CN219619160U - Portable integrated geological radar measuring device - Google Patents

Abstract

The utility model discloses a portable integrated geological radar measuring device, which relates to the field of engineering geological detection equipment, and comprises a main body mechanism, a main body mechanism and a measuring device, wherein the main body mechanism comprises a frame assembly and working wheels arranged at two ends below the frame assembly, and a connecting assembly is arranged below the frame assembly; the mounting mechanism comprises a cross rod arranged in the frame assembly, a first adjusting rod is movably connected to the outer part of the cross rod, and a supporting component is arranged on one side of the first adjusting rod; the storage mechanism comprises a bearing frame arranged at one end of the frame assembly, and a first damping ring cylinder is arranged at one end of the bearing frame. According to the portable integrated geological radar measuring device, the detection radar is arranged below the frame assembly, the gravity center is low, the overall stability is high, and four operation wheels are arranged at two ends of the frame assembly, so that a worker can conveniently and stably move by utilizing the auxiliary pushing device, and the detection is convenient.

Description

Portable integrated geological radar measuring device

Technical Field

The utility model relates to the field of engineering geological detection equipment, in particular to a portable integrated geological radar measuring device.

Background

Geological radar (GPR) is a geophysical prospecting technology for detecting a surface layer underground structure or a target body, and has the characteristics of nondestructive testing, high resolution, reliability and the like. The geological radar has wide application in the fields of mine disaster source detection, roadbed detection, underground pipe network detection, cultural relic archaeology and the like.

Through retrieval, bulletin number (CN 106080677B) is a portable geological radar urban road detection vehicle, which comprises a main body push rod, a supporting and traveling mechanism, a handle tray mechanism and a control unit fixing mechanism. The main body push rod is a telescopic push rod, three connecting rotating shafts are arranged on the main body push rod and are respectively positioned at two ends and the middle part of the main body push rod in a downward position, and the main body push rod is sequentially connected with a handle tray mechanism, a radar antenna and a supporting travelling mechanism, and all the parts can rotate around the shafts. The supporting travelling mechanism main body is a triangular supporting frame, and three corners are sequentially connected with a guide rod and two rollers: the handle tray mechanism is used for controlling the detection vehicle and placing the radar host: the control unit fixing mechanism fixes the control unit at the waist of the main body push rod. The method solves the problem that the existing geological radar road detection mode can not simultaneously meet the detection efficiency and flexibility: the detection vehicle is a herringbone cart when in work, and is a straight-line trailer when not in work, so that the device is convenient to carry, and the road detection work is flexible and does not lose efficiency.

The above-mentioned published patent has following drawbacks in the concrete use: (1) When the device is used, the radar detection equipment is placed at the front end of the main body push rod, and the device is only provided with two operation wheels, so that the lower end of the main body push rod is inclined forwards and pressed downwards under the action of the gravity of the radar detection equipment, and the geological personnel pushing device is inconvenient to carry out geological detection; (2) The device is inconvenient to store the equipment storage box when in use, and the practicability is low.

Disclosure of Invention

The utility model aims to provide a portable integrated geological radar measuring device, so as to solve the problems in the background technology.

In order to solve the problems, the technical scheme adopted by the utility model is as follows:

portable integrated geological radar measuring device includes

The main body mechanism comprises a frame assembly and working wheels arranged at two ends below the frame assembly, a connecting assembly is arranged below the frame assembly, the connecting assembly comprises a detection radar, a hollow insertion pipe, a round pipe and a fixing bolt, the detection radar is arranged below the frame assembly, one end of the round pipe is fixedly connected with the upper surface of the detection radar, one end of the hollow insertion pipe is fixedly connected with the lower surface of the frame assembly, one end of the round pipe, which is far away from the detection radar, is connected with the hollow insertion pipe in a plugging manner, a first jack is formed in the outer surface of the hollow insertion pipe, a second jack is formed in the outer surface of the round pipe, and one end of the fixing bolt penetrates through the first jack and is connected with the second jack in a plugging manner;

the mounting mechanism comprises a cross rod arranged in the frame assembly, a first adjusting rod is movably connected to the outer part of the cross rod, a supporting component is arranged on one side of the first adjusting rod, the supporting component comprises a second adjusting rod and a clamping head, one end of the second adjusting rod is rotatably connected with one side of the outer part of the first adjusting rod, and one end of the clamping head is connected with the other end of the second adjusting rod;

the storage mechanism comprises a support arranged at one end of the frame assembly, a first damping ring cylinder is arranged at one end of the support, one end of the support is rotationally connected with the frame assembly through the first damping ring cylinder, and a constraint component is arranged at one side of the support.

