CN213980863U - Water prevention and control device for geological measurement - Google Patents

Abstract

The utility model relates to a prevention and cure water engineering technical field, concretely relates to a prevention and cure water installation for geological survey, including positioning mechanism and the mechanism that catchments, positioning mechanism includes the arc piece, a plurality of funnel shaped holes have evenly been seted up to the arcwall face intermediate position of arc piece, the laminating of the bottom surface of arc piece has the branch liquid strip. In the utility model, a plurality of water collecting mechanisms are fixed on the top of the positioning mechanism in sequence, the rotating shaft adjusts the angle of the rotating plate, and the rotating plate is tightly attached to the top wall of the channel to collect the seepage water; the two ends of the arc-shaped block are respectively clamped and fixed with the two inserting strips of the supporting mechanism, the water conveying pipe is embedded into the round hole of the connecting column in a sliding mode, the flange is used for realizing connection of adjacent water conveying pipes and fixation of a plurality of water prevention and control devices, the seepage water is collected in the water conveying pipe discharge passage, the seepage water on the top wall of the passage is discharged while the protection passage is used smoothly, and the threat of the seepage water to the erosion of the passage for detection constructors is eliminated.

Description

Water prevention and control device for geological measurement

Technical Field

The utility model relates to a prevention and cure water engineering technical field, concretely relates to prevention and cure water installation for geological survey.

Background

In the coal mine exploration process, the geological environment needs to be thoroughly detected, including geological measurement work of a pit well and a shallow detection channel, however, in some areas with abundant rainfall, the seepage water at the top of the channel can flow along the rock wall, the seeper water is formed on the ground of the channel to influence the use of the machinery by people, meanwhile, the seepage water can cause continuous erosion damage to the soft part of the rock stratum of the channel, and under the threat of surface water and underground seepage water, a stabilizing device capable of collecting and discharging water is needed to protect the safety of detection constructors.

SUMMERY OF THE UTILITY MODEL

In order to overcome the technical problem, the utility model aims to provide a water control device for geological measurement, which is sequentially fixed on the top of a positioning mechanism through a plurality of water collecting mechanisms, the rotating shaft adjusts the angle of a rotating plate, and the rotating plate is tightly attached to the top wall of a channel to collect seepage water; the two ends of the arc-shaped block are respectively clamped and fixed with the two inserting strips of the supporting mechanism, the water conveying pipe is embedded into the round hole of the connecting column in a sliding mode, the flange is used for realizing connection of adjacent water conveying pipes and fixation of a plurality of water prevention and control devices, the seepage water is collected in the water conveying pipe discharge passage, the seepage water on the top wall of the passage is discharged while the protection passage is used smoothly, and the threat of the seepage water to the erosion of the passage for detection constructors is eliminated.

The purpose of the utility model can be realized by the following technical scheme:

a water prevention and control device for geological measurement comprises a positioning mechanism and a water collection mechanism, wherein the positioning mechanism comprises an arc-shaped block, a plurality of funnel-shaped holes are uniformly formed in the middle of the arc-shaped surface of the arc-shaped block, and a liquid separation strip is attached to the bottom surface of the arc-shaped block;

the top end of the positioning mechanism is provided with a plurality of water collecting mechanisms corresponding to the positions of the funnel-shaped holes, each water collecting mechanism comprises a connecting plate, a positioning block is fixedly connected to the middle position of the bottom surface of each connecting plate, the positioning blocks are in sliding clamping connection with the corresponding positions of the arc-shaped blocks, a water accumulating groove is formed in the middle position of the top surface of each connecting plate, a first circular hole is formed in the center of each connecting plate, and four transverse grooves are symmetrically formed in two sides of each connecting plate; the connecting hole has been seted up to the both sides wall symmetry of cross slot, the bilateral symmetry of connecting plate is provided with two rotor plates, and two the guide way has all been seted up to a lateral wall that the rotor plate is close to the ponding groove, the bottom of rotor plate has linked firmly the axis of rotation, the both ends of axis of rotation are rotated with the connecting hole that corresponds the position respectively and are connected, positioning mechanism's both ends symmetry is provided with two supporting mechanism, and the roof infiltration water of hole is collected to the guide way of rotor plate, and the ponding groove of connecting plate is with the round hole one of infiltration water direction bottom, and the round hole one corresponds with hourglass hopper-shaped pore pair, and the infiltration water flows into the arc and divides the recess between the liquid strip and shunts to both sides.

