The invention concerns a protection system for tension members designed and intended to protect a tension member arranged between two sections of a structure, comprising two or more shell elements which can be arranged circumferentially around the tension member and which together surround a cavity intended to accommodate the tension member, and a joining means whereby the shell elements can be detachably connected to each other.
Such tension member protection systems are known in the prior art. They are generally used to protect the tension member from heat and/or fire and/or impact and/or mechanical damage and/or other events which may threaten its integrity, whether of natural or human origin.
A design consisting of two or more shell elements that can be arranged circumferentially around the tension member allows, on the one hand, the retrofitting of tension member protection systems on tension members of existing structures, such as cable-stayed bridges, and, on the other hand, the temporary removal of the tension member protection systems from the tension members, for example in order to carry out maintenance on the tension members.
From US 2011/0302856 A1, a tension member protection system of the same class is known, for the mounting of which on the tension member a plurality of brackets must first be attached, which are designed with hinges and with plates hingedly attached to the brackets. Shell elements protecting the tension member are then attached to these plates. A disadvantage of this design is that the circumferential sections in which the hinges are arranged are designed with reduced wall thickness to enable the shell elements to pivot, hence these form weak points of the aforementioned tension member protection system.
It is therefore the object of the invention to provide an improved tension member protection system.
This object is attained according to the invention by means of a tension member protection system of the type mentioned above, in which the joining means for joining at least two shell elements, which in the cavity-forming state lie with their two contact surfaces against each other, comprise a plurality of joining sleeves, each of which is assigned to one of the two shell elements, the joining sleeves being designed and arranged on the shell elements in such a way that, in the cavity-forming state, they interlock so that, viewed in the longitudinal direction of the tension member protection system, their through-holes only entirely overlap when the two shell elements lie with their contact surfaces against each other, and the joining means further comprise a rod-shaped element which is designed and intended to be passed through the through-holes of the interlocking joining sleeves.
Although the joining means according to the invention appear to be of hinge-like design due to the interaction of the joining sleeves and the rod-shaped element, they do not allow the two shell elements under consideration to swivel relative to each other. This is prevented by the fact that the rod-shaped element can only be passed through the through-holes of the interlocking joining sleeves when the two shell elements lie with their contact surfaces against each other. This design allows the tension member protection system to have the same radial extent in the circumferential section in which the joining means are arranged as in all other circumferential sections. The tension member protection system according to the invention therefore has no weak points.
In order to prevent moisture from penetrating into the joint between the two shell elements, it is proposed that a cover plate be provided which covers the joint between the two adjacent shell elements and is fastened to at least one of the two shell elements.
To conceal the circumferential position at which the joint is actually located, at least one further cover plate can also be provided which is fastened to the outer surface of one of the shell elements.
With the aim of achieving an effective joining of the two shell elements, it is proposed in a further development of the invention that the length of the rod-shaped element be essentially equal to the length of the tension member protection system. As a simple means of preventing the rod-shaped element from accidentally falling of its own accord out of the lower end of the tension member protection system in the assembled state, the tension member protection system can be provided with a base plate. It is furthermore advantageous, after the rod-shaped element has been inserted, to close the upper end of the tension member protection system in the assembled state with a cover plate to at least hinder, if not prevent access to the rod-shaped element.
If a plurality of tension member protection systems according to the invention are arranged in the longitudinal direction immediately adjacent to one another on a tension member, the rod-shaped element may also be of a length that is essentially equal to the length of the overall arrangement of tension member protection systems.
Effective interaction of the joining sleeves and the rod-shaped element can be achieved by the fact that the joining sleeves assigned to one shell element and the joining sleeves assigned to the other shell element interlock in alternating sequence. It is also advantageous if the joining sleeves assigned to the two shell elements are of the same length. Only the end joining sleeves in the longitudinal direction of the tension member can be of a different length.
To simplify production of the shell elements, it is proposed in a further development of the invention that the joining sleeves should have a rectangular, preferably square, cross-section. In this case, the joining sleeves can be provided as separate elements which can be fastened to the respective shell element or the housing of the respective shell element, for example by welding, soldering, gluing or another suitable fastening technique, after laying one of their rectangular or square sides against it.
