CN203894225U - Mining geology water potential layering collector - Google Patents
Mining geology water potential layering collector Download PDFInfo
- Publication number
- CN203894225U CN203894225U CN201420334212.9U CN201420334212U CN203894225U CN 203894225 U CN203894225 U CN 203894225U CN 201420334212 U CN201420334212 U CN 201420334212U CN 203894225 U CN203894225 U CN 203894225U
- Authority
- CN
- China
- Prior art keywords
- flow
- pipe
- collecting unit
- handle
- water collecting
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Landscapes
- Pit Excavations, Shoring, Fill Or Stabilisation Of Slopes (AREA)
Abstract
The utility model discloses a mining geology water potential layering collector, relating to the field of mining geology exploration and aiming at solving the problem of being incapable of realizing the collection on the underground layering water potential. N groups of water potential collection units are connected sequentially end to end from top to bottom to form a cylinder type structure; a NO.1 cone is coaxially fixed on the tail end of the water potential collection unit at the lowermost position; a handle is fixed on the initial end of the water potential collection unit at the uppermost position; a through hole is formed in the handle, one end of a gas guide pipeline passes through the through hole and extends above the handle, the gas guide pipeline is fixedly connected with the handle through the through hole; the other end of the gas guide pipeline is fixedly connected with a NO.3 cone; and the side surface of the No.3 cone is fixedly connected with the side wall of a water collecting pipe positioned in the water potential collection unit at the lowermost position. The mining geology water potential layering collector is applicable to the layering collection of mining geology water potential.
Description
Technical field
The utility model relates to Mine geological prospecting field.
Background technology
Geologic prospecting is for finding out mineral reserve distribution situation, the situations such as the position of mensuration ore body, shape, size, the regularity of ore formation, rock property, tectonic structure.
The underground flow of water situation in mining area is the larger influence factor of mining activities, and under earth's surface, the flow of water state of each soil layer and the flow of water change and will determine final recovery scheme.But at present, for the flow of water collection under earth's surface, only can realize the whole flow of water collection of investigation depth, cannot realize the collection of the layering flow of water.
Utility model content
The utility model is in order to solve the existing problem that cannot realize the collection of the earth's surface lower leaf flow of water, thereby a kind of mining geology flow of water layering collector is provided.
Mining geology flow of water layering collector, it comprises handle 1, circular cone 2, N group flow of water collecting unit, gas-guide pipeline 9 and No. three circular cones 10; N is greater than 1 integer;
Every group of flow of water collecting unit comprises vitrified-clay pipe 3, collector pipe 5, air guide connecting pipe 8 and M the wing 4 that catchments; M is greater than 1 integer;
The top of vitrified-clay pipe 3 is head ends of this group flow of water collecting unit, the end sealing of described vitrified-clay pipe 3; The bottom of described vitrified-clay pipe 3 is communicated with the top of collector pipe; The bottom end seal of described collector pipe 5; The bottom of described collector pipe is the tail end of this group flow of water collecting unit;
M catchments, and the wing 4 is top end opening and lower end is tapered structure; The M wing 4 that catchments is uniform and be fixed on the lateral wall of vitrified-clay pipe 3; On the sidewall of the vitrified-clay pipe 3 of each wing 4 correspondence of catchmenting, all have gully-hole;
On the sidewall of collector pipe 5, have gas port, this gas port is communicated with gas-guide pipeline 9 by air guide connecting pipe 8;
The head and the tail connection successively from top to bottom of N group flow of water collecting unit, forms right cylinder formula structure;
Be positioned at the tail end of the flow of water collecting unit of below and be coaxially fixed with circular cone 2 No. one; The head end that is positioned at the flow of water collecting unit of the top is fixed with handle 1;
On handle 1, have a through hole, one end of gas-guide pipeline 9 is by this through hole and extend to handle 1 top, and the pipeline of described gas-guide pipeline 9 is fixedly connected with handle 1 by this through hole; The other end of described gas-guide pipeline 9 is fixedly connected with No. three circular cones 10;
The side of No. three circular cones 10 be arranged in the sidewall of the collector pipe 5 of the flow of water collecting unit of below and be fixedly connected with.
