiled heavy object in a state in which the longitudinal direction of the main body and the central axis of the coiled heavy object are arranged side by side .

Here, it is preferable that a plurality of the transverse support portions and the transverse support portions are provided, and they are alternately arranged along the longitudinal direction of the main body.

The lateral support portion is disposed to intersect with the longitudinal support portion and the side end portion of the lateral support portion is provided with a connection groove portion for eliminating interference with the coiled heavy object supported by the longitudinal support portion .

The main body includes a pair of side beams spaced apart from each other by a predetermined distance in a state of being faced to each other in parallel with each other and extending in the longitudinal direction and a front beam connecting the front ends of the side beams to each other, And a rear beam connecting the rear ends of the side beams to each other, wherein both ends of the lateral supports connect the pair of side beams to each other.

Here, it is preferable that the transverse support portion and the longitudinal support portion are recessed concavely in a "V" shape.

In this case, it is preferable that a plurality of coils are stacked in a multi-stage structure in a state that they are accommodated in the container for cargo transportation in a state in which the coil-shaped heavy objects are stacked.

According to the present invention, there is provided an electronic device comprising: a main body extending back and forth along a longitudinal direction; A transverse support disposed on an upper surface of the body so as to support and support the coiled heavy object in a state in which the transverse direction intersecting the longitudinal direction of the body and the central axes of the coiled heavy object are arranged side by side; And a vertical support disposed on an upper surface of the main body so as to support and support the coiled heavy object in a state in which the longitudinal direction of the main body and the central axis of the coiled heavy object are arranged side by side, The weight of the coil-shaped heavy object can be selected in the lateral direction or in the longitudinal direction depending on the length of the coil-shaped heavy object. Thus, the inner space of the container is not wasted.

1 is a perspective view of a coiled heavy object support which is one embodiment of the present invention.
FIG. 2 is a view showing a state in which the coil-shaped heavy object is lifted up in the longitudinal direction in parallel with the longitudinal direction of the container on the upper surface of the coiled heavy object support shown in FIG.
Fig. 3 is a view showing a state in which a coil-shaped heavy object is raised on the upper surface of the coiled heavy object support shown in Fig. 1 in a transverse direction perpendicular to the longitudinal direction of the container.
Fig. 4 is a front view of the coiled heavy object support shown in Fig. 1. Fig.
5 is a left side view of the coiled heavy object support shown in Fig.
6 is a right side view of the coiled heavy object support shown in Fig.
7 is a plan view of the coiled heavy object support shown in Fig.
8 is a cross-sectional view taken along line AA of the coiled heavy object support shown in Fig.
9 is a BB line sectional view of the coiled heavy object support shown in Fig.
Fig. 10 is a bottom view of the coiled heavy object support shown in Fig. 1. Fig.
11 is a partially enlarged perspective view of the bottom of the coiled heavy object support shown in Fig.
12 is an enlarged view of the friction preventing unit shown in Fig.
Fig. 13 is a view showing a state in which the friction preventing unit shown in Fig. 1 operates. Fig.
14 is a sectional view of the friction preventing unit shown in Fig.
Fig. 15 is a view showing another embodiment of the friction preventing unit shown in Fig. 1. Fig.
16 is a sectional view of the friction preventing unit shown in Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a coiled heavy object support according to an embodiment of the present invention. FIG. 2 is a side view of the coiled heavy object support shown in FIG. 1, showing a state in which the coiled heavy object is raised in the longitudinal direction FIG. Fig. 3 is a view showing a state in which a coil-shaped heavy object is raised on the upper surface of the coiled heavy object support shown in Fig. 1 in a transverse direction perpendicular to the longitudinal direction of the container.

1 to 3, a coiled heavy object support 100 according to a preferred embodiment of the present invention includes a plurality of coils, such as a hot coil formed by heating and rolling a metal such as a steel to a recrystallization temperature or higher, Called support coil rack, which is accommodated in the interior of the cargo transportation container C in a state in which coil type heavy material R having a weight of tens tons is loaded.

