CN211718538U - Quick electrode laying device for geophysical prospecting measurement - Google Patents

Abstract

The utility model relates to the field of geophysical prospecting measuring equipment, and discloses a rapid electrode laying device for geophysical prospecting measurement, which comprises a bottom plate and a vertical plate, wherein the top surface of the bottom plate is provided with a first chute, a slide block is arranged in the first chute in a sliding manner, one side of the slide block is provided with a first spring, the other end of the first spring is provided with a limiting block, the end part of the first chute is provided with an L-shaped clamping plate, the two sides of the clamping plate are respectively provided with a baffle plate, the bottom of the clamping plate is provided with two collision beads, the side surfaces of the two collision beads are respectively provided with a collision bead seat, the collision bead seat is provided with a third spring, the top of the limiting block is provided with a third rotating shaft, the limiting block is rotatably provided with a gland through the third rotating shaft, the bottom surface of the gland is provided with a pressing strip, the top surface of the, when a plurality of electrodes are required to be arranged, the working efficiency of people can be effectively improved.

Description

Quick electrode laying device for geophysical prospecting measurement

Technical Field

The utility model belongs to geophysical prospecting measuring equipment field, concretely relates to can be used to geophysical prospecting measuring to open electrode and lay device.

Background

Geophysical measurements are based on physical properties of different rocks or ores, such as: the mineral exploration is performed according to the difference of magnetism, conductivity, density, elasticity and the like. Commonly used geophysical prospecting methods are: earthquake and soil metal quantity measurement, etc. The working methods need measurement work coordination during working so as to determine the shape of the measuring net and the position of a measuring point timely and accurately according to the design of geophysical prospecting work on a working site. And after the work is finished, continuous measurement is carried out on the measurement network according to the national geodetic control point, and the plane and elevation position of the measurement network are provided.

The high-density resistivity method is an array exploration method which is one of important exploration technologies in the engineering and environmental fields at present and is used for researching the distribution rule of conduction current in the earth under the action of a manually applied stable current field on the basis of the difference of the electrical conductivity of rock and soil. When field measurement is carried out, all electrodes (dozens to hundreds) are placed on each measuring point of an observation profile, then a program-controlled electrode conversion device and a micro-computer engineering electrical measuring instrument are utilized to realize rapid and automatic data acquisition, and after measurement results are sent to a micro-computer, the data can be processed and various graphic results about the distribution of the earth-electricity section can be given.

The high-density resistivity method needs to be used for arranging a plurality of electrodes, and currently, workers mostly adopt a manual hammer mode when arranging the electrodes, but the working strength of the arrangement of the electrodes in the mode is high, and meanwhile, the time is consumed, so that how to arrange the electrodes quickly and in a labor-saving manner becomes a problem to be solved urgently.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a quick electrode arrangement device that can be used to geophysical prospecting survey to solve the problem that wastes time and energy when the electrode is laid in the geophysical prospecting survey nowadays.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a can be used to geophysical prospecting measuring quick electrode and lay device, includes bottom plate and riser, first spout has been seted up to the bottom plate top surface, and the inside slidable mounting of first spout has the slider, first spring is installed to slider one side, and the other end of first spring installs the stopper, the cardboard that is the L type is installed to first spout tip, and the cardboard both sides all install the baffle, the cardboard bottom is installed and is bumped the pearl, bumps the pearl and is provided with two, and two bump pearl sides all install and bump the pearl seat, bump the pearl seat and install the third spring, the third pivot is installed at the stopper top, and the stopper rotates through the third pivot and install the gland, the layering is installed to the gland bottom surface, the second spring is installed to the stopper top surface, and the gland bottom surface is connected with the second spring.

Preferably, the bottom plate is provided with universal wheels at the bottom, and the side surface of the bottom plate is provided with a handle.

Preferably, the fixing base is installed to the riser side, and fixing base one end installs the pivot, the depression bar is installed through the pivot rotation to the fixing base, install the push down subassembly on the depression bar to realize the push down of gland.

Preferably, the pressing assembly comprises a second sliding groove formed in the bottom surface of the pressing rod, a roller is slidably mounted inside the second sliding groove, a second rotating shaft is mounted inside the roller, and the roller is rotatably mounted with a guide rod through the second rotating shaft.

