CN111948026B - Steel plate local buckling test device with sliding block and test method thereof - Google Patents

Abstract

The invention discloses a steel plate local buckling test device with a sliding block and a test method thereof, wherein the test device comprises a pedestal, an axial loading assembly, a non-loading side constraint assembly and a unidirectional constraint assembly; the pedestal is provided with a plurality of axial grooves in a penetrating way along the axial direction, the unidirectional constraint assembly comprises a plurality of groups of threaded ejector rods, the number of the groups of threaded ejector rods is equal to that of the axial grooves, each group of threaded ejector rods comprises at least one threaded ejector rod, all the threaded ejector rods in each group of threaded ejector rods are correspondingly inserted into each axial groove, the threaded ejector rods are sleeved with a pressure sensor and a nut, the lower end face of the pressure sensor is abutted against the pedestal, the upper end face of the pressure sensor is abutted against the nut, and the top ends of the threaded ejector rods are abutted against a test piece steel plate; the non-loading limit restraint subassembly locates test piece steel sheet vertical axial's left and right sides respectively, and non-loading limit restraint subassembly includes fixing base and sliding block, is equipped with the sliding tray along the axial on the fixing base, and the sliding block embedding is in the sliding tray, and test piece steel sheet is connected with the sliding block.

Description

Steel plate local buckling test device with sliding block and test method thereof

Technical Field

The invention relates to the technical field of steel plate buckling test, in particular to a steel plate local buckling test device with a sliding block and a test method thereof.

Background

In recent years, along with the rapid expansion of social economy, a large number of high-rise and super high-rise buildings are emerging, and in these building structures, steel-concrete composite members such as pure steel plate shear walls, steel plate concrete composite shear walls, steel pipe concrete columns and the like are increasingly used. However, with the application of high-strength concrete and high-strength steel, the width-to-thickness ratio of the steel plates outside the members is also larger and larger, and the problem of local buckling of the steel plates is also highlighted gradually, so that the steel plates are paid attention to engineering personnel. In terms of cost economy, when a thin-wall combined member is adopted, the mechanical properties of materials of steel and concrete are required to be fully exerted, and the yield strength of the steel is required to be fully developed. In terms of structural safety, the occurrence of the problem of local buckling of the steel plate can lead to early damage of the component and even overall failure of the structure, and cause disasters. Therefore, under the common requirements of economy and safety, the research on the problem of local buckling of the steel plates with the combined structure is necessary. Only if the rules and modes of the local buckling of the steel plate are clarified, measures can be taken in a targeted manner to avoid or delay the occurrence of the local buckling of the steel plate. The method not only can produce good economic significance and adapt to the trend of the development of the times, but also has important significance for the development and application of the steel-concrete combined structure and the thin-wall steel structure in engineering.

At present, partial workers at home and abroad begin to conduct related researches on the local buckling performance of square, rectangular and other section steel tube concrete columns. However, the current research on the local buckling of the steel plate is not comprehensive, and most of the researches are in the finite element and theoretical research stages, so that research results cannot be compared and corrected with accurate test data. The reason is that there is no test device for systematically researching the local buckling of the steel plate at home and abroad. And a plurality of problems exist in the current test researches on the local buckling performance of the steel plate at the outer side of the steel tube concrete column. Such as: the loading design is unreasonable, loading end equipment cannot accurately and independently apply load to the steel plate, side constraint force generated by inner side concrete cannot be considered, boundary conditions cannot be accurately considered, current test research is based on specific components, and test results have no universal meaning and the like. These problems directly restrict the research progress of the local buckling performance of the steel structure and the combined structure.

Therefore, it is necessary to provide a steel plate buckling test loading device for the action between the steel plate and the concrete and the actual boundary condition of the steel plate.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, and provides a steel plate local buckling test device with a sliding block, which is used for researching the local buckling performance of the steel plate under the condition that a non-loading edge is a clamped boundary and under the condition of unidirectional constraint.

