CN220565293U - Foundation anti-pulling bearing performance detection device - Google Patents

Abstract

The utility model provides a foundation anti-pulling bearing performance detection device, belongs to the technical field of construction engineering, and aims to solve the problem that the detection cost is high because a plurality of groups of connecting rods are required to be replaced after the detection of the existing detection device is completed, and the detection device comprises a supporting transverse plate, a bottom connecting plate, a connecting flange plate, a traction connecting plate, a connecting plug, a traction connecting block, a welding block stabilizing mechanism and a welding block alignment mechanism; the bottom connecting plate is fixedly connected to the lower end face of the supporting transverse plate; the connecting flange plate is fixedly connected to the lower end face of the bottom connecting plate; the traction connecting disc screw is connected to the lower end surface of the connecting flange disc; the connecting plug block is fixedly connected to the upper end face of the traction connecting disc; the traction connecting block is connected in an inserting way in the traction connecting disc; the welding block stabilizing mechanism is arranged in the connecting plug block; the welding block alignment mechanism is arranged on the traction connecting block. The welding block stabilizing mechanism is adopted, the traction connecting block is guaranteed to be fixed on the connecting plug block, and the welding block aligning mechanism is adopted, so that the even stress of the foundation frame is guaranteed.

Description

Foundation anti-pulling bearing performance detection device

Technical Field

The utility model belongs to the technical field of construction engineering, and particularly relates to a foundation anti-pulling bearing performance detection device.

Background

The pull-out resistance of a building structure is required to be considered when building a building underground or offshore, so that a foundation needs to be built when building the building, and after the foundation is built, the pull-out resistance of the foundation needs to be detected by using a detection device for the pull-out resistance bearing performance.

According to CN202122877322.2, the utility model discloses foundation anti-poking bearing performance detection equipment, which comprises a supporting plate, wherein a hydraulic cylinder is arranged at the top of the supporting plate, a drawing assembly is arranged at the top of the hydraulic cylinder, the drawing assembly comprises a fixed plate and a fixed assembly, the fixed assembly is detachably connected to one side of the fixed plate, the fixed plate is connected with a bearing plate through the fixed assembly, and a first connecting column is fixedly arranged at the bottom of the bearing plate; the limiting block of the traction rod penetrates through the rectangular hole of the fixed column, the traction rod is rotated, the limiting block is crossed with the rectangular hole, the traction rod and the pulling disc are detachably connected, the traction rod is pushed downwards and rotated, the traction rod is separated from the pulling disc, welding spots on the traction rod are polished and removed conveniently, and the traction rod is used repeatedly.

Based on the above, the existing detection device generally detects the anti-pulling performance through welding the multiple groups of connecting rods and the foundation frame together, after detection is completed, the connecting rods are cut off, when the multiple groups of connecting rods are different in length after being cut, when the detection device is used for the second time for detection, the foundation frame is easily stressed unevenly due to the fact that the multiple groups of connecting rods are different in length, the quality of detection is affected, and the multiple groups of connecting rods are replaced, so that the detection cost is high.

Disclosure of Invention

In order to solve the technical problems, the utility model provides a foundation anti-pulling bearing performance detection device, which aims to solve the problems that the existing detection device generally detects the anti-pulling performance through welding a plurality of groups of connecting rods and foundation frames together, after detection is completed, the connecting rods are cut off, when the lengths of the groups of connecting rods after the cutting are different, and when the detection device is used for the second time for detection, the foundation frames are easily stressed unevenly due to the fact that the lengths of the groups of connecting rods are different, the quality of detection is affected, and the detection cost is high due to the fact that the groups of connecting rods are replaced.

The utility model discloses a foundation anti-pulling bearing performance detection device, which is characterized by comprising the following specific technical means:

a foundation anti-pulling bearing performance detection device comprises a supporting transverse plate, a connecting hydraulic cylinder, a drawing assembly, a bottom connecting plate, a connecting flange plate, a traction connecting plate, a connecting plug, a traction connecting block, a welding block stabilizing mechanism and a welding block alignment mechanism; the connecting hydraulic cylinders are provided with a plurality of groups, and the groups of connecting hydraulic cylinders are respectively and fixedly connected to the upper end surfaces of the supporting transverse plates; the drawing assembly is fixedly connected to a plurality of groups of telescopic rods connected with the hydraulic cylinders; the bottom connecting plate is fixedly connected to the lower end face of the supporting transverse plate; the connecting flange plate is fixedly connected to the lower end face of the bottom connecting plate; the traction connecting disc screw is connected to the lower end surface of the connecting flange disc; the connecting plug blocks are provided with a plurality of groups, and the connecting plug blocks are respectively and fixedly connected to the upper end surface of the traction connecting disc; the traction connecting block is connected in an inserting way to the traction connecting disc and the inside of the traction connecting disc; the welding block stabilizing mechanisms are provided with a plurality of groups, and the welding block stabilizing mechanisms are respectively arranged in the connecting plug blocks; the welding block alignment mechanisms are provided with a plurality of groups, and the welding block alignment mechanisms are respectively arranged on the plurality of groups of traction connecting blocks.

