Roll cargo transportation container and apparatus for preventing roll cargo from divergence of roll core

Disclosed is a novel roll-cargo transporting container which securely holds roll cargo in position by provision of sliding frame member below the top frame member and by effect of bracket members set to the bottom frame member and sliding frame member.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a container for transporting roll cargo 
and an apparatus for preventing roll cargo from incurring divergence of 
roll core on the way of transportation, more particularly, to a novel 
container for transporting roll cargo and a novel apparatus which prevents 
roll cargo from incurring divergence of roll core from the original 
condition taking place on the way of sea/land transportation. 
2. Description of the Related Art 
Of a variety of steel materials exported from Japan for example, majority 
of hot coils are delivered to general iron works, and thus, these hot 
coils have sizable thickness. On arrival at processing factories of the 
imported country, these hot coils are sheared into predetermined length or 
rerolled before eventually being delivered to markets. 
Now, looking at the method of transporting hot coils having sizable 
thickness, unit weight is variable according to the shape and dimension. 
Normally, hot coils are handled by transportation specialists as heavy 
cargo. In many cases, hot coils are shipped on a conventional freight 
vessel at a specially installed quay of a steel mill by applying special 
cranes. Any conventional freight vessel transports a huge bulk of hot 
coils in the condition preventing them from breaking loose by heavily 
binding them with lumber dunnage, wedges, chocks, and wires, while 
directly stacking hot coils on double-bottomed deck inside of the hold in 
multiple rows and layers. Normally, unit weight of each hot coil is quite 
heavy and often exceeds the allowable loading capacity of any conventional 
container, and thus, actually, hot coils are not transported by any 
container failing under ISO standard. 
On the other hand, recently, export of complete coils made from sheets from 
Japan increases, which are typically used for manufacturing automotive 
parts in local factories of the imported country. These complete coils are 
directly delivered to press work of the automotive part manufacturing line 
without being reprocessed by local factories, i.e., in the ex-Japanese 
factory condition. It is therefore extremely important for those who are 
responsible for the transportation to thoroughly safeguard the shipped hot 
coils from incurring deformation and/or damage caused by breakdown of 
cargo on the way of transportation or by careless loading and unloading 
operations or by adverse effect of binding members. 
On the other hand, local factories on the part of the imported country are 
not always at a site close to harbors, but in many cases, these are 
located in the inland areas. As a result, complete hot coils are subject 
to overland transportation until arrival at the designated local factory 
via trucks or freight trains after unloading them from the freight vessel 
at the port. Therefore, it is very important for those being in charge of 
transportation to carefully protect the complete sheet coils from 
incurring deformation and/or damage on the way of overland transportation. 
More particularly, when transporting complete sheet coils by means of a 
freight vessel, these coils are directly stacked in multiple rows and 
layers in the hold. Consequently, complete sheet coils arc subjected to 
heavy-weight pressure generated by multiple-layer stack, while they are 
also subjected to lateral pressure generated by rolling and pitching of 
the freight vessel itself. In addition, the roll cargo is subjected to 
repeated loading and unloading processes on the way of distribution and 
also to additional load generated by binding apparatus. As a result, shape 
of the roll cargo is frequently deformed and cargo itself also incures 
substantial damage Since overland transportation must be executed in many 
cases, those accidents can take place more frequently. 
Taking those critical problems into consideration, the inventor tried to 
materialize transportation of sheet-coils or wire coils (hereinafter 
merely called hot coils as a whole) by storing them in an ISO standard 
container. Nevertheless, it became clear for the inventor that, if hot 
coils were merely stored inside of the ISO container, external force 
against the freight vessel or train adversely affects loaded hot coils, 
thus causing them to displace inside of the container, and then, hot coils 
might be subjected to unexpected pressure enough to deform these coils, or 
friction might be generated between the loaded hot coils to result in the 
grave damage. In the light of those critical problems mentioned above, the 
inventor could not materialize the aimed object for a long while. 
Furthermore, since hot coils are prepared in a variety of forms for 
shipment and there are substantial differences in the dimension and weight 
of these coils, the constitution of the container itself needs to be 
compatible with a wide variety of hot coils. Consequently, it was quite 
difficult for the inventor to devise practical art for achieving the aimed 
object. 
Not only hot coils, there were similar problems in the transportation of 
roll papers available for newspaper etc. 
SUMMARY OF THE INVENTION 
The primary object of the invention is to provide a novel container suited 
for transporting roll cargo. 
Another object of the invention is to securely prevent cargo from incurring 
even the slightest deformation and/or damage on the way of sea and/or 
overland transportation. 
Another object of the invention is to provide a novel container which is 
compatible with a variety of dimensions of roll cargo. 
Another object of the invention is to provide a novel container which can 
be folded into a flat and non-bulky configuration when being collected. 
A still further object of the invention is to provide means for preventing 
roll cargo from incurring divergence of the core of rolled material from 
the original condition on the way of transportation. 
Now, therefore, in order to securely achieve those objects mentioned above, 
the roll-cargo transporting container related to the invention features 
provision of the following: 
top frame member which is removably installed between the top edges of main 
pillar frame members erected on four corners of the bottom frame member; 
sliding frame member which slides itself in the vertical direction in a 
range corresponding to upper half of the main pillar frame members; and 
a plurality of slidable bracket members having arc-shaped surfaces which 
come into contact with hot coils, where these bracket members are slidably 
installed above the surface of the bottom frame member and below the 
surface of sliding frame member; 
Desirably, the main pillar frame members should be of square shape. It is 
more desirable that the main pillar frame members are respectively 
provided with inwardly oriented projections on their surfaces where main 
pillars face each other, and furthermore, it is desirable that the main 
pillar frame members are provided with wedges which integrally combine the 
bottom frame member with the main pillar frame members by being inserted 
between the edge portions of the bottom frame member and the inward 
projections. 