Preferably, a fixed block is arranged at one end of the frame assembly, and an auxiliary pushing frame is arranged on the upper surface of the fixed block.

Preferably, one end of the first adjusting rod is movably connected with a display, one end of the clamping head is provided with a centering rod, one end of the centering rod is movably connected with a machine head, and two sides of the inside of the frame assembly are movably connected with hack levers.

Preferably, the outer surface of the hack lever is rotationally connected with a second damping ring cylinder, and the outer surface of the second damping ring cylinder is fixedly connected with one end of the centering lever, which is far away from the machine head.

Preferably, the restraint assembly comprises a longitudinal restraint strap, a first slot and a first insert, one end of the longitudinal restraint strap is fixedly connected with one end of the frame assembly, one end of the first slot is fixedly connected with the other end of the longitudinal restraint strap, one end of the first insert is arranged on the outer surface of the support frame, and the first insert is buckled and connected with the first slot.

Preferably, the restraint assembly further comprises a transverse restraint strap, a second slot and a second insert block, one end of the transverse restraint strap is connected with the outer surface of the support frame, one end of the second slot is fixedly connected with the other end of the transverse restraint strap, one end of the second insert block is connected with the outer surface of the support frame, and the second insert block is buckled and connected with the second slot.

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

according to the utility model, by utilizing the characteristics that one end of the circular tube far away from the detection radar is connected with the hollow insertion tube in an inserting way and the characteristics that one end of the fixing bolt penetrates through the first insertion hole and the second insertion hole in an inserting way, the detection radar is conveniently installed below the frame assembly, the installation and the disassembly are convenient, the detection radar is installed below the frame assembly, the gravity center is low, the overall stability is high, four operation wheels are arranged at two ends of the frame assembly, and the detection is convenient and rapid because the staff can stably move by utilizing the auxiliary pushing frame pushing device.

According to the utility model, a worker rotates the hack lever to enable the hack lever to be vertical to the ground, then rotates the position of the centering lever by utilizing the characteristic that the outer surface of the second damping ring cylinder is fixedly connected with one end of the centering lever far away from the machine head, then, the worker connects the machine head with one end of the centering lever, rotates the second adjusting lever, and limits the position of the centering lever by utilizing the clamping head at one end of the second adjusting lever, wherein after measurement is finished, the worker is convenient to utilize the rotation connection characteristic of the structure, and then, the device is convenient to fold and store.

According to the utility model, the storage box is restrained from two directions by using the transverse restraining belt and the longitudinal restraining belt, so that the storage box is effectively prevented from sliding down due to vibration of the vehicle body in the moving process of the detection vehicle.

Drawings

FIG. 1 is a schematic view of the external overall structure of a portable integrated geological radar measuring device;

FIG. 2 is a schematic diagram of the main body mechanism of the portable integrated geological radar measuring device;

FIG. 3 is a schematic diagram of a frame assembly of a portable integrated geological radar measuring device;

FIG. 4 is an enlarged view of a portion of the portable integrated geological radar measuring device at A in FIG. 2;

FIG. 5 is a schematic diagram of the mounting mechanism of the portable integrated geological radar measuring device;

fig. 6 is a schematic diagram of a storage mechanism structure of the portable integrated geological radar measuring device.

In the figure: 100. a main body mechanism; 101. a frame assembly; 102. a working wheel; 103. detecting a radar; 104. a hollow cannula; 105. a round tube; 106. a fixing bolt; 107. an auxiliary pushing frame; 200. a mounting mechanism; 201. a cross bar; 202. a first adjusting lever; 203. a second adjusting lever; 204. a clamping head; 205. a display; 206. centering rod; 207. a machine head; 208. a hack lever; 209. a second damping ring cylinder; 300. a storage mechanism; 301. a support frame; 302. a first damping ring cylinder; 303. a longitudinal restraint strap; 304. a first slot; 305. a first plug; 306. a lateral restraint strap; 307. a second slot; 308. and a second plug.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Embodiment one:

referring to FIGS. 1-6, the present utility model is a portable integrated geological radar measuring device, comprising