The rod-shaped element may however have a circular cross-section. Such round rods can be obtained at reasonable cost.
Regardless of the cross-sectional shape of the joining sleeves and of the rod-shaped element, it is advantageous if the cross-section of the joining sleeves has internal dimensions which are larger than the external dimensions of the cross-section of the rod-shaped element. For example, it is advantageous if the diameter of a rod-shaped element with a circular cross-section is smaller than the side length of a square-shaped joining sleeve. This makes it possible to insert the rod-shaped element into the interlocking joining sleeves even if their passage openings do not overlap completely.
In order to protect the joining means effectively against external influences, it is proposed in a further development of the invention to arrange the joining sleeves in a radial section of the two shell elements adjoining the cavity, preferably directly adjacent to the cavity. This allows the actual protection system to extend radially outside the joining means, protecting not only the tension member but also the joining means.
In a further development of the invention, the joining sleeves can be arranged in the cavity. The connection means are preferably arranged with an intermediate web on an inner circumferential surface of the shell elements or can be arranged directly adjacent to the inner circumferential surface of the shell elements.
This arrangement protects the joining means even more effectively against external influences.
In a further embodiment of the invention, a coupling device can be arranged in the contact surfaces of at least two shell elements, which lie against each another in the cavity-forming state, which couples the contact surfaces of at least two shell elements with each other. This eliminates shear stresses between the contact surfaces.
In a further development of the invention, it is proposed that at least one shell element should have a housing, and preferably all shell elements should have a housing, whose interior accommodates the protection system. The housing can be made of sheet steel, for example.
The invention is explained in more detail below using the attached drawings and embodiment examples, as follows:
In
The tension member 110 consists of multiple strands 111 and can be used, for example, to transfer the loads of deck slabs of cable-stayed bridges to the pylon(s). However, any other function/structure is also conceivable for which or in which tension members can be used.
The tension member protection system 100 furthermore comprises two or more shell elements 120 which are arranged around the tension member 110 and thus form a circular cylinder with an internal cavity 130. The cavity 130 of the circular cylinder formed by the shell elements 120 serves to accommodate the tension member 110. To form this cavity 130, the contact surfaces 123 of the shell elements 120 lie against each other.
The shell elements 120 are made of a metallic material, but can also be made of any other material that meets the requirements of the invention.
As can be seen from
The shell elements 120 can be designed as solid elements or as hollow elements. In either case, each of the shell elements 120 has an outer surface or outer circumferential surface 121, an inner circumferential surface 122 and two contact surfaces 123.
Furthermore, the shell elements 120 have an indentation 124 on the contact surfaces 123 which extends along the entire shell element 120 and which, after the shell elements 120 have been joined to form a circular cylinder, serves to accommodate a rod-shaped element 140. The indentation 124 can in particular be square or rectangular, so as to accommodate a rod-shaped element 140 with square, rectangular or round cross-section. However, the indentation can also be round, to accommodate a rod-shaped element that is round or square or of any other shape that meets the requirements of the invention. If the indentation 124 is square, as is the case in
Each shell element 120 has an indentation 124 on each contact surface 123. There can however be more indentations 124 on each of the contact surfaces 123 or on one or more of a number of contact surfaces 123. The indentation can preferably be located on the side of the contact surface 123 which is adjacent to the inner circumferential surface of the shell element 120. However, the indentation 124 may be located in any other position on the contact surface 123.
Once the shell elements 120 are joined together and the contact surfaces 123 lie against each other, the indentations of two adjacent contact surfaces 123 create a cavity 125 of square or rectangular shape, if they are so designed, or of circular or cylindrical shape if they are of circular design, for example.
As previously mentioned, the cavities 125 formed by the indentations 124 serve to receive a rod-shaped element 140. Such an element is shown in an exploded view in
In addition, the tension member protection system 100 comprises a cover plate 150 which covers the joints 151 between the two abutting contact surfaces 123 of the shell elements 120 and is fastened to at least one of the two shell elements 120. To conceal the circumferential position at which the joints of the shell elements 120 are actually located, at least one further cover plate 150 can also be provided which is fastened to the outer circumferential surface 121 of one of the shell elements 120. The cover plates 150 can be fastened to the outer circumferential surface 121 of the shell element 120 by means of bolts. However, any other expedient fastening means may be chosen.
