• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Reinforcement device applicable to existing structures, forming with it an attached structure activated by means of tester forces consisting of a tested element (2) that with its action unloads the existing structure (1), an element compressed by the action of the tesado, some unions (4) with one or several degrees of freedom with respect to the existing structure (1) and that release it from pernicious efforts induced by the tesado and a support (5) where the device delivers the portion of load that has assumed . (Machine-translation by Google Translate, not legally binding)
    公开号:ES2746623A1
    申请号:ES201930821
    申请日:2019-09-24
    公开日:2020-03-06
    发明作者:Aparicio Javier Martínez;Miguel Guillermo Capellán
    申请人:Arenas & Asoc Ingenieria De Diseno S L P;
    IPC主号:
    专利说明:

    [0001]
    [0002] EXISTING STRUCTURE REINFORCEMENT DEVICE
    [0003]
    [0004] TECHNICAL SECTOR
    [0005]
    [0006] The present invention relates to a device for reinforcing existing structures. This device is applicable to all structural configurations, although it is particularly adapted to lattice-type bridge structures, and ensures a significant increase in the bearing capacity of the structure.
    [0007]
    [0008] BACKGROUND OF THE INVENTION
    [0009]
    [0010] Currently, the needs for reinforcing structures have increased due to the aging of many structures and due to the convenience of making them capable of supporting greater loads than those with which they were originally conceived.
    [0011]
    [0012] It is not uncommon for structural rehabilitation specialists to face the problem of designing a structural reinforcement to improve load capacity in a very important way. Among the tools that these professionals have is the possibility of arranging cables or tendons that are tightened with which they seek to unload the existing structure, enabling it to assume additional loads over those that it could initially take. In this case, it would be a matter of providing straight or even curved cable ties. These solutions are advantageous for the minimal contribution of material that they require and because the connections between this material to the existing structure are few and concentrated. In other words, it has economic and constructive advantages.
    [0013]
    [0014] However, the main problem with these prestressing solutions is that the cable's own clamping force introduces a compression stress in some part of the structure that, in some cases, particularly lattice bridges, is not capable of assuming it, for so the potential of the solution cannot be fully deployed. In order to do this, material must be added to the parts damaged by the stressing force, but these reinforcements are generally expensive: they require adding resistant material directly on existing parts, which cannot be disassembled to be replaced by more resistant ones, being forced to resort to solder joints or resin bonding.
    [0015]
    [0016] The part of the tensile force that is detrimental to the structure must be adequately managed, either by applying it to a part of the existing structure that has sufficient capacity for it, or by reinforcing the parts of the existing structure that require it. . In this proposal for a reinforcing device, it is sought that this damaging part be collected within the device and not transferred to the existing structure.
    [0017]
    [0018] Analyzing the existing patents worldwide, different solutions have been found whose differences with respect to the proposed model are explained below.
    [0019]
    [0020] US4691399A, applied for by Kim Jai, B .; Yadlosky, John M., proposes a reinforcing device formed by supporting arches encompassed within the existing latticework. Each of these arches includes the elements that form an arched path and, among others, a stressed element that joins the two ends of the arch. This reinforcing solution differs from the one proposed, in that the reinforcing device is not self-balancing in terms of the clamping force, since it delivers clamping loads outside the device. Specifically, the tensioned element is directly attached to the truss, so the bridge must participate through them to support the horizontal component of the tensioning load, which is just what you want to avoid with the proposed device.
    [0021]
    [0022] JP3732468B2, applied for by Asahi Engineering KK, deals with a bridge reinforcement structure in which through auxiliary triangular structural frames, each of which is built at opposite ends of a lattice girder or arch beam and A cable stretched between the auxiliary triangular structural frames, an upward steering force is exerted on the lattice girder or the arc girder, thus effectively inducing a load resistance force. This reinforcing solution differs from the one proposed, in that the reinforcing device is not self-balancing in terms of the clamping force, since it delivers clamping loads outside the device. Specifically, the stressed element is directly attached to the lattice beam or arc beam, so, through them, the bridge must participate to support the horizontal component of the stressed load, which is just what you want avoid with the proposed device.