1-4, the main body mechanism 100 comprises a frame assembly 101 and working wheels 102 arranged at two ends below the frame assembly 101, a connecting component is arranged below the frame assembly 101, the connecting component comprises a detection radar 103, a hollow insertion tube 104, a round tube 105 and a fixed bolt 106, the detection radar 103 is arranged below the frame assembly 101, one end of the round tube 105 is fixedly connected with the upper surface of the detection radar 103, one end of the hollow insertion tube 104 is fixedly connected with the lower surface of the frame assembly 101, one end of the round tube 105, far away from the detection radar 103, is connected with the hollow insertion tube 104 in an inserting way, a first jack is arranged on the outer surface of the hollow insertion tube 104, a second jack is arranged on the outer surface of the round tube 105, and one end of the fixed bolt 106 penetrates through the first jack to be connected with the second jack in an inserting way;

one end of the frame assembly 101 is provided with a fixed block, and the upper surface of the fixed block is provided with an auxiliary pushing frame 107.

From the above, during the use, when needing to carry out the ground quality testing, the staff is kept away from the one end that detects radar 103 through utilizing pipe 105 and is connected with hollow intubate 104 characteristics that insert and close this moment and the characteristics that fixed bolt 106 one end passed first jack and second jack insert and close and be connected, then be convenient for install detection radar 103 in frame assembly 101 below, it is convenient to install and dismantle, it is low to install detection radar 103 in frame assembly 101 below focus, overall stability is strong, and frame assembly 101 both ends are equipped with four operation wheels 102 altogether, the staff of being convenient for utilizes supplementary pushing away 107 thrust device steady removal, it is convenient to detect.

Embodiment two:

referring to fig. 1 and 5, the mounting mechanism 200 includes a cross bar 201 disposed inside the frame assembly 101, a first adjusting bar 202 is movably connected to the outside of the cross bar 201, a support assembly is disposed on one side of the first adjusting bar 202, the support assembly includes a second adjusting bar 203 and a clamping head 204, one end of the second adjusting bar 203 is rotatably connected to one side of the outside of the first adjusting bar 202, and one end of the clamping head 204 is connected to the other end of the second adjusting bar 203;

one end of the first adjusting rod 202 is movably connected with a display 205, one end of the clamping head 204 is provided with a centering rod 206, one end of the centering rod 206 is movably connected with a machine head 207, and two sides of the inside of the frame assembly 101 are movably connected with hack levers 208;

the outer surface of the hack lever 208 is rotationally connected with a second damping ring cylinder 209, and the outer surface of the second damping ring cylinder 209 is fixedly connected with one end of the centering rod 206 far away from the machine head 207.

It can be seen from the above that, when in use, the operator rotates the hack lever 208 to make the hack lever 208 perpendicular to the ground, then rotates the centering lever 206 by utilizing the characteristic that the outer surface of the second damping ring cylinder 209 is fixedly connected with the end of the centering lever 206 far away from the nose 207, and then rotates the centering lever 206, and then, the operator connects the nose 207 with one end of the centering lever 206, rotates the second adjusting lever 203, and utilizes the clamping head 204 at one end of the second adjusting lever 203 to limit the position of the centering lever 206, wherein, after the measurement is completed, the operator is convenient to utilize the rotation connection characteristic of the structure, and then is convenient to fold and store the device.

Embodiment III:

referring to fig. 1 and 6, the storage mechanism 300 includes a support 301 disposed at one end of the frame assembly 101, a first damping ring cylinder 302 is disposed at one end of the support 301, one end of the support 301 is rotatably connected with the frame assembly 101 through the first damping ring cylinder 302, and a constraint component is disposed at one side of the support 301;

the restraint assembly comprises a longitudinal restraint strap 303, a first slot 304 and a first insert block 305, one end of the longitudinal restraint strap 303 is fixedly connected with one end of the frame assembly 101, one end of the first slot 304 is fixedly connected with the other end of the longitudinal restraint strap 303, one end of the first insert block 305 is arranged on the outer surface of the carrier 301, and the first insert block 305 is buckled and connected with the first slot 304;

the restraint assembly further comprises a transverse restraint strap 306, a second slot 307 and a second insert block 308, one end of the transverse restraint strap 306 is connected with the outer surface of the carrier 301, one end of the second slot 307 is fixedly connected with the other end of the transverse restraint strap 306, one end of the second insert block 308 is connected with the outer surface of the carrier 301, and the second insert block 308 is buckled and connected with the second slot 307.

From the above, when in use, a worker places the equipment storage box above the carrier 301, firstly, the storage box is constrained by utilizing the characteristic that the first plug block 305 is buckled and connected with the first slot 304, then the storage box is constrained by utilizing the longitudinal constraint belt 303, and then the storage box is constrained by utilizing the characteristic that the second plug block 308 is buckled and connected with the second slot 307, then the storage box is constrained by utilizing the transverse constraint belt 306, and then the storage box is constrained from two directions, so that the storage box is prevented from falling due to the vibration of the vehicle body in the moving process of the detection vehicle.

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 principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. Portable integrated geological radar measuring device, its characterized in that: comprising

The main body mechanism (100) comprises a frame assembly (101) and working wheels (102) arranged at two ends below the frame assembly (101), a connecting component is arranged below the frame assembly (101), the connecting component comprises a detection radar (103), a hollow insertion pipe (104), a round pipe (105) and a fixing bolt (106), the detection radar (103) is arranged below the frame assembly (101), one end of the round pipe (105) is fixedly connected with the upper surface of the detection radar (103), one end of the hollow insertion pipe (104) is fixedly connected with the lower surface of the frame assembly (101), one end of the round pipe (105) far away from the detection radar (103) is connected with the hollow insertion pipe (104) in an inserting mode, a first insertion hole is formed in the outer surface of the hollow insertion pipe (104), a second insertion hole is formed in the outer surface of the round pipe (105), and one end of the fixing bolt (106) penetrates through the first insertion hole and is connected with the second insertion hole in an inserting mode.

The mounting mechanism (200) comprises a cross rod (201) arranged in the frame assembly (101), a first adjusting rod (202) is movably connected to the outside of the cross rod (201), a supporting component is arranged on one side of the first adjusting rod (202), the supporting component comprises a second adjusting rod (203) and a clamping head (204), one end of the second adjusting rod (203) is rotatably connected with one side of the outside of the first adjusting rod (202), and one end of the clamping head (204) is connected with the other end of the second adjusting rod (203);

the storage mechanism (300) comprises a support frame (301) arranged at one end of the frame assembly (101), a first damping ring cylinder (302) is arranged at one end of the support frame (301), one end of the support frame (301) is rotatably connected with the frame assembly (101) through the first damping ring cylinder (302), and a constraint component is arranged on one side of the support frame (301).

2. The portable integrated geological radar measuring device of claim 1, wherein: one end of the frame assembly (101) is provided with a fixed block, and the upper surface of the fixed block is provided with an auxiliary pushing frame (107).

3. The portable integrated geological radar measuring device of claim 1, wherein: the device is characterized in that one end of the first adjusting rod (202) is movably connected with a display (205), one end of the clamping head (204) is provided with a centering rod (206), one end of the centering rod (206) is movably connected with a machine head (207), and two sides of the interior of the frame assembly (101) are movably connected with hack levers (208).

4. A lightweight integrated geological radar measuring device according to claim 3, characterized in that: the outer surface of the hack lever (208) is rotationally connected with a second damping ring cylinder (209), and the outer surface of the second damping ring cylinder (209) is fixedly connected with one end of the centering rod (206) far away from the machine head (207).

5. The portable integrated geological radar measuring device of claim 1, wherein: the restraint assembly comprises a longitudinal restraint strap (303), a first slot (304) and a first insert block (305), one end of the longitudinal restraint strap (303) is fixedly connected with one end of the frame assembly (101), one end of the first slot (304) is fixedly connected with the other end of the longitudinal restraint strap (303), one end of the first insert block (305) is mounted on the outer surface of the support frame (301), and the first insert block (305) is buckled and connected with the first slot (304).

6. The portable integrated geological radar measuring device of claim 5, in which: the restraint assembly further comprises a transverse restraint strap (306), a second slot (307) and a second insert block (308), one end of the transverse restraint strap (306) is connected with the outer surface of the support frame (301), one end of the second slot (307) is fixedly connected with the other end of the transverse restraint strap (306), one end of the second insert block (308) is connected with the outer surface of the support frame (301), and the second insert block (308) is buckled and connected with the second slot (307).