Further, the welding block stabilizing mechanism comprises: a stabilizing slot and a top insert; the stable slot is arranged on the upper end surface of the connecting plug; the top insert block is fixedly connected to the upper end face of the traction connecting block, and the stable slot is in plug-in connection with the top insert block.

Further, the solder bump stabilizing mechanism further comprises: a fixed slot and a stable insert block; the fixed slot is arranged in the middle of the outer end surface of the traction connecting block; the stable plug block is connected to the outer side of the inner portion of the connecting plug block in a sliding mode, and the fixed slot is connected with the stable plug block in a plug-in mode.

Further, the solder bump stabilizing mechanism further comprises: a stabilizing slider and a stabilizing spring; the two groups of the stable sliding blocks are respectively and fixedly connected to the stable inserting blocks; the stabilizing springs are provided with two groups, the two groups of stabilizing springs are respectively and fixedly connected inside the connecting plug, and the two groups of stabilizing springs are respectively and elastically connected with the two groups of stabilizing sliding blocks.

Further, the welding block alignment mechanism comprises: the traction inner slide block, the traction welding block and the inner slide cavity; the traction inner sliding block is fixedly connected to the lower end face of the traction connecting block; the traction welding block slides on the lower side of the traction connecting block; the inner sliding cavity is formed in the upper side of the inner portion of the traction welding block, and the traction inner sliding block is connected in a sliding mode in the inner sliding cavity.

Further, the solder bump alignment mechanism further comprises: an internal spring; the inner spring is fixedly connected with the inner lower end face of the inner sliding cavity, and the inner spring is elastically connected with the lower end face of the traction inner sliding block.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, by adopting the welding block stabilizing mechanism, the top inserting block is inserted into the stable inserting groove when the traction connecting block is inserted into the connecting inserting block, the top inserting block is clamped by the stable inserting groove, the traction connecting block is prevented from rotating at an angle, the traction connecting block is prevented from falling off the connecting inserting block due to rotation of the traction connecting block, the top inserting block is clamped in the stable inserting groove, the stable inserting block is inserted into the fixed inserting groove, and the traction connecting block is ensured to be fixed on the connecting inserting block.

The utility model adopts the welding block alignment mechanism to realize that when the traction connecting block is fixed on the connecting plug, a plurality of groups of traction welding blocks are welded and connected with the foundation frame, the traction welding blocks slide on the lower side of the traction connecting block, a plurality of groups of traction welding blocks are aligned with the foundation frame uniformly, when the long traction welding blocks slide on the lower side of the traction connecting block, the lengths of the plurality of groups of traction welding blocks are the same, the traction welding blocks are welded with the foundation frame together, the stress uniformity of the foundation frame is ensured when the foundation frame tests the anti-pulling performance, and the test quality is improved.

Drawings

Fig. 1 is a schematic structural diagram of the pull-out resistance detection device of the present utility model.

Fig. 2 is a schematic view of the structure of the traction sheave of the present utility model.

Fig. 3 is a schematic view of the structure of the traction link of the present utility model.

Fig. 4 is a schematic diagram showing the structure of the solder bump stabilizing mechanism according to the present utility model when the solder bump stabilizing mechanism is inserted.

FIG. 5 is a schematic view of a solder bump stabilizing mechanism according to the present utility model.

Fig. 6 is a schematic structural view of the solder bump alignment mechanism of the present utility model.

In the figure, the correspondence between the component names and the drawing numbers is:

1. a supporting cross plate; 2. connecting a hydraulic cylinder; 3. a drawing assembly; 4. a bottom connecting plate; 5. a connecting flange plate; 6. traction connection plate; 7. connecting the plug blocks; 701. a stable slot; 8. traction connection blocks; 801. a top plug; 802. a fixed slot; 803. traction of the inner slide; 9. stabilizing the insert block; 901. stabilizing the sliding block; 10. a stabilizing spring; 11. traction welding blocks; 1101. an internal sliding chamber; 12. an internal spring.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples.