It also comprises N level sensor 11, outlet pipeline 6 and No. two circular cones 7;
Every group of flow of water collecting unit also comprises outlet connecting pipe 13, on the sidewall of collector pipe 5, has wire hole, and this wire hole is communicated with outlet pipeline 9 by conductor connecting pipe 13; Level sensor 11 in this group flow of water collecting unit extends to the outside of outlet pipeline 9 successively through wire hole, conductor connecting pipe 13 and outlet pipeline 9 on collector pipe 5 sidewalls;
The left side of handle 1 has through hole, and one end of described outlet pipeline 6 extends to handle 1 top through this through hole, and the pipeline of described outlet pipeline 6 is fixedly connected with handle 1 by this through hole;
The other end of outlet pipeline 6 is fixedly connected with No. two circular cones 7; The side of No. two circular cones 7 be arranged in the sidewall of the collector pipe 5 of the flow of water collecting unit of below and be fixedly connected with;
N level sensor 11 lays respectively in N collector pipe 5.
It also comprises extension rod 12, and the head end of collector pipe 5 that is arranged in the flow of water collecting unit of the top is connected with handle 1 by connecting link 12.
The utility model can be realized the collection of the layer-stepping flow of water, and the liquid water content of realizing different soil gathers respectively, and acquisition precision is high.
Accompanying drawing explanation
Fig. 1 is structural representation of the present utility model.
Embodiment
Embodiment one, in conjunction with Fig. 1, this embodiment is described, mining geology flow of water layering collector, it comprises handle 1, circular cone 2, N group flow of water collecting unit, gas-guide pipeline 9 and No. three circular cones 10; N is greater than 1 integer;
Every group of flow of water collecting unit comprises vitrified-clay pipe 3, collector pipe 5, air guide connecting pipe 8 and M the wing 4 that catchments; M is greater than 1 integer;
The top of vitrified-clay pipe 3 is head ends of this group flow of water collecting unit, the end sealing of described vitrified-clay pipe 3; The bottom of described vitrified-clay pipe 3 is communicated with the top of collector pipe; The bottom end seal of described collector pipe 5; The bottom of described collector pipe is the tail end of this group flow of water collecting unit;
M catchments, and the wing 4 is top end opening and lower end is tapered structure; The M wing 4 that catchments is uniform and be fixed on the lateral wall of vitrified-clay pipe 3; On the sidewall of the vitrified-clay pipe 3 of each wing 4 correspondence of catchmenting, all have gully-hole;
On the sidewall of collector pipe 5, have gas port, this gas port is communicated with gas-guide pipeline 9 by air guide connecting pipe 8;
The head and the tail connection successively from top to bottom of N group flow of water collecting unit, forms right cylinder formula structure;
Be positioned at the tail end of the flow of water collecting unit of below and be coaxially fixed with circular cone 2 No. one; The head end that is positioned at the flow of water collecting unit of the top is fixed with handle 1;
On handle 1, have a through hole, one end of gas-guide pipeline 9 is by this through hole and extend to handle 1 top, and the pipeline of described gas-guide pipeline 9 is fixedly connected with handle 1 by this through hole; The other end of described gas-guide pipeline 9 is fixedly connected with No. three circular cones 10;
The side of No. three circular cones 10 be arranged in the sidewall of the collector pipe 5 of the flow of water collecting unit of below and be fixedly connected with.
The difference of the mining geology flow of water layering collector described in embodiment two, this embodiment and embodiment one is, it also comprises N level sensor 11, outlet pipeline 6 and No. two circular cones 7;
Every group of flow of water collecting unit also comprises outlet connecting pipe 13, on the sidewall of collector pipe 5, has wire hole, and this wire hole is communicated with outlet pipeline 9 by conductor connecting pipe 13; Level sensor 11 in this group flow of water collecting unit extends to the outside of outlet pipeline 9 successively through wire hole, conductor connecting pipe 13 and outlet pipeline 9 on collector pipe 5 sidewalls;
The left side of handle 1 has through hole, and one end of described outlet pipeline 6 extends to handle 1 top through this through hole, and the pipeline of described outlet pipeline 6 is fixedly connected with handle 1 by this through hole;
The other end of outlet pipeline 6 is fixedly connected with No. two circular cones 7; The side of No. two circular cones 7 be arranged in the sidewall of the collector pipe 5 of the flow of water collecting unit of below and be fixedly connected with;
N level sensor 11 lays respectively in N collector pipe 5.
Present embodiment before use, can gather the soil layer in mining area to be measured by existing soil sample harvester, defines the degree of depth of each soil layer.
Present embodiment in use, by pressing or thump handle, is inserted underground by main body of the present utility model.Make respectively to organize flow of water collecting unit and lay respectively at different soil layers.Because each group flow of water collecting unit is separate, therefore respectively organizing flow of water collecting unit will independently be collected in the flow of water of corresponding soil layer, thereby realizes the collection of the different soil flow of water.
