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What is Allplan Bridge?
Allplan Bridge is a powerful parametric BIM solution for bridge engineers, combining all phases of bridge design from highly detailed model creation, including prestressing tendons, to the integration of the construction process, structural analysis with code-based design, and drawing production, in one solution.
- Tailored solutions for different bridge types, such as precast girder bridges, and all parts of super and substructure including bridge equipment.
- Fully parametric model, including intelligent reinforcement, enabling easy templating and fast and precise model changes for maximum flexibility and superior project delivery.
- Interoperability of the geometrical and analytical model for more efficient project collaboration.
HOW ALLPLAN BENEFITS YOUR BUSINESS
Features of Allplan Bridge
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- 1 \ TERRAIN & ROAD DESIGN Reliable Terrain Models Right from the Start
- Easy and Quick Start through Intuitive Design Workflows
- Parametric Modeling enables Adjustment of Input Parameters at Any Time.
- Automated Plan and Report Outputs
- 2 \ MODELING & PRESTRESSING Parametric Bridge Oriented Modeling
- Customized Modeling for Precast Girder Bridges
- Free Parametric Modeling
- Tendon Modeling Made Simple
- Placement of Detailing Objects
- 3 \ STRUCTURAL ANALYSIS Derivation of Analytical Model
- Construction Sequence Calculation
- Time Dependent Analysis
- Permanent and Variable Loads
- Traffic Loads
- Dynamic Analysis
- Superposition and Combinations
- Code-based Design
- 4 \ REINFORCEMENT MODELING & DELIVERABLES 3D Reinforcement in Next to No Time
- Detail Complex Reinforcement
- Easily Work with Curved Structures
- Fast and Precise Production of Deliverables
- Steel Lists with Detailed Information
- 5 \ COLLABORATION Superior Issue Management
- Coordinate Models
- Data Re-use
- Open BIM Data Exchange with IFC
- Exchange Analytical Model
In order to optimally align bridges and roads within the terrain environment right from the start, a correct and detailed terrain model is of central importance. With Allplan, terrain data in various formats can be easily uploaded, visualized, and edited. Create sections and terrain views to identify the best variants for your infrastructure project.
[...read more]In order to optimally align bridges and roads within the terrain environment right from the start, a correct and detailed terrain model is of central importance. With Allplan, terrain data in various formats can be easily uploaded, visualized, and edited. Create sections and terrain views to identify the best variants for your infrastructure project.
The clear user interface enables easy and fast learning of the product. Despite the simple interface, the solution offers a wide range of functions that enable creation of complex road geometries. The fully automated overall model check and the individual cross-section check enable rapid error detection and identify potential reasons.
[...read more]The clear user interface enables easy and fast learning of the product. Despite the simple interface, the solution offers a wide range of functions that enable creation of complex road geometries. The fully automated overall model check and the individual cross-section check enable rapid error detection and identify potential reasons.
The parametric tools for road design in Allplan allow you to conveniently plan the road layout associated with the bridge. You can make changes to the design quickly and easily by adjusting the corresponding parameters. Road design and bridge modeling go hand in hand with a single software solution.
[...read more]The parametric tools for road design in Allplan allow you to conveniently plan the road layout associated with the bridge. You can make changes to the design quickly and easily by adjusting the corresponding parameters. Road design and bridge modeling go hand in hand with a single software solution.
The common plan output drawings are directly derived from the model. Besides the automated plan outputs, also reports for volumetric calculations, distance or stakeout points can be generated. Every change of a modeling parameter is immediately reflected in the results. Of course, the user can freely select the desired parameters for the output.
[...read more]The common plan output drawings are directly derived from the model. Besides the automated plan outputs, also reports for volumetric calculations, distance or stakeout points can be generated. Every change of a modeling parameter is immediately reflected in the results. Of course, the user can freely select the desired parameters for the output.