Embodiment one:

as shown in fig. 1 to 5:

the utility model provides a foundation anti-pulling bearing performance detection device which comprises a supporting transverse plate 1, a connecting hydraulic cylinder 2, a drawing assembly 3, a bottom connecting plate 4, a connecting flange 5, a traction connecting plate 6, a connecting plug 7, a traction connecting block 8 and a welding block stabilizing mechanism, wherein the connecting flange is arranged on the bottom of the supporting transverse plate; the connecting hydraulic cylinders 2 are provided with a plurality of groups, and the plurality of groups of connecting hydraulic cylinders 2 are respectively and fixedly connected to the upper end face of the supporting transverse plate 1; the drawing assembly 3 is fixedly connected to the telescopic rods of the plurality of groups of connecting hydraulic cylinders 2; the bottom connecting plate 4 is fixedly connected to the lower end surface of the supporting transverse plate 1; the connecting flange plate 5 is fixedly connected to the lower end surface of the bottom connecting plate 4; the traction connecting disc 6 is connected with the lower end surface of the connecting flange disc 5 by screws; the connecting plug blocks 7 are provided with a plurality of groups, and the connecting plug blocks 7 are respectively and fixedly connected with the upper end face of the traction connecting disc 6; the traction connecting block 8 is connected in an inserting way to the traction connecting disc 6 and the inside of the traction connecting disc 6; the welding block stabilizing mechanisms are provided with a plurality of groups, and the welding block stabilizing mechanisms are respectively arranged inside the connecting plug blocks 7.

Wherein, welding piece stabilizing mean includes: a stabilizing socket 701 and top plug 801; the stabilizing slot 701 is arranged on the upper end surface of the connecting plug 7; top inserted block 801 fixed connection is in the pulling even piece 8 up end, and firm slot 701 and top inserted block 801 are pegged graft and are connected, in the use, pulls even piece 8 and drives top inserted block 801 and remove, and top inserted block 801 removes firm slot 701 position department, inside the inside firm slot 701 of connection inserted block 7 was inserted to top inserted block 801.

Wherein, welding piece stabilizing mean still includes: a fixed socket 802 and a stable socket 9; the fixed slot 802 is arranged in the middle of the outer end surface of the traction connecting block 8; firm inserted block 9 sliding connection is in the inside outside of connecting inserted block 7, and fixed slot 802 and firm inserted block 9 are pegged graft and are connected, and in the use, draw and connect piece 8 inside inserting connecting inserted block 7, draw and connect piece 8 drive fixed slot 802 and remove inside the firm slot 701, and firm inserted block 9 inserts inside the fixed slot 802.

Wherein, welding piece stabilizing mean still includes: a stabilizing slider 901 and a stabilizing spring 10; the two groups of stable sliding blocks 901 are arranged in total, and the two groups of stable sliding blocks 901 are fixedly connected to the stable inserting blocks 9 respectively; the firm spring 10 is provided with two sets of altogether, and two sets of firm springs 10 are fixed connection respectively inside connecting the inserted block 7, and two sets of firm springs 10 respectively with two sets of firm slider 901 elastic connection, in the use, firm slider 901 slides in the drive of firm spring 10, and firm slider 901 slides and drives firm inserted block 9 and slide, and firm inserted block 9 slides and inserts inside fixed slot 802.

Specific use and action of the first embodiment:

in the use, draw even piece 8 and drive top inserted block 801 and remove, top inserted block 801 removes the firm slot 701 position department, inside the inside firm slot 701 of inserted connection inserted block 7 was inserted to top inserted block 801, draw even piece 8 and drive fixed slot 802 and remove inside firm slot 701, firm inserted block 9 inserts fixed slot 802 inside, firm spring 10 drives firm slider 901 and slides, firm slider 901 slides and drives firm inserted block 9 and slide, firm inserted block 9 slides and inserts fixed slot 802 inside, realize guaranteeing to draw even piece 8 at the inside stability of connected inserted block 7.

Embodiment two:

on the basis of the first embodiment, as shown in fig. 6:

the welding block alignment mechanism is provided with a plurality of groups, the welding block alignment mechanisms are respectively arranged on the plurality of groups of traction connecting blocks 8, and the welding block alignment mechanism comprises: a traction inner slide 803, a traction weld 11, and an inner slide chamber 1101; the traction inner slide 803 is fixedly connected to the lower end face of the traction connecting block 8; the traction welding block 11 slides on the lower side of the traction connecting block 8; the inside of the inner sliding cavity 1101 is arranged on the upper side of the inside of the traction welding block 11, the traction inner sliding block 803 is connected inside the inner sliding cavity 1101 in a sliding mode, in the use process, the traction welding block 11 slides below the traction connecting block 8, the traction welding block 11 slides to drive the traction inner sliding block 803 to slide, and the traction inner sliding block 803 slides inside the inner sliding cavity 1101.

