阅读说明：本技术 用于连接在船的甲板上叠置在彼此之上的两个集装箱的联接件 (Coupling for connecting two containers stacked on top of each other on the deck of a ship ) 是由 克里斯提·佰德科 沃尔夫冈·蒂勒 于 2019-11-13 设计创作，主要内容包括：一种用于连接在船的甲板上叠置在彼此之上的两个集装箱的联接件(10),具有：第一联接突出部(11),其可插入到位于上方的集装箱的下包角件(12)中并可在那里预锁定；第二联接突出部(13),其在联接状态中接合到位于下方的集装箱的上包角件中；第一联接突出部的支承面(20),其在联接状态中搁置在位于上方的集装箱的下包角件的内边缘上；以及第一联接突出部的间隔件,使得联接件只能沿特定的定向插入到位于上方的集装箱的下包角件中。为了减小所谓的“打开效应”并且因此提高拉出力,联接件特征在于,间隔件具有与第一联接突出部的支承面对准的支承面,并且在联接状态中其同样搁置在位于上方的集装箱的下包角件处的内边缘上。(Coupling (10) for connecting two containers stacked on top of each other on the deck of a ship, having: a first coupling projection (11) which can be inserted into a lower corner fitting (12) of a container located above and can be pre-locked there; a second coupling projection (13) which, in the coupled state, engages into an upper corner fitting of a container located below; a bearing surface (20) of the first coupling projection which, in the coupled state, rests on an inner edge of a lower corner fitting of the container located above; and a spacer of the first coupling projection, such that the coupling member can only be inserted into the lower corner fitting of an overlying container in a particular orientation. In order to reduce the so-called "opening effect" and thus to increase the pull-out force, the coupling is characterized in that the spacer has a bearing face which is aligned with the bearing face of the first coupling projection and which in the coupled state likewise rests on the inner edge at the lower corner fitting of the container located above.)

1. Coupling (10) for connecting two containers stacked on top of each other on the deck of a ship, having:

a first coupling projection (11) which can be inserted into a lower corner fitting (12) of a container located above and can be pre-locked therein;

a second coupling projection (13) which, in the coupled state, engages into a corner fitting of an underlying container;

a bearing surface (20) of the first coupling projection (11) which, in the coupled state, rests on an inner edge at the lower corner fitting (10) of the container located above; and

-spacers (27) of the first coupling projections (11) such that the coupling (10) can only be inserted in a specific orientation into the lower corner pieces (12) of the container located above;

characterized in that the spacer (27) has a bearing surface (28) which is aligned with the bearing surface (20) of the first coupling projection (11) and which in the coupled state also rests on the inner edge at the lower corner fitting (12) of the container located above.

2. The coupling according to claim 1, wherein the outer side (29) and the inner side (30) extend wedge-shaped onto each other.

3. The coupling according to claim 2, wherein the outer side (29) extends at a first angle (Y), in particular 0 ° to 30 °, preferably 10 °, to a longitudinal axis (24) of the upper coupling lug (11), and the inner side (30) extends at a second angle (Z), in particular 0 ° to 30 °, preferably 10 °, to the longitudinal axis of the upper coupling lug, the first and second angles being identical to or different from each other.

4. The coupling as claimed in any of claims 1 to 3, wherein the locking head (18) of the upper coupling projection (11) projects laterally by an amount (F) which is greater than or equal to half the length (E) of the long hole (16) in the corner fitting (12) at its longest position (F ≧ E/2).

5. The coupling according to any of the claims 1 to 4, wherein the width (B) of the bearing surface (20) is equal to or slightly smaller than the width (B1) of the edge of the plate (17) of the corner piece (12).

6. A coupling according to any of claims 1 to 5, wherein a stop plate (14) is connected to which the rod (15) of the first coupling protrusion is connected, wherein the length (D) of the rod (15), measured from the upper side of the stop plate (14) to the bearing surface (20), is adapted to the thickness (C) of the lower plate (17).