It is more desirable that the main pillar frame members are erected and 
diassembled in the manner of falling themselves flat on the bottom frame 
member, and yet, it is also desirable that the bottom frame member has 
auxiliary frame members which are erected when the main pillar frame 
members remain flat on the bottom frame member. 
Furthermore, it is also desirable that bracket members are removably 
installed to the upper surface of the sliding frame member. 
To constitute the roll cargo transporting container related to the 
invention, the top frame member is removably installed between the upper 
edges of the main pillar frame members erected on four corners of the 
bottom frame member, and in addition, sliding frame member is installed in 
a range corresponding to upper half of the main pillar frame members so 
that it can slide itself in the vertical direction, and yet, arc-shaped 
surfaces are formed on the upper surface of the bottom frame member and 
the bottom surface of the sliding frame member to allow bracket members to 
slide themselves. Those constituents allow bracket members to slide 
themselves in accordance with external diameter of roll cargo before 
storing roll cargo in this condition and stably support roll cargo inside 
of the container by sliding the sliding frame member so that bracket 
members can come into contact with the surface of roll cargo. 
The apparatus for preventing roll cargo from incurring divergence of the 
core of rolled material from the original state features provision of the 
following; a pair of lengthy rigid bodies which are respectively longer 
than the inner diameter and shorter than the outer diameter of roll cargo 
and fixed along both end surfaces of roll cargo; and a pair of connection 
members connecting the pair of lengthy rigid bodies through the inner 
space of roll cargo. 
It is desirable that buffer layers are integrally formed on the external 
surfaces of the pair of lengthy rigid bodies for coming into contact with 
roll cargo. The buffer layers should be provided at least in a range 
coming into contact with edge surface of roll cargo. Alternately, buffer 
layers may also be provided all over the surfaces of lengthy rigid bodies. 
Connection member is composed of a pair of leading chains. It is desirable 
that through-holes and mechanism for securing the pair of leading chains 
are provided in the center of each of lengthy rigid bodies. This mechanism 
may be of the one which thrusts leading chains or the one capable of 
performing seesaw-like operation. 
As mentioned above, since the apparatus for preventing roll cargo from 
incurring divergence of the core of rolled material from the original 
position provides a pair of lengthy rigid bodies which are respectively 
longer than the inner diameter and shorter than the outer diameter of roll 
cargo and also a pair of connection members connecting the pair of lengthy 
rigid bodies through the inner space of roll cargo, the inner 
circumference of roll cargo can uniformly be controlled over a specific 
range in conjunction with the movement of roll cargo in the axial 
direction. As a result, when the external force is applied in the axial 
direction of roll cargo, amount of friction resistance at the border 
between the uniformly controlled portion and the outer portion outgrows 
that is generated on the innermost circumference of roll cargo, and thus, 
when certain external force less than substantial amount is applied to 
roll cargo, the apparatus related to the invention securely prevents the 
inner circumference of roll cargo from sliding in the axial direction.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
FIG. 1 is the perspective view of a preferred embodiment of the roll cargo 
transporting container related to the invention. The top frame member 1 
and the bottom frame member 2 respectively having flatboard shape are 
disposed at the top and the bottom by maintaining a certain distance 
almost corresponding to the external diameter of roll cargo 7 having the 
largest dimensions. Square and hollow main pillar frame members 3 
respectively connect lateral sides of the top and bottom frame members 1 
and 2. Sliding frame member 4 is also provided, which slides itself 
throughout the upper-half range of the main pillar frame member 3. A pair 
of bracket members 5 are slidably and removably installed to the upper 
surface of the bottom frame member 2 and the bottom surface of the sliding 
frame member 4. In addition, another pair of bracket members 5' are 
removably installed to the bottom surface of the top frame member 1 and 
the bottom surface of the sliding frame member 4. 
Referring now to FIGS. 2 and 3, a preferred embodiment of the roll cargo 
transporting container related to the invention is described below. 
The bottom frame member 2 is provided with narrow-width projections 22 and 
23 on the lateral surfaces of square board 21 having the predetermined 
thickness. A pair of guide grooves 24 are provided in the position close 
to the center of square board 21. Bracket member 5 is provided in order 
that it can slidably be engaged with guide groove 24. In addition, each 
pair of wedge-engaging grooves 25 and 26 are provided at specific 
positions on the upper surfaces of projections 22 and 23. 
The top frame member 1 has flat shape identical to that of the bottom frame 
member 2. The top frame member 1 is provided with four cutout positions 11 
engaging with each piece of the main pillar frame members 3 engaging with 
four corners. In addition, the top frame member 1 is provided with 
toggle-thrusting portions (not shown) at specific positions of these 
cutout portions 11 for connection with respective main pillar frame 
members 3. The top frame member 1 is also provided with engaging hole 12 
at a specific position for allowing insertion of the projection of flange 
member 5' which is described later on. 
The main pillar frame member 3 is of hollow and square configuration, which 
is provided with a pair of vertical pillar members 31 and the upper and 
lower frames 32 and 33 which connect both edges of vertical pillar member 
31. Of these, only the upper frame 32 has narrow width. Inwardly 
projecting trapezoidal members 34 are installed to specific positions at 
the lower portion of the opposite vertical pillar members 31. 
