CN219671450U - Foundation bearing capacity detection device - Google Patents

Abstract

The utility model provides a foundation bearing capacity detection device, which comprises a base, wherein a detection assembly is arranged in the middle of the bottom of the base, the top surface of the base is fixedly connected with a lifting assembly, the detection assembly comprises a sleeve fixedly connected to the middle of the bottom of the base, a probe rod is connected in a penetrating manner in the sleeve, the bottom of an electromagnetic block is magnetically adsorbed with the probe rod through a connecting block, a detection probe is fixedly connected to the bottom of the probe rod, the probe rod is rapidly lifted through the lifting assembly, a driving motor drives a screw rod to rotationally lift through a group of bevel gears, the bottom of the screw rod is fixedly connected with an electromagnetic block, magnetism is increased after the electromagnetic block is electrified to adsorb the connecting block, the probe rod at the bottom of the connecting block is driven to lift, namely the detection probe at the bottom of the probe rod is lifted along with the connecting block, and when the preset height is reached, the electromagnetic block is demagnetized to enable the probe rod to drive the detection probe to fall to the ground and penetrate the ground.

Description

Foundation bearing capacity detection device

Technical Field

The utility model relates to the technical field of building detection, in particular to a foundation bearing capacity detection device.

Background

The foundation is the foundation of building, and is particularly important to the detection of the bearing capacity of foundation, and conventional foundation bearing capacity detection device generally is the manual lifting weight and beats the probe rod for the detection probe of probe rod bottom pierces ground, in order to accomplish the bearing capacity detection of foundation, but has certain risk and the testing result is inaccurate in the operation process, and "a foundation bearing capacity detection device" that is disclosed at application number "CN202121227332.5", it "includes the bottom plate, the both sides of bottom plate surface upper end all fixedly connected with backup pad, two the middle part of backup pad internal surface one side all is provided with the slide, limiting hole has been seted up at the middle part of bottom plate surface upper end, limiting hole's internal surface sliding connection has the probe rod, the upper end fixedly connected with of probe rod surface has the supporting weight" is an increasingly mature technique, and it adopts the motor to drive the rolling ware rotatory, draws up the impact piece of wire rope one end, and the detection probe in order to replace manual operation, greatly reduces the operation risk and improves the detection precision, but has certain not enough in use: when the detection probe is pulled up and put down, the probe directly collides with the ground and pierces the ground, the inclination of the probe is easy to occur, the lifting height (the lifting height of the lifting head of the detection) is inconvenient to directly read each time, and then the detection precision can be affected.

Disclosure of Invention

The present utility model is directed to a foundation bearing capacity detection device, so as to solve the problems set forth in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the foundation bearing capacity detection device comprises a base station, wherein a detection assembly is arranged in the middle of the bottom of the base station, and the top surface of the base station is fixedly connected with a lifting assembly;

the lifting assembly comprises a motor box fixedly connected to the top surface of the base platform, a driving motor is fixedly connected to the inside of the motor box, a lifting box is fixedly connected to one side of the motor box, a first conical gear is fixedly connected to the output end of the driving motor, a second conical gear is connected to one side of the first conical gear in a meshed mode, a screw rod is connected to the inner thread of the second conical gear in a threaded mode, the top of the second conical gear is rotatably connected with the inner wall of the top of the lifting box, an auxiliary assembly is fixedly connected to the top of the lifting box, and the bottom of the screw rod is fixedly connected with the detection assembly through an electromagnetic block.

As a preferred embodiment of the present utility model: the detection assembly comprises a sleeve fixedly connected to the middle of the bottom of the base, a probe rod is connected to the sleeve in a penetrating mode, the bottom of the electromagnetic block is magnetically adsorbed with the probe rod through the connecting block, and a detection probe is fixedly connected to the bottom of the probe rod.

As a preferred embodiment of the present utility model: the auxiliary assembly comprises a protection cylinder fixedly connected to the top of the lifting box, a sliding groove is formed in one side of the protection cylinder, a marker post is rotatably connected to the top surface of the screw rod, one side of the marker post is slidably connected with the sliding groove, and a graduated scale is fixedly connected to one side of the sliding groove.

As a preferred embodiment of the present utility model: the middle of the front face of the base station is connected with a tool box in a sliding manner.

As a preferred embodiment of the present utility model: the bottom of base station all around corner all fixedly connected with supporting leg, a plurality of the equal fixedly connected with anti-skidding callus on sole of bottom of supporting leg.

As a preferred embodiment of the present utility model: one side of the electromagnetic block is provided with a clamping groove which is clamped with the top of the connecting block.

As a preferred embodiment of the present utility model: the control panel is fixedly connected to the corner of one side of the front surface of the base station, a driving motor switch and an electromagnetic block switch which are electrically connected with an external power supply are arranged on the surface of the control panel, and the driving motor and the electromagnetic block are electrically connected with the driving motor switch and the electromagnetic block switch respectively.