    [0023] JP3597168B2, applied for by Asahi Engineering KK, deals with a bridge reinforcement structure in which a cable stretched in the direction of the bridge length, forces a uniform reaction upwards in order to improve the load capacity of the bridge . The ends of that cable connect to both ends of the bridge and a plurality of hydraulic jacks installed at the bottom of the bridge, between the cable and the bridge girders, allow the cable to be stretched by imposing a force that reinforces the load-bearing capacity. This reinforcing solution differs from the one proposed, in that the reinforcing device is not self-balancing in terms of the clamping force, since it delivers clamping loads outside the device. In particular, the reinforced structure must be able to support the horizontal component of the stress load, which is just what you want to avoid with the proposed device.
    [0024]
    [0025] Patent CN106567344B, applied for by Zhejiang University, proposes a bridge reinforcement system through a structure that comprises five parts: prestressed cables, a lattice, a distribution beam, some cable steering wheels on top of the piles of the bridge and wheels transmitting the force of the cables to the lattice. This reinforcing solution differs from the one proposed, in that the reinforcing device is not self-balancing in terms of the clamping force, since it delivers clamping loads outside the device. Specifically, you must establish supports at the end of the cables to support the horizontal component of the tensioning load, which is just what you want to avoid with the proposed device.
    [0026]
    [0027] Patent CN102140780A, applied for by Zhejiang Electric Power Design Institute, proposes a reinforcing device composed of external prestressing cables under the bridge which passes by sliding chairs on top of the piers and below a steel frame structure with wheels for guidance of the cable at the bottom. It is also defined that the cable must be anchored at its ends in a special structure on the ground. It is a conceptually identical system to the one previously described, although with different execution details. This reinforcing solution differs from the one proposed, in that the reinforcing device is not self-balancing in terms of the clamping force, since it delivers clamping loads outside the device. Specifically, you must establish supports at the end of the cables to support the horizontal component of the tensioning load, which is just what you want to avoid with the proposed device.
    [0028] Patent FR2843979A1, applied for by Jean Muller International et al., Is a bridge reinforcement device made up of at least one beam mounted on supports and at least one cable supported on the face of the beam opposite the application face of the load. The cable is applied to the load surface by means of a diverter located at the height of a support and provided with a cable guide. This reinforcing solution differs from the one proposed, in that the reinforcing device is not self-balancing in terms of the clamping force, since it delivers clamping loads outside the device. Specifically, it must involve the bridge deck to support the horizontal component of the stress load, which is just what you want to avoid with the proposed device.
    [0029]
    [0030] Patent CN104695341A, applied for by Beijing University of Technology, is a cable-stayed beam structure for the reinforcement of large continuous beam bridges. It is a non-self-compensating structure of the beams, consisting mainly of a lattice, vertical support bars and a prestressed cable. The non-self-compensating cable-stayed beam structure has the characteristic of not self-compensating since the prestressed cable is not connected with its own anchors at two ends of the frame at the top, but is fixed to bridge pillars on two sides of a bridge span by means of anchoring devices for traction cables and, in addition, the vertical back pressure generated by the prestressed tension of the prestressed cable acts on the beam of the main bridge through the frame, so that the effects of reinforcing the bridge beam and improve the support property of the bridge girder. This reinforcing solution differs from the one proposed, in that the reinforcing device is not self-balancing in terms of the clamping force, since it delivers clamping loads outside the device. Specifically, the stressed element is directly attached to the bridge pillars, so the bridge deck must participate through them to support the horizontal component of the stressed load, which is exactly what you want to avoid with the proposed device.
    [0031]
    [0032] CN104894984A, applied for by Guangxi Transportation Research Institute, is a rigid frame bridge reinforcement method adopting an inverted suspension bridge system. It is a conceptually identical system to the one previously described, although with different execution details. This reinforcing solution differs from the one proposed, in that the reinforcing device is not self-balancing in terms of the clamping force, since it delivers clamping loads outside the device. Specifically, the stressed element is directly attached to the bridge deck, so it must participate to support the horizontal component of the stress load, which is just what you want to avoid with the proposed device.
    [0033]
    [0034] The CN105088972A patent, applied for by the Guangxi Transportation Research Institute, is a rigid frame bridge reinforcement method similar to that described in the CN104894984A patent, but where the cable passes through towers placed above the board. It is a conceptually identical system to the one previously described, although with different execution details. This reinforcing solution differs from the one proposed, in that the reinforcing device is not self-balancing in terms of the clamping force, since it delivers clamping loads outside the device. Specifically, the tensioned element is directly attached to the bridge deck, so it must participate to support the horizontal component of the tensioning load, which is just what you want to avoid with the proposed device.
    [0035]
    [0036] EXPLANATION OF THE INVENTION
    [0037]
    [0038] It is a structure reinforcement device, specially adapted for lattice bridges, consisting of an attached structure composed of one or more stressed elements, that is, a cable or tendon, straight or curved, and one or more compressed elements joined to the existing structure in a plurality of points. These unions are characterized in that they release unfavorable degrees of freedom so that the existing structure does not suffer under the stresses produced during the stressing. This last point is essential, since if this release of the relative movements between one structure and another is not included, the existing structure runs the risk of being overloaded during the stressing operation, and the full potential of any solution can never be harnessed that includes a stressed element, which would be limited by the strength of the structure itself.
    [0039]
    [0040] The liberation of degrees of freedom between the additional structure and the existing one is achieved by allowing the longitudinal sliding to compression or traction, so that the deformation of the additional structure, expressly built with the appropriate resistance, receives all the unfavorable loads. from the stress, but not the existing structure, which is freed from loads in all parts where the device comes to influence and, therefore, fully capable of receiving loads greater than it could originally withstand.
    [0041] The result of the entire device is that no relevant tensioning loads are transferred to the exterior of the reinforcing device, that is, it is self-balancing, freeing the existing structure (1) and its environment from the damaging part of the tensioning.
    [0042]
    [0043] One of the advantages of the device is that the contribution of material is adjusted to the minimum necessary to introduce the prestressing and withstand unfavorable compressions. In addition, the joints to be made on site are limited in quantity and extent, since the beneficial effect is not simply adding material to the existing structure, but previously releasing it from its load without significantly damaging it. The level of discharge that can be obtained is whatever is desired, and the sign of the efforts that request the existing structure can even be reversed.
    [0044]
    [0045] Other advantages are of a constructive nature, since the application of this solution can be done effectively by attaching it from the outside, which facilitates its application, since many times the structure, in general, a bridge, must be kept in service. In this reinforcement solution, actions inside the bridge are not necessary, beyond what may be collateral to the action, so that vehicle traffic is not impeded.
    [0046]
    [0047] BRIEF DESCRIPTION OF THE DRAWINGS
    [0048]
    [0049] To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, a set of drawings is included as an integral part of said description, where, by way of illustration and not limitation, the next:
    [0050]
    [0051] Figure 1.- Shows a perspective view of a lattice bridge before the reinforcement is executed by means of the device.
    [0052] Figure 2.- Shows a perspective view of a lattice bridge with the reinforcement by means of the proposed device with cable with catenary layout.
    [0053] Figure 3.- Shows an elevation view of a truss bridge before the reinforcement is executed by means of the device.
    [0054] Figure 4.- Shows an elevation view of a lattice bridge with the reinforcement by means of the proposed device with cable with catenary layout.
    [0055] Figure 5.- Shows an elevation view of another lattice bridge from before the reinforcement was executed by means of the device.
    [0056] Figure 6.- Shows an elevation view of the lattice bridge of the previous figure, with the reinforcement by means of the proposed device with straight cable ties.