Preferably, the end, far away from the gyro wheel, of the guide rod is provided with a pressing block, the surface of the fixing seat is provided with a through hole, the guide rod penetrates through the through hole, the surface of the vertical plate is provided with a sash, and the pressing rod penetrates through the sash.

Preferably, the first sliding chute is internally provided with an electrode, and the electrode is positioned on the other side of the sliding block.

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

(1) the utility model discloses a set up spring and slider, promote the slider through the spring to promote the electrode motion, make can once only save a plurality of electrodes, need not repeatedly when laying the electrode and take out the electrode, can directly nail into the electrode once more after nailing into an electrode, saved staff's laying time.

(2) The utility model discloses a set up the depression bar, the guide arm, the mode of gyro wheel and spout, the gyro wheel rolls in the spout and drives the guide arm and remove for people directly can accomplish the operation of driving the electrode nail into ground through the depression bar, and the strength of spending when reducing the nail and driving the electrode makes the staff can more relax quick completion electrode and lay.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of the presser part of the present invention;

FIG. 3 is a schematic structural view of the compression bar portion of the present invention;

FIG. 4 is an enlarged view taken at A in FIG. 2;

fig. 5 is a schematic structural view of the vertical plate of the present invention;

in the figure: 1-handle, 2-vertical plate, 3-fixed seat, 4-universal wheel, 5-pressure rod, 6-guide rod, 7-first rotating shaft, 8-pressure block, 9-pressure strip, 10-gland, 11-first spring, 12-slide block, 13-second spring, 14-first sliding chute, 15-bottom plate, 16-electrode, 17-third spring, 18-clamping plate, 19-collision bead, 20-collision bead seat, 21-second sliding chute, 22-roller, 23-through hole, 24-second rotating shaft, 25-limiting block, 26-baffle, 27-third rotating shaft and 28-sash.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides the following technical solutions: a rapid electrode laying device for geophysical prospecting measurement comprises a bottom plate 15 and a vertical plate 2, wherein a first sliding groove 14 is formed in the top surface of the bottom plate 15, a sliding block 12 is slidably mounted inside the first sliding groove 14, a first spring 11 is mounted on one side of the sliding block 12, a limiting block 25 is mounted at the other end of the first spring 11, an L-shaped clamping plate 18 is mounted at the end of the first sliding groove 14, baffles 26 are mounted on two sides of the clamping plate 18 to limit an electrode 16, two collision beads 19 are mounted at the bottom of the clamping plate 18, two collision beads 19 are arranged, two collision bead seats 20 are mounted on the side surfaces of the two collision beads 19, a third spring 17 is mounted on the collision bead seats 20, a third rotating shaft 27 is mounted at the top of the limiting block 25, a gland 10 is rotatably mounted through the third rotating shaft 27 on the limiting block 25, the gland 10 can rotate through the third rotating shaft 27 to realize pressing, a pressing strip 9 is mounted, and the bottom surface of the gland 10 is connected with a second spring 13 to realize the restoration of the gland 10 after being pressed down.

Preferably, universal wheel 4 is installed to bottom plate 15 bottom, and bottom plate 15 side-mounting has handle 1, can drive the device when pulling handle 1 and wholly remove.

Preferably, 2 side-mounting on the riser have fixing base 3, and 3 one end of fixing base installs pivot 7, and fixing base 7 rotates through pivot 7 and installs depression bar 5, installs the subassembly that pushes down on the depression bar 5 to realize the pushing down of gland 10.

Preferably, the pressing assembly comprises a second sliding groove 21 formed in the bottom surface of the pressing rod 5, a roller 22 is slidably mounted inside the second sliding groove 21, a second rotating shaft 24 is mounted inside the roller 22, the roller 22 is rotatably mounted with the guide rod 6 through the second rotating shaft 24, and the roller 22 drives the guide rod 6 to move along the second sliding groove 21.

Preferably, briquetting 8 is installed to the one end that gyro wheel 22 was kept away from to guide arm 6, and through-hole 23 has been seted up on the fixing base 3 surface, and guide arm 6 runs through-hole 23, because through-hole 23 is spacing to the guide arm, guide arm 6 can only reciprocate, sash 28 has been seted up on riser 2 surface, and depression bar 5 runs through in sash 28.

Preferably, the first chute 14 contains an electrode 16 therein, and the electrode 16 is located on the other side of the slider 12, and the slider 12 can push the electrode 16 to move.

