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Installation Technical
Manual
Technical data
MQS System
Version 2.0 EN | December 2015
Page 2 Installation Technical Manual – Product Line Technical Data – MQS System
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Terms of common cooperation /
Legal disclaimer
The product loading capacities published in these Technical Data Sheets are only valid for the mentioned codes or
technical data generation methods and the defined application conditions (e.g. ambient temperature load capacity not
valid in case of fire, data not valid in support structures when mixed with third party products), assuming sufficient
fastener, base material and building structure strength. Additional calculations, checks and releases by the
responsible structural engineer might be needed to clarify the capacity of base material and building structure.
Suitability of structures combining different products for specific applications needs to be verified by conducting a
system design and calculation, using for example Hilti PROFIS software. In addition, it is crucial to fully respect the
Instructions for Use and to assure clean, unaltered and undamaged state of all products at any time in order to
achieve this loading capacity (e.g. misuse, modification, overload, corrosion).
As products but also technical data generation methodologies evolve over time, technical data might change at any
time without prior notice. We recommend to use the latest technical data sheets published by Hilti.
In any case the suitability of structures combining different products for specific applications need to be checked and
cleared by an expert, particularly with regard to compliance with applicable norms and permits, prior to using them for
any specific facility. This book only serves as an aid to interpret the suitability of structures combining different
products for specific applications without any guarantee as to the absence of errors, the correctness and the
relevance of the results or suitability for a specific application. User must take all necessary and reasonable steps to
prevent or limit damage. The suitability of structures combining different products for specific applications are only
recommendations that need to be confirmed with a professional designer and/or structural engineers to ensure
compliance with User`s specific jurisdiction and project requirements.
MQS System – Technical Data
Page 3 Installation Technical Manual – Product Line Technical Data – MQS System
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Contents and overview of this manual
Product Designation Item number Page
Seismic channel hinges
MQS-AC-10 2083725 4
MQS-AC-12 2083726 6
MQS-ACD-10 2083727 8
MQS-ACD-12 2083728 10
Seismic rod hinges
MQS-AB-8 2083730 12
MQS-AB-10 2083731 14
MQS-AB-12 2083732 16
MQS-AB-16 2083733 18
MQS-H 8 2083738 20
MQS-H 10 2083739 22
MQS-H 12 2083740 24
MQS-CH-10 2083741 26
Rod brace
MQ3D-AS 2083742 28
Seismic angles
MQS-W 41 2083735 30
MQS-W 72 2083736 32
MQS-W 41D 2083737 34
Rod stiffener
MQS-RS 311943 36
MQS System – Technical Data
Page 4 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AC-10 seismic channel hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-AC-10 seismic channel hinge 2083725
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
239 g
Submittal text:
Hilti hinge for seismic bracing with MQ channels, MQ system, made of steel
S275JR according to DIN EN 10025-2, electro galvanized surface finish,
typically used to install seismic-resistant bracings made of channels or
struts. The hinge consists of two parts: a 6 mm steel base hinge with a 11.5
mm hole and a 4 mm steel channel connector with one fastening slot with
butterfly shape hole. The hinge mechanism is secured with a M10x25 bolt
class 8.8 and a M10 nut class 8. The channel connector is provided with a
side steel fold for a better locking mechanism with Hilti MQ channels (C
profiles). Material weight: 239 g
Designation D
Design load
+ Fx - Fx
MQS-AC-10 11.5 mm 6.24 kN 6.24 kN
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Base hinge S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bracing connector S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x20 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
MQS System – Technical Data
Page 5 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AC-10 seismic channel hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
MQS System – Technical Data
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 14.5
• Mathcad Prime® 2.0
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Conclusions
The results of tests, combined with FEM analysis, show that the channel connector MQS-AC-10 can efficiently be
used for the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular
seismic-resistant support depends on the set up of the used components and its interaction with the base material.
Test set up FEM Analysis Method
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Page 6 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AC-12 seismic channel hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-AC-12 seismic channel hinge 2083726
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
239 g
Submittal text:
Hilti hinge for seismic bracing with MQ channels, MQ system, made of steel
S275JR according to DIN EN 10025-2, electro galvanized surface finish,
typically used to install seismic-resistant bracings made of channels or
struts. The hinge consists of two parts: a 6 mm steel base hinge with a 13.6
mm hole and a 4 mm steel channel connector with one fastening slot with
butterfly shape hole. The hinge mechanism is secured with a M10x25 bolt
class 8.8 and a M10 nut class 8. The channel connector is provided with a
side steel fold for a better locking mechanism with Hilti MQ channels (C
profiles). Material weight: 239 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Base hinge S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bracing connector S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x20 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation D
Design load
+ Fx - Fx
MQS-AC-12 13.6 mm 6.24 kN 6.24 kN
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 7 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AC-12 seismic channel hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 14.5
• Mathcad Prime® 2.0
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the channel connector MQS-AC-12 can efficiently be
used for the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular
seismic-resistant support depends on the set up of the used components and its interaction with the base material.