Hereinafter, it is assumed that the container C is a dry container, which is a general goods container used for transporting freight such as freezing, liquid, ventilation, etc., which does not require special attention. On the other hand, the container C is a rectangular steel frame structure, and the inner floor is welded to the floor F having a rectangular flat plate shape.

The coiled heavy object support 100 includes a main body 10 and a friction preventing unit 20.

The main body 10 includes a side frame 11, a front frame 12, a rear frame 13, a side frame 11, a side frame 11, 14, a transverse support 15, and a longitudinal support 16.

The side beams 11 are formed as long beams extending in the longitudinal direction along the first central axis C1. The side beams 11 are spaced apart from each other by a predetermined distance in a state where they face each other in parallel. In the present embodiment, the side beam 11 includes a forcible beam having an "I " -shaped cross section.

The lower surfaces of the pair of side beams 11 protrude downward so as to contact the floor F of the container C and to transmit a load. That is, the lower surface of the side beam 11 is a rear end contact surface S2 capable of contacting the floor F as shown in Figs.

Each of the pair of side beams 11 has a pair of fork insertion openings 17 formed in the central outer surface of each of the pair of side beams 11 as holes for inserting a fork of a forklift.

As shown in Fig. 7, the front end outer side surface of the side beam 11 is formed to be inclined in such a shape that its width decreases toward the front side.

A guide member 18, which is a rectangular metal plate, is welded to the outer surface of the front end of the side beam 11.

11 and 12, a friction preventing unit receiving groove 111 capable of receiving the friction preventing unit 20 described later is formed on the front end of the side beam 11.

The frictional protection unit receiving groove 111 is formed in a letter "A" shape and extends along the longitudinal direction C1 of the side beam 11.

The friction-preventing-unit receiving groove 111 is welded to the receiving groove reinforcing member 112 for structural reinforcement.

The receiving groove reinforcing member 112 has a shape corresponding to the shape of the friction preventing unit receiving groove 111 and has the same width as the lower flange 114 of the side beam 11, 114).

The upper surface of the receiving groove reinforcing member 112 and the lower surface of the upper flange 115 of the side beam 11 are connected by a reinforcing member 113.

The front beam 12 is a beam connecting the front ends of the side beams 11 and is extended in the left and right direction C2 perpendicular to the first center axis C1, (11) to each other. In the present embodiment, the front beam 12 includes a forcible beam having an "S"

The rear beam 13 is a beam connecting the rear ends of the side beams 11 and is extended in the left and right direction C2 perpendicular to the first center axis C1, (11) to each other. In the present embodiment, the rear beam 13 includes a forcible beam having an "S" -shaped cross section.

A pair of fork insertion openings 17 are formed in the outer surface of the central portion of the rear beam 13, which are holes that allow fork of a fork lift to be inserted.

The beam 14 is a beam extended along the second central axis C2, and both ends are coupled to the pair of side beams 11, as shown in Figs. 5 and 10 .

The lateral support portion 15 is formed in a state in which the lateral direction C2 perpendicular to the longitudinal direction C1 of the main body 10 and the central axis CR of the coiled heavy object R are arranged side by side , And can support and support the coil-like heavy material (R).

The lateral support portion 15 is a metal plate member recessed and recessed in a "V" shape so as to be able to support and support the coiled heavy object R, (C1).

The lateral support portion 15 includes a pair of inclined surfaces 151 facing each other in a V shape and a bottom surface 152 in the form of a horizontal flat plate is provided between the pair of inclined surfaces 151. [ Or the like.

The transverse support portion 15 having the bottom surface 152 is provided to avoid interference between the cross beam 14 and the fork insertion hole 17 and in the present embodiment, As shown in FIG.

The transverse support portion 15 extends along the second central axis C2 by a predetermined length and both ends connect the inner ends of the pair of side beams 11 to each other.