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

1) The quick lifting probe rod is carried out through the lifting assembly, the driving motor drives the screw rod to rotate and ascend through the set of conical gears, the bottom of the screw rod is fixedly connected with the electromagnetic block, magnetism is increased to adsorb the connecting block after the electromagnetic block is electrified, then the probe rod at the bottom of the connecting block is driven to ascend, namely the detection probe at the bottom of the probe rod is lifted along with the lifting block, after the preset height is reached, the electromagnetic block demagnetizes to enable the probe rod to drive the detection probe to fall on the ground and penetrate the ground, compared with the traditional mode of manually lifting the probe rod, more labor is saved, the detection accuracy is better, the sleeve is arranged to standardize the falling angle of the probe rod, and the inclination of the probe rod is effectively avoided when the probe rod falls;

2) The lifting height of the probe rod is visually checked through the auxiliary assembly, when the screw rod is rotationally lifted, the marker post at the top of the screw rod is lifted along with the sliding groove on one side of the protection barrel, the graduated scale is arranged on one side of the sliding groove, and the lifting height of the probe rod is visually seen through the position of the observed marker post on the graduated scale, so that the detection accuracy is effectively guaranteed.

Drawings

FIG. 1 is a schematic structural view of embodiment 1 of the present utility model;

FIG. 2 is a schematic cross-sectional view of the front partial structure of embodiment 1 of the present utility model;

FIG. 3 is a schematic diagram showing the disassembly of the detection assembly according to embodiment 1 of the present utility model;

FIG. 4 is a schematic diagram showing the disassembly of the auxiliary assembly according to embodiment 1 of the present utility model;

fig. 5 is a schematic structural view of embodiment 2 of the present utility model.

In the figure: 1. a base station; 2. a detection assembly; 21. a sleeve; 22. a probe rod; 23. a connecting block; 24. a detection probe; 3. an auxiliary component; 31. a protective cylinder; 32. a chute; 33. a target; 34. a graduated scale; 4. a lifting assembly; 41. a motor case; 42. a driving motor; 43. lifting the box; 44. a first bevel gear; 45. a second bevel gear; 46. a screw rod; 47. an electromagnetic block; 5. a tool box; 6. support legs; 7. an anti-skid foot pad; 8. a control panel; 9. the clamping groove.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

Example 1

Referring to fig. 1-4, the present utility model provides a technical solution: the foundation bearing capacity detection device comprises a base station 1, wherein a detection component 2 is arranged in the middle of the bottom of the base station 1, and a lifting component 4 is fixedly connected to the top surface of the base station 1;

the lifting assembly 4 comprises a motor box 41 fixedly connected to the top surface of the base 1, a driving motor 42 is fixedly connected to the inside of the motor box 41, a lifting box 43 is fixedly connected to one side of the motor box 41, a first conical gear 44 is fixedly connected to the output end of the driving motor 42, a second conical gear 45 is connected to one side of the first conical gear 44 in a meshed mode, a screw rod 46 is connected to the inner side of the second conical gear 45 in a threaded mode, the top of the second conical gear 45 is rotatably connected with the inner wall of the top of the lifting box 43, an auxiliary assembly 3 is fixedly connected to the top of the lifting box 43, and the bottom of the screw rod 46 is fixedly connected with the detection assembly 2 through an electromagnetic block 47.

Preferably, the detection assembly 2 comprises a sleeve 21 fixedly connected to the middle of the bottom of the base 1, a probe rod 22 is connected in a penetrating mode in the sleeve 21, the bottom of the electromagnetic block 47 is magnetically adsorbed with the probe rod 22 through a connecting block 23, and the bottom of the probe rod 22 is fixedly connected with a detection probe 24.

Specifically, after the electromagnetic block 47 is powered on, a large magnetism is generated and the connecting block 23 is adsorbed to lift, the connecting block 23 drives the probe rod 22, the probe rod 22 drives the detection probe 24 at the bottom of the probe rod, and the detection probe 24 is lifted.

Preferably, the auxiliary assembly 3 comprises a protection barrel 31 fixedly connected to the top of the lifting box 43, a chute 32 is formed in one side of the protection barrel 31, a marker post 33 is rotatably connected to the top surface of the screw rod 46, one side of the marker post 33 is slidably connected with the chute 32, and a graduated scale 34 is fixedly connected to one side of the chute 32.

Specifically, the marker post 33 is lifted along with the screw rod 46 through the marker post 33, the marker post 33 is lifted in the chute 32, and then the position height of the marker post 33 is visually seen by the graduated scale 34 on one side of the chute 32, and the lifting height of the probe rod 22 is visually read.

Preferably, the tool box 5 is slidably connected to the middle of the front surface of the base 1.

Specifically, the tool box 5 is used for accommodating and detecting tools for taking.