Page 8 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-ACD-10 seismic channel hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-ACD-10 seismic channel hinge 2083727
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
314 g
Submittal text:
Hilti hinge for seismic bracing with MQ channels, MQ system, made of steel
S275JR according to DIN EN 10025-2, electro galvanized surface finish,
typically used to install seismic-resistant bracings made of channels or
struts. The hinge consists of two parts: a 6 mm steel base hinge with a 11.5
mm hole and a 4 mm steel channel connector with two fastening slots with
butterfly shape hole. The hinge mechanism is secured with a M10x25 bolt
class 8.8 and a M10 nut class 8. The channel connector is provided with a
side steel fold for a better locking mechanism with Hilti MQ channels (C
profiles). Material weight: 314 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Base hinge S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bracing connector S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x20 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation D
Design load
+ Fx - Fx
MQS-ACD-10 11.5 mm 11.60 kN 11.60 kN
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 9 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-ACD-10 seismic channel hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 14.5
• Mathcad Prime® 2.0
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the channel connector MQS-ACD-10 can efficiently be
used for the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular
seismic-resistant support depends on the set up of the used components and its interaction with the base material.
Page 10 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-ACD-12 seismic channel hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-ACD-12 seismic channel hinge 2083728
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
314 g
Submittal text:
Hilti hinge for seismic bracing with MQ channels, MQ system, made of steel
S275JR according to DIN EN 10025-2, electro galvanized surface finish,
typically used to install seismic-resistant bracings made of channels or
struts. The hinge consists of two parts: a 6 mm steel base hinge with a 13.6
mm hole and a 4 mm steel channel connector with two fastening slots with
butterfly shape hole. The hinge mechanism is secured with a M10x25 bolt
class 8.8 and a M10 nut class 8. The channel connector is provided with a
side steel fold for a better locking mechanism with Hilti MQ channels (C
profiles). Material weight: 314 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Base hinge S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bracing connector S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x20 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation D
Design load
+ Fx - Fx
MQS-ACD-12 13.6 mm 11.60 kN 11.60 kN
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 11 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-ACD-12 seismic channel hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 14.5
• Mathcad Prime® 2.0
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the channel connector MQS-ACD-12 can efficiently be
used for the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular
seismic-resistant support depends on the set up of the used components and its interaction with the base material.
Page 12 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AB-8 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-AB-8 seismic rod hinge 2083730
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
195 g
Submittal text:
Hilti hinge for seismic bracing with threaded rods, made of steel S275JR
according to DIN EN 10025-2, electro galvanized surface finish, typically
used to install seismic-resistant bracings made of threaded rods. The hinge
consists of two parts: a 6 mm steel base hinge with a 9.4 mm hole and a 3
mm steel connector for M10 threaded rods. The rod connector is provided
with a side opening for a post-installation of the seismic bracing made of
threaded rod. The hinge mechanism is secured with a M10x25 bolt class
8.8 and an M10 nut class 8. Material weight: 195 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Base hinge S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bracing connector DD11 - EN 10111 fy = 235 N/mm2 fu = 440 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x20 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation D
Design load
+ Fx - Fx
MQS-AB-8 9.4 mm 4.56 kN n.a.
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 13 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AB-8 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the rod connector MQS-AB-8 can efficiently be used for
the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 14 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AB-10 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-AB-10 seismic rod hinge 2083731
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
195 g
Submittal text:
Hilti hinge for seismic bracing with threaded rods, made of steel S275JR
according to DIN EN 10025-2, electro galvanized surface finish, typically
used to install seismic-resistant bracings made of threaded rods. The hinge
consists of two parts: a 6 mm steel base hinge with a 11.5 mm hole and a 3
mm steel connector for M10 threaded rods. The rod connector is provided
with a side opening for a post-installation of the seismic bracing made of
threaded rod. The hinge mechanism is secured with a M10x25 bolt class
8.8 and an M10 nut class 8. Material weight: 195 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Base hinge S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bracing connector DD11 - EN 10111 fy = 235 N/mm2 fu = 440 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x20 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation D
Design load
+ Fx - Fx
MQS-AB-10 11.5 mm 4.56 kN n.a.
