CN203881563U - Fixed point long-term mine site geological structure collection device - Google Patents
Fixed point long-term mine site geological structure collection device Download PDFInfo
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- CN203881563U CN203881563U CN201420334214.8U CN201420334214U CN203881563U CN 203881563 U CN203881563 U CN 203881563U CN 201420334214 U CN201420334214 U CN 201420334214U CN 203881563 U CN203881563 U CN 203881563U
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- steel pipe
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Abstract
The utility model discloses a fixed point long-term mine site geological structure collection device and relates to a geological structure collection device. The fixed point long-term mine site geological structure collection device aims at solving the problem that the existing mine site geological structure detection is low in accuracy due to the fact that long-term fixed point collection cannot be achieved. A cross strain sensor, a longitudinal strain sensor, a soil pressure, a displacement meter, a temperature sensor and a humidity sensor are respectively arranged inside a first soil collection wing, a second soil collection wing, a third soil collection wing, a fourth soil collection wing, a fifth soil collection wind and a sixth soil collection wing; a conical head is fixed at the lower end of a steel pipe; a rotary handle is vertically fixed at the top of the steel pipe; a disc type handle of every soil collector is vertically fixed at the top of a steel pipe type soil collection chamber; a detection box is a box body with the upper end provided with an opening; the bottom side of the detection box is provided with three through holes; lower ends of the two soil collectors and the lower end of a detector respectively penetrate the three through holes to extend to the exterior of the detection box. The fixed point long-term mine site geological structure collection device is applicable to mine site geological structure exploration process.
Description
Technical field
The utility model relates to a kind of tectonic structure harvester.
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.
For the on-the-spot tectonic structure in mine, survey because the difference of geologic condition is selected different modes at present, as rock geology adopts the drill bit that can smash rock, carry out soil sample detection etc.
These modes are all to carry out disposable detection by the mode of reconnaissance, and it is larger that Effect on Detecting is affected by acquisition environment, and the actual architectonic error in the result of detection and this area is larger, and detection accuracy is lower.
Utility model content
The utility model is owing to cannot realizing the collection of long-term fixed point, to cause the problem that detection accuracy is low in order to solve the on-the-spot architectonic detection in existing mine, thereby the on-the-spot tectonic structure in a kind of mine long-term harvester of fixing a point is provided.
The on-the-spot tectonic structure in the mine long-term harvester of fixing a point, it comprises surveys case 1, two soil-collecting devices and detectors;
Detector comprises steel pipe 2, collect the native wing 4 for No. one, collect the native wing 5 for No. two, collect the native wing 6 for No. three, collect the native wing 7 for No. four, collect the native wing 8 for No. five, collect the native wing 9, conical head 10 and rotary handle 11, transverse strain sensor 41, longitudinal strain sensor 51, earth pressure gauge 61, displacement meter 71, temperature sensor 81 and humidity sensor 91 No. six;
Describedly collect the native wing 4 for No. one, collect the native wing 5 for No. two, collect the native wing 6 for No. three, collect the native wing 7 for No. four, collect the native wing 8 No. five and collect that the native wing 9 is end openings and front end is tapered structure for No. six;
Collect the native wing 4 for No. one and collect the native wing 5 mirrors for No. two to the both sides that are fixed on steel pipe 2;
Collect the native wing 6 for No. three and collect the native wing 7 mirrors for No. four to the both sides that are fixed on steel pipe 2;