Preferably, the corners all around the bottom of base 1 are all fixedly connected with supporting leg 6, and the bottom of a plurality of supporting legs 6 is all fixedly connected with anti-skidding callus on the sole 7.

In particular, the device is placed more smoothly via a plurality of anti-slip footpads 7.

Working principle: the user carries out quick lifting probe 22 through lifting subassembly 4, wherein driving motor 42 drives first conical gear 44 and rotates, first conical gear 44 drives second conical gear 45 and rotates, and the inside threaded connection of second conical gear 45 has lead screw 46, and the top of second conical gear 45 is rotatory with the inner wall of lifting case 43 and be connected, and then lead screw 46 is driven rotatory lift, and then lead screw 46 drives the electromagnetic block 47 of its bottom and rises, electromagnetic block 47 carries out magnetism and adsorbs connecting block 23 after the electric connection, and the bottom fixedly connected with probe 22 of connecting block 23, and then the lifting is accomplished to probe 22 and the detection probe 24 of bottom, compared with traditional manual lifting mode, more quick laborsaving, thereby after lifting to a take a altitude, make probe 22 carry out the landing and stab ground along sleeve 21 inside by electromagnetic block 47 degaussing, thereby better completion foundation bearing capacity's detection.

Example 2

Referring to fig. 5, the distinguishing features of this embodiment, which distinguish embodiment 1, are: one side of the electromagnetic block 47 is provided with a clamping groove 9 which is clamped with the top of the connecting block 23.

Specifically, a clamping groove 9 is formed on one side of the electromagnetic block 47 to better clamp the connecting block 23, so that the lifting of the probe 22 is better completed.

Preferably, the corner of one side of the front surface of the base 1 is fixedly connected with a control panel 8, the surface of the control panel 8 is provided with a driving motor switch and an electromagnetic block switch which are electrically connected with an external power supply, and the driving motor 42 and the electromagnetic block 47 are respectively electrically connected with the driving motor switch and the electromagnetic block switch.

Specifically, each electric device is controlled by the control panel 8 to ensure that the device can be used normally.

Claims (7)

1. The utility model provides a foundation bearing capacity detection device, includes base station (1), its characterized in that: a detection assembly (2) is arranged in the middle of the bottom of the base station (1), and a lifting assembly (4) is fixedly connected to the top surface of the base station (1);

lifting subassembly (4) are including fixedly connected with motor case (41) on base station (1) top surface, the inside fixedly connected with driving motor (42) of motor case (41), one side fixedly connected with lifting case (43) of motor case (41), the output fixedly connected with first conical gear (44) of driving motor (42), one side meshing of first conical gear (44) is connected with second conical gear (45), the inside threaded connection of second conical gear (45) has lead screw (46), the top of second conical gear (45) rotates with the top inner wall of lifting case (43) to be connected, the top fixedly connected with auxiliary assembly (3) of lifting case (43), the bottom of lead screw (46) is through electromagnetic block (47) and detection subassembly (2) fixed connection.

2. The foundation load bearing capacity detection device according to claim 1, wherein: the detection assembly (2) comprises a sleeve (21) fixedly connected to the middle of the bottom of the base (1), a probe rod (22) is connected in the sleeve (21) in a penetrating mode, the bottom of the electromagnetic block (47) is magnetically adsorbed with the probe rod (22) through a connecting block (23), and a detection probe (24) is fixedly connected to the bottom of the probe rod (22).

3. The foundation load bearing capacity detection device according to claim 1, wherein: the auxiliary assembly (3) comprises a protection barrel (31) fixedly connected to the top of the lifting box (43), a sliding groove (32) is formed in one side of the protection barrel (31), a marker post (33) is rotatably connected to the top surface of the screw rod (46), one side of the marker post (33) is slidably connected with the sliding groove (32), and a graduated scale (34) is fixedly connected to one side of the sliding groove (32).

4. The foundation load bearing capacity detection device according to claim 1, wherein: the middle part of the front surface of the base station (1) is connected with a tool box (5) in a sliding way.

5. The foundation load bearing capacity detection device according to claim 1, wherein: the support legs (6) are fixedly connected to corners around the bottom of the base station (1), and anti-slip foot pads (7) are fixedly connected to the bottoms of the support legs (6).

6. The foundation load bearing capacity detection device according to claim 1, wherein: one side of the electromagnetic block (47) is provided with a clamping groove (9) which is clamped with the top of the connecting block (23).

7. The foundation load bearing capacity detection device according to claim 1, wherein: the control panel (8) is fixedly connected to the corner of one side of the front surface of the base station (1), a driving motor switch and an electromagnetic block switch which are electrically connected with an external power supply are arranged on the surface of the control panel (8), and the driving motor (42) and the electromagnetic block (47) are electrically connected with the driving motor switch and the electromagnetic block switch respectively.