Another object of the invention is: the test method of the steel plate local buckling test device with the sliding block is provided.

The technical scheme of the invention is as follows: a steel plate local buckling test device with a sliding block is used for researching the local buckling performance of a test piece steel plate and comprises a pedestal, an axial loading assembly, a non-loading side constraint assembly and a unidirectional constraint assembly;

The pedestal is provided with a plurality of axial grooves in a penetrating way along the axial direction, the unidirectional constraint assembly comprises a plurality of groups of threaded ejector rods, the number of the groups of threaded ejector rods is equal to that of the axial grooves, each group of threaded ejector rods comprises at least one threaded ejector rod, all the threaded ejector rods in each group of threaded ejector rods are correspondingly inserted into each axial groove, the threaded ejector rods are sleeved with a pressure sensor and a nut, the lower end face of the pressure sensor is abutted against the pedestal, the upper end face of the pressure sensor is abutted against the nut, and the top ends of the threaded ejector rods are abutted against a test piece steel plate;

The axial loading assembly is respectively arranged at the front side and the rear side of the axial direction of the test piece steel plate, and comprises two clamping steel plates, a movable steel plate, a guide rail and a pushing mechanism, wherein the two clamping steel plates jointly clamp one axial end of the test piece steel plate and are fixed through bolts;

The non-loading limit restraint subassembly is located test piece steel sheet vertical axial's left and right sides respectively, and non-loading limit restraint subassembly includes fixing base and sliding block, fixing base and pedestal fixed connection, and the inside of fixing base is equipped with the sliding tray along the axial, and the trompil is seted up towards test piece steel sheet direction to the sliding tray, and the fixing base is equipped with the stopper at the upper and lower both ends of trompil, and the sliding block embedding sliding tray is in and with sliding tray sliding connection, and the stopper is used for limiting the sliding block and rotates from top to bottom, and test piece steel sheet vertical axial's both ends are connected with the sliding block respectively.

Further, the clamping steel plate is L-shaped, the clamping steel plate comprises clamping plates and fixing plates which are connected perpendicularly to each other, the clamping plates of the two clamping steel plates jointly clamp one axial end of the test piece steel plate and are fixed through bolts, and the fixing plates of the two clamping steel plates are fixed to the movable steel plate through bolts respectively.

Further, a first rib plate is arranged on the clamping steel plate, and two sides of the first rib plate are welded with the clamping plate and the fixing plate respectively. By arranging the first rib plate, the clamping steel plate is prevented from being deformed under stress in the axial loading process.

Further, the movable steel plate axially extends towards the pushing mechanism to form a sliding block, the sliding block is in sliding connection with the guide rail, a second rib plate is arranged between the sliding block and the movable steel plate, and two sides of the second rib plate are welded with the movable steel plate and the sliding block respectively.

Further, the pushing mechanism comprises a jack and a reaction frame, the reaction frame is fixed on the pedestal through bolts, the outer cylinder of the jack is fixed on the reaction frame, and the ejector rod of the jack is connected with the movable steel plate.

Further, the pedestal is provided with four column feet, four boss are formed by protruding the top surface of the pedestal, the four bosses are distributed on two sides of the vertical shaft of the plurality of axial grooves in two pairs, and two ends of the fixing seat are axially arranged on the two bosses.

Further, the fixing base is fixed with the boss through welding, and the test piece steel plate is fixed with the sliding block through welding.

Further, still include vertical spacing subassembly, vertical spacing subassembly includes slide bar and slide rail, and the slide rail is along axial installation in the pedestal top surface, and the bottom of slide bar is equipped with spacing slider along the axial, spacing slider and slide rail sliding connection are equipped with the screw thread on the slide bar, and the top of slide bar runs through test piece steel sheet, and the test piece steel sheet passes through the nut lock solid to the slide bar.

Further, the sliding groove and the sliding block are both T-shaped.