All types of bridges, whether complex or simple, can be modeled with Allplan Bridge. This is possible due to its principal modeling method - the 3D parametric model description considers the road layout, bridge alignment and required cross-sections. It is tailored for bridges with a geometry that is directly governed by the axis. It also allows modeling of complex geometries, including double curved alignment, and variable cross-sections.
[...read more]All types of bridges, whether complex or simple, can be modeled with Allplan Bridge. This is possible due to its principal modeling method - the 3D parametric model description considers the road layout, bridge alignment and required cross-sections. It is tailored for bridges with a geometry that is directly governed by the axis. It also allows modeling of complex geometries, including double curved alignment, and variable cross-sections.
Precast girder bridges have one thing in common – their component geometry. The straight profile of precast girders is why their geometry is not directly impacted by the road or bridge axis. That is why Allplan Bridge provides special features and a specialized workflow. The reuse of girder shapes and lengths is a further typical feature of precast girder bridges and in Allplan Bridge “modular modeling” addresses this whilst providing an efficient workflow.
[...read more]Precast girder bridges have one thing in common – their component geometry. The straight profile of precast girders is why their geometry is not directly impacted by the road or bridge axis. That is why Allplan Bridge provides special features and a specialized workflow. The reuse of girder shapes and lengths is a further typical feature of precast girder bridges and in Allplan Bridge “modular modeling” addresses this whilst providing an efficient workflow.
The third modelling technique available in Allplan Bridge allows the user to parametrically model the entire bridge or its sub elements freely in 3D space using volumetric primitives and Boolean operations. In the first release of this new technology for volumetric primitives advanced prisms are implemented - the basic shape of a prism is defined using the well-known cross-section definition. Because this is rather a more general parametric modeling technique, it can be used for parametric modeling of other infrastructure requirements as well.
[...read more]The third modelling technique available in Allplan Bridge allows the user to parametrically model the entire bridge or its sub elements freely in 3D space using volumetric primitives and Boolean operations. In the first release of this new technology for volumetric primitives advanced prisms are implemented - the basic shape of a prism is defined using the well-known cross-section definition. Because this is rather a more general parametric modeling technique, it can be used for parametric modeling of other infrastructure requirements as well.
Allplan Bridge makes it easy to model a wide range of types of pre-stressing: with immediate or later bond, internal and external, longitudinal, transverse and vertical, as well as with non-standard geometry.
[...read more]Allplan Bridge makes it easy to model a wide range of types of pre-stressing: with immediate or later bond, internal and external, longitudinal, transverse and vertical, as well as with non-standard geometry.
Parametric objects from the Allplan library, can be referenced in Allplan Bridge to add further details such as reinforcement, anchor devices of tendons or lamp posts to the bridge model. To do this, reference points are defined and linked to the object in the Allplan library using the respective name. When the parametric model is transferred to Allplan, the corresponding objects are positioned and adjusted whenever the model is updated.
[...read more]Parametric objects from the Allplan library, can be referenced in Allplan Bridge to add further details such as reinforcement, anchor devices of tendons or lamp posts to the bridge model. To do this, reference points are defined and linked to the object in the Allplan library using the respective name. When the parametric model is transferred to Allplan, the corresponding objects are positioned and adjusted whenever the model is updated.
After creating the BIM bridge model, you can perform the structural analysis of the bridge directly in Allplan Bridge. The analysis model is automatically derived from the geometrical model which is complemented with all the analysis relevant definitions. This process is completely user controlled and greatly reduces the amount of work and susceptibility to errors.
[...read more]After creating the BIM bridge model, you can perform the structural analysis of the bridge directly in Allplan Bridge. The analysis model is automatically derived from the geometrical model which is complemented with all the analysis relevant definitions. This process is completely user controlled and greatly reduces the amount of work and susceptibility to errors.