Further, the method comprises the following steps: the supporting mechanism includes the grafting piece, and the symmetry has linked firmly two cuttings on the side of grafting piece, and two adjacent one sides of cuttings all paste mutually with the both sides of arc piece one end and lean on, and the bottom of two cuttings all pastes mutually with the one end that divides the liquid strip top and lean on, the bottom surface of grafting piece has linked firmly the spliced pole, round hole two has been seted up to the bottom of spliced pole, the inside of spliced pole is located along its vertical central line and has seted up square groove one between grafting piece and the round hole two, the bottom of spliced pole closes soon and is connected with the base, utilizes grafting piece fixed positioning mechanism's both ends, and the infiltration water between arc piece and the branch liquid strip flows into square groove one.

Further, the method comprises the following steps: the inner side of the round hole II is embedded with a water delivery pipe in a sliding mode, a square groove II is formed in the side wall of the middle position of the water delivery pipe, the water delivery pipe is moved, the square groove II is opened, and sampling detection of the seepage water can be conducted.

Further, the method comprises the following steps: the water accumulation groove is embedded with a filter screen, the filter screen is used for filtering large rock walls in the permeating water, and the situation that the particles enter the arc-shaped block and are blocked by the positioning mechanism due to the fact that the particles are separated from the groove between the liquid separating strips is avoided.

Further, the method comprises the following steps: the end of the rotating shaft, which is close to the connecting hole, is screwed and connected with a hexagon nut, the rotating angle of the rotating plate is 0-60 degrees, the hexagon nut is tightly attached to the connecting hole in a screwing mode, the rotating angle of the rotating plate is fixed, the top surface of the rotating plate is tightly attached to the corresponding position of the top wall of the channel, and therefore the water collecting mechanism supports the top wall of the channel.

Further, the method comprises the following steps: the size of the square groove II is larger than that of the square groove I, and the seepage water flowing into the square groove I flows into the square groove II and is conveyed out of the channel through the water conveying pipe.

Further, the method comprises the following steps: one end of the water pipe is connected with a flange, the length of the water pipe is equal to that of the connecting plate and the rotating plate, the water pipes of the water prevention and control devices are sequentially connected through the flange, the positioning mechanism and the water collecting mechanism at the top of the device are continuous and parallel, and the joint of the water pipe and the connecting column is fixed on the side wall of the channel through the fixing mechanism to prevent the water pipe from sliding and prevent the vibration of the supporting mechanism.

The utility model has the advantages that:

1. the positioning blocks are connected with the arc blocks through the studs, the plurality of water collecting mechanisms are sequentially fixed at the tops of the positioning mechanisms, one end of the rotating shaft is screwed with the hexagon nut to fix the angle of the rotating plate, and the rotating plate is tightly attached to the top wall of the channel to collect the seepage water; the two ends of the arc-shaped block are respectively clamped and fixed with the two inserting strips of the supporting mechanism, the water delivery pipe is embedded at the position of the round hole of the connecting column in a sliding manner, and the connection of the adjacent water delivery pipes and the fixation of the plurality of water prevention and control devices are realized by using the flange; the roof infiltration water of pot hole is collected to the guide way of rotor plate, gathers in raceway escape canal, has discharged the infiltration water of passageway roof when protecting the unblocked use of passageway in the clearance of water accumulation groove, round hole one and funnel shaped hole, arc piece and the branch liquid strip that are used for collecting and filtering the infiltration water respectively, square groove one and the square groove two that corresponds, has got rid of the infiltration water and has given the threat of surveying constructor to the erosion of passageway.

Drawings

The present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic structural view of the middle positioning mechanism and the supporting mechanism of the present invention;

FIG. 3 is a schematic structural view of the water collecting mechanism of the present invention;

fig. 4 is a schematic view of the structure of the turning plate of the present invention.

In the figure: 100. a positioning mechanism; 110. an arc-shaped block; 111. a funnel-shaped aperture; 120. a liquid separating strip; 200. a water collecting mechanism; 210. a connecting plate; 211. positioning blocks; 212. a water accumulation tank; 213. a first round hole; 214. a transverse groove; 2141. connecting holes; 215. a filter screen; 220. a rotating plate; 221. a guide groove; 222. a rotating shaft; 223. a hexagonal nut; 300. a support mechanism; 310. an insertion block; 311. cutting; 320. connecting columns; 330. a second round hole; 340. a first square groove; 350. a base; 400. a water delivery pipe; 410. a second square groove; 420. and (4) a flange.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely below with reference to 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 of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-4, a water prevention and control device for geological measurement comprises a positioning mechanism 100 and a water collection mechanism 200, wherein the positioning mechanism 100 comprises an arc block 110, a plurality of funnel-shaped holes 111 are uniformly formed in the middle of the arc surface of the arc block 110, and a liquid separation strip 120 is attached to the bottom surface of the arc block 110;