The other technical scheme of the invention is as follows: according to the test method of the steel plate local buckling test device with the sliding block, the pushing mechanism pushes the movable steel plate to move axially, and the movable steel plate moves axially to drive the clamping steel plate to move axially so as to provide axial loading force for the test piece steel plate; providing a vertical limiting assembly, enabling a sliding rod to penetrate through a test piece steel plate and be locked through a nut, and restraining the test piece steel plate in the area from outwards displacing in a plane so as to prevent the test piece steel plate from locally buckling; providing a plurality of threaded ejector rods, providing unidirectional constraint force for a test piece steel plate, changing the magnitude of the unidirectional constraint force by adjusting the tightness of nuts on the threaded ejector rods, so as to simulate the local buckling condition of the test piece steel plate under different unidirectional constraint forces, and adjusting the spacing between the threaded ejector rods to ensure that the spacing between the threaded ejector rods is from large to small so as to simulate the situation that the test piece steel plate is bulged towards an unconstrained direction in the loading process under unidirectional rigid constraint; and the non-loading edge constraint assembly is provided, and the sliding block is limited to rotate up and down through the limiting block so as to simulate the solid support boundary of the non-loading edge of the test piece steel plate.

Compared with the prior art, the invention has the following beneficial effects:

(1) The non-loading side constraint component is provided with a sliding groove and a sliding block, and the sliding block is limited to rotate up and down through a limiting block so as to simulate the solid support boundary of the non-loading side of the test piece steel plate.

(2) The axial loading assembly adopts the clamping steel plates to clamp the loading edges of the test piece steel plates, so that the loading condition of the solid support boundaries of the two loading edges of the test piece steel plates can be realized, the axial loading assembly restrains the displacement of the clamping steel plates through the guide rail, the clamping steel plates can only move along the axial direction, and the loading accuracy is ensured.

(3) Providing a plurality of threaded ejector rods, providing unidirectional constraint force for the test piece steel plate, wherein the threaded ejector rods can effectively simulate the action of concrete and the steel plate, and the distances among the plurality of threaded ejector rods are adjusted from large to small by adjusting the distances among the plurality of threaded ejector rods, so that the situation that the test piece steel plate is bulged towards an unconstrained direction in the loading process under unidirectional rigid constraint can be simulated; under the condition of the pressure sensor, the threaded ejector rod pushes the steel plate to simulate different unidirectional constraint forces, simulate the lateral expansion of concrete and simulate the local buckling condition of the steel plate with unidirectional stress.

(4) The steel plate local buckling test device with the sliding block can provide axial and lateral loading and non-loading end constraint conditions, can better simulate the stress conditions of the steel plate under different loading conditions and boundary conditions, can better simulate the local buckling process of the steel plate in the combined structure during loading, and provides reliable test results for theoretical research and application design.

(5) The vertical limiting assembly is provided, the sliding rod penetrates through the test piece steel plate and is locked through the nut, the sliding rod is axially flat along the sliding rail along with the limiting sliding block, a certain region of the test piece steel plate is fixed, the region of the test piece steel plate can only translate along the axial direction, out-of-plane displacement of the test piece steel plate in the region is restrained, and local buckling of the region of the test piece steel plate is prevented.

Drawings

FIG. 1 is a schematic diagram of the assembly of a test device of the present invention with a test piece steel plate.

FIG. 2 is a schematic structural view of the test device of the present invention.

FIG. 3 is a front view of the test device of the present invention.

FIG. 4 is a partial top view of the test device of the present invention.

Fig. 5 is a cross-sectional view taken along line A-A of fig. 4.

Fig. 6 is a cross-sectional view taken along line B-B of fig. 4.

Fig. 7 is a cross-sectional view of fig. 4 taken along line C-C.

Fig. 8 is a cross-sectional view of fig. 4 taken along line D-D.

Fig. 9 is a schematic structural view of the one-way restraint assembly of the present invention.

Fig. 10 is a schematic structural view of the vertical limiting assembly of the present invention.

FIG. 11 is a schematic diagram of a non-load side constraint assembly of the present invention.