The utility model discloses a theory of operation and use flow: when the electrodes 16 need to be arranged, the gland 10 is firstly pushed upwards, a plurality of electrodes 16 are placed in the first sliding groove 14, the handle 1 is pulled, the whole device is moved to a measuring point, then downward pressure is applied to the pressure rod 5, the pressure rod 5 rotates along the rotating shaft 7, thrust is generated on the roller 22, the roller 22 slides along the second sliding groove 21, the guide rod 6 is driven by the second rotating shaft 24 to move downwards, the pressure block 8 generates pressure on the gland 10, the gland 10 presses the pressing strip 9 downwards, the pressing strip 9 generates pressure on the electrodes 16, pressure is generated on the collision bead 19 below the electrodes 16, the collision bead seat 20 connected with the collision bead 19 generates pressure on the third spring 17, the collision bead 19 is pushed to two sides, the electrodes 16 are pressed into the ground, after the electrodes 16 are pressed into the ground, the pressure rod 5 is loosened, the gland 10 is upwards bounced due to the action of the second spring 13, the pressing strip 9 is driven to leave the position of the electrode groove 18, at the moment, the first spring 11 pushes the sliding block 12 to move, the sliding block 12 pushes the electrode 16 to move, the next electrode 16 is pushed to the position of the electrode 16 which is pressed into the ground before, the handle 1 is pulled to move the device to the next electrode 16 arrangement point, the pressing rod 5 is pressed down again, the operation of nailing the electrode 16 into the ground can be completed, the operation is repeated until the arrangement of the measurement points is completed, at the moment, the device is removed, the electrode 16 is installed through a cable, and the cable is installed on an instrument, so that the measurement data can be obtained.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a can be used to geophysical prospecting measuring quick electrode and lay device which characterized in that: the device comprises a bottom plate (15) and a vertical plate (2), wherein a first sliding groove (14) is formed in the top surface of the bottom plate (15), a sliding block (12) is arranged inside the first sliding groove (14) in a sliding mode, a first spring (11) is arranged on the side surface of the sliding block (12), a limiting block (25) is arranged at the other end of the first spring (11), an L-shaped clamping plate (18) is arranged at the end part of the first sliding groove (14), baffle plates (26) are arranged on two sides of the clamping plate (18), collision beads (19) are arranged at the bottom of the clamping plate (18), two collision beads (19) are arranged, collision bead seats (20) are arranged on the side surfaces of the two collision beads (19), a third spring (17) is arranged on the collision bead seats (20), a third rotating shaft (27) is arranged at the top of the limiting block (25), a gland (10) is rotatably arranged on the limiting block (25) through the third rotating, and a second spring (13) is installed on the top surface of the limiting block (25), and the bottom surface of the gland (10) is connected with the second spring (13).

2. The rapid electrode deployment device for geophysical measurements as claimed in claim 1, wherein: the universal wheel (4) is installed to bottom plate (15) bottom, and bottom plate (15) side-mounting has handle (1).

3. The rapid electrode deployment device for geophysical measurements as claimed in claim 1, wherein: riser (2) side-mounting has fixing base (3), and fixing base (3) one end installs pivot (7), fixing base (3) are rotated through pivot (7) and are installed depression bar (5), install down the subassembly that pushes down on depression bar (5) to realize pushing down of gland (10).

4. A rapid electrode deployment device for geophysical measurements as claimed in claim 3 wherein: the lower pressing component comprises a second sliding groove (21) formed in the bottom surface of the pressing rod (5), a roller (22) is arranged inside the second sliding groove (21) in a sliding mode, a second rotating shaft (24) is arranged inside the roller (22), and the roller (22) is rotatably provided with a guide rod (6) through the second rotating shaft (24).

5. The rapid electrode deployment device for geophysical measurements as claimed in claim 4, wherein: one end of the guide rod (6) far away from the roller (22) is provided with a pressing block (8), the surface of the fixing seat (3) is provided with a through hole (23), the guide rod (6) penetrates through the through hole (23), the surface of the vertical plate (2) is provided with a sash (28), and the pressing rod (5) penetrates through the sash (28).

6. The rapid electrode deployment device for geophysical measurements as claimed in claim 1, wherein: an electrode (16) is contained in the first sliding chute (14), and the electrode (16) is positioned on the other side of the sliding block (12).

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