the top end of the positioning mechanism 100 is provided with a plurality of water collecting mechanisms 200 corresponding to the positions of the funnel-shaped holes 111, each water collecting mechanism 200 comprises a connecting plate 210, the middle position of the bottom surface of each connecting plate 210 is fixedly connected with a positioning block 211, the positioning blocks 211 are in sliding clamping connection with the corresponding positions of the arc-shaped blocks 110, the middle position of the top surface of each connecting plate 210 is provided with a water accumulating groove 212, the center of each connecting plate 210 is provided with a first round hole 213, and two sides of each connecting plate 210 are symmetrically provided with four transverse grooves 214; connecting hole 2141 has been seted up to the both sides wall symmetry of transverse groove 214, the bilateral symmetry of connecting plate 210 is provided with two rotor plates 220, and guide way 221 has all been seted up to two rotor plates 220 near a lateral wall of ponding groove 212, the bottom of rotor plate 220 has linked firmly axis of rotation 222, the both ends of axis of rotation 222 rotate with the connecting hole 2141 that corresponds the position respectively and are connected, positioning mechanism 100's both ends symmetry is provided with two supporting mechanism 300, the roof infiltration water of pothole is collected to rotor plate 220's guide way 221, ponding groove 212 of connecting plate 210 is with a round hole 213 of infiltration water direction bottom, a round hole 213 corresponds with funnel shaped hole 111, the infiltration water flows in the recess between arc piece 110 and the minute liquid strip 120 and shunts to both sides.

Supporting mechanism 300 includes grafting piece 310, and the symmetry has linked firmly two cuttings 311 on the side of grafting piece 310, two adjacent one sides of cuttings 311 all paste with the both sides of arc piece 110 one end mutually, and the bottom of two cuttings 311 all pastes with the one end that divides the liquid strip 120 top mutually and pastes, the bottom surface of grafting piece 310 has linked firmly spliced pole 320, round hole two 330 has been seted up to the bottom of spliced pole 320, the inside of spliced pole 320 is located along its vertical central line and has seted up square groove one 340 between grafting piece 310 and round hole two 330, the bottom of spliced pole 320 closes soon and is connected with base 350, utilize the both ends of grafting piece 310 fixed position mechanism 100, the infiltration water between arc piece 110 and the branch liquid strip 120 flows into square groove one 340.

The water pipe 400 is embedded into the inner side of the second round hole 330 in a sliding mode, the second square groove 410 is formed in the side wall of the middle position of the water pipe 400, the water pipe 400 is moved, the second square groove 410 is opened, and sampling detection of the permeated water can be conducted.

The filter screen 215 is embedded in the water collecting groove 212, and the filter screen 215 is used for filtering large rock wall particles in the permeated water, so that the particles are prevented from entering a groove between the arc-shaped block 110 and the liquid separating strip 120 to cause the blockage of the positioning mechanism 100.

The hexagonal nut 223 is screwed to one end, close to the connecting hole 2141, of the rotating shaft 222, the rotating angle of the rotating plate 220 is 0-60 degrees, the rotating plate 220 is tightly attached to the connecting hole 2141 through screwing of the hexagonal nut 223, the rotating angle is fixed by the rotating plate 220, the top surface of the rotating plate 220 is tightly attached to the corresponding position of the top wall of the channel, and therefore the water collecting mechanism 200 supports the top wall of the channel.

The size of the second square groove 410 is larger than that of the first square groove 340, and the permeating water flowing into the first square groove 340 flows into the second square groove 410 and is conveyed out of the channel through the water conveying pipe 400; one end of the water pipe 400 is connected with a flange 420, the length of the water pipe 400 is equal to the length of the connecting plate 210 and the rotating plate 220, the flange 420 is used for sequentially connecting the water pipes 400 of the water prevention and control devices, the positioning mechanism 100 and the water collecting mechanism 200 at the top of the device are continuous and parallel, and the joint of the water pipe 400 and the connecting column 320 is fixed on the side wall of the channel by using a fixing mechanism to prevent the water pipe 400 from sliding and the supporting mechanism 300 from vibrating.

The side wall of the positioning block 211 is fixed with the arc block 110 by a stud, so that the stability between the water collecting mechanism 200 and the positioning mechanism 100 is improved; the water collecting groove 212, the first round hole 213, the arc-shaped block 110, the first square groove 340 and the second square groove 410 are all provided with anti-rust layers so as to weaken the corrosion of the permeated water to the inside of the device.