Test piece steel plate 100, pedestal 1, axial groove 2, column foot 3, boss 4, screw ejector 5, pressure sensor 6, nut 7, movable steel plate 8, guide rail 9, grip block 10, fixed plate 11, first floor 12, slider 13, second floor 14, fixing base 15, sliding block 16, sliding groove 17, stopper 18, jack 19, reaction frame 20, slide bar 21, slide rail 22, spacing slider 23.

Detailed Description

The present invention will be described in further detail with reference to examples, but embodiments of the present invention are not limited thereto.

Examples

As shown in fig. 1 and 2, the present embodiment provides a steel plate local buckling test device with a slider, which is used for researching local buckling performance of a test piece steel plate 100, and includes a pedestal 1, an axial loading assembly, a non-loading edge constraint assembly, a unidirectional constraint assembly and a vertical limiting assembly.

As shown in fig. 2 and 3, a plurality of axial grooves 2 are formed in the pedestal in a penetrating manner along the axial direction, four column bases 3 are arranged on the bench, the four column bases protrude out of the top surface of the bench to form four bosses 4, and the four bosses are distributed on two sides of the plurality of axial grooves in the vertical axial direction.

As shown in fig. 2, fig. 5 and fig. 9, the unidirectional restraint subassembly includes multiunit screw ejector pin 5, the group number of screw ejector pin equals with the quantity of axial groove, and contain at least one screw ejector pin in every screw ejector pin of group, all screw ejector pins in every screw ejector pin of group insert every axial groove correspondingly, pressure sensor and nut have all been cup jointed to the screw ejector pin, and pressure sensor's lower terminal surface butt pedestal, pressure sensor's up end butt nut, the equal butt test piece steel sheet in top of screw ejector pin is used for providing unidirectional restraint force, pressure sensor and external electronic equipment electric connection, elasticity between adjusting nut and the screw ejector pin is passed through to the nut oppression pressure sensor applys a counter-force for the screw ejector pin, this counter-force is the unidirectional restraint force that the screw ejector pin applyed in the test piece steel sheet.

As shown in fig. 6 and 10, the vertical limiting assembly comprises a sliding rod 21 and a sliding rail 22, the sliding rail is axially arranged on the top surface of the pedestal, a limiting sliding block 23 is axially arranged at the bottom of the sliding rod and is in sliding connection with the sliding rail, threads are arranged on the sliding rod, the top of the sliding rod penetrates through a test piece steel plate, and the test piece steel plate is locked to the sliding rod through a nut. And fixing a certain region of the test piece steel plate, so that the region of the test piece steel plate can only translate along the axial direction, the out-of-plane displacement of the test piece steel plate in the region is restrained, and the region of the test piece steel plate is prevented from local buckling.

As shown in fig. 2, fig. 4 and fig. 8, the axial loading assembly is respectively arranged at the front side and the rear side of the axial direction of the test piece steel plate, the axial loading assembly comprises two clamping steel plates, a movable steel plate 8, a guide rail 9 and a pushing mechanism, the two clamping steel plates are used for jointly clamping one axial end of the test piece steel plate and are fixed through bolts, one end of each clamping steel plate is connected with the movable steel plate, the guide rail is axially arranged on the top surface of the test bed seat, the movable steel plate is slidably connected with the guide rail, the pushing mechanism is arranged on the test bed seat, the pushing mechanism is used for pushing the movable steel plate to axially slide along the guide rail, in this embodiment, the clamping steel plates are in an L shape, each clamping steel plate comprises a clamping plate 10 and a fixing plate 11 which are mutually perpendicular and are connected, the clamping plates of the two clamping steel plates are jointly clamped at one axial end of the test piece steel plate and are fixed through bolts, the fixing plates of the two clamping steel plates are respectively fixed to the movable steel plate through bolts, a first rib plate 12 is arranged on each clamping steel plate, and two sides of the first rib plates are welded with the clamping plates respectively, and the first rib plates are arranged to avoid stress deformation of the clamping steel plates in the axial loading process. The movable steel plate axially extends towards the pushing mechanism to form a sliding block 13, the sliding block is in sliding connection with the guide rail, a second rib plate 14 is arranged between the sliding block and the movable steel plate, two sides of the second rib plate are respectively welded with the movable steel plate and the sliding block, and the movable steel plate is restrained by the guide rail to displace, so that the clamping steel plate can only axially move, and the loading accuracy is ensured; the pushing mechanism comprises a jack 19 and a reaction frame 20, wherein the reaction frame is L-shaped, the reaction frame is fixed on the pedestal through bolts, the outer cylinder of the jack is fixed on the reaction frame, and the ejector rod of the jack is connected with the movable steel plate.