7. The coupling according to claim 6, wherein said length (D) of said rod (15) is equal to the thickness (C) of said plate (17).

Technical Field

The invention relates to a coupling for connecting two containers stacked on top of each other on the deck of a ship, the coupling having: a first coupling projection which is insertable into and prelockable in a lower corner fitting of an overhead container; a second coupling projection which, in the coupled state, engages into the upper corner fitting of the container located below; a bearing surface of the first coupling projection which, in the coupled state, rests on an inner edge of a lower corner fitting of the container located above; and a spacer of the first coupling protrusion, so that the coupling member can be inserted into only the lower corner fitting of the container located above in a specific direction.

Background

Such a coupling is known from EP 1784348B 1 of the applicant.

Such couplings are used for interconnecting containers transported as stacks of containers at the deck of the ship (on the deck lids). In this case, the lowermost container and sometimes also the higher containers are additionally secured by lashing bars by means of lashing bridges. However, the coupling members are often the only fasteners that the containers of the higher floors avoid losing during shipping.

At the loading of the container, the coupling piece is first inserted with its first (upper) coupling projection into the four lower corner fittings of the container to be loaded by the handler on the quay and is pre-locked there. The containers are now lifted by a crane (container bridge) to the deck of the ship and are lowered there onto the loaded containers. Here, the second (lower) coupling projection penetrates into the four upper corner fittings of the loaded container. In the now stacked state of the containers, the second coupling lug engages into the upper corner fitting of the already loaded container, which is now located below, and in this way secures the newly loaded container, which is now located above, against loss during sea transport. This state is referred to as a coupled state within the scope of the present disclosure.

EP 1784348B 1 mentioned at the outset relates to a so-called fully automatic twist lock (FAT). In particular with this type of coupling, it is important that the coupling is always inserted in a specific direction by the handler into the corner fitting of the container located above and is pre-locked, since otherwise it may result in the containers no longer separating from each other when removed (unloaded). For this purpose, EP 1784348B 1 proposes a spacer which prevents the coupling from being inserted in the wrong direction and from being pre-locked.

In the coupled state, the coupling piece surrounds the edges of the corner piece in a C-shape. A pulling force acts on the coupling due to a lifting force acting on the container, which lifting force is caused by sea conditions, which tensile force causes the coupling to bend elastically (upwards). Furthermore, the corner wrap of the container is also elastically deformed. The sum of these two elastic deformations can, in the case of particularly high forces, lead to the coupling becoming disengaged from engagement with the corner fitting (so-called opening effect, Aufmacheffekt) and, in the worst case, to the container being lost or even to the sea crew being injured. In the so-called category, therefore, the maximum permissible tensile force (in professional rings referred to as "Pull-Out-focus") is defined for a particular coupling.

Disclosure of Invention

Starting from this, the invention is based on the problem of improving a coupling of the aforementioned type in order to reduce the opening effect and thus to increase the pull-out force.

In order to solve this problem, the coupling according to the invention is characterized in that the spacer has a bearing surface which is aligned with the bearing surface of the first coupling projection and in the coupled state also rests on the inner edge at the lower corner fitting of the container located above.

Therefore, the bearing surface of the first coupling projection enlarges the bearing surface of the spacer. These two bearing surfaces form a common bearing surface of the first coupling projection on the inner edge of the corner fitting. The pressure on the edge of the lower corner fitting of the container located above is thereby reduced for the same tensile force. In addition, the pressure further influences the inner wall of the corner fitting, thereby reducing the lever arm. Therefore, the edge of the corner fitting is less deformed. In this way, the opening effect can be reduced and thus the pull-out force can be increased. This increases the safety margin of the coupling for a predetermined payload (workload). Conversely, with the same safety reserve, the payload can be increased. Furthermore, the vertical play of the coupling pieces in the container corners is also reduced due to the smaller deformations, which also has a positive effect. At the same time, it was surprisingly found in the prototype (template) that the prototype can still be inserted well into the corner fitting and can be pre-locked there.