Collect the native wing 8 for No. five and collect the native wing 9 mirrors for No. six to the both sides that are fixed on steel pipe 2;
Collect the native wing 4 for No. one and collect the top that the native wing 5 is positioned at steel pipe 2 for No. two;
Collect the native wing 6 for No. three and collect the middle part that the native wing 7 is positioned at steel pipe 2 for No. four;
Collect the native wing 8 for No. five and collect the bottom that the native wing 9 is positioned at steel pipe 2 for No. six;
Transverse strain sensor 41, longitudinal strain sensor 51, earth pressure gauge 61, displacement meter 71, temperature sensor 81 and humidity sensor 91 are separately positioned on and collect the native wing 4 for No. one, collect the native wing 5 for No. two, collect the native wing 6 for No. three, collect the native wing 7 for No. four, collect the native wing 8 and collect for No. six in the native wing 9 for No. five;
Collect the native wing 4 for No. one, collect the native wing 5 for No. two, collect the native wing 6 for No. three, collect the native wing 7 for No. four, collect the native wing 8 and collect for No. six on the native wing 9 for No. five and have cable hole, on steel pipe 2, have six cable holes,
The data line of transverse strain sensor 41 successively penetrates steel pipe 2 inside through cable hole and first cable hole on steel pipe 2 of collecting the native wing 4 for No. one, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of longitudinal strain sensor 51 is successively through collecting the cable hole of the native wing 5 for No. two and second cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of earth pressure gauge 61 is successively through collecting the cable hole of the native wing 6 for No. three and the 3rd cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of displacement meter 71 is successively through collecting the cable hole of the native wing 7 for No. four and the 4th cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of temperature sensor 81 is successively through collecting the cable hole of the native wing 8 for No. five and the 5th cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of humidity sensor 91 is successively through collecting the cable hole of the native wing 9 for No. six and the 6th cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
Conical head 10 is fixed on the lower end of steel pipe 2, and rotary handle 11 is vertically fixed on the top of steel pipe 2;
Each soil-collecting device comprises disc type handle 21 and steel pipe type collection provincialism 22, and described steel pipe type integrates the bottom of provincialism 22 as conical structure; Disc type handle 21 is directly fixed on the top of steel pipe type collection provincialism 22;
Detection case 1 is the casing of upper shed, and the bottom surface of described detection case 1 has three through holes, and the lower end of two soil-collecting devices and the lower end of detector extend to through these three through holes the outside of surveying case 1 respectively.
It also comprises that each soil-collecting device also comprises circular arc armourplate glass 23, on the sidewall of described steel pipe type collection provincialism 22, connects and has form along its length, and circular arc armourplate glass 23 is by this form sealing.
Top and the bottom of steel pipe 2 are helicitic texture, and the mode that conical head 10 is threaded connection is fixed on the lower end of steel pipe 2, and the mode that rotary handle 11 is threaded connection is vertically fixed on the top of steel pipe 2.
The length of surveying case 1 is greater than the length of soil-collecting device, and is greater than the length of detector.
The utility model in use, is embedded in scene, mine by detection case 1, makes main body fixed point of the present utility model be arranged in continuously the soil layer under earth's surface, thereby realize the on-the-spot architectonic structured data in mine, fixes a point for a long time to survey, and detecting error is little, and detection accuracy is high.The utility model is preserved original soil sample simultaneously, as the long-term comparison sample of surveying of geology, thereby realizes the precise monitoring of qualitative change over the ground.