As shown in fig. 6, 7 and 11, the non-loading limit restraining component is respectively arranged at the left side and the right side of the vertical axial direction of the test piece steel plate, the non-loading limit restraining component comprises a fixing seat 15 and a sliding block 16, two ends of the fixing seat are axially welded on two bosses, a sliding groove 17 is axially arranged in the fixing seat, a hole is formed in the sliding groove towards the direction of the test piece steel plate, limiting blocks 18 are arranged at the upper end and the lower end of the hole of the fixing seat, the sliding block is embedded into the sliding groove and is in sliding connection with the sliding groove, the limiting blocks are used for limiting the sliding block to vertically rotate, and two ends of the vertical axial direction of the test piece steel plate are respectively welded with the sliding block. In this embodiment, both the sliding groove and the sliding block are T-shaped.

According to the test method of the steel plate local buckling test device with the sliding block, the pushing mechanism pushes the movable steel plate to move axially, and the movable steel plate moves axially to drive the clamping steel plate to move axially so as to provide axial loading force for the test piece steel plate; providing a vertical limiting assembly, enabling a sliding rod to penetrate through a test piece steel plate and be locked through a nut, and restraining the test piece steel plate in the area from outwards displacing in a plane so as to prevent the test piece steel plate from locally buckling; providing a plurality of threaded ejector rods, providing unidirectional constraint force for a test piece steel plate, checking the stress of a pressure sensor through external electronic equipment, changing the unidirectional constraint force by adjusting the tightness of nuts on the threaded ejector rods, so as to simulate the local buckling condition of the test piece steel plate under different unidirectional constraint forces, and adjusting the spacing between the threaded ejector rods to ensure that the spacing between the threaded ejector rods is from large to small so as to simulate the situation that the test piece steel plate is bulged towards an unconstrained direction in the loading process under unidirectional rigid constraint; and the non-loading edge constraint assembly is provided, and the sliding block is limited to rotate up and down through the limiting block so as to simulate the solid support boundary of the non-loading edge of the test piece steel plate.

As described above, the present invention can be better realized, and the above-described embodiments are only preferred embodiments of the present invention, and are not intended to limit the scope of the present invention; all equivalent changes and modifications are intended to be covered by the scope of the appended claims.

Claims (6)

1. The steel plate local buckling test device with the sliding block is used for researching the local buckling performance of a test piece steel plate and is characterized by comprising a pedestal, an axial loading assembly, a non-loading side constraint assembly, a unidirectional constraint assembly and a vertical limiting assembly;

The pedestal is provided with a plurality of axial grooves in a penetrating way along the axial direction, the unidirectional constraint assembly comprises a plurality of groups of threaded ejector rods, the number of the groups of threaded ejector rods is equal to that of the axial grooves, each group of threaded ejector rods comprises at least one threaded ejector rod, all the threaded ejector rods in each group of threaded ejector rods are correspondingly inserted into each axial groove, the threaded ejector rods are sleeved with a pressure sensor and a nut, the lower end face of the pressure sensor is abutted against the pedestal, the upper end face of the pressure sensor is abutted against the nut, and the top ends of the threaded ejector rods are abutted against a test piece steel plate;

