CN212964167U - Water resource intelligent data acquisition system - Google Patents
Water resource intelligent data acquisition system Download PDFInfo
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- CN212964167U CN212964167U CN202022255780.8U CN202022255780U CN212964167U CN 212964167 U CN212964167 U CN 212964167U CN 202022255780 U CN202022255780 U CN 202022255780U CN 212964167 U CN212964167 U CN 212964167U
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Abstract
An intelligent water resource data acquisition system comprises a driving mechanism and a sampling mechanism; the driving mechanism comprises a first motor, a first steel rope is wound on an output shaft of the first motor, the first steel rope is fixedly connected with a heavy hammer, and the heavy hammer is fixedly connected with a second steel rope; sampling mechanism includes the second motor with second steel cable fixed connection, the shell of second motor is through a plurality of connecting rod fixedly connected with base members, wear to be equipped with the sampling tube on the base member, the inside sample chamber of seting up a plurality of circumferencial direction evenly distributed along the sampling tube of base member, be provided with the sensor in the sample chamber, the base member rotates and is connected with the sleeve, telescopic upper end seals and with the output shaft fixed connection of second motor, the venthole has been seted up to telescopic upper end, the sampling tube stretches into in the sleeve, an inlet opening has been seted up on the telescopic section of thick bamboo wall, the inlet opening is linked together with one of them sample chamber. The utility model discloses can obtain the different water resource sample of many copies degree of depth in the sampling process, can obtain abundanter water resource data.
Description
Technical Field
The utility model relates to a water resource detects technical field, specific water resource intelligent data acquisition system that says so.
Background
In order to ensure the water safety, the quality of water resources needs to be detected on many occasions. In the detection process, the sampling precision directly influences the data acquisition result, and therefore is very important. In the prior art, sampling mostly depends on manual work, and the inefficiency is lower, or fixed point sampling, and the abundance of sample is relatively poor, if need improve the sample abundance, just need set up a plurality of sampling devices, and the cost is higher.
SUMMERY OF THE UTILITY MODEL
In order to solve the deficiencies in the prior art, the utility model aims to provide a water resource intelligence data acquisition system can obtain the different water resource sample of many copies degree of depth at a sampling in-process to can obtain abundanter water resource data, and efficiency is higher.
In order to achieve the above object, the utility model discloses a concrete scheme does:
an intelligent water resource data acquisition system comprises a driving mechanism and a sampling mechanism; the driving mechanism comprises a first motor, a first steel rope is wound on an output shaft of the first motor, a heavy hammer is fixedly connected with the first steel rope, and a second steel rope is fixedly connected with the heavy hammer; the sampling mechanism comprises a second motor fixedly connected with the second steel rope, a shell of the second motor is fixedly connected with a base body through a plurality of connecting rods, a sampling tube penetrates through the base body, a plurality of sample cavities which are uniformly distributed along the circumferential direction of the sampling tube are formed in the base body, a sensor is arranged in each sample cavity, the base body is rotatably connected with a sleeve, the upper end of the sleeve is sealed and fixedly connected with an output shaft of the second motor, an air outlet is formed in the upper end of the sleeve, the sampling tube extends into the sleeve, a water inlet is formed in the wall of the sleeve, and the water inlet is communicated with one of the sample cavities.
Preferably, the driving mechanism comprises a guide cylinder, the guide cylinder is vertically arranged above the water surface, the upper end of the guide cylinder is connected with a pulley, and the first steel rope is wound around the pulley, penetrates through the guide cylinder and then is fixedly connected with the heavy hammer.
Preferably, the weight comprises an upper section and a lower section which are integrally connected, the upper section is cylindrical, the lower section is conical, and the large end of the lower section is fixedly connected with the upper section.
Preferably, the sample chamber penetrates through the bottom of the base body, a plurality of grooves corresponding to the sample chamber in a one-to-one manner are fixedly formed in the bottom of the base body, a third motor is arranged in each groove, an output shaft of the third motor is vertically arranged downwards and extends out of each groove, and a baffle is connected to the third motor in a driving manner and used for opening or closing the sample chamber.
Preferably, a filter screen is fixedly arranged inside the lower end of the sampling tube.
Preferably, the plurality of connecting rods are uniformly distributed along a circumferential direction of the second motor.
The utility model discloses can obtain the different water resource sample of many copies degree of depth in a sample process to can obtain abundanter water resource data, and efficiency is higher.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.
Fig. 1 is a schematic view of the overall structure of the embodiment of the present invention.
Fig. 2 is a schematic structural view of the sampling mechanism.
Reference numerals: 1-a first motor, 2-a first steel rope, 3-a pulley, 4-a guide cylinder, 5-a heavy hammer, 6-a second steel rope, 7-a sampling mechanism, 8-a second motor, 9-an air outlet, 10-a sleeve, 11-a sampling tube, 12-a base body, 13-a sample cavity, 14-a sensor, 15-a baffle, 16-a third motor, 17-a filter screen, 18-a water inlet and 19-a connecting rod.
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 and 2, fig. 1 is a schematic view of an overall structure of an embodiment of the present invention, and fig. 2 is a schematic view of a sampling mechanism.
An intelligent water resource data acquisition system comprises a driving mechanism and a sampling mechanism 7.
The driving mechanism comprises a first motor 1, a first steel rope 2 is wound on an output shaft of the first motor 1, a heavy hammer 5 is fixedly connected to the first steel rope 2, and a second steel rope 6 is fixedly connected to the heavy hammer 5.
When the water sampling device is used, the sampling mechanism 7 is firstly downwards placed into a water resource to be detected by using the driving mechanism, specifically, the first motor 1 is started to release the first steel rope 2 from the first motor 1, and under the action of the gravity of the heavy hammer 5, the second steel rope 6 and the sampling mechanism 7 downwards move until the sampling mechanism 7 enters the water resource. After the sampling mechanism 7 enters water resources, water enters the sampling tube 11 and flows upwards in the sampling tube 11 along with the downward movement of the sampling mechanism 7, meanwhile, air in the sampling tube 11 is extruded out of the air outlet hole 9, after the water enters the sleeve 10, the second motor 8 starts to drive the sleeve 10 to rotate, so that the water inlet hole 18 is communicated with a sample cavity 13, the water enters the sample cavity 13, and meanwhile, the air in the sample cavity 13 is discharged through the water inlet hole 18 and the air outlet hole 9; then the driving mechanism drives the sampling mechanism 7 to move downwards continuously, water in the sampling tube 11 gradually becomes deep water resource, at the moment, the second motor 8 drives the sleeve 10 to rotate again, so that the water in the sampling tube 11 flows into the other sample cavity 13 through the water inlet hole 18, and the rest is done in sequence, so that a plurality of samples with different depths can be obtained at one time. The drive mechanism can then be reversed to lift the sampling mechanism 7 out of the water supply and to take a sample for data acquisition using the sensor 14 in the sample chamber 13. After the data collection is complete, the sample in the sample chamber 13 may be expelled, thereby preparing for the next collection. It should be noted that the height of the air outlet 9 is higher than that of the water inlet 18.
The utility model discloses can obtain the different water resource sample of many copies degree of depth in a sample process to can obtain abundanter water resource data, and efficiency is higher.
Further, actuating mechanism includes guide cylinder 4, and guide cylinder 4 sets up perpendicularly above the surface of water, and the upper end of guide cylinder 4 is connected with pulley 3, and first steel cable 2 walks around pulley 3 and pass behind guide cylinder 4 and weight 5 fixed connection. In order to guarantee that sampling mechanism 7 can move down, set up guