CN219951884U - Heavy power touch detection device - Google Patents

Abstract

The utility model discloses a heavy power sounding device, which relates to geological detection, in particular to a heavy power sounding device, comprising a probe rod and a penetrating hammer, wherein the probe rod is provided with a probe and a hammer seat, and the heavy power sounding device is characterized in that: the utility model is convenient to move, and can finish detection and movement operation by a single person, and saves time and labor.

Description

Heavy power touch detection device

Technical Field

The utility model relates to geological exploration, in particular to a heavy dynamic sounding device.

Background

The dynamic sounding principle is a common geological exploration method, and by utilizing the gravity and impact force of a drill rod, physical properties and structural characteristics of the stratum are observed and recorded through the contact of the drill rod and the stratum, so that the properties and distribution of the underground stratum are deduced. The current common power feeler device comprises probe rod and core through hammer, and the probe rod bottom is provided with the probe, and there is a hammer seat that is used for bearing the core through hammer in the middle part of the probe rod, needs two at least people to operate when using, and is comparatively inconvenient.

Chinese patent publication No. CN216739548U provides a dynamic sounding apparatus, which uses a supporting device that needs to be disassembled before and after use, is inconvenient to use and difficult to move, and often needs to detect multiple points during dynamic sounding detection, so that a dynamic sounding apparatus that is easy to move is needed.

Disclosure of Invention

The utility model aims to solve the technical problems that: a heavy duty power penetration test device is provided which is easy to move.

In order to solve the technical problems, the utility model comprises a probe rod and a penetrating hammer, wherein the probe rod is provided with a probe and a hammer seat, the probe rod comprises a cylindrical frame, the cylindrical frame comprises two circular frames and a limiting structure, the two circular frames are connected through a transverse connecting frame, the limiting structure is arranged on the two circular frames, the limiting structure comprises two mutually parallel limiting grooves, the limiting grooves are arranged along the diameter of the circular frames, the probe rod is provided with a limiting rod, the limiting rod is mutually perpendicular to the probe rod, and two ends of the limiting rod are respectively arranged in the two limiting grooves.

Preferably, the limiting rod penetrates through the hammer seat and is fixedly connected with the hammer seat. The limiting rod and the hammer seat are limited at the same height, so that the vertical displacement of the penetrating hammer and the entering of the probe rod into the ground can be prevented while a better limiting effect is provided.

Preferably, the device comprises a limiting ring, wherein the limiting ring is arranged on the probe rod, and the limiting rod penetrates through the limiting ring and is fixedly connected with the limiting ring. The limiting ring can limit the height that the through hammer lifted at every turn to be certain, can improve the precision of test, sets up two gag levers in addition and can guarantee that the probe rod is parallel always with the spacing groove for as long as guarantee spacing groove and ground are perpendicular in actual testing process, just can make probe rod and ground perpendicular always, spacing groove and cylindrical frame relatively fixed, so as long as fixed cylindrical frame, just can ensure that the probe rod is perpendicular with ground.

Preferably, the two ends of the limiting rod are respectively provided with an expansion part, and the two expansion parts are respectively positioned at the outer sides of the two limiting grooves. The expansion part is used for limiting the limit rod not to move left and right, so that the probe rod can be kept vertical to the ground all the time in the testing process.

Preferably, the limiting structure comprises limiting beams, each circular frame is provided with two parallel limiting beams, and the limiting grooves are formed between the two parallel limiting beams.

Preferably, the cylindrical frame comprises a supporting device, the supporting device comprises a grounding bracket, the grounding bracket is rotationally connected with the limiting beam, and the grounding bracket is in two states of being tightly attached to the limiting beam and being perpendicular to the limiting beam. When the detection is carried out, the grounding bracket is perpendicular to the limiting beam, and a support is provided for the cylindrical frame, so that the limiting groove is enabled to be perpendicular to the ground all the time in the test process, and further the probe rod is enabled to be perpendicular to the ground all the time in the test process; after the detection is finished, the grounding support is tightly attached to the limiting beam, and the grounding support is prevented from affecting the movement of the cylindrical frame.

Preferably, the grounding support has four grounding supports. The four grounding brackets are respectively connected with the four limiting beams, so that a better supporting effect is provided for the cylindrical frame.