The longitudinal support portion 16 is formed in a state in which the longitudinal direction C1 of the main body 10 and the central axis CR of the coiled heavy object R are arranged in parallel to each other, And is a member that can support and support the coil-shaped heavy object R.

The longitudinal support portion 16 is a metal plate member recessed and recessed in a "V" shape so as to be able to support and support the coiled heavy object R, and a plurality of longitudinal support portions 16 are provided on the upper surface of the body 10, (C1).

The longitudinal support portion 16 includes a pair of inclined surfaces 161 facing each other in the shape of a "V ". A bottom surface 162 in the form of a horizontal flat plate is provided between the pair of inclined surfaces 161, Or the like. The longitudinal support portion 16 extends a predetermined length along the first central axis C1.

The transverse support portion 15 and the longitudinal support portion 16 are alternately arranged along the longitudinal direction C1 of the main body 10. [ In the present embodiment, five transverse support portions 15 are provided, and six longitudinal support portions 16 are provided.

At least one of the opposite ends of the longitudinal support portion 16 is welded to a side end portion of the adjacent lateral support portion 15. The transverse support portion 15 is formed to cross the longitudinal support portion 16, Respectively.

That is, the plurality of lateral support portions 15 and the longitudinal support portions 16 have a unit connection structure similar to the " king "shape as shown in Fig.

At least one of the side end portions of the lateral support portion 15 is provided with a notch shaped connection groove portion 153 for eliminating interference with the coiled heavy object R mounted on the upper surface of the longitudinal support portion 16 Respectively.

The friction preventing unit 20 is an apparatus for reducing the frictional resistance of the container C to the floor F when the main body 10 advances forward inside the container C, 12, a pair of sliders 21, a bracket 22, a pin 23, a lubrication pad 24, and a slider 25 are disposed on the lower surface of the front end of the main body 10, And a guide member (25).

The slider 21 is a metal member slidable with respect to the floor F of the container C and includes a lower plate 211 and a connecting portion 212.

The lower plate 211 is a metal plate member extending along the first central axis C1 and has a shape similar to that of a ski plate. As shown in FIG. 12, (114).

A curved surface portion 214 bent upward is disposed at both ends of the lower plate 211 and a flat surface portion 215 parallel to the floor F is disposed between the curved surface portions 214.

The connection portions 212 are vertically disposed with a pair of metal members spaced apart from each other, and the lower end portion is welded to the upper surface of the lower plate 211.

A coupling hole 213, which is a circular hole, is formed in the upper end of the connection portion 212.

The brackets 22 are vertically arranged as a pair of metal members and are spaced apart from each other. The upper ends of the brackets 22 are welded to the lower surface of the accommodation groove reinforcing member 112.

The lower end of the bracket 22 is formed with a coupling hole 221 which is a circular hole and a rectangular plate-shaped reinforcing member 222 is welded to the periphery of the coupling hole 221.

The upper end of the connection part 212 is inserted between the lower ends of the pair of brackets 22 and the connection hole 213 of the connection part 212 and the connection hole 221 of the bracket 22 Are in the corresponding positions.

The pin 23 is a circular rod extending along the third central axis C3 and passes through both the coupling hole 213 of the coupling portion 212 and the coupling hole 221 of the bracket 22 The connecting portion 212 and the bracket 22 are engaged with each other.

The connecting portion 212 and the bracket 22 are coupled to each other by the pin 23 so as to be rotatable relative to each other. Here, the third central axis C3 intersects perpendicularly with the first central axis C1 and the second central axis C2.

The lubrication pad 24 is a flat belt-like member having a coefficient of friction equal to or less than a predetermined value and extends along the longitudinal direction of the slider 21. A screw 26 is provided on the lower surface of the slider 21, Respectively.

The lubrication pad 24 is preferably made of a soft material as compared with steel, which is a material of the side beam 11. In this embodiment, the lubrication pad 24 is made of a high-strength synthetic resin having slippery material.