    [0057]
    [0058] 1 = Existing structure
    [0059] 2 = Stressed element
    [0060] 3 = Compressed element
    [0061] 4 = Sliding connection between compressed and stressed element
    [0062] 5 = Support that delivers the loads of the reinforcement structure
    [0063]
    [0064] PREFERRED EMBODIMENT OF THE INVENTION
    [0065]
    [0066] As can be seen in the referred figures, on the existing structure (1), the different components of the reinforcing structure described in this invention are distributed. There are one or more elements that are tested (2) to download the existing structure. Associated with these are one or more elements that are compressed (3) by the action of the tesado. Between the existing structure and the reinforcing structure there are sliding joints (4) where they are required to release the deformation from one to the other during the tensioning and that they effectively transfer the discharge force. The tensioned element (2) and compressed (3) are connected to each other in one or more knots (4), also sliding, so that the tensioning load is transferred in a convenient way. There is a point where the reinforcing structure rests (5), this support being able to be inside or outside the existing structure itself. The function of this support (5) is to deliver the loads collected by the reinforcement structure in a place where they can be safely received.
    [0067]
    [0068] Currently, the projects of reinforcing lattice bridge structures are solved by extensively adding steel pieces to the existing structure, with which a large number of joints have to be executed on site. Other times a prestressing is applied that unloads the structure, although this solution is limited in lattice structures in that the compression added by the stress does not excessively overload any part, which forces the structure to be reinforced by adding more pieces of steel on the existing structure. With this invention the discharge of the existing structure (1) is achieved, as in the case of using a prestressing solution, but freeing it from the undesirable compression induced by the stress due to the use of sliding joints (3), all this forming a set that is in solidarity with the existing structure. It is also achieved that the device acts passively as reinforcement, especially in the face of horizontal wind and earthquake loads, benefiting the existing structure (1) without the need to add other reinforcements.
    权利要求:
    Claims (8)
    [1]
    1a.- Device for reinforcing existing structures, comprising:
    • one or more stressed elements (2) that with its action discharges the existing structure (1),
    • one or more elements compressed (3) by the action of the stressed element (2), • sliding joints (4) with one or more degrees of freedom with respect to the existing structure (1), and
    • one or more supports (5) where the device delivers the load it assumes.
    [2]
    2a.- Device for reinforcing existing structures, according to claim 1, characterized by delivering the load on one or more supports (5), either inside or outside the existing structure (1).
    [3]
    3a.- Device for reinforcing existing structures, according to claim 1, characterized by being applied to an existing lattice-type structure.
    [4]
    4a.- Reinforcement device for existing structures, according to claim 1, characterized by being applied on a bridge.
    [5]
    5a.- Device for reinforcing existing structures, according to claim 1, characterized in that the tensioned element (2) is a prestressing tendon, a cable for tensioning or a prestressed bar.
    [6]
    6a.- Device for reinforcing existing structures, according to claim 1, characterized in that the stressed element (2) has a straight, curved or broken shape.
    [7]
    7a.- Reinforcement device for existing structures, according to claim 1, characterized by being built interchangeably with steel, concrete or other resistant material.
    [8]
    8a.- Reinforcement device for existing structures, according to claim 1, characterized by being attached to the existing structure (1), to work against loads not directly originated by the stress, collaborating with the existing structure itself (1) in such a way passive.
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    同族专利:
    公开号 | 公开日
    ES2746623B2|2021-02-22|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JPH07259018A|1994-03-18|1995-10-09|Kurimoto Ltd|Cable stiffened water pipe bridge|
    US20040040100A1|2002-09-04|2004-03-04|Mitsuhiro Tokuno|Reinforcement structure of truss bridge or arch bridge|
    US7146672B1|2005-09-23|2006-12-12|Meheen H Joe|Tunable load sharing arch bridge|
    US20100281632A1|2009-05-08|2010-11-11|Meheen H Joe|Tunable Load Sharing Arch Bridge|
    CN104695341A|2015-03-08|2015-06-10|北京工业大学|Non-self-balanced beam string structure for reinforcing large-span continuous beam bridge|
    法律状态:
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    优先权:
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    ES201930821A|ES2746623B2|2019-09-24|2019-09-24|REINFORCEMENT DEVICE FOR EXISTING STRUCTURES|ES201930821A| ES2746623B2|2019-09-24|2019-09-24|REINFORCEMENT DEVICE FOR EXISTING STRUCTURES|
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