Wedge-engaging groove 35 is provided at the bottom portion of the 
inwardly-projecting trapezoidal member 34. The reference numeral 36 
represents toggle-insertion hole and 37 fixing hole having such a shape 
identical to that is formed in the corner metal fittings of any 
conventional ISO standard container. Distance between the lower frame 33 
and the bottom surface of the inwardly-projecting trapezoidal member 34 is 
slightly wider than the thickness of projections 22 and 23. 
A pair of guide grooves 41 are provided at specific positions of flat board 
(having flat shape identical to that of the top frame member 1) of the 
sliding frame member 4 being opposite from guide grooves 24, and in 
addition four engaging holes 42 are provided against engaging holes 12. 
Bracket members 5 are provided with projections 53 which slidably engage 
with guide grooves 24 and 41 below lengthy rigid bodies 51 having 
arc-shaped surface (52) being engaged with external circumferential 
surface of roll cargo 7. Cargo operator can selectively mount lengthy 
rigid bodies 51 by choosing the one having a single arc-shaped surface 52 
or the one having two arc-shaped surfaces 52. Bracket member 5' has the 
constitution almost identical to that of bracket member 5. Bracket member 
5' has a pair of projections (not shown) engaging with holes 12 and 42 in 
place of projection 53 mentioned above. These are the only difference 
between bracket members 5 and 5'. 
To assemble the roll cargo transporting container featuring the 
constitution mentioned above, container operator first inserts projections 
22 and 23 between the lower frame 33 of the main pillar frame member 3 and 
the inwardly projecting trapezoidal member 34 for securing the bottom 
frame member 2. Next, operator inserts wedges 6 between projections 22 and 
23 and the inwardly projecting trapezoidal member 34 so that 
wedge-engaging grooves 25, 26, and 35 can respectively be engaged with 
wedges 6. As a result, the bottom frame member 2 and a pair of main pillar 
frame members 3 can integrally be combined with each other. Operator then 
engages a pair of bracket members 5 with guide grooves 24 of the bottom 
frame member 2, and then he can properly set positions of these bracket 
members 5 in accordance with external diameter of roll cargo 7 to be 
stored in the container. 
Consequently, operator can load roll cargo 7 on the bottom frame member 2 
in process of packaging operation at the production line of manufacturing 
factory by allowing roll cargo 7 to be supported by arc-shaped surfaces 52 
of the pair of bracket members 5. Next, operator lowers the position of 
sliding frame member 4 whose four corners remain being engaged with the 
main pillar frame member 3. This allows flange member 5 below sliding 
frame member 4 to be engaged with the upper surface of roll cargo 7 before 
surrounding the roll cargo with four arc-shaped surfaces 52. Operator then 
positions the top frame member 1 at the top of the main pillar frame 
member 3, and then, he thrusts toggles (not shown) into the top frame 
member 1 through toggle-inserting holes 36. This integrally combines the 
top frame member 1 with the main pillar frame members 3 and prevents the 
sliding frame member 4 from being disengaged. Refer now to FIG. 4-A. 
Operator can store roll cargo 7 having the largest diameter while sliding 
frame member 4 remains in contact with the top frame member 1. Conversely, 
operator can also store roll cargo 7 having relatively narrow diameter 
while the sliding frame member 4 is apart from the top frame member 1. If 
the condition shown in FIG. 4-B were present, it is desirable that sliding 
frame member 4 be prevented from freely sliding itself by inserting spacer 
(not shown) between sliding frame member 4 and the top frame member 1. 
While the condition shown in FIG. 4-B is present, lateral surface of roll 
cargo is surrounded by arc-shaped surfaces 52 of flange member 5 at four 
positions so that roll cargo can immovably be fixed in position. 
Consequently, the container embodied by the invention safely transports 
roll cargo without causing even the slightest deformation and/or damage to 
occur during sea or overland transportation. 
After completing sea or overland transportation of roll cargo stored in the 
container related to the invention, operator first draws out wedges 6 and 
toggles, and then he disengages the top frame member 1, bottom frame 
member 2, main pillar frame members 3, and the sliding frame member 4, 
from each other. Finally, each unit of container embodied by the invention 
is disassembled into a compact unit before eventually being transported to 
a certain destination. For example, if the length of the roll cargo 
transporting container related to the invention is one third the total 
length (20 ft for example) of any conventional ISO standard container, 
then, three units of the disassembled containers embodied by the invention 
can be stored in each ISO standard container, and likewise, six units of 
the disassembled container embodied by the invention can be stored in a 40 
ft-long conventional ISO container. 
If roll cargo 7 had significantly narrow diameter, operator mounts two 
pieces of bracket members 5 each having an arc-shaped surface 52 and 
another bracket member 5 having two arc-shaped surfaces 52 to the bottom 
frame member 2 by engaging them with guide grooves 24, and then, operator 
mounts two pieces of roll cargo 7 in order that these can be supported by 
arc-shaped surfaces 52 facing each other. Operator then lowers the 
position of sliding frame member 4 engaged with bracket member 5' on the 
bottom surface by allowing bracket member 5' to face bracket 5 having an 
arc-shaped surface 52, and then, operator sandwiches two pieces of roll 
cargo 7 between these brackets. 
Next, as was done for the bottom frame member 2, operator then mounts three 
pieces of bracket members 5 onto upper surface of sliding frame member 4. 