The BIM model in Allplan Bridge contains also the 4th dimension – time – which is considered when specifying the construction process. To perform construction sequence analysis, the product analyzes the previously defined construction schedule and assembles all necessary calculation definitions in an automated process, such as self-weight load cases, element activation and calculation actions. This includes input data for calculating nonlinear time effects, creep, shrinkage and relaxation. All the generated items are listed in “logging” and with that complete transparency is enabled.
[...read more]The BIM model in Allplan Bridge contains also the 4th dimension – time – which is considered when specifying the construction process. To perform construction sequence analysis, the product analyzes the previously defined construction schedule and assembles all necessary calculation definitions in an automated process, such as self-weight load cases, element activation and calculation actions. This includes input data for calculating nonlinear time effects, creep, shrinkage and relaxation. All the generated items are listed in “logging” and with that complete transparency is enabled.
Particularly important for the construction stage analysis of prestressed and reinforced concrete structures is the correct consideration of the time-dependent effects. In Allplan Bridge the calculation of creep and shrinkage of concrete and relaxation of prestressing steel is code-compliant and available according to several standards, including EN and AASHTO.
[...read more]Particularly important for the construction stage analysis of prestressed and reinforced concrete structures is the correct consideration of the time-dependent effects. In Allplan Bridge the calculation of creep and shrinkage of concrete and relaxation of prestressing steel is code-compliant and available according to several standards, including EN and AASHTO.
The weight and the position of superimposed dead loads (like sidewalk, road pavement, etc.) are automatically retrieved from the geometrical model. Additional loads, like temperature change (including nonlinear temperature distribution), wind loads, settlement, loads due to braking and acceleration, etc. can be defined and applied easily as well.
[...read more]The weight and the position of superimposed dead loads (like sidewalk, road pavement, etc.) are automatically retrieved from the geometrical model. Additional loads, like temperature change (including nonlinear temperature distribution), wind loads, settlement, loads due to braking and acceleration, etc. can be defined and applied easily as well.
The definition of the traffic load is split into 2 steps – automatic or manual definition of notional lanes and load trains (moving loads). The moving load calculation is based on the theory of (related) influence lines allowing an easy and swift calculation. First the influence lines are calculated and then the evaluation of influence lines is performed and the results are saved into an envelope.
[...read more]The definition of the traffic load is split into 2 steps – automatic or manual definition of notional lanes and load trains (moving loads). The moving load calculation is based on the theory of (related) influence lines allowing an easy and swift calculation. First the influence lines are calculated and then the evaluation of influence lines is performed and the results are saved into an envelope.
Allplan Bridge uses the multi-mode Response Spectrum Method for evaluating the effects of seismic loading. Mathematically, this solution is based on the excitation of the relevant natural modes and combining the different modal contributions. Internal force and displacement amplitudes related to the individual natural modes are superimposed using different methods, such as the Complete Quadratic Combination (CQC) to obtain the envelope of extreme values.
[...read more]Allplan Bridge uses the multi-mode Response Spectrum Method for evaluating the effects of seismic loading. Mathematically, this solution is based on the excitation of the relevant natural modes and combining the different modal contributions. Internal force and displacement amplitudes related to the individual natural modes are superimposed using different methods, such as the Complete Quadratic Combination (CQC) to obtain the envelope of extreme values.
The user-friendliness and usability of the superposition in Allplan Bridge is groundbreaking. The schematic definition of the superposition combines maximum flexibility and optimal overview. The same applies for the combinations, which are defined and visualized in a table form, giving the user optimal overview of different combination types and load factors. Furthermore, it is possible to select several stress components in user-defined stress points and perform a stress leading superposition.
[...read more]The user-friendliness and usability of the superposition in Allplan Bridge is groundbreaking. The schematic definition of the superposition combines maximum flexibility and optimal overview. The same applies for the combinations, which are defined and visualized in a table form, giving the user optimal overview of different combination types and load factors. Furthermore, it is possible to select several stress components in user-defined stress points and perform a stress leading superposition.
Once the global effects are calculated and the relevant envelopes have been created the user can perform code dependent design tasks to determine the required reinforcement content. After the reinforcement area has been calculated or manually specified, ULS and SLS checks can be performed according to different international standards.
[...read more]Once the global effects are calculated and the relevant envelopes have been created the user can perform code dependent design tasks to determine the required reinforcement content. After the reinforcement area has been calculated or manually specified, ULS and SLS checks can be performed according to different international standards.
Even with a very complex bridge design, the reinforcement of the bridge with Allplan can be realised with great precision. With the help of PythonParts, Allplan saves significant time and effort.
[...read more]Even with a very complex bridge design, the reinforcement of the bridge with Allplan can be realised with great precision. With the help of PythonParts, Allplan saves significant time and effort.
Easily and conveniently sweep reinforcement designs along paths creating deliverables for curved structures.
[...read more]Easily and conveniently sweep reinforcement designs along paths creating deliverables for curved structures.
Especially with complex, multi-curved bridge axes, you can save significant working time with the "Section along curve".
[...read more]Especially with complex, multi-curved bridge axes, you can save significant working time with the "Section along curve".
Thanks to the fact that the bridge model and the reinforcement are detailed in 3D, the creation of the drawings is very easy. Since the views and sections are associative, the creation of detailed plan types can be accomplished very quickly.
[...read more]Thanks to the fact that the bridge model and the reinforcement are detailed in 3D, the creation of the drawings is very easy. Since the views and sections are associative, the creation of detailed plan types can be accomplished very quickly.
The digital bridge model contains a multitude of information. Comprehensive reports with dimensions, areas, volumes, weights and quantities are available at the touch of a button. This also applies to rebar bending schedules.
[...read more]The digital bridge model contains a multitude of information. Comprehensive reports with dimensions, areas, volumes, weights and quantities are available at the touch of a button. This also applies to rebar bending schedules.
Communicate tasks, manage and document changes centrally and more effectively within project teams via Allplan and Bimplus.
[...read more]Communicate tasks, manage and document changes centrally and more effectively within project teams via Allplan and Bimplus.
Work efficiently with data from specialist providers such as alignment data from LandXML and others, coordinate models and deliverables centrally in Bimplus.
[...read more]Work efficiently with data from specialist providers such as alignment data from LandXML and others, coordinate models and deliverables centrally in Bimplus.
Saving a complete model of a project or only a part of it (e.g.: a pier) as a TCL (text file), enables you to easily reuse data. Even more, this allows users to create templates of complete models or only of specific bridge elements allowing even faster project delivery.
[...read more]Saving a complete model of a project or only a part of it (e.g.: a pier) as a TCL (text file), enables you to easily reuse data. Even more, this allows users to create templates of complete models or only of specific bridge elements allowing even faster project delivery.
Over the years, IFC has been developed and now, it has reached version 4. This latest development is exciting for the infrastructure sector because with IFC 4.3, product definitions for Bridges, Roads and Rails have been added to the IFC taxonomy. Secondly, the definition of the spatial structure for infrastructure domains has been enhanced. Thus, this will allow easier and more standardized breakdown of infrastructure projects.
[...read more]Over the years, IFC has been developed and now, it has reached version 4. This latest development is exciting for the infrastructure sector because with IFC 4.3, product definitions for Bridges, Roads and Rails have been added to the IFC taxonomy. Secondly, the definition of the spatial structure for infrastructure domains has been enhanced. Thus, this will allow easier and more standardized breakdown of infrastructure projects.
The analytical model generated in Allplan Bridge can be uploaded to the cloud-based BIM platform Allplan Bimplus. This allows users to transfer the analytical model to other structural analysis solutions connected to Allplan Bimplus.
[...read more]The analytical model generated in Allplan Bridge can be uploaded to the cloud-based BIM platform Allplan Bimplus. This allows users to transfer the analytical model to other structural analysis solutions connected to Allplan Bimplus.
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