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 15 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AB-10 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the rod connector MQS-AB-10 can efficiently be used for
the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 16 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AB-12 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-AB-12 seismic rod hinge 2083732
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
195 g
Submittal text:
Hilti hinge for seismic bracing with threaded rods, made of steel S275JR
according to DIN EN 10025-2, electro galvanized surface finish, typically
used to install seismic-resistant bracings made of threaded rods. The hinge
consists of two parts: a 6 mm steel base hinge with a 13.6 mm hole and a 3
mm steel connector for M10 threaded rods. The rod connector is provided
with a side opening for a post-installation of the seismic bracing made of
threaded rod. The hinge mechanism is secured with a M10x25 bolt class
8.8 and an M10 nut class 8. Material weight: 195 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Base hinge S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bracing connector DD11 - EN 10111 fy = 235 N/mm2 fu = 440 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x20 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation D
Design load
+ Fx - Fx
MQS-AB-12 13.6 mm 4.56 kN n.a.
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 17 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AB-12 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the rod connector MQS-AB-12 can efficiently be used for
the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 18 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AB-16 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-AB-16 seismic rod hinge 2083733
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
195 g
Submittal text:
Hilti hinge for seismic bracing with threaded rods, made of steel S275JR
according to DIN EN 10025-2, electro galvanized surface finish, typically
used to install seismic-resistant bracings made of threaded rods for big
diameter pipes, direct fixation on the pipe-ring flanges. The hinge consists
of two parts: a 6 mm steel base hinge with a 16.3 mm hole and a 3 mm
steel connector for M10 threaded rods. The rod connector is provided with a
side opening for a post-installation of the seismic bracing made of threaded
rod. The hinge mechanism is secured with a M10x25 bolt class 8.8 and an
M10 nut class 8. Material weight: 195 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Base hinge S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bracing connector DD11 - EN 10111 fy = 235 N/mm2 fu = 440 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x20 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation D
Design load
+ Fx - Fx
MQS-AB-16 16.3 mm 4.56 kN n.a.
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 19 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-AB-16 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the rod connector MQS-AB-16 can efficiently be used for
the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 20 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-H-8 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-H-8 seismic rod hinge 2083738
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
79 g
Submittal text:
Hilti hinge for seismic bracing with threaded rods, made of steel S275JR
according to DIN EN 10025-2, electro galvanized surface finish. Hinge
typically used for connection of the seismic-resistant bracing to vertical
threaded rods. The hinge consists of a U-clamp that can be slid onto an M8
threaded rod; the hinge mechanism is secured by a clevis pin 360° rotatable
with a M10 inner thread for the seismic bracing installation. Material weight:
195 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Bracing component S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Clevis pin 11SMnPb37+C -
EN 10277-3 fy = 305 N/mm2 fu = 370 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Designation D A
Design load
+ Fx - Fx
MQS-H-8 M8 8.3 mm 12.96 kN n.a.
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 21 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-H-8 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the rod connector MQS-H-8 can efficiently be used for
the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 22 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-H-10 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-H-10 seismic rod hinge 2083739
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
79 g
Submittal text:
Hilti hinge for seismic bracing with threaded rods, made of steel S275JR
according to DIN EN 10025-2, electro galvanized surface finish. Hinge
typically used for connection of the seismic-resistant bracing to vertical
threaded rods. The hinge consists of a U-clamp that can be slid onto an
M10 threaded rod; the hinge mechanism is secured by a clevis pin 360°
rotatable with a M10 inner thread for the seismic bracing installation.
Material weight: 195 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Bracing component S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Clevis pin 11SMnPb37+C -
EN 10277-3 fy = 305 N/mm2 fu = 370 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Designation D A
Design load
+ Fx - Fx
MQS-H-10 M10 10.3 mm 12.96 kN n.a.
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 23 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-H-10 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the rod connector MQS-H-10 can efficiently be used for
the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 24 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-H-12 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-H-12 seismic rod hinge 2083740
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
79 g
Submittal text:
Hilti hinge for seismic bracing with threaded rods, made of steel S275JR
according to DIN EN 10025-2, electro galvanized surface finish. Hinge
typically used for connection of the seismic-resistant bracing to vertical
threaded rods. The hinge consists of a U-clamp that can be slid onto an
M12 threaded rod; the hinge mechanism is secured by a clevis pin 360°
rotatable with a M10 inner thread for the seismic bracing installation.
Material weight: 195 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Bracing component S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Clevis pin 11SMnPb37+C -
EN 10277-3 fy = 305 N/mm2 fu = 370 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Designation D A
Design load
+ Fx - Fx
MQS-H-12 M12 12.3 mm 12.96 kN n.a.