The working principle is as follows: when the water collecting mechanism is used, the water collecting mechanism 200 is sequentially placed at the top of the positioning mechanism 100, the positioning block 211 and the arc block 110 are clamped and fixed at the position corresponding to the funnel-shaped hole 111 through the double-screw bolt, the filter screen 215 is embedded into the water collecting tank 212, and the hexagonal nut 223 is screwed at one end of the rotating shaft 222 to fix the angle of the rotating plate 220;

starting a machine to vertically lift the assembled water collecting mechanism 200 and the positioning mechanism 100, enabling the rotating plate 220 to be tightly attached to the top wall of the channel to collect the permeated water, respectively clamping and fixing two inserting strips 311 of an inserting block 310 of the supporting mechanism 300 at two ends of the arc-shaped block 110, screwing and connecting a base 350 at the bottom of the connecting column 320, and removing the auxiliary machine when the base 350 is adjusted to be parallel to the ground and stable;

the water pipe 400 is embedded in the position of the second round hole 330 in a sliding mode, the second square groove 410 corresponds to the bottom end of the first square groove 340, the adjacent water pipes 400 are connected through the flange 420, and the plurality of water prevention and control devices are connected and fixed; the guide groove 221 of the rotating plate 220 collects the top wall seepage water of the pot hole, the top wall seepage water passes through the water collecting groove 212, the first round hole 213, the first funnel-shaped hole 111, the gap between the arc block 110 and the liquid separating strip 120, the first square groove 340 and the second square groove 410 which are used for collecting and filtering the seepage water respectively, and finally the seepage water is collected in the water delivery pipe 400 discharge channel, the seepage water on the top wall of the channel is discharged while the channel is protected to be smoothly used, and the threat of the seepage water to the channel erosion to detection constructors is eliminated.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is illustrative and explanatory only, and various modifications, additions and substitutions as described for the specific embodiments described herein may be made by those skilled in the art without departing from the scope of the invention or exceeding the scope of the invention as defined in the claims.

Claims (7)

1. The water prevention and control device for geological measurement comprises a positioning mechanism (100) and a water collection mechanism (200), and is characterized in that the positioning mechanism (100) comprises an arc-shaped block (110), a plurality of funnel-shaped holes (111) are uniformly formed in the middle of the arc-shaped surface of the arc-shaped block (110), and a liquid separation strip (120) is attached to the bottom surface of the arc-shaped block (110);

the top end of the positioning mechanism (100) is provided with a plurality of water collecting mechanisms (200) corresponding to the positions of the funnel-shaped holes (111), each water collecting mechanism (200) comprises a connecting plate (210), a positioning block (211) is fixedly connected to the middle position of the bottom surface of each connecting plate (210), the positioning blocks (211) are in sliding clamping connection with the corresponding positions of the arc-shaped blocks (110), a water accumulating groove (212) is formed in the middle position of the top surface of each connecting plate (210), a first round hole (213) is formed in the center of each connecting plate (210), and four transverse grooves (214) are symmetrically formed in two sides of each connecting plate (210); connecting hole (2141) have been seted up to the both sides wall symmetry of horizontal groove (214), the bilateral symmetry of connecting plate (210) is provided with two rotor plates (220), and two guide way (221) have all been seted up to rotor plate (220) near a lateral wall in ponding groove (212), the bottom of rotor plate (220) has linked firmly axis of rotation (222), the both ends of axis of rotation (222) rotate with connecting hole (2141) that correspond the position respectively and are connected, the both ends symmetry of positioning mechanism (100) is provided with two supporting mechanism (300).

2. The water control device for geological measurement according to claim 1, wherein the supporting mechanism (300) comprises an inserting block (310), two inserting strips (311) are symmetrically and fixedly connected to one side face of the inserting block (310), one side, adjacent to the two inserting strips (311), of each inserting strip is attached to two sides of one end of the arc-shaped block (110), the bottoms of the two inserting strips (311) are attached to one end of the top of the liquid separating strip (120), the bottom face of the inserting block (310) is fixedly connected with a connecting column (320), a round hole II (330) is formed in the bottom of the connecting column (320), a square groove I (340) is formed in the connecting column (320) and located between the inserting block (310) and the round hole II (330) along the vertical center line of the connecting column, and the bottom end of the connecting column (320) is connected with a base (350) in a screwing mode.

3. The water control device for geological measurement as recited in claim 2, wherein a water pipe (400) is slidably embedded into the inner side of the round hole II (330), and a square groove II (410) is formed in the side wall of the middle position of the water pipe (400).

4. The device as claimed in claim 1, wherein the water collecting tank (212) is embedded with a filter screen (215).

5. The water control device for geological survey according to claim 1, characterized in that a hexagonal nut (223) is screwed to one end of the rotation shaft (222) near the connection hole (2141), and the rotation angle of the rotation plate (220) is 0-60 °.

6. The water control device for geological survey according to claim 3, characterized in that the size of square groove two (410) is larger than the size of square groove one (340).

7. The water control device for geological measurement according to claim 3, characterized in that one end of the water pipe (400) is connected with a flange (420), and the length of the water pipe (400) is equal to the length of the connecting plate (210) and the rotating plate (220).

Images