The degree of depth in present embodiment can be threaded connection pipe and regulate, and installs the screw nipple of different length between two adjacent groups flow of water collecting unit additional that is:, realizes the adjusting of embedded depth and corresponding soil layer.
The difference of the mining geology flow of water layering collector described in embodiment three, this embodiment and embodiment one is, it also comprises extension rod 12, and the head end of collector pipe 5 that is arranged in the flow of water collecting unit of the top is connected with handle 1 by extension rod 12.
The difference of the mining geology flow of water layering collector described in embodiment four, this embodiment and embodiment one is, N=4.
The difference of the mining geology flow of water layering collector described in embodiment five, this embodiment and embodiment one is, M=4.
The difference of the mining geology flow of water layering collector described in embodiment six, this embodiment and embodiment one is, it also comprises filter screen, on each wing 4 that catchments, all arranges and a filter screen.
The object of present embodiment and effect are to prevent that soil from stopping up the gully-hole on vitrified-clay pipe.
Claims (5)
1. mining geology flow of water layering collector, is characterized in that: it comprises handle (1), a circular cone (2), N group flow of water collecting unit, gas-guide pipeline (9) and No. three circular cones (10); N is greater than 1 integer;
Every group of flow of water collecting unit comprises vitrified-clay pipe (3), collector pipe (5), air guide connecting pipe (8) and M the wing (4) that catchments; M is greater than 1 integer;
The top of vitrified-clay pipe (3) is the head end of this group flow of water collecting unit, the end sealing of described vitrified-clay pipe (3); The bottom of described vitrified-clay pipe (3) is communicated with the top of collector pipe; The bottom end seal of described collector pipe (5); The bottom of described collector pipe is the tail end of this group flow of water collecting unit;
M catchments, and the wing (4) is top end opening and lower end is tapered structure; The M wing (4) that catchments is uniform and be fixed on the lateral wall of vitrified-clay pipe (3); On the sidewall of the vitrified-clay pipe (3) that each wing that catchments (4) is corresponding, all have gully-hole;
On the sidewall of collector pipe (5), have gas port, this gas port is communicated with gas-guide pipeline (9) by air guide connecting pipe (8);
The head and the tail connection successively from top to bottom of N group flow of water collecting unit, forms right cylinder formula structure;
Be positioned at the tail end of the flow of water collecting unit of below and be coaxially fixed with a circular cone (2); The head end that is positioned at the flow of water collecting unit of the top is fixed with handle (1);
On handle (1), have a through hole, one end of gas-guide pipeline (9) is by this through hole and extend to handle (1) top, and the pipeline of described gas-guide pipeline (9) is fixedly connected with handle (1) by this through hole; The other end of described gas-guide pipeline (9) is fixedly connected with No. three circular cones (10);
The side of No. three circular cones (10) be arranged in the sidewall of the collector pipe (5) of the flow of water collecting unit of below and be fixedly connected with.
2. mining geology flow of water layering collector according to claim 1, is characterized in that it also comprises N level sensor (11), outlet pipeline (6) and No. two circular cones (7);
Every group of flow of water collecting unit also comprises outlet connecting pipe (13), on the sidewall of collector pipe (5), has wire hole, and this wire hole is communicated with outlet pipeline (9) by conductor connecting pipe (13); Level sensor (11) in this group flow of water collecting unit extends to the outside of outlet pipeline (9) successively through wire hole, conductor connecting pipe (13) and outlet pipeline (9) on collector pipe (5) sidewall;
The left side of handle (1) has through hole, and one end of described outlet pipeline (6) extends to handle (1) top through this through hole, and the pipeline of described outlet pipeline (6) is fixedly connected with handle (1) by this through hole;
The other end of outlet pipeline (6) is fixedly connected with No. two circular cones (7); The side of No. two circular cones (7) be arranged in the sidewall of the collector pipe (5) of the flow of water collecting unit of below and be fixedly connected with;
N level sensor (11) lays respectively in N collector pipe (5).
3. mining geology flow of water layering collector according to claim 1, it is characterized in that it also comprises extension rod (12), the head end of collector pipe (5) that is arranged in the flow of water collecting unit of the top is connected with handle (1) by extension rod (12).
4. mining geology flow of water layering collector according to claim 1, is characterized in that N=4.
5. mining geology flow of water layering collector according to claim 1, is characterized in that M=4.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201420334212.9U CN203894225U (en) | 2014-06-20 | 2014-06-20 | Mining geology water potential layering collector |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201420334212.9U CN203894225U (en) | 2014-06-20 | 2014-06-20 | Mining geology water potential layering collector |
Publications (1)
Publication Number | Publication Date |
---|---|
CN203894225U true CN203894225U (en) | 2014-10-22 |
Family
ID=51720612
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201420334212.9U Expired - Fee Related CN203894225U (en) | 2014-06-20 | 2014-06-20 | Mining geology water potential layering collector |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN203894225U (en) |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104391105A (en) * | 2014-12-03 | 2015-03-04 | 南京林业大学 | Water-free soil matrix potential profile measurement device |
CN104990575A (en) * | 2015-07-09 | 2015-10-21 | 中国地质大学(武汉) | Combined underground water monitoring device |
CN105526969A (en) * | 2016-03-18 | 2016-04-27 | 张豫 | River water ecosystem environmental factor acquisition method |
CN109507381A (en) * | 2018-11-29 | 2019-03-22 | 福建力普检测有限公司 | A kind of mudflat seawater water monitoring device |
-
2014
- 2014-06-20 CN CN201420334212.9U patent/CN203894225U/en not_active Expired - Fee Related
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104391105A (en) * | 2014-12-03 | 2015-03-04 | 南京林业大学 | Water-free soil matrix potential profile measurement device |
CN104391105B (en) * | 2014-12-03 | 2016-01-20 | 南京林业大学 | A kind of anhydrous soil matrix gesture profile survey device |
CN104990575A (en) * | 2015-07-09 | 2015-10-21 | 中国地质大学(武汉) | Combined underground water monitoring device |
CN105526969A (en) * | 2016-03-18 | 2016-04-27 | 张豫 | River water ecosystem environmental factor acquisition method |
CN105526969B (en) * | 2016-03-18 | 2018-04-24 | 广州地理研究所 | River aquatic ecosystem envirment factor acquisition method |
CN109507381A (en) * | 2018-11-29 | 2019-03-22 | 福建力普检测有限公司 | A kind of mudflat seawater water monitoring device |
CN109507381B (en) * | 2018-11-29 | 2019-10-11 | 福建力普检测有限公司 | A kind of mudflat seawater water monitoring device |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN203894225U (en) | Mining geology water potential layering collector | |
US9371185B2 (en) | Method for distributed storage and use of underground water in mine | |
CN105242028B (en) | One kind is taken out filling by skyscraper load and subsoil water and causes soil body delaminating deposition model test apparatus and test method | |
CN103670383B (en) | A kind of method and apparatus identifying shale oil deposit Effective Reservoirs | |
EP2975436A3 (en) | Systems, machines, program products, transmitter assemblies and associated sensors to explore and analyze subterranean geophysical formations | |
Zhu et al. | Seismic-based sediment provenance analysis in continental lacustrine rift basins: An example from the Bohai Bay Basin, China | |
CN104989369B (en) | A kind of huge discharge downhole oil-water separation annular space measuring and adjusting system | |
CN103114827B (en) | Multi-scenarios method coal bed gas extraction simulation experiment method | |
CN101806224B (en) | Method for predicting extraction productivity of underground coal-seam gas | |
CN202494442U (en) | Stratum layering and settlement measuring device | |
CN203658352U (en) | Water gushing-sand pouring disaster simulation test system of coal-seam mining induction top plate | |
CN104533402A (en) | Multi-phase superimposed combined braided channel sand phase determining method | |
CN103454119A (en) | Portable soil moisture in-situ collector | |
CN205120708U (en) | Test device of mechanism is subsided in simulation collecting space area | |
CN105866837A (en) | Offshore non-repetitive time-lapse seismic multi-stratum system mutual equalization processing method | |
CN203881563U (en) | Fixed point long-term mine site geological structure collection device | |
CN105604539A (en) | Multi-parameter combination logging probe | |
CN204728182U (en) | Grade elevation control device | |
CN102116170B (en) | Method for determining grid type layer-through drilling intervals of floor roadway | |
CN201857953U (en) | Advanced abutment pressure monitoring device on coal face | |
CN203721372U (en) | Deep well high-speed data transmission system cable | |
CN105607128A (en) | Geological fault detection method under hard and soft interbedded geological condition | |
CN205982659U (en) | Mend three -dimensional seismic prospecting observation system of coal of saying with big gun | |
CN203572970U (en) | Overburden failure range detection system under impact of mining | |
CN107741254A (en) | A kind of multifunctional monitoring device of coal field mining subsidence soil damage |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20141022 Termination date: 20170620 |
|
CF01 | Termination of patent right due to non-payment of annual fee |