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 25 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-H-12 seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the rod connector MQS-H-12 can efficiently be used for
the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 26 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-CH seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-CH seismic rod hinge 2083741
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
95 g
Submittal text:
Hilti hinge for seismic bracing with threaded rods, made of steel S275JR
according to DIN EN 10025-2, electro galvanized surface finish. Hinge
typically used for connection of the seismic-resistant bracing to the base
material. The hinge consists of a base component with a 11.5 mm hole for
the fixation to the base material; the hinge mechanism is secured by a
clevis pin 360° rotatable with a M10 inner thread for the installation of
seismic bracing made of M10 rod. Material weight: 95 g
Designation
Design load
+ Fx - Fx
MQS-CH 4.67 kN n.a.
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Base component S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Clevis pin 11SMnPb37+C -
EN 10277-3 fy = 305 N/mm2 fu = 370 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
MQS System – Technical Data
Page 27 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-CH seismic rod hinge
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the rod connector MQS-CH can efficiently be used for
the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 28 Installation Technical Manual – Product Line Technical Data – MQS System
MQ3D-AS seismic rod brace
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQ3D-AS seismic rod brace 2083742
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
73 g
Submittal text:
Hilti rod brace, seismic bracing with threaded rods, made of steel DD11
according to DIN EN 10111, 3 mm steel thickness, electro galvanized
surface finish, provided with a 10.5 mm hole, typically used for the fixation
to the base material or to the Hilti seismic angles MQS-W. The threaded rod
connection consists of a side opening for a post-installation of the seismic
bracing made of M10 rod. Material weight: 73 g
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Bracing connector DD11 - EN 10111 fy = 235 N/mm2 fu = 440 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Designation
Design load
+ Fx - Fx
MQ3D-AS 4.56 kN n.a.
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for α = 45°±15°
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 29 Installation Technical Manual – Product Line Technical Data – MQS System
MQ3D-AS seismic rod brace
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the rod connector MQ3D-AS can efficiently be used for
the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 30 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-W 41 seismic angle set
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-W 41 seismic angle set 2083735
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
396 g (including reinforcement bow, nuts and bolts)
Submittal text:
Hilti seismic 90° angle, MQ system, made of steel S275JR according to DIN
EN 10025-2, 4 mm steel with electro galvanized surface finish, provided
with 2 lateral wings with 10.5 mm, typically used for connection of two
perpendicular Hilti MQ channels and for installation of seismic-resistant
bracings. The angle is provided with a side steel fold and a clutch tooth for a
better locking mechanism with Hilti MQ channels (C profiles), fixation with
special fastening slot with butterfly shape holes. The angle is completed
with a omega-shape reinforcement for Hilti MQ-41 channels, fixed to the
angle wings through 2 screws M10x25 class 8.8 and 2 nuts M10 class 8 (all
included in the pack). Material weight: 396 g
2x 2x 1x 1x
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Angle S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bow S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x25 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation
Design load
+ F1 - F1
MQS-W 41 set 6.10 kN 6.10 kN
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for all angles.
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 31 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-W 41 seismic angle set
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the channel connector MQS-W41 can efficiently be used
for the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 32 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-W 72 seismic angle set
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-W 72 seismic angle set 2083736
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
450 g (including reinforcement bow, nuts and bolts)
Submittal text:
Hilti seismic 90° angle, MQ system, made of steel S275JR according to DIN
EN 10025-2, 4 mm steel with electro galvanized surface finish, provided
with 2 lateral wings with 10.5 mm, typically used for connection of two
perpendicular Hilti MQ channels and for installation of seismic-resistant
bracings. The angle is provided with a side steel fold and a clutch tooth for a
better locking mechanism with Hilti MQ channels (C profiles), fixation with
special fastening slot with butterfly shape holes. The angle is completed
with a omega-shape reinforcement for Hilti MQ-72 channels, fixed to the
angle wings through 2 screws M10x25 class 8.8 and 2 nuts M10 class 8 (all
included in the pack). Material weight: 450 g
2x 2x 1x 1x
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Angle S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bow S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x25 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation
Design load
+ F1 - F1
MQS-W 72 set 6.10 kN 6.10 kN
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for all angles.
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 33 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-W 72 seismic angle set
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the channel connector MQS-W72 can efficiently be used
for the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular seismic-
resistant support depends on the set up of the used components and its interaction with the base material.