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, the on-the-spot tectonic structure in the mine long-term sniffer of fixing a point, it comprises surveys case 1, two soil-collecting devices and detectors;
Detector comprises steel pipe 2, collect the native wing 4 for No. one, collect the native wing 5 for No. two, collect the native wing 6 for No. three, collect the native wing 7 for No. four, collect the native wing 8 for No. five, collect the native wing 9, conical head 10 and rotary handle 11, transverse strain sensor 41, longitudinal strain sensor 51, earth pressure gauge 61, displacement meter 71, temperature sensor 81 and humidity sensor 91 No. six;
Describedly collect the native wing 4 for No. one, collect the native wing 5 for No. two, collect the native wing 6 for No. three, collect the native wing 7 for No. four, collect the native wing 8 No. five and collect that the native wing 9 is end openings and front end is tapered structure for No. six;
Collect the native wing 4 for No. one and collect the native wing 5 mirrors for No. two to the both sides that are fixed on steel pipe 2;
Collect the native wing 6 for No. three and collect the native wing 7 mirrors for No. four to the both sides that are fixed on steel pipe 2;
Collect the native wing 8 for No. five and collect the native wing 9 mirrors for No. six to the both sides that are fixed on steel pipe 2;
Collect the native wing 4 for No. one and collect the top that the native wing 5 is positioned at steel pipe 2 for No. two;
Collect the native wing 6 for No. three and collect the middle part that the native wing 7 is positioned at steel pipe 2 for No. four;
Collect the native wing 8 for No. five and collect the bottom that the native wing 9 is positioned at steel pipe 2 for No. six;
Transverse strain sensor 41, longitudinal strain sensor 51, earth pressure gauge 61, displacement meter 71, temperature sensor 81 and humidity sensor 91 are separately positioned on and collect the native wing 4 for No. one, collect the native wing 5 for No. two, collect the native wing 6 for No. three, collect the native wing 7 for No. four, collect the native wing 8 and collect for No. six in the native wing 9 for No. five;
Collect the native wing 4 for No. one, collect the native wing 5 for No. two, collect the native wing 6 for No. three, collect the native wing 7 for No. four, collect the native wing 8 and collect for No. six on the native wing 9 for No. five and have cable hole, on steel pipe 2, have six cable holes,
The data line of transverse strain sensor 41 successively penetrates steel pipe 2 inside through cable hole and first cable hole on steel pipe 2 of collecting the native wing 4 for No. one, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of longitudinal strain sensor 51 is successively through collecting the cable hole of the native wing 5 for No. two and second cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of earth pressure gauge 61 is successively through collecting the cable hole of the native wing 6 for No. three and the 3rd cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of displacement meter 71 is successively through collecting the cable hole of the native wing 7 for No. four and the 4th cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of temperature sensor 81 is successively through collecting the cable hole of the native wing 8 for No. five and the 5th cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
The data line of humidity sensor 91 is successively through collecting the cable hole of the native wing 9 for No. six and the 6th cable hole on steel pipe 2 penetrates steel pipe 2 inside, and through the upper end of steel pipe 2, extend out to the outside of steel pipe 2;
Conical head 10 is fixed on the lower end of steel pipe 2, and rotary handle 11 is vertically fixed on the top of steel pipe 2;
Each soil-collecting device comprises disc type handle 21 and steel pipe type collection provincialism 22, and described steel pipe type integrates the bottom of provincialism 22 as conical structure; Disc type handle 21 is directly fixed on the top of steel pipe type collection provincialism 22;
Detection case 1 is the casing of upper shed, and the bottom surface of described detection case 1 has three through holes, and the lower end of two soil-collecting devices and the lower end of detector extend to through these three through holes the outside of surveying case 1 respectively.
Principle of work: the utility model in use, is imbedded detection case below earth's surface; Then by disk handle, a soil-collecting device is screwed in to soil layer, then screw out and obtain original soil sample, and preserve.
Then rotary handle screws in soil layer by detector, by transverse strain sensor 41, longitudinal strain sensor 51, earth pressure gauge 61, displacement meter 71, temperature sensor 81 and humidity sensor 91, gather transverse strain, longitudinal strain, pressure, displacement, the temperature and humidity of this regional soil, testing staff gathers above-mentioned data by checkout equipment at external lead-in wire place, realizes the detection of the on-the-spot tectonic structure structured data in mine.
When needs are known current soil sample data, adopt disk handle that second soil-collecting device screwed in to soil layer, gather current soil sample, by the soil sample data with original, contrast, realize the detection that soil sample is changed.
The fix a point difference of long-term sniffer of the on-the-spot tectonic structure in mine described in embodiment two, this embodiment and embodiment one is, it also comprises that each soil-collecting device also comprises circular arc armourplate glass 23, on the sidewall of described steel pipe type collection provincialism 22, connect and have form along its length, circular arc armourplate glass 23 is by this form sealing.
Present embodiment can be observed the hierarchical structure of the soil sample of collection intuitively.Meanwhile, this armourplate glass can be set to demountable structure, convenient wherein certain a part of soil sample of taking out.