The cover plates 150 can be made of a metallic material, but can also be made of any other material that meets the requirements of the invention. Furthermore, the cover plates 150 can be curved, preferably corresponding to the curvature of the outer circumferential surface 121.
The tension member protection system 100 also comprises joining sleeves 160. These are joining means for joining the shell elements 120. Each joining sleeve is hollow and has a through-hole 165 and end faces 162. The joining sleeves 160 are arranged on the shell elements 120 in the cavities 125 formed by the indentations 124. The joining sleeves 160 therefore have a cross-section that is complementary to the cavities 125. For example, if the cavities 125 are square shaped, the joining sleeves 160 have a corresponding square cross-section.
Regardless of the cross-sectional shape of the joining sleeves 160 and the rod-shaped element 140, it is advantageous if the cross-section of the through-hole 165 of the joining sleeves 160 has internal dimensions which are larger than the (largest) external dimensions of the cross-section of the rod-shaped element 140. In particular, the diameter of the rod-shaped element 140, if it has a circular cross-section, should be smaller than the smallest internal side length of the through-hole 165 of the joining sleeves 160 or than the diameter at the inner circumference of the through-hole 165 of the joining sleeves 160. Furthermore, the dimension of the largest side length of the rod-shaped element 140, if it has a rectangular (or square) cross-section, should be smaller than the smallest internal side length of the through-hole 165 of the joining sleeves 160 or than the diameter at the inner circumference of the through-hole 165 of the joining sleeves 160.
Each joining sleeve 160 is attached to the surface 124a in an indentation 124 which runs parallel to the contact surface 123, via suitable fastening means or methods and is thus assigned to a shell element 120. Naturally, the joining sleeves 160 can also be joined to one or both side faces 124b or be designed integrally with the respective indentation 124. If the indentation 124 is circular, the joining sleeve 160 is attached to the whole of the indentation 124.
A plurality of joining sleeves 160 is arranged in each cavity 125, one half of the plurality of joining sleeves 160 being attached to one shell element 120 and the other half of the plurality of joining sleeves 160 being attached to the other shell element 120. The joining sleeves 160 are preferably fastened to one shell element 120 and the other shell element 120 in an alternating sequence. The joining sleeves 160 are attached in such a way that, when the contact surfaces of the shell elements 120 lie against each other, they engage with each other so that the through-holes 165 of the joining sleeves 160 completely overlap in the longitudinal direction of the tension member protection system 100 and the end faces 162 of the joining sleeves 160 lie against each other. Alternatively, the joining sleeves can be attached and assigned to the shell elements in a different sequence, provided that the joining of joining sleeves 160 arranged in this way by means of the rod-shaped element 140 leads to a positive connection of the two shell elements 120. For example, two joining sleeves 160 can be attached to one shell element 120 and, proceeding in the longitudinal direction of the tension member protection system 100, one joining sleeve 160 can then be attached to the other shell element 120, and so on.
Alternatively, certain spaces may be present between the end faces 162 of the joining sleeves 160, provided that a joining of joining sleeves 160 arranged in this way by means of the rod-shaped element 140 leads to a positive connection of the two shell elements 120.
The joining sleeves 160 are made of a metallic material, but can also be made of any other suitable material. To simplify the manufacturing process, the joining sleeves 160 can be of the same length. The end joining sleeves 160 in the longitudinal direction of the tension member 110 may however be of a different length. Alternatively, the joining sleeves 160 can be of different lengths.
To join the shell elements 120, they are brought into contact at the contact surfaces 123 so that the joining sleeves engage with each other and the through-holes 165 are aligned with each other. The rod-shaped elements 140 are then inserted into the through-holes 165 of the joining sleeves 160 until they are fully inserted in the joining sleeves 160.