Wherein, the welding piece alignment mechanism still includes: an internal spring 12; the inner spring 12 is fixedly connected to the lower end face inside the inner sliding cavity 1101, the inner spring 12 is elastically connected to the lower end face of the traction inner sliding block 803, and in the use process, the traction inner sliding block 803 slides inside the inner sliding cavity 1101 to drive the inner spring 12 to stretch.

Specific use and action of the second embodiment:

during the use, the traction welding block 11 slides under the traction connecting block 8, the traction welding block 11 slides to drive the traction sliding block 803 to slide, the traction sliding block 803 slides in the inner sliding cavity 1101 to drive the inner spring 12 to stretch and retract, and the alignment of a plurality of groups of traction welding blocks 11 is ensured.

Claims (6)

1. The utility model provides a foundation resistance to plucking bearing performance detection device which characterized in that: the device comprises a supporting transverse plate (1), a connecting hydraulic cylinder (2), a drawing assembly (3), a bottom connecting plate (4), a connecting flange plate (5), a traction connecting plate (6), a connecting plug (7), a traction connecting block (8), a welding block stabilizing mechanism and a welding block aligning mechanism; the connecting hydraulic cylinders (2) are provided with a plurality of groups, and the groups of connecting hydraulic cylinders (2) are respectively and fixedly connected to the upper end face of the supporting transverse plate (1); the drawing assembly (3) is fixedly connected to the telescopic rods of the plurality of groups of connecting hydraulic cylinders (2); the bottom connecting plate (4) is fixedly connected to the lower end face of the supporting transverse plate (1); the connecting flange plate (5) is fixedly connected to the lower end face of the bottom connecting plate (4); the traction connecting disc (6) is connected with the lower end face of the connecting flange disc (5) through screws; the connecting plug blocks (7) are provided with a plurality of groups, and the plurality of groups of connecting plug blocks (7) are respectively and fixedly connected to the upper end face of the traction connecting disc (6); the traction connecting block (8) is connected in an inserting way to the traction connecting disc (6) and the inside of the traction connecting disc (6); the welding block stabilizing mechanisms are provided with a plurality of groups, and the welding block stabilizing mechanisms are respectively arranged in the connecting plug blocks (7); the welding block alignment mechanisms are provided with a plurality of groups, and the welding block alignment mechanisms are respectively arranged on the plurality of groups of traction connecting blocks (8).

2. The foundation anti-pulling bearing performance detection device as defined in claim 1, wherein: the welding block stabilizing mechanism comprises: a stabilizing socket (701) and a top insert (801); the stable slot (701) is arranged on the upper end surface of the connecting plug block (7); the top plug block (801) is fixedly connected to the upper end face of the traction connecting block (8), and the socket (701) is firmly connected with the top plug block (801) in a plug-in mode.

3. The foundation anti-pulling bearing performance detection device as defined in claim 1, wherein: the welding block stabilizing mechanism further comprises: a fixed slot (802) and a stable insert block (9); the fixed slot (802) is arranged in the middle of the outer end surface of the traction connecting block (8); the stable plug block (9) is connected to the outer side of the inside of the connecting plug block (7) in a sliding mode, and the fixing slot (802) is connected with the stable plug block (9) in a plug-in mode.

4. A foundation anti-pulling load bearing performance detection device as defined in claim 3, wherein: the welding block stabilizing mechanism further comprises: a stabilizing slider (901) and a stabilizing spring (10); the two groups of stable sliding blocks (901) are arranged in total, and the two groups of stable sliding blocks (901) are fixedly connected to the stable inserting blocks (9) respectively; the stabilizing springs (10) are provided with two groups, the two groups of stabilizing springs (10) are respectively and fixedly connected inside the connecting plug block (7), and the two groups of stabilizing springs (10) are respectively and elastically connected with the two groups of stabilizing sliding blocks (901).

5. The foundation anti-pulling bearing performance detection device as defined in claim 1, wherein: the welding block alignment mechanism comprises: a traction inner slide (803), a traction weld block (11) and an inner slide chamber (1101); the traction inner sliding block (803) is fixedly connected to the lower end face of the traction connecting block (8); the traction welding block (11) slides on the lower side of the traction connecting block (8); the inner sliding cavity (1101) is formed in the upper side of the inner portion of the traction welding block (11), and the traction inner sliding block (803) is connected in a sliding mode in the inner sliding cavity (1101).

6. The foundation anti-pulling bearing performance detection device according to claim 5, wherein: the welding block alignment mechanism further comprises: an internal spring (12); the inner spring (12) is fixedly connected with the inner lower end face of the inner sliding cavity (1101), and the inner spring (12) is elastically connected with the lower end face of the traction inner sliding block (803).