Operator then mounts two pieces of roll cargo 7 onto bracket members 5, 
and then, he sets the top frame member 1 between main pillar frame members 
3 while the top frame member 1 is engaged with two pieces of bracket 
members 5' on the bottom surface. Operator then thrusts toggles to allow 
additional two pieces of roll cargo 7 to firmly be sandwiched in position. 
By implementing those sequential processes mentioned above, as shown in 
FIG. 4-C, the container related to the invention can securely store four 
pieces of roll cargo 7 without causing them to come into contact with each 
other and move out of the fixed position. The container related to the 
invention stably holds roll cargo 7 in the predetermined position even 
when being subjected to external force generated by rolling and pitching 
of the freight vessel or by startup and stop of the movement of trucks on 
the way of transportation, thus securely preventing roll cargo from 
incurring unexpected deformation and/or damage. 
FIGS. 5 and 6 respectively show another preferred embodiment of the 
container related to the invention. Differences from those preferred 
embodiments cited above are described below. 
Using hinge member 37, the main pillar frame members 3 are erected in the 
manner they can fall flat on the bottom frame member 2 as required. 
Auxiliary pillar members 3' replacing the main pillar frame members 3 are 
installed via hinge members 38 for erection. More particularly, one of the 
main pillar frame members 3 is set to a specific height position flush 
with the upper surface of the bottom frame member 2 so that it can fall 
flat as required. Auxiliary pillar member 3' in conjunction with the 
former main pillar frame member 3 is set to a specific position higher 
than the other auxiliary pillar member 3' in conjunction with the latter 
main pillar frame member 3. 
Accordingly, like the above preferred embodiment, the container related to 
this preferred embodiment stably holds roll cargo 7 in position by falling 
down auxiliary pillar member 3' using hinge member 38 followed by erection 
of the main pillar frame member 3 by means of hinge member 37. No special 
member is provided for holding the erected main pillar frame member 3, 
however, since the presence of the sliding frame member 4 prevents hinge 
member 37 from moving itself in the folding direction, assembled condition 
of the container is securely maintained. 
When the container related to this preferred embodiment is free from 
transportation of roll cargo 7, operator first falls down the main pillar 
frame member 3 set to a specific height position flush with the upper 
surface of the bottom frame member 2, and then, he falls down the other 
main pillar frame member 3. This allows the operator to stack up both of 
the flatly-laid main pillar frame members 3 for storage on the upper 
surface of the bottom frame member 2. Next, operator erects auxiliary 
pillar members 3' in place of those main pillar frame members 3, and then, 
operator can lower the total height of the container by allowing corners 
of sliding frame member 4 and the top frame member 1 to remain in the 
engagement with respective auxiliary pillar members 3'. Although no 
special member is provided for holding the erected auxiliary pillar 
members 3', since the top frame member 1 and sliding frame member 4 
jointly prevent hinge member 38 from moving itself in the folding 
direction, folding condition of the container can securely be maintained. 
When either the main pillar frame member 3 or the auxiliary pillar member 
3' is erected, it is desirable that fixing members like bolts or locking 
members (not shown) capable of rotating and moving forward and backward 
against the bottom frame member 2 be used for integrally connecting either 
the main pillar frame member 3 or the auxiliary pillar member 3' to the 
bottom frame member 2 in order that the integrated container body can 
sufficiently be durable to unexpected load generated by external force on 
the way of transportation. 
If the length of the roll cargo transporting container embodied by the 
invention were one third the total length (20 ft) of any conventional ISO 
standard container, as shown in FIG. 8, cargo operator can store a 
plurality of 20 ft-containers B or 40 ft-containers C of ISO standard on 
the double-bottom deck of the hold of a full-container freight vessel 
above the roll cargo transporting containers A stored by an array on the 
bottom by removably installing container-fixing sockets (not shown) in the 
interim space reserved for storing 20 ft and/or 40 ft ISO standard 
containers. In this case, the freight vessel can store three units of the 
roll cargo transporting container A in the space capable of storing a 20 
ft ISO container B, or the freight vessel can store six units of the roll 
cargo transporting container A in the space capable of storing a 40 ft ISO 
container C. Like the full-container freight vessel, any conventional 
freight vessel equipped with loaded-container retentive mechanism can 
jointly load the roll cargo transporting containers related to the 
invention together with conventional ISO standard containers. Conversely, 
as shown in FIG. 9, any conventional freight vessel without 
loaded-container retentive facilities can also execute slide-loading of 
roll cargo transporting containers related to the invention by employing 
cranes and forklifts in the longitudinal or latutudinal direction inside 
of the hold by stacking up containers in double layers and also the 
following storage operation by installing sliding beams 62 and 63 onto the 
double-bottom deck 61 inside of the hold. Note that the sliding beam 62 is 
used for handling conventional ISO standard containers, whereas sliding 
beam 63 is used for handling roll cargo transporting containers. Cargo 
operator can also load ISO standard containers on the upper layer as 
required. Stacking beam 64 shown in FIG. 9 prevents weight of containers 
on the upper layer from adversely affecting those containers in the lower 
layers and also prevents stacked containers from collapsing themselves and 
incurring damage from rolling and pitching of the freight vessel on the 
way of sea transportation. Sliding wire 65 transmits transferring force to 
containers which are supported by sliding beams. Those sliding beams and 
stacking beams cited above are well known, which are respectively cited in 
the Japanese Patent Nos. 1,560,716, 1,486,340, and 1,560,716. 
When transporting roll cargo containers related to the invention overland, 
cargo operator can jointly stack them together with conventional ISO 
standard containers by removably installing positioning members inside of 
the existing container-fixing space of a freight car or a truck. In 
particular, when transporting these by means of a trailer or a truck, 
cargo operator can easily execute binding operation merely by binding roll 
cargo transporting containers related to the invention. 
FIG. 10 is the perspective view of another preferred embodiment of the roll 
cargo transporting container related to the invention. FIG. 11 is the 
exploded perspective view of the container shown in FIG. 10. Only the 
constituents of the top frame member 1, bottom frame member 2, main pillar 
frame member 3, sliding frame member 4, and bracket members 5 and 5' make 
differences from those of the preferred embodiment shown in FIG. 1. 
The top frame member 1 is composed of the center-open frame member and 
corrugated member mounted onto the center, thus achieving light-weight 
construction and retention of sufficient strength as well. Provision of 
four guide grooves 24 and deletion of wedge-engaging grooves 25 and 26 
make differences from the constitution of the bottom frame member 2 shown 
in FIG. 1. 
The main pillar frame member 3 shown in FIG. 10 differs from the one shown 
in FIG. 1 in the following points. Vertical pillar member is split into 
two parts, i.e., provision of base pillar member 31a which is set to the 
low position and vertical pillar member 31b which is set to the upper 
position; provision of connection member 8 for integrally erecting 
vertical pillar member 31b on base pillar member 31a; provision of 
lay-down guide mechanism 8' which facilitates inclining of vertical pillar 
member 31b towards base pillar member 31a; and provision of projection 38 
which can be thrusted into the specific position of the upper half of 
vertical pillar member 31b. 
As shown in FIGS. 12 through 14, connection member 8 is composed of the 
following; casing 81, rotary member 82 which is rotatably stored in casing 
81, locking member 83 which rotates itself following the rotation of 
rotary member 82 or enters into or goes out of rotary member 82, and 
driving wires 84 and 84' which rotate rotary member 82. 
Rotary member 82 is composed of disc 82a having grooves 82b and 82b' for 
winding wires 84 and 84' onto circumferential surface of disc 82a, and 
screw shaft 82c which projects itself from the center of disc 82c. A hole 
(not shown) formed in the bottom surface and at a position close to 
circumferential edge of disc 82a stores click-stop ball 82f which is 
constantly energized in the upward direction by spring 82e. 
Position of rotary member 82 is correctly controlled by allowing the 
click-stop ball 82f to be engaged with concave 81d formed at a specific 
position of space 81c of the casing 81. Wires 84 and 84' are wound to 
rotate rotary member 82 in the direction opposite from each other. 
Locking member 83 is composed of the following; screw cylinder 83a spirally 
matching screw shaft 82c, engaging 83b engaging with corner metal fitting 
31c of vertical pillar member 31b (this corner metal fitting is compatible 
with ISO standard), and spring 83c stored in screw cylinder 83a in the 
compressed condition. Engaging member 83b is provided with rectangular 
(extending in one direction) and flat configuration, while the upper 
surface having isosceles triangular shape projects itself upward. Range of 
the rotation of locking member 83 is controlled by causing engaging 
projection 83f outside of the casing 81 to be engaged with engaging member 
83b. 
Locking member 83 is rotated by spring 83c in a specific range (about a 
maximum of 90.degree.) ruled by engaging projection 83f in the follow-up 
movement against the rotation of rotary member 82. Locking member 83 moves 
forward and backward in accordance with relative rotation of screw shaft 
82c and screw cylinder 83a. Concretely, when the rotary member 82 rotates 
in one direction while engaging member 83b remains engaged with projection 
83f, locking member 83 is moved in the direction close to casing 81 
resisting force energized by spring 83c. When the locking member 83 
rotates in the inverse direction, force energized by spring 83c moves the 
locking member 83 in the direction apart from casing 81. Consequently, 
range of the rotation of engaging member 83b is restricted by projection 
83f, thus allowing cargo operator to easily connect and disconnect 
engaging member 83b to and from the cover metal fitting 31c. 
As shown in FIG. 15-A, the lay-down guide mechanism 8' is composed of the 
following; guide member 85 which is integrally set to the inner side of 
base pillar member 31a, flange member 86 integrally set to the bottom of 
vertical pillar member 31b, auxiliary guide member 87 which is set to the 
upper edge of guide member 85 so that it can horizontally rotate itself, 
and shaft 88 which projects itself from a specific position below the 
flange member 86. 
Shaft 88 is engaged with guide groove 85a of guide member 85 so that it can 
perform sliding operation. When shaft 88 moves itself to the uppermost 
position along guide groove 85a, auxiliary guide member 87 is moved to the 
position of guide member 85. This allows shaft 88 to be held by arc-shaped 
concave 87a of the auxiliary guide 87 so that shaft can be held in the 
condition without making downward movement. 
Consequently, when the base pillar member 31a is disengaged from the 
vertical pillar member 31b by removing connection member 8, the vertical 
pillar member 31b inclines and falls flat pivoting shaft 88. As shown in 
FIG. 15-B, when rotating auxiliary guide member 87 by slightly raising 
shaft 88 while laying the vertical pillar member 31b flat, shaft 88 
descends itself by effect of own weight so that the vertical frame member 
31b can flatly be laid on the bottom frame member 2. Operator can erect 
vertical pillar member 31b by reversing those processes mentioned above. 