The axial loading assembly is respectively arranged at the front side and the rear side of the axial direction of the test piece steel plate, and comprises two clamping steel plates, a movable steel plate, a guide rail and a pushing mechanism, wherein the two clamping steel plates jointly clamp one axial end of the test piece steel plate and are fixed through bolts;

The non-loading side constraint assembly is respectively arranged at the left side and the right side of the vertical axis of the test piece steel plate, the non-loading side constraint assembly comprises a fixed seat and a sliding block, the fixed seat is fixedly connected with the pedestal, a sliding groove is arranged in the fixed seat along the axial direction, the sliding groove is provided with an opening towards the direction of the test piece steel plate, the fixed seat is provided with limiting blocks at the upper end and the lower end of the opening, the sliding block is embedded into the sliding groove and is in sliding connection with the sliding groove, the limiting blocks are used for limiting the sliding block to rotate up and down, and the two ends of the vertical axis of the test piece steel plate are respectively connected with the sliding block;

The clamping steel plates are L-shaped and comprise clamping plates and fixing plates which are mutually and perpendicularly connected, the clamping plates of the two clamping steel plates jointly clamp one axial end of the test piece steel plate and are fixed through bolts, and the fixing plates of the two clamping steel plates are respectively fixed to the movable steel plate through bolts;

The movable steel plate axially extends towards the pushing mechanism to form a sliding block, the sliding block is in sliding connection with the guide rail, a second rib plate is arranged between the sliding block and the movable steel plate, and two sides of the second rib plate are respectively welded with the movable steel plate and the sliding block;

The vertical limiting assembly comprises a sliding rod and a sliding rail, the sliding rail is axially arranged on the top surface of the pedestal, a limiting sliding block is axially arranged at the bottom of the sliding rod and is in sliding connection with the sliding rail, threads are arranged on the sliding rod, the top of the sliding rod penetrates through a test piece steel plate, and the test piece steel plate is locked to the sliding rod through a nut;

the sliding groove and the sliding block are both T-shaped.

2. The device for testing the local buckling of the steel plate with the sliding block according to claim 1, wherein the clamping steel plate is provided with a first rib plate, and two sides of the first rib plate are welded with the clamping plate and the fixing plate respectively.

3. The device for testing the local buckling of the steel plate with the sliding block according to claim 1, wherein the pushing mechanism comprises a jack and a reaction frame, the reaction frame is fixed on the pedestal through bolts, the outer cylinder of the jack is fixed on the reaction frame, and the ejector rod of the jack is connected with the movable steel plate.

4. The device for testing the local buckling of the steel plate with the sliding block according to claim 1, wherein the pedestal is provided with four column feet, four boss are formed by protruding out of the top surface of the pedestal, the four bosses are distributed on two sides of the plurality of axial grooves in the vertical axial direction, and two ends of the fixing seat are axially arranged on the two bosses.

5. The device for testing the local buckling of the steel plate with the sliding block according to claim 4, wherein the fixing base and the boss are fixed through welding, and the test piece steel plate and the sliding block are fixed through welding.

6. A test method based on the steel plate local buckling test device with the sliding block according to any one of claims 1-5, which is characterized in that a pushing mechanism is used for pushing a movable steel plate to move axially, and the movable steel plate moves axially to drive a clamping steel plate to move axially so as to provide axial loading force for a test piece steel plate;

Providing a plurality of threaded ejector rods, providing unidirectional constraint force for a test piece steel plate, changing the magnitude of the unidirectional constraint force by adjusting the tightness of nuts on the threaded ejector rods, so as to simulate the local buckling condition of the test piece steel plate under different unidirectional constraint forces, and adjusting the spacing between the threaded ejector rods to ensure that the spacing between the threaded ejector rods is from large to small so as to simulate the situation that the test piece steel plate is bulged towards an unconstrained direction in the loading process under unidirectional rigid constraint;

And the non-loading edge constraint assembly is provided, and the sliding block is limited to rotate up and down through the limiting block so as to simulate the solid support boundary of the non-loading edge of the test piece steel plate.