Appendix A
To ensure the seismic performance of steel structures joined using vises, it is important to confirm that the vises are not damaged from practical use. The mechanical performance of the vises was investigated using FEM analysis in Marc software. The dimensions of the vise are shown in
Figure A1, and
Table A1,
Table A2 and
Table A3 summarize the chemical composition and mechanical properties of the vise.
Figure A1.
Dimensions of vise with high-hardness screw bolt.
Figure A1.
Dimensions of vise with high-hardness screw bolt.
Table A1.
Chemical composition of vise (%).
Table A1.
Chemical composition of vise (%).
| C | Si | Mn | P | S | Cu | Ni | Cr | Mo |
---|
Standard (%) | 0.37~ | 0.15~ | 0.55~ | ≤0.03 | ≤0.03 | ≤0.30 | ≤0.25 | 0.85~ | 0.15~ |
0.44 | 0.35 | 0.95 | 1.25 | 0.35 |
Measured (%) | 0.41 | 0.26 | 0.7 | 0.019 | 0.015 | 0.11 | 0.08 | 1.11 | 0.17 |
Table A2.
Chemical composition of bolt (%).
Table A2.
Chemical composition of bolt (%).
| C | Si | Mn | P | S | Cu | Ni | Cr | Mo |
---|
Standard (%) | 0.37~ | 0.15~ | 0.55~ | ≤0.03 | ≤0.03 | ≤0.30 | ≤0.25 | 0.85~ | 0.15~ |
0.44 | 0.35 | 0.95 | 1.25 | 0.35 |
Measured (%) | 0.42 | 0.29 | 0.8 | 0.023 | 0.014 | 0.1 | 0.06 | 1.01 | 0.18 |
Table A3.
Mechanical properties (JIS standard: reference value).
Table A3.
Mechanical properties (JIS standard: reference value).
Spec | Tensile Test (No. 4 Test Piece) | Hardness Test |
---|
SCM440 | σy (N/mm2) | σu (N/mm2) | Elongation (%) | Contraction (%) | Hardness (HB) |
834 | 980.7 | 12 more | 45 more | 285~352 |
There are two different loadings of the analysis, as shown in
Figure A2. A force corresponding to shearing deformation, shown in
Figure A2 (a), is applied if slipping occurs between the two steel plates. A force corresponding to tensile deformation, shown in
Figure A2 (b), is applied when the axial force of the bolt is introduced by a torque wrench. Under these loading conditions, the stress state and load versus deformation relationships are discussed through numerical analysis.
Figure A2.
Applied forces to vise: (a) slipping force; (b) axial force.
Figure A2.
Applied forces to vise: (a) slipping force; (b) axial force.
The main body of the vise is analyzed by a mesh model with 10 nodes of solid elements, as shown in
Figure A3. As shown in
Figure A4, analytical supports are set at the top and bottom of the open part of the C shape of the vise. The four points at the bottom of the open part are fixed by pin supports. A horizontal sliding support is applied in the analysis of (a), and a vertical sliding support is applied in the analysis of (b). When the displacements are applied at the top of the vise, the reaction and relative displacements are obtained in each direction. The von Mises yield condition is used. The stress–strain model is defined as a bilinear elastoplastic model in
Figure A5, and the material properties are listed in
Table A4. The strain-hardening coefficient is the inclination of the line between the yielding point and the tensile strength corresponding to a strain of 20%. The relationship between true stress and logarithmic strain is applied to the analysis.
Figure A3.
Boundary condition and direction of applied force in FEM mesh model of vise.
Figure A3.
Boundary condition and direction of applied force in FEM mesh model of vise.
Figure A4.
Boundary condition and direction of force in vises: (a) slipping force; (b) axial force.
Figure A4.
Boundary condition and direction of force in vises: (a) slipping force; (b) axial force.
Figure A5.
Bilinear stress–strain model.
Figure A5.
Bilinear stress–strain model.
Table A4.
Constants in the material model.
Table A4.
Constants in the material model.
σy (N/mm2) | σu (N/mm2) | εt (%) |
---|
834 | 980.7 | 20 |
Figure A6 presents the load–displacement relationship in the direction of (a). In the figure, softening behavior is observed at approximately 30 kN; however, after that, the strength increases almost linearly up to 80 kN. After the steel plates joined by the vises start to slip, the bolt sustains a horizontal force. In this case, the main body of the vise, which provides twisting deformation, is subjected to the shearing force shown in
Figure A2 (a) and
Figure A4 (a).
Figure A6.
Load–displacement relationship under force applied in direction of (a).
Figure A6.
Load–displacement relationship under force applied in direction of (a).
In the study of the vise itself, an allowable force of shear is set as 75 kN per vise. The force of the screw bolt of the vise in the direction orthogonal to the bolt was defined as the “digging strength”, which was described in a study conducted by Uno [
22]. The digging strength corresponds to the axial force of the bolts of 75 kN, since the shape of the bolthead is triangular at 45-90-45.
As shown in
Figure A6, even when the shearing force reaches 75 kN, the vise maintains its strength.
Figure A7 presents a contour diagram of von Mises stress at a displacement of 4 mm in case (a). In the figure, some parts of the vise are yielding; however, the stresses in most parts remain elastic. This indicates that no practical problems arise when using a vise for seismic retrofitting.
Figure A7.
Contour diagram of von Mises stress at a displacement of 4 mm in case of (a).
Figure A7.
Contour diagram of von Mises stress at a displacement of 4 mm in case of (a).
Figure A8 shows the load–displacement relationship in the direction of (b). The opening deformation of the vice is caused by a reaction from the axial force of the screw bolts introduced from a torque wrench. In the figure, the opening force remains elastic up to 200 kN. Thus, an allowable axial force of the bolt is set as 200 kN. This is shown by the solid red line in
Figure A8. Since the compressive force introduced into the bolt is 75 kN (red dotted line in
Figure A8) during normal use of the vise, there is a sufficient margin in terms of strength.
Figure A8.
Load–displacement relationship under force applied in direction of (b).
Figure A8.
Load–displacement relationship under force applied in direction of (b).
Figure A9 shows a contour diagram of the von Mises stress at a displacement of 2 mm in case (b). In this figure, the yielding parts are displayed along the inside of the vise; however, the stresses of the other parts remain under yielding stress at a load of 200 kN. The applied load is 75 kN under normal use. Even if a double load is applied, the vise retains its connecting performance.
Figure A9.
Contour diagram of von Mises stress at a displacement of 2 mm in the case of (b).
Figure A9.
Contour diagram of von Mises stress at a displacement of 2 mm in the case of (b).