To prevent the rod-shaped elements 140 from falling out of their own accord, a base plate (not shown) can be attached to the lower end of the tension member protection system 100. When assembled, a cover plate (not shown) can also be attached to the upper end of the tension member protection system 100.
Furthermore, to protect the tension member protection system 100, a housing (not shown) can be mounted over it. The base plate, the cover plate and the housing can be made of sheet steel. Alternatively, the housing can be made of any other suitable material.
An alternative, second embodiment can also be conceived whereby part 1160a of the plurality of joining sleeves 1160 is designed integrally with the shell element 1120, as shown in
Furthermore, in this embodiment the shell elements 1120 have joining sleeves 1160b protruding from the other contact surface 1123, which are fastened thereon by welding, soldering, gluing or an alternative fastening method. These joining sleeves 1160b are circular in the cross-sectional portion further away from the contact surface 1123, a web being arranged in the joining sleeves 1160b between the contact surface 1123 and the circular section. A through-hole 1165 is located in the circular section of the joining sleeves 1160b, through which the rod-shaped element 1140 is finally passed after the contact surfaces 1123 have been joined together.
The openings 1164 are designed and arranged so that the joining sleeves 1160b can pass through the openings 1164 when the shell elements 1120 are joined together. When the contact surfaces 1123 of two shell elements 1120 lie against each other, the respective joining sleeve 1160b is completely accommodated in the opening 1164 and in the through-hole 1163 underneath. For this purpose, the openings 1164 should be arranged in the longitudinal direction of the contact surface 1123 at the same distances from the lower (or upper) end section of the shell element 1120 and from the outer circumferential surface 1121 as the joining sleeves 1160b.
Therefore, each joining sleeve 1160b should be so designed that the radius of the circular portion of the joining sleeve 1160b essentially corresponds to the radius of the through-hole 1163 and the maximum linear expansion between the contact surface 1123 and the opposite inner circumferential surface corresponds to that of the through hole 1163.
Furthermore, the extent of the joining sleeves 1160b in the longitudinal direction of the shell elements 1120 is small in comparison to their height.
The joining sleeves 1160b are arranged at equal distances on the contact surfaces 1123. “Equal” in this context means that the joining sleeves 1160b are arranged at equal distances in the longitudinal direction of the respective contact surface 1123. However, it also means that the joining sleeves 1160b are fastened to one contact surface 1123 and to another contact surface 1123 at the same distances from the base plate and cover plate.
The joining sleeves 1160b can have chamfered edges. The openings 1164 can also be chamfered on the side facing the contact surface 1123.
For this embodiment, the shell element 1120 should be designed as a hollow body, otherwise the openings 1164 should have a passage to the through hole 1163 which allows the joining sleeves 1160b to pass through.
In this embodiment, the cover plate(s) 1150 can be fitted in a recess 1152 of the outer circumferential surface 1121. This recess extends above and below the joint 1151.
In a third embodiment of the invention, the reference numbers are increased by 2000 and only the differences compared with the first embodiment are described. In this third embodiment of a tension member protection system 2100, the joining sleeves 2160 are arranged in the cavity 2130. As shown in
The joining sleeves 2160 are circular in
Optionally, in this third embodiment of the invention, a coupling device 2400 can be arranged in the contact surfaces 2123 of at least two shell elements 2120, which lie against each another in the cavity 2130 forming state, which couples the contact surfaces 2123 of at least two shell elements 2120 with each other. This coupling device 2400 may comprise a projection 2410 on one of the two contact surfaces 2123 which lie against each other in the cavity 2130 forming state and a depression 2420 in the other. The projection 2120 and the depression 2420 are designed so that they interlock when the shell elements 2120 form the cavity 2130.
The coupling device 2400 can be arranged along the entire length of the contact surfaces 2123 so that it forms a continuous strip. Alternatively, multiple coupling devices 2400 can be arranged over the entire length of the contact surfaces 2123, so that the individual coupling devices 2400 act at those points. The coupling devices 2400 can have the same or alternatively different lengths. There may be equal or different distances between the coupling devices 2400.
Number | Date | Country | Kind |
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10 2017 218 479.5 | Oct 2017 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/068950 | 7/12/2018 | WO | 00 |