Page 34 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-W 41D seismic angle set
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/2
Designation Item number
MQS-W 41D seismic angle set 2083737
Corrosion protection:
Galvanized according to DIN EN ISO 2081, zinc thickness 12 mm
Weight:
466 g (including reinforcement bow, nuts and bolts)
Submittal text:
Hilti seismic 90° angle, MQ system, made of steel S275JR according to DIN
EN 10025-2, 4 mm steel with electro galvanized surface finish, provided
with 2 lateral wings with 10.5 mm, typically used for connection of two
perpendicular Hilti MQ channels and for installation of seismic-resistant
bracings. The angle is provided with a side steel fold and a clutch tooth for a
better locking mechanism with Hilti MQ channels (C profiles), fixation with
special fastening slot with butterfly shape holes. The angle is completed
with a omega-shape reinforcement for Hilti MQ-41D channels, fixed to the
angle wings through 2 screws M10x25 class 8.8 and 2 nuts M10 class 8 (all
included in the pack). Material weight: 466 g
2x 2x 1x 1x
Material properties:
Component Material Yield strength Ultimate strength E-modulus Shear modulus
Angle S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Bow S275JR - EN 10025 fy = 275 N/mm2 fu = 410 N/mm2 E = 210000 N/mm2 G = 80769 N/mm2
Hexagonal screw M10x25 DIN 933 steel grade 8.8 | Hexagonal nut M10 DIN 934 class 8
Designation
Design load
+ F1 - F1
MQS-W 41D set 6.10 kN 6.10 kN
Shown load values are design values (FRd). The partial safety factor for the action is 1.0. Load values are valid for all angles.
Note: final load for a particular seismic support is depending on the set up of the used items!
MQS System – Technical Data
Page 35 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-W 41D seismic angle set
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 2/2
Design criteria used for loading capacity
Methodology:
• Finite Element Analysis (FEM)
• Hardware tests
Standards, codes:
• EN 1990 Basics of structural design 03.2003
• EN 1991-1-1 Eurocode 1: Actions on structures – Part 1-1: General actions– densities, self-weight, imposed loads
for buildings 09.2011
• EN 1993-1-1 Eurocode 3: Design of steel structures – Part 1-1: General rules and rules for buildings 03.2012
• EN 1993-1-3 Eurocode 3: Design of steel structures – Part 1-3: General rules- Supplementary rules for cold-
formed members and sheeting 03.2012
• EN 1993-1-5 Eurocode 3: Design of steel structures – Part 1-5: Plated structural elements 03.2012
• EN 1993-1-8 Eurocode 3: Design of steel structures – Part 1-8: Design of joints 03.2012
• EN 1998-1 Eurocode 8: Design of structure for earthquakes resistance – Part 1: General rules, seismic actions
and rules for buildings
Software:
• ANSYS® 15
• Mathcad Prime® 2.0
• SCIA-ESA Engineer® 2013.0.1036
Environmental conditions:
• No low (<-10°C) temperatures, no high (> 100°C) temperatures
• No fatigue loads
Test set up FEM Analysis Method
MQS System – Technical Data
Self weight
Live load
Action Resistance
Design load
Yield strength Design load
Capacity limit
1.35
1.5
Conclusions
The results of tests, combined with FEM analysis, show that the channel connector MQS-W41D can efficiently be
used for the installation of seismic-resistant bracings of non-structural elements. The final capacity for a particular
seismic-resistant support depends on the set up of the used components and its interaction with the base material.
Page 36 Installation Technical Manual – Product Line Technical Data – MQS System
MQS-RS rod stiffener
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
Data version: 2.0 | Date: 12.2015 | Page 1/1
Designation Item number
MQS-RS rod stiffener 311943
Corrosion protection:
Zinc chromate according to ASTM B633 SC1
Weight:
63 g
Submittal text:
Hilti rod stiffener, reinforcement element for threaded rod using Hilti MQ
channels, steel Q235 with heat treatment 25-35 HRC, galvanized according
to ASTM B633 SC1. The stiffener consists of a serrated squared nut and a
hexagonal screw, typically used to reinforce vertical threaded rods under
compression loads. Material weight: 63 g
Material properties:
Component Material
Serrated square nut Q235 cold rolled, HRC 25-35
Screw 3/8”-16 x 1-1/2” per AISI B18
MQS System – Technical Data
Page 37 Installation Technical Manual – Product Line Technical Data – MQS System
Boundary conditions - Terms of common cooperation / Legal disclaimer and guidelines as defined at the beginning of this book need to be mandatorily respected
MQS System – Technical Data
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Hilti. Outperform. Outlast.
Hilti Corporation | 9494 Schaan | Liechtenstein | P +423-234 2111 | www.hilti.com