The subject matter of the dependent claims is other constructive configurations of the coupling according to the invention which facilitate penetration of the upper coupling projection into the lower corner fitting of the container located above, or further improve the load-bearing properties.

Drawings

The invention will be explained below on the basis of embodiments shown in the drawings. Shown in the attached drawings:

figure 1 shows in side view a coupling piece with the features of the invention pre-locked in the lower corner fittings of a container located above,

figure 2 shows the corner fitting according to figure 1 in a front view,

figure 3 shows the corner fitting according to figure 1 in a top view,

figure 4 is a schematic view of the introduction of force into the coupling according to figure 1,

fig. 5 is a schematic illustration of the introduction of a force into the coupling according to fig. 1 under the action of a load.

Detailed Description

The figure shows a coupling 10, in particular a so-called full Automatic twist-lock-FAT, for connecting two containers stacked on top of each other at their corners on the deck of a ship.

The coupling piece 10 has a first upper coupling lug 11 which is still inserted by the handler on the quay into the lower corner fitting 12 of the container, not shown in detail, located above. For this purpose, the container is lifted by a crane. Then, the handler puts the upper coupling protrusion 11 of each coupling member 10 into each of the four corner fittings 12. The container is now lifted by the crane to the deck of the ship and lowered onto the already loaded container (container located below). In this case, the second lower coupling projection 13 penetrates into the upper corner fitting of the container located below and engages with it completely automatically in this case. When the container located above is lifted with the crane, the lower coupling projection 13 is again completely automatically disengaged from engagement with the upper corner fitting of the container located below when the container is removed. However, the coupling 10 reliably secures the container during sea transport, avoiding lifting and loss of the container. This is described in more detail, for example, in EP 1534612B 1, in the initially mentioned EP 1784348B 1 or in EP 2892828B 1. The last-mentioned EP 2892828B 1 shows a lower coupling projection, which corresponds to the lower coupling projection 13 of the present coupling 10.

In the present case, a stop plate 14 is provided between the upper and lower coupling projections 11, 13, which stop plate 14, instead of the shown form, may have the shape of only a ridge, which, when they are located directly on top of each other, engages in a groove formed by a chamfer at the elongated hole of the corner fitting 12. Proceeding from the stop plate 14, the upper coupling lug 11 has a lever 15, by means of which the upper coupling lug 11 engages through an elongated hole 16 at the corner fitting 12. The length D of the lever 15, measured from the upper side of the stop plate 14, is adapted to the thickness C of a lower plate 17, in which lower plate 17 an elongated hole 16 is arranged. Typically, the length D of the shank 15 is equal to or slightly longer than the thickness C of the plate 17 (FIG. 2). The length D should not be too large compared to the thickness C, since the vertical play of the coupling 10 is thereby also increased. Ideally, D ═ C, at least within typical manufacturing tolerances. In this case, the vertical play of the upper coupling projection 11 in the corner fitting 12 is equal to "zero" (D-C ═ 0).

Connected to the lever 15 is the (upper) side of the locking head 18 opposite the stop plate 14, which projects to one side, i.e. to the same side as the locking nose 19 at the lower coupling projection. The coupling element 10 thus surrounds the corner fitting with its locking head 18 and locking nose 19C-shaped when stacked in containers on top of one another (in the coupled state). In fig. 4 and 5, this is indicated by the shaded area. The lower bearing surface 20 at the locking head 18 rests at the plate 17. The locking head 18 projects with respect to the stem 15 by a width B adapted to the distance B1 from the longitudinal edge of the elongated hole 16 to the adjacent side wall 21 of the elongated hole 16. In other words, the width B is adjusted to the width B1 of the edge of the plate 17 surrounding the elongated hole 16, which edge is located below the support surface 20. Specifically, B ═ B1 or less. In general, B and B1 should be dimensioned such that the lateral play of the rod 15 relative to the elongated hole 16 corresponds approximately to the play between the locking head 18 and the side wall 21. Ideally, the two plays are the same.