Preferably, the supporting device comprises a fixing rod, one end of the fixing rod is rotatably connected with the circular frame, a nut is arranged at the other end of the fixing rod, screw holes matched with the nut are formed in the circular frame and the grounding bracket, and the fixing rod is fixedly connected with the circular frame only and is fixedly connected with the circular frame and the grounding bracket at two ends respectively. During detection, nuts on the fixing rods are matched with screw holes on the grounding support, so that two ends of the fixing rods are fixedly connected with the circular frame and the grounding support respectively, a stable framework similar to a triangle is formed, and the supporting device can achieve a better supporting effect. After the detection is completed, the contact nuts are matched with screw holes on the grounding support, then the nuts are matched with screw holes on the circular frame, both ends of the fixing rod are fixedly connected with the circular frame, and the fixing rod is prevented from affecting the movement of the cylindrical frame.

Preferably, a stiffening beam is arranged between the circular frame and the limiting beam, and two ends of the stiffening beam are respectively and fixedly connected with the circular frame and the limiting beam.

Preferably, the limit beam is provided with scales. The distance of the probe rod extending into the ground can be obtained through the moving distance of the expansion block, so that detection data can be obtained more intuitively, and the recording and the calculation of the data are facilitated.

The beneficial effects of the utility model are as follows: when the test device is used, the limit rod is placed in the limit groove, the probe rod and the limit groove are perpendicular to the ground, then a dynamic touch test is carried out, after the test is finished, the probe rod and the through hammer are taken out, the cylindrical frame is rolled to the next place to be detected, and the position is finely adjusted through dragging, so that the test can be carried out. Compared with the prior art, the utility model is convenient to move, and can finish detection and movement operation by a single person, and the time and the labor are saved.

Drawings

FIG. 1 is a schematic diagram of the structure of the utility model in detection;

FIG. 2 is a schematic diagram of the results of the present utility model as it moves;

FIG. 3 is a schematic view of the probe and hammer;

in the figure: 1. the device comprises a probe rod, 2, a core through hammer, 3, a cylindrical frame, 4, a probe, 5, a hammer seat, 6, a limiting ring, 7, a limiting rod, 8, a circular frame, 9, a transverse connecting frame, 10, a limiting beam, 11, a limiting groove, 12, a reinforcing beam, 13, an expansion part, 14, a grounding support, 15, a fixing rod, 16, a nut, 17, a screw hole, 18 and a scale.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the drawings in the embodiments of the present utility model, in which all directional indications (such as up, down, left, right, front, and rear … …) are only used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

Referring to fig. 1-3, a heavy power feeler device comprises a feeler lever 1, a penetrating hammer 2 and a cylindrical frame 3, wherein a probe 4, a hammer seat 5, a limiting ring 6 and a limiting rod 7 are arranged on the feeler lever 1, and the limiting rod 7 is mutually perpendicular to the feeler lever 1. The limiting rods 7 are two, one limiting rod 7 penetrates through the hammer seat 5 and is fixedly connected with the hammer seat 5, and the other limiting rod 7 penetrates through the limiting ring 6 and is fixedly connected with the limiting ring 6. The limiting ring 6 is used for limiting the lifting height of the through hammer 2, so that a tester can ensure that the lifting height of the through hammer 2 is required to be compounded every time when operating by hand, and the testing accuracy is improved.

The cylinder frame 3 includes circular frame 8, limit structure, and circular frame 8 has two, and two circular frames 8 pass through transverse connection frame 9 to be connected, and limit structure sets up on two circular frames 8, and limit structure includes spacing roof beam 10, is provided with two parallel spacing roof beams 10 on every circular frame 8, forms spacing groove 11 between two parallel spacing roof beams 10, and two spacing grooves 11 are parallel to each other, and spacing groove 11 sets up along the diameter of circular frame 8. A stiffening beam 12 is arranged between the circular frame 8 and the limiting beam 10, and two ends of the stiffening beam 12 are respectively fixedly connected with the circular frame 8 and the limiting beam 10. The stop beam 10 is provided with graduations 18.

The both ends of gag lever post 7 set up respectively in two spacing grooves 11, and gag lever post 7 both ends are provided with expansion portion 13 respectively, and two expansion portion 13 are located the outside of two spacing grooves 11 respectively just.

The cylinder frame 3 includes strutting arrangement, strutting arrangement include earthing bracket 14 and dead lever 15, earthing bracket 14 and spacing roof beam 10 swivelling joint, earthing bracket 14 have with spacing roof beam 10 paste tightly and with spacing roof beam 10 two kinds of states perpendicularly, dead lever 15 one end and circular frame 8 swivelling joint, the other end of dead lever 15 is provided with nut 16, all be provided with on circular frame 8 and the earthing bracket 14 with nut 16 complex screw 17, dead lever 15 have only with circular frame 8 fixed connection and both ends respectively with circular frame 8, two kinds of states of ground connection bracket 14 fixed connection. The four grounding brackets 14 are respectively connected with the four limiting beams 10.

During detection, the limiting rod 7 is arranged in the limiting groove 11, the probe rod 1 and the limiting groove 11 are perpendicular to the ground, the grounding support 14 is perpendicular to the limiting beam 10, the fixing rod 15 is in fixed connection with the grounding support 14 after the fixing rod 15 is in non-matching with the circular frame 8, a triangle-like frame is formed, a supporting effect is provided, and then detection is carried out; when the movement is required after the detection, the connection between the fixing rod 15 and the grounding bracket 14 is canceled, both ends of the fixing rod 15 are connected to the circular frame 8, and then the grounding bracket 14 is tightly attached to the limiting beam 10, so that the movement can be performed. Compared with the prior art, the utility model is convenient to move, and can finish detection and movement operation by a single person, and the time and the labor are saved.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the spirit and scope of the utility model as defined by the appended claims and their equivalents.

Claims (10)

1. The utility model provides a heavy power feeler device, includes probe rod and core through hammer, is provided with probe and hammer seat on the probe rod, its characterized in that: including the cylinder type frame, the cylinder type frame include circular frame, limit structure, circular frame has two, two circular frames pass through the transverse connection frame and connect, limit structure sets up on two circular frames, limit structure includes two spacing grooves that are parallel to each other, the diameter setting of circular frame is followed to the spacing groove, is provided with the gag lever post on the gag lever post, gag lever post and gag lever post mutually perpendicular, the both ends of gag lever post set up respectively in two spacing grooves.

2. The heavy duty power penetration test device of claim 1, wherein: the limiting rod penetrates through the hammer seat and is fixedly connected with the hammer seat.

3. The heavy duty power penetration test device of claim 1, wherein: the locating device comprises a locating ring, wherein the locating ring is arranged on a probe rod, and the locating rod penetrates through the locating ring and is fixedly connected with the locating ring.

4. The heavy duty power penetration test device of claim 1, wherein: the two ends of the limiting rod are respectively provided with an expansion part, and the two expansion parts are respectively positioned at the outer sides of the two limiting grooves.

5. The heavy duty power penetration test device of claim 1, wherein: the limiting structure comprises limiting beams, two parallel limiting beams are arranged on each circular frame, and the limiting grooves are formed between the two parallel limiting beams.

6. The heavy duty power penetration test device of claim 5, wherein: the cylindrical frame comprises a supporting device, the supporting device comprises a grounding bracket, the grounding bracket is rotationally connected with the limiting beam, and the grounding bracket is in two states of being tightly attached to the limiting beam and being perpendicular to the limiting beam.

7. The heavy duty power penetration test device of claim 6, wherein: the supporting device comprises a fixing rod, one end of the fixing rod is rotatably connected with the circular frame, a nut is arranged at the other end of the fixing rod, screw holes matched with the nut are formed in the circular frame and the grounding bracket, and the fixing rod is fixedly connected with the circular frame only and is fixedly connected with the circular frame and the grounding bracket at two ends respectively.

8. The heavy duty power penetration test device of claim 6, wherein: the number of the grounding brackets is four.

9. The heavy duty power penetration test device of claim 5, wherein: a reinforcing beam is arranged between the circular frame and the limiting beam, and two ends of the reinforcing beam are fixedly connected with the circular frame and the limiting beam respectively.

10. The heavy duty power penetration test device of any one of claims 5-9, wherein: the limiting beam is provided with scales.