The fix a point difference of long-term sniffer of the on-the-spot tectonic structure in mine described in embodiment three, this embodiment and embodiment one is, top and the bottom of steel pipe 2 are helicitic texture, the mode that conical head 10 is threaded connection is fixed on the lower end of steel pipe 2, and the mode that rotary handle 11 is threaded connection is vertically fixed on the top of steel pipe 2.
Present embodiment adopts the mode of screw thread, when needs deep layer samples, is threaded connection extension tube, can realize the soil sample of deep layer.
The fix a point difference of long-term sniffer of the on-the-spot tectonic structure in mine described in embodiment four, this embodiment and embodiment one is, the length of surveying case 1 is greater than the length of soil-collecting device, and is greater than the length of detector.
In present embodiment, when one of them soil-collecting device collects initial soil sample, be about to soil-collecting device and be placed in detection case, realize the complete preservation of original soil sample, meanwhile, survey case 1 and can also take in this soil-collecting device and detector simultaneously, be convenient for carrying.Again and, surveying case 1 can also be that water-proof type is surveyed case, protection detector and soil-collecting device are not subject to the impact of rainwater.
Claims (4)
1. the on-the-spot tectonic structure in the mine long-term harvester of fixing a point, is characterized in that: it comprises surveys case (1), two soil-collecting devices and a detector;
Detector comprises steel pipe (2), collects the native wing (4) for No. one, collects the native wing (5) for No. two, collects the native wing (6) for No. three, collects the native wing (7) for No. four, collects the native wing (8) for No. five, collects the native wing (9) for No. six, conical head (10) and rotary handle (11), transverse strain sensor (41), longitudinal strain sensor (51), earth pressure gauge (61), displacement meter (71), temperature sensor (81) and humidity sensor (91);
Describedly collect the native wing (4) for No. one, collect the native wing (5) for No. two, collect the native wing (6) for No. three, collect the native wing (7) for No. four, collect the native wing (8) for No. five and collect that the native wing (9) is end openings and front end is tapered structure for No. six;
Collect the native wing (4) for No. one and collect the native wing (5) mirror for No. two to the both sides that are fixed on steel pipe (2);
Collect the native wing (6) for No. three and collect the native wing (7) mirror for No. four to the both sides that are fixed on steel pipe (2);
Collect the native wing (8) for No. five and collect the native wing (9) mirror for No. six to the both sides that are fixed on steel pipe (2);
Collect the native wing (4) for No. one and collect the top that the native wing (5) is positioned at steel pipe (2) for No. two;
Collect the native wing (6) for No. three and collect the middle part that the native wing (7) is positioned at steel pipe (2) for No. four;
Collect the native wing (8) for No. five and collect the bottom that the native wing (9) is positioned at steel pipe (2) for No. six;
Transverse strain sensor (41), longitudinal strain sensor (51), earth pressure gauge (61), displacement meter (71), temperature sensor (81) and humidity sensor (91) are separately positioned on and collect the native wing (4) for No. one, collect the native wing (5) for No. two, collect the native wing (6) for No. three, collect the native wing (7) for No. four, collect the native wing (8) for No. five and collect for No. six in the native wing (9);
Collect the native wing (4) for No. one, collect the native wing (5) for No. two, collect the native wing (6) for No. three, collect the native wing (7) for No. four, collect the native wing (8) for No. five and collect for No. six on the native wing (9) and have cable hole, on steel pipe (2), have six cable holes;
The data line of transverse strain sensor (41) successively penetrates steel pipe (2) inside through cable hole and first cable hole on steel pipe (2) of collecting the native wing (4) for No. one, and through the upper end of steel pipe (2), extend out to the outside of steel pipe (2);
The data line of longitudinal strain sensor (51) successively penetrates steel pipe (2) inside through the cable hole and second cable hole on steel pipe (2) that collect the native wing (5) for No. two, and through the upper end of steel pipe (2), extend out to the outside of steel pipe (2);
The data line of earth pressure gauge (61) is successively through collecting the cable hole of the native wing (6) for No. three and the 3rd cable hole on steel pipe (2) penetrates steel pipe (2) inside, and through the upper end of steel pipe (2), extend out to the outside of steel pipe (2);
The data line of displacement meter (71) is successively through collecting the cable hole of the native wing (7) for No. four and the 4th cable hole on steel pipe (2) penetrates steel pipe (2) inside, and through the upper end of steel pipe (2), extend out to the outside of steel pipe (2);
The data line of temperature sensor (81) is successively through collecting the cable hole of the native wing (8) for No. five and the 5th cable hole on steel pipe (2) penetrates steel pipe (2) inside, and through the upper end of steel pipe (2), extend out to the outside of steel pipe (2);
The data line of humidity sensor (91) is successively through collecting the cable hole of the native wing (9) for No. six and the 6th cable hole on steel pipe (2) penetrates steel pipe (2) inside, and through the upper end of steel pipe (2), extend out to the outside of steel pipe (2);
Conical head (10) is fixed on the lower end of steel pipe (2), and rotary handle (11) is vertically fixed on the top of steel pipe (2);
Each soil-collecting device comprises disc type handle (21) and steel pipe type collection provincialism (22), and described steel pipe type integrates the bottom of provincialism (22) as conical structure; Disc type handle (21) is directly fixed on the top of steel pipe type collection provincialism (22);
Surveying case (1) is the casing of upper shed, and the bottom surface of described detection case (1) has three through holes, and the lower end of two soil-collecting devices and the lower end of detector extend to through these three through holes the outside of surveying case (1) respectively.
2. the on-the-spot tectonic structure in the mine according to claim 1 long-term harvester of fixing a point, it is characterized in that it also comprises that each soil-collecting device also comprises circular arc armourplate glass (23), on the sidewall of described steel pipe type collection provincialism (22), connect and have form along its length, circular arc armourplate glass (23) is by this form sealing.
3. the on-the-spot tectonic structure in the mine according to claim 1 long-term harvester of fixing a point, the top and the bottom that it is characterized in that steel pipe (2) are helicitic texture, the mode that conical head (10) is threaded connection is fixed on the lower end of steel pipe (2), and the mode that rotary handle (11) is threaded connection is vertically fixed on the top of steel pipe (2).
4. the on-the-spot tectonic structure in the mine according to claim 1 long-term harvester of fixing a point, is characterized in that the length of surveying case (1) is greater than the length of soil-collecting device, and is greater than the length of detector.
Priority Applications (1)
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CN201420334214.8U CN203881563U (en) | 2014-06-20 | 2014-06-20 | Fixed point long-term mine site geological structure collection device |
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CN201420334214.8U CN203881563U (en) | 2014-06-20 | 2014-06-20 | Fixed point long-term mine site geological structure collection device |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN106525498A (en) * | 2016-12-16 | 2017-03-22 | 鞍钢集团矿业有限公司 | Easy quantitative sampling device for inhomogeneous powder |
CN109209499A (en) * | 2018-07-06 | 2019-01-15 | 黑龙江工业学院 | Coal Mine Safety Monitoring System and monitoring method under wireless self-networking based on fiber Bragg grating sensor |
CN111472842A (en) * | 2020-04-01 | 2020-07-31 | 安徽金联地矿科技有限公司 | Mine underground environment detection device and control system thereof |
-
2014
- 2014-06-20 CN CN201420334214.8U patent/CN203881563U/en not_active Expired - Fee Related
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN106525498A (en) * | 2016-12-16 | 2017-03-22 | 鞍钢集团矿业有限公司 | Easy quantitative sampling device for inhomogeneous powder |
CN109209499A (en) * | 2018-07-06 | 2019-01-15 | 黑龙江工业学院 | Coal Mine Safety Monitoring System and monitoring method under wireless self-networking based on fiber Bragg grating sensor |
CN111472842A (en) * | 2020-04-01 | 2020-07-31 | 安徽金联地矿科技有限公司 | Mine underground environment detection device and control system thereof |
CN111472842B (en) * | 2020-04-01 | 2022-06-10 | 安徽金联地矿科技有限公司 | Mine underground environment detection device and control system thereof |
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