A curved surface portion 241 bent upward is disposed at both ends of the lubrication pad 24 and a flat surface portion 242 parallel to the floor F is disposed between the curved surface portions 241.

The lower surface of the planar portion 242 of the lubrication pad 24 is a front end contact surface S1 capable of contacting the floor F as shown in Figs.

13, when the rear end of the main body 10 is lifted by the forklift and the main body 10 is inclined forward by a certain angle?, The slider 21 does not rotate The lower surface S2 of the side beam 11 does not contact the floor F and only the lower surface S1 of the flat surface portion 242 of the lubrication pad 24 is exposed to the floor F To transmit the load. It is sufficient if the maximum value of the angle? Has a value of 10 to 20 degrees.

The height H1 of the lubricating pad 24 as the front end contact surface S1 and the height H2 of the bottom surface of the side surface beam 11 as the rear end contacting surface S2 in the present embodiment are Are the same as each other.

Therefore, when the main body 10 is not tilted (? = 0), the lower surface S2 of the pair of side rails 11 and the lower surface S1 of the flat surface portion 242 of the lubrication pad 24, Cooperates with the floor F of the container C to transmit the load.

The guide member 25 is a member for accurately guiding the left and right positions of the main body 10 when the main body 10 advances forward in the container C, As shown in Fig.

The guide member 25 is a circular rod bent in a C shape and one end is welded to the outer surface of the connecting portion 212 and the other end is welded to the side beam 11, As shown in Fig.

The guide member 25 is slidable in contact with the inner wall of the container C when the main body 10 advances forward within the container C.

The coiled heavy object support 100 of the above-described configuration comprises: a main body 10 extending back and forth along the longitudinal direction C1; Like weight R in a state in which the lateral direction C2 perpendicular to the longitudinal direction C1 of the main body 10 and the central axis CR of the coiled heavy object R are arranged side by side A transverse support portion (15) disposed on the upper surface of the body (10) so as to support the transverse support portion (15); The weight of the coil-like heavy object R may be supported in a state in which the longitudinal direction C1 of the body 10 and the center axis CR of the coil- The weight of the coiled heavy object R can be selected in the lateral direction or in the longitudinal direction depending on the length of the coiled heavy object R stored therein since the vertical support portion 16 disposed on the upper surface of the body 10 There is an advantage that the internal space of the container C is not wasted.

In the coiled heavy object support 100, a plurality of the transverse support portions 15 and the longitudinal support portions 16 are provided and alternately arranged along the longitudinal direction C1 of the main body 10 So that it is possible to dispose a plurality of the transverse support portions 15 and the longitudinal support portions 16 as many as possible.

The longitudinal support portion 15 of the coiled heavy object support 100 is disposed so as to intersect with the longitudinal support portion 16 and the lateral support portion 15 has a longitudinal support portion Shaped weight R supported by the vertical support portion 16 and the coiled heavy object R supported by the vertical support portion 16 by the horizontal support portion 15, There is an advantage that the number and size of the mold heavy materials R are not reduced.

The coiled heavy object support 100 includes a pair of side beams spaced apart from each other by a predetermined distance in a state in which the main body 10 is extended in the longitudinal direction C1, A front beam 12 connecting the front ends of the side beams 11 to each other and a rear beam 13 connecting the rear ends of the side beams 11 to each other, 15 has the advantage that the structural rigidity of the main body 10 is increased by reinforcing the main body 10 by the lateral support portions 15 because both ends connect the pair of side beams 11 to each other have.

Since the transverse support portion 15 and the longitudinal support portion 16 are recessed concavely in the shape of a "V" in the coiled heavy object support 100, the body 10 can be moved forward, backward, Shaped load R can be stably supported from the transverse support portion 15 and the longitudinal support portion 16 without detaching from the transverse support portion 15 and the longitudinal support portion 16 Can be accommodated in the main body 10, so that the overall height can be minimized.