Sliding frame member 4 used for this preferred embodiment is provided with 
four guide grooves 41 and engaging mechanism 89 which prevents sliding 
frame member 4 from moving upward, thus making difference from that is 
used for the preferred embodiment shown in FIG. 1. 
FIG. 16 is the exploded perspective view of the engaging mechanism 89 
mounted on sliding frame member 4 for preventing it from moving upward. 
Engaging mechanism 89 is composed of engaging member 89b which is spirally 
engaged with rotatable screw shaft 89a and slidably controlled, and 
rotation supporting base 89d which supports screw shaft 89a so that it can 
incline and fall flat itself as required. 
Engaging member 89b is made of flat plate having a specific shape, whose 
tip end has nail portion 89c which vertically extends upward. Projection 
38 formed at a specific position of vertical pillar member 31b has concave 
38f storing nail portion 89c at a specific position of the bottom surface. 
Consequently, cargo operator can set position for allowing upward movement 
of sliding frame member 4 by causing engaging member 89b to ascend itself 
by rotating screw shaft 89a for allowing insertion of engaging member 89b 
into concave 38f of projection 38 set to the vertical pillar member 31b. 
As a result, roll cargo 7 can securely be held between sliding frame 
member 4 and flange member 5 by first lowering position of sliding frame 
member 4 to a level flush with the upper surface of roll cargo 7 and then 
turning screw shaft 89a. This securely prevents sliding frame member 4 
from rising by applying projection 38 and engaging member 89b so that roll 
cargo 7 can be held in the initially wound condition. 
Foldable constitution makes difference between bracket members 5 and 5'. 
Bracket member 5 is composed of a plurality of pairs of projections 53 
slidably engaged with guide grooves 24 and 41, which is installed to a 
specific position below lengthy rigid body 51 having inclined surface 52 
engaged with external surface of roll cargo 7. Cargo operator can 
selectively mount bracket member 5 having an inclined surface or two 
inclined surfaces as required. 
Referring now to FIGS. 17 through 20, detailed description is given below. 
The lengthy rigid body 51 is composed of bottom plate 51a having 
projection 53 at a specific position of bottom surface, vertical plate 51b 
which is rotatably connected to a side of bottom plate 51a, and inclined 
plate 51c which is rotatably connected to a side opposite from the side of 
bottom plate 51a just mentioned. 
Bottom plate 51a has projections 53 at specific positions of bottom 
surface, where projections 53 extend themselves in the opposite direction 
in correspondence with guide grooves 24. Aperture 55 penetrating wedge 56 
is provided at the tip portion of two pairs of projections on both ends of 
the bottom plate 51a. 
Vertical plate 51b and inclined plate 51c are rotatably connected to each 
other by means of hinge members 51e set to both sides of the bottom plate 
51a. 
The projection 53 has aperture 55 at the position opposite from the 
positioning hole 28 formed at the predetermined positions of two pairs of 
flanges 27 set in parallel with guide groove 24. The projection 53 can be 
secured to the bottom frame member 2 by penetrating wedge 56 through 
positioning hole 28 and aperture 55. Bone-frame plate 51g is installed to 
the predetermined position of the lateral surface of vertical plate 51b 
being opposite from the inclined plate 51c so that the bone-frame plate 
51g can rotate itself in the horizontal direction. The bottom end of 
bone-frame plate 51g remains in contact with bottom plate 51a. The top end 
of bone-frame plate 51g remains in contact with inclined plate 51c. 
Stopper 51d prevents bone-frame plate 51g from rotating itself. 
After completing assembly, the upper surface of the inclined plate 51c is 
coated with rubber. 
Rivet 51h is removably installed to the position at which the vertical 
plate 51h is in contact with the inclined plate 51c. 
Consequently, after completing assembly, lengthy rid body 51 having 
right-angled triangular shape is generated. Operator can sequentially fold 
the bone-frame plate 51g after removing rivet 51h, vertical plate 51b, and 
the inclined plate 51c so that the entire unit can be folded into a 
flate-plate structure as shown in FIG. 20 by means of two-dot chained 
line. 
The above description has referred to bracket member 5 having a single 
inclined surface 52. Bracket member 5 having two inclined surfaces 52 can 
be made by rotatably installing the inclined plate 51c in place of 
vertical plate 51b. Constitution of other portions may be identical to 
that of the single inclined surface bracket member. In addition, as shown 
in FIG. 22, even when using such a bracket member 5 without having 
vertical plate 51b, if stopper 51d could securely prevent the rotation of 
the bone-frame plate 51g, bracket member 5 can securely support roll cargo 
7. Note that bracket member 5' has the constitution almost identical to 
that of bracket member 5 except for the provision of projections (not 
shown) engaging with holes 12 and 42 instead of projection 53. 
Consequently, when employing this preferred embodiment, like the one shown 
in FIG. 1, the roll cargo transporting container related to the invention 
stably stores roll cargo having a wide variety of dimensions. In 
particular, this preferred embodiment allows engaging mechanism 89 to 
securely prevent sliding frame member 4 from moving upward, thus 
significantly promoting stability in holding roll cargo in position. 
FIGS. 23 and 24 respectively present a still further preferred embodiment 
of the roll cargo transporting container related to the invention. When 
inclining and falling vertical pillar member 31b flat, auxiliary pillar 
member 39 is connected to it via hinge member 39aso that hinge member 39 
can be erected in place of vertical pillar member 31b. 