Furthermore, in fig. 3, an imaginary circle 22 is drawn whose diameter E is centered on the center of the elongated hole 16 (the intersection of the two axes 23 and 24). The arcuate end surface 25 of the slot 16 also follows the contour of the circle 22, as is clearly visible in fig. 3. The diameter E thus corresponds to the maximum length of the elongated hole 16.

It can also be seen from fig. 3 that the locking head 18 projects from the axis 24 by an amount F which corresponds to half the diameter E. In this case, the transverse edges 26 of the locking head 18 form tangents to the imaginary circle 22. Alternatively, F may also be greater than half the diameter E. That is, it is effective that F.gtoreq.E/2.

The coupling 10 described so far also has a spacer 27 that prevents the coupling 10 from being installed upside down. This is described in detail in the initially mentioned EP 1784348B 1. However, the spacer 27 of the present invention differs from this prior art mainly in the following points:

the spacer 27 of the invention has on the one hand a bearing face 28 which is aligned with the bearing face 20 of the locking head 18, the bearing face 28 of the spacer 27 thus likewise rests on (abuts against) the plate 17 of the corner fitting 12, in other words the bearing faces 20 and 28 form a uniform bearing face for the locking head 18 on the plate 17, in other words the length a of the locking head 18 which is reduced by the spacer is extended to the total length L of the locking head, the total length L is greater than the length of the lateral straight edge of the oblong hole (here likewise a), and in the present case even greater than E.

As can be seen in fig. 3, in the embodiment shown, the spacer extends away from the actual locking head 18 and extends wedgingly towards its free end. In particular, the outer (side facing the side wall 21) side 29 of the spacer 27 is arranged at an angle Z to the side wall 21 (which extends parallel to the longitudinal axis 24 of the elongated hole 16). The inner (opposite sidewall 21) side 30 extends at an angle Y to the longitudinal axis 24 of the slot 16. As can be seen from the figures, the lateral side 29 and the medial side 30 extend wedge-shaped to each other (above). The angles Y and Z may be the same or different from each other. The angles Y and Z are in this case each between 0 ° and 30 °. Preferably, they are 10 °.

The upper side 31 of the spacer 27 descends in a ramp-like manner, i.e. at an angle W (fig. 1), away from the actual locking head 18 towards the free end. The angle W is then again between 0 ° and 30 °, 10 ° also being particularly preferred here.

Finally, the common upper side 32 of the locking head 18 and the spacer 27 descends outwardly (towards the side wall 21) in a ramp-like manner, i.e. at an angle X (fig. 2). The angle X is between 30 ° and 60 °, with 45 ° being particularly preferred.

The angles Y and Z also contribute to ease of penetration of the upper coupling projection 11 into the elongated hole 16. The angles W and Z are mainly used for weight reduction.

As can also be seen from fig. 1, the lever 15 has a lever shoulder 33 adjacent to the stop plate, which is furthermore longer in particular than the lever 15. The rod shoulder 33 has a contour, as seen in plan view, which corresponds to the contour of the elongated hole 16 and thus reduces the play of the coupling part 10 relative to the elongated hole 16, in particular when viewed in the longitudinal direction (axis 24) of the elongated hole 16, without this hindering the insertion of the upper coupling projection 11 into the corner fitting 12.

List of reference numerals:

10 coupling piece

11 coupling projection

12 cornerite parts

13 coupling projection

14 stop board

15 handle

16 long hole

17 plate

18 locking head

19 locking nose

20 bearing surface

21 side wall

22 round

23 axis of rotation

24 axis(s)

25 end face

26 edge of the glass

27 spacer

28 bearing surface

29 side surface

30 side surface

31 upper side

32 upper side

33 rod shoulder

Length of edge of slot a 16

Width B

Distance B1

C board thickness

Length of D rod

E diameter.