Since the coiled heavy object support 100 can be accommodated in the interior of the cargo transportation container C with the coiled heavy object R mounted thereon, And loads the coiled heavy objects R to a destination, stacks a plurality of coiled heavy object supports 100 in one of a plurality of containers C and stores the same in a plurality of stages, C), the general cargo can be accommodated in the internal space, and the overall transportation cost can be reduced.

The coiled heavy object support 100 is a heavy object support received in the interior of the cargo transportation container C in a state in which the heavy object R is loaded and includes a main body 10 extending back and forth along the longitudinal direction C1; And a friction preventing unit (20) provided on a lower surface of a front end of the main body (10) for reducing a frictional resistance of the container (C) to a floor (F) The frictional protection unit 20 can prevent the load of the heavy object R from being dispersed when the body 10 advances inside the container C in a state where the body 10 is tilted forward, When the heavy object R is stored in the container C using the forklift in a state in which it is in contact with the floor F of the container C by the load of the heavy object R, There is an advantage that the lower surface of the heavy object support does not scratch and damage the floor F of the container C.

The coiled heavy object support 100 includes a pair of side beams spaced apart from each other by a predetermined distance in a state in which the main body 10 is extended in the longitudinal direction C1, A front beam 12 connecting the front ends of the side beams 11 to each other and a rear beam 13 connecting the rear ends of the side beams 11 to each other, Since the lower surface of the beam 11 contacts the floor F of the container C to transmit the load so that no load is transmitted near the center of the floor F, The durability of the container C is increased and the frictional resistance with respect to the floor F is also reduced.

In addition, since the coil type heavy object support 100 is provided with the friction preventing unit receiving groove 111 capable of receiving the friction preventing unit 20 on the lower surface of the front end of the side beam 11, The prevention unit 20 can be received so as not to protrude downward from the lower surface of the lower flange 114 of the side beam 11 so that the frictional protection unit 20 can be prevented from being damaged by an external impact The height H1 of the lubricant pad 24 as the front end contact surface S1 and the height H2 of the bottom surface of the side surface beam 11 as the rear end contact surface S2 can be made equal to each other have.

Since the coil type heavy object support 100 is coupled with the accommodation groove reinforcement member 112 for structural reinforcement in the friction preventive unit receiving groove 111, There is an advantage that strength reduction can be prevented.

The lower end of the coiled heavy object support 100 may be in contact with the floor F of the container C and the upper end of the coiled heavy object support 100 may be coupled to the main body 10 When the main body 10 is tilted forward by an angle? Within a predetermined range, the flat surface of the slider 21 can be inclined with respect to the surface of the slider 21 regardless of the value of the angle? The entire area of the floor 215 is kept in contact with the floor F, so that the load can be dispersed.

The lower plate 211 of the slider 21 is fixed to the lower surface of the slider 21 by the lubrication pad 24 having a coefficient of friction equal to or smaller than a predetermined value. There is an advantage that the coefficient of friction with respect to the floor F can be further reduced as compared with the case of directly contacting the floor F.

The rear end of the main body 10 is supported by the forklift so that the main body 10 is supported by the main body 10, 10 can be maximized in a state in which the friction preventing unit 20 is inclined forward by a predetermined angle alpha.

In the state that the main body 10 is not inclined, the lower surface of the pair of side beams 11 and the lower surface of the friction preventing unit 20 cooperate with each other, When the main body 10 is tilted forward by contacting the floor F of the main body 10 with the rear end of the main body 10, The load is transmitted to the floor F of the container C so that the load caused by the heavy object R can be effectively dispersed regardless of whether the main body 10 is tilted with respect to the floor F There is an advantage.

Although a plurality of physically separated longitudinal support portions 16 are used in this embodiment, it is needless to say that a configuration in which the plurality of longitudinal support portions 16 are physically integrated may be used.

The slider 21 of the friction prevention unit 20 can be rotated relative to the main body 10 by the hinge structure including the pin 23, Of course may be used. For example, when the lower plate 211 is formed to extend forward from the lower flange 114, the slider 21 is rotated relative to the main body 10 using the elastic deformation of the lower plate 211, .

In this embodiment, the connection between the connecting portion 212 and the bracket 22 is a hinge structure using one pin 23 or a hinge structure using two pins 23 as shown in Figs. 15 and 16, It goes without saying that the structure may also be used.

The coil type heavy object support 100a shown in FIG. 15 has substantially the same structure and effects as the coil type heavy object support 100, and therefore only differences between the two will be described.

The coiled heavy object support 100a includes a bracket 22a having two circular coupling holes 221 and a coupling portion having two coupling holes 213a formed in a long vertical direction as shown in FIG. 212a.

Accordingly, the pin 23 is relatively moved up and down in a state of being inserted into the engagement hole 213a, so that the connection portion 212a is rotated relative to the bracket 22a. At this time, the third center axis C3, which is the center of rotation, is located about the middle of the pair of coupling holes 213a.

The technical scope of the present invention is not limited to the contents described in the above embodiments, and the equivalent structure modified or changed by a person having ordinary skill in the art can be applied to the technical It is clear that the present invention does not depart from the scope of thought.

[Description of Reference Numerals]
100: Coil type heavy weight support
10: Body
11: Side beam
12: Front beam
13: Rear beam
14: Rear beam
15:
16: longitudinal support
17: Fork insert
18: Guide member
20: Friction prevention unit
21: Slider
22: Bracket
23:
24: Lubricating pad
25: Guide member
26: Screw
111: Friction prevention unit receiving groove
112: receiving groove reinforcing member
113: reinforcing member
114: Lower flange
115: upper flange
151:
152: bottom surface
153: connecting groove
161:
162: bottom surface
211: Lower plate
212:
213: coupling ball
214:
215: plane portion
221: coupling ball
222: reinforcing member
241:
242:
C: Container
CR: Coil-type heavy weight center axis
C1: longitudinal direction
C2: second center axis
C3: third center axis
F: Floor
H1: Contact surface height
H2: rear end contact surface height
S1: Shear contact surface
S2: rear end contact surface

Claims (6)

A coiled heavy object support capable of loading a coiled heavy object,
A body extending back and forth along the longitudinal direction;
A transverse support disposed on an upper surface of the body so as to support and support the coiled heavy object in a state in which the transverse direction intersecting the longitudinal direction of the body and the central axes of the coiled heavy object are arranged side by side;
And a longitudinal support disposed on an upper surface of the main body so as to support and support the coiled heavy object in a state in which the longitudinal direction of the main body and the central axis of the coiled heavy object are arranged side by side,
Wherein the transverse support portion is disposed to intersect with the longitudinal support portion,
Characterized in that a side end portion of the transverse support portion is provided with a connection groove portion for eliminating interference with a coil-shaped heavy object supported by the longitudinal support portion The method according to claim 1,
Wherein a plurality of the transverse support portions and the longitudinal support portions are provided, and are alternately arranged along the longitudinal direction of the main body. delete The method according to claim 1,
Wherein the main body includes a pair of side beams spaced apart from each other by a predetermined distance in a state of being faced to each other in parallel with each other and extending in the longitudinal direction, a front beam connecting the front ends of the side beams to each other, And a rear beam connecting the rear ends of the side beams to each other,
Characterized in that the lateral support portion has both end portions connecting the pair of side beams to each other, The method according to claim 1,
Characterized in that the transverse support portion and the longitudinal support portion are concavely recessed in a "V" shape. The method according to claim 1,
It is possible to receive the inside of the container for freight transportation in a state in which the coiled heavy object is loaded,
And a plurality of coils are stacked in a plurality of stages in a state that the coils are not stacked.

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