Design Any Telecom Tower Type All-in-One Telecom Structure Design Software!!
Imagine designing any telecom tower type smoothly in one advanced software! That’s what exactly ASMTower does. With its user-friendly interface and advanced features, ASMTower enables you to seamlessly create the best possible design scenario for your telecom tower project. ASMTower can streamline your workflow and achieve optimal results in telecom tower design.
This leads us to question, what types of structures are commonly used in telecom industry?
1. Self-supporting tower
Self-supporting towers are a popular choice for supporting antennas due to their many benefits, whether they are 4-legged or 3-legged towers. One major advantage is their ability to reach heights over 100m while using less steel weight than monopole towers, making them a cost-effective option for robust and towering structures. Additionally, they require less space than guyed towers, which need additional space for their guy wires, making self-supporting towers ideal for urban settings.
2. Monopole
Monopoles have a smaller footprint and sleeker design, making them less obtrusive and more appealing in urban areas compared to self-supporting towers. They also require fewer materials and less installation time, resulting in reduced costs and time in implementation process.
3. Guyed tower
Guyed masts are a popular choice for telecommunications applications when a large area and significant height are required. These slender structures can reach heights of over 600 meters, making them ideal for broadcasting, cellular networks, and military communications. Unlike self-supporting towers, guyed masts rely on tensioned cables called guy wires anchored to the ground for support, enabling the construction of tall structures using less material. This design makes guyed masts a cost-effective solution for achieving great heights.
4. Guyed pole
Guyed masts are a popular choice for telecommunications applications when a large area and significant height are required. These slender structures can reach heights of over 600 meters, making them ideal for broadcasting, cellular networks, and military communications. Unlike self-supporting towers, guyed masts rely on tensioned cables called guy wires anchored to the ground for support, enabling the construction of tall structures using less material. This design makes guyed masts a cost-effective solution for achieving great heights.
5. Rooftop tower
Guyed masts are a popular choice for telecommunications applications when a large area and significant height are required. These slender structures can reach heights of over 600 meters, making them ideal for broadcasting, cellular networks, and military communications. Unlike self-supporting towers, guyed masts rely on tensioned cables called guy wires anchored to the ground for support, enabling the construction of tall structures using less material. This design makes guyed masts a cost-effective solution for achieving great heights.
Foundation design
In addition to designing the structures themselves, ASMTower can also design the foundation for the structure, whether it be monopiles or raft foundation. With the automatic reflection of the super structure to the foundation, it absolutely streamlines foundation’s design with no room for human mistakes.
With following supported standards ASMTower will be your best choice
- The American standard, with the latest addendums:
- ANSI/TIA-222-G
- ANSI/TIA-222-H
- ANSI/TIA-222-I
- The European standard EN1993-3-1 with the following national annexes:
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General EN
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EN 1991-1-4:2005 EN 1993-3-1:2006 CEN Annex |
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Cyprus
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NA to CYS EN 1991.1.4:2005 NA to CYS EN 1993.3.1:2006(AC:2009) |
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Denmark
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EN 1991.1.4 DK NA:2007 DS/EN 1993.3.1 DK NA :2013 |
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France
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NF EN 1991.1.4/NA/A1 Juillet 2011 NF EN 1993-3-1/NA2008-07 |
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Germany
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DIN EN 1991.1.4/NA:2008-9 DIN EN 1993.3.1:2010-12 |
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Ireland
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IS EN 1991-1-4:2005/NA:2013 NA:2010+A1:2020 to I.S. EN 1993-3-1:2006&AC:2009 |
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Netherlands
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NEN-EN 1991-1-4+A1+C2:2011/NB:2019+C1:2020 NEN-EN 1993-3-1:2007/NB:2012 |
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Poland
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PN-EN 1991.1.4 listopad 2008 PN-EN 1993.3.1 Listopad 2008 |
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Romania
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SR EN 1991.1.4:2006/NB:2007 GEN EN 1993.3.1 :2006 |
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Singapore
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NA to SS EN 1991.1.4:2009 GEN EN 1993.3.1 :2006 |
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Sri Lanka
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NA to SLS EN 1991.1.4:2019 GEN EN 1993.3.1 :2006 |
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United Kingdom
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BS EN 1991.1.4:2005+A1:2010 NA to BS EN 1993-3-1 :2006 |