As a result, after falling vertical pillar member 31b flat, all the 
constituent members can be folded into a low-height integrated unit (see 
FIG. 25) by first erecting auxiliary pillar members 39 on the base pillar 
members 31a and then storing sliding frame member 4 and the top frame 
member 1 under guidance of auxiliary pillar members 39. 
FIG. 26 is the partially exploded perspective view of a still further 
preferred embodiment of the roll cargo transporting container related to 
the invention. Base pillar members 31a are integrally connected to the 
bottom frame member 2. Space between four main pillar frame members 3 is 
covered with tarpaulin sheets for example. Forked pockets 102 are provided 
below the bottom surface of the bottom frame member 2 in the direction 
crossing each other at right angle. These make up differences from the 
above-cited preferred embodiments. 
More particularly, covers 101 are provided with a specific dimension enough 
to cover space formed by the edges of the top frame member 1, bottom frame 
member 2, and the main pillar frame member 3. Edges of cover 101 are 
secured with U-shaped bolts 103 which allow insertion of nuts 104 into 
both ends. 
FIG. 27 is the vertical sectional view representing the condition in which 
cover 101 is secured to the top frame member 1 with U-shaped bolts 103. 
Apertures are provided at specific positions of the top frame member 1 for 
allowing insertion of U-shaped bolts 103. Plate 105 is installed to a 
specific position below the bottom surface of the top frame member 1 for 
ruling the positions of nuts 104. Metal fittings (not shown) are provided 
at specific positions of the edges of cover 101 for allowing insertion of 
U-shaped bolts 103. In addition, the bottom plate 51a is also provided 
with wire 106 which penetrates space formed by U-shaped bolts 103 and 
cover 101, while the bottom plate 51a is also provided with water-proof 
member 107 at a position close to the U-shaped-bolt-secured position. 
Cover-fixing member is installed to a specific position of the bottom 
frame member 2 so that it can be prevented from overlapping another 
cover-fixing member installed to the vertical pillar member 31b while this 
member 31b still remains folded. 
As a result, when employing this preferred embodiment, the roll cargo 
transporting container securely protects roll cargo from adversely being 
affected by wind and rain and also from incurring sweat damage, thus 
allowing all of roll cargo to be safely transported to destinations 
without degrading original quality at all. In addition, the roll cargo 
transporting container related to the invention allows operators to easily 
stack up containers during outdoor operations at the origin of shipment 
and also at the destination as well. 
It should be understood that the scope of the roll cargo transporting 
container related to the invention is by no means confined to those 
preferred embodiments cited above, but the invention also offers 
possibility for removably connecting the top frame member 1, bottom frame 
member 2, and the main pillar frame members 3 to each other by means of 
bolts, another possibility for removably connecting the bottom frame 
member 2, sliding frame member 4, and bracket member 41 to each other by 
means of bolts, and another possibility for integrally combining base 
pillar member 31a with the bottom frame member 2 for example. 
FIG. 28 is the schematic perspective view of a preferred embodiment of the 
apparatus for preventing roll cargo from incurring divergence of the core 
of roll during transportation. FIG. 29 is the lateral view sectioned in 
the center. The apparatus has a pair of lengthy rigid bodies 91 and 92 and 
also a pair of leading chains. More particularly, lengthy rigid body 91 is 
substantially the grooved body composed of lengthy and flat plate having 
both lengthy sides being folded in right angle. The lengthy rigid body 91 
has a flat plate member connecting the center portion of the grooved body 
in the longitudinal direction. Except for the center portion, rubber mat 
layers 91a and 91b are bonded to the surface of lengthy rigid body 91 
coming into contact with roll cargo. Eye ring 91c is set to a specific 
position close to rubber mat layer 91 for connecting an end of leading 
chain 93. Through-hole 91d is formed at a specific position close to the 
other rubber mat layer 91b for allowing penetration of leading chain 94. 
Chain sieve 91e is set to the center of the lengthy rigid body 91. 
Cargo-fixing metal fitting 91f is also provided. In addition, chain 
stopper 91g incorporating clamping mechanism is provided at a position 
close to the member which draws out leading chain. Eye ring 91h is set to 
a specific position close to the edge of the upper surface of lengthy 
rigid body 91. 
As shown in FIGS. 30A and B, cargo-fixing metal fitting 91f is integrally 
provided with groove 95a, cutout portion 95b allowing leading chain 94 to 
enter into and go out of groove 95a, stopper 95c freely moving itself in 
the direction close to groove 95a, and stopper groove 95d which is 
provided at the tip of the stopper 95c for inhibiting return movement of 
leading chain 94. In addition, the cargo-fixing metal fitting 91f is also 
provided with screw 95e which allows the entire unit to move forward and 
backward while correctly maintaining the position relationship between 
each constituent mentioned above (see FIG. 28). When leading chain 94 
moves in the direction shown by arrow A of FIG. 30-A, stopper 95c freely 
moves itself (see two-dot chained line of FIG. 30-A) to allow leading 
chain 94 to smoothly move itself. When leading chain 94 is pulled in the 
inverse direction, movement of stopper 95c is inhibited (see solid line 
shown in FIG. 30-A), and as a result, movement of leading chain 94 is 
inhibited by stopper groove 95d. 
Lengthy rigid body 92 has the constitution exactly identical to that of 
lengthy rigid body 91, and thus, description of which is deleted. 
When installing the apparatus in subject to roll cargo 7, first cargo 
operator inserts leading chains 93 and 94 into center hole 7a of roll 
cargo 7 in the direction opposite from each other, and then, he inserts 
the free ends of leading chains 93 and 94 extending from center hole 7a 
into through-holes 92d and 91d, and finally, he draws out these free ends 
through chain sieves 92e and 91e fixed metal fittings 92f and 91f, and 
finally clamp-freed chain stoppers 92g and 91g, respectively. 
Direction of inserting leading chains 93 and 94 into fixed metal fittings 
92f and 91f is arranged in order that free ends can be set to the movable 
side. 
Lengthy rigid bodies 91 and 92 are drawn in the direction approaching each 
other by allowing operator to pull leading chains 93 and 94 drawn outside, 
and as a result, rubber mat layers 91a, 91b, 92a, and 92b, are 
respectively pressed against both-end surfaces of roll cargo 7. Operator 
then causes chain stoppers 91g and 92g to generate clamping force to fix 
leading chains 93 and 94 in the drawn-out condition. Then, operator moves 
fixed metal fittings 92f and 91f by rotating screw 95e of the fixed metal 
fittings 92f and 91f (see solid line in FIG. 29) so that the fixed leading 
chains 93 and 94 can enter into fully tensive condition. 
When this condition is present, lengthy rigid bodies 91 and 92 apply 
pressure to the sandwiched roll cargo 7 from inner circumferential layer 
covering specific range. Consequently, both the lengthy rigid bodies and 
roll cargo 7 are integrally unified, while the external surface of the 
unified body is subjected to retentive force. This in turn prevents inner 
layers of roll cargo 7 from sequentially projecting themselves in one 
direction when external force is applied to roll cargo in the axial 
direction, thus allowing the edge surface of roll cargo 7 to constantly 
remain in the perfect vertical alignment without collapse. Furthermore, 
since chains or wire ropes 91j and 92j securely connect intervals between 
eye rings 91h and 92h and adjacent structures, accidental projection and 
displacement of the inner layers of roll cargo 7 in one direction can be 
prevented more securely. 
As is clear from the above description, roll cargo 7 is securely sandwiched 
by lengthy rigid bodies 91 and 92 by insertion of leading chains 93 and 94 
through center hole 7a of roll cargo 7, and thus, the above mechanism can 
easily be applied to roll cargo having narrow center hole 7a. 
It should be understood that the constitution of fixed metal fittings 91f 
and 92f is not confined to the one shown in FIG. 30, but the invention 
also allows use of another constitution capable of selectively determining 
tensive and tension-free condition of leading chains 93 and 94 by 
activating seesaw-like swinging movement or by moving simplified 
lead-chain guide member forward and backward. 
FIG. 31 is the lateral sectional view of another preferred embodiment of 
the apparatus in subject related to the invention. Lengthy tubular rigid 
bodies 91 and 92 are introduced, whose specific portions close to the 
center are connected to each other by means of steel belet 71 which is 
endlessly connected to fixed metal fitting 72. This makes difference from 
that is shown in FIG. 28. 
The apparatus related to this embodiment can easily be applied to any kind 
of roll cargo 7 having sizable inner diameters. Like the above preferred 
embodiment, quite satisfactory effect in the prevention of roll cargo from 
incurring projection and displacement of the inner layers can be achieved 
by employing simple constitution of the mechanism. 
FIG. 32 is the schematic perspective view of a still further preferred 
embodiment of the apparatus in subject related to the invention. To make 
difference from those embodiments cited above, crossed constitution of 
lengthy rigid bodies 91 and 92 is introduced. 
When this preferred embodiment is used, crossed constitution of lengthy 
rigid bodies 91 and 92 provides an increased area available for firmly 
sandwiching roll cargo 7, thus promoting the effect of pressed sandwiching 
operation and providing improved effect for securely preventing roll cargo 
from incurring projection and displacement of the inner layers of roll 
cargo 7 on the way of sea/overland transportations. 
FIG. 33 is the schematic perspective view of a still further preferred 
embodiment of the apparatus in subject related to the invention. To make 
the difference from the above preferred embodiments, two pairs of lengthy 
rigid bodies are provided in parallel with each other. 
Like the above preferred embodiment shown in FIG. 32, two pairs of lengthy 
rigid bodies 91 and 92 provide an increased area available for firmly 
sandwiching roll cargo 7, thus promoting the effect of pressed sandwiching 
operation and providing improved effect for securely preventing roll cargo 
from incurring projection and displacement of the inner layers of roll 
cargo on the way of sea/overland transportations. When implementing this 
preferred embodiment, by providing each lengthy rigid body with a specific 
length identical to that of those lengthy rigid bodies used for the above 
preferred embodiments, roll cargo 7 is subjected to overall sandwiching 
pressure which is applicable to the portion adjacent to external 
circumference. This significantly improves the effect of securely 
preventing roll cargo from incurring projection and displacement of the 
inner layers of roll cargo on the way of sea and overland transportations. 
It should be understood that the invention does not confine the 
constitution of the apparatus for preventing roll cargo from incurring 
divergence of roll core only to those constituent components described 
above, but the invention also allows use of projected parallel pattern or 
disc pattern for constituting lengthy rigid bodies 91 and 92, and in 
addition, these lengthy rigid bodies may be folded as required. It is also 
possible for the invention to use only a piece of leading chain for 
generating pressed sandwiching force against roll cargo by first covering 
one of lengthy rigid bodies with the leading chain and then penetrating 
the other lengthy rigid body. It is also possible for the invention to use 
bar members for connecting those lengthy rigid bodies and allow 
interposition of twist locking and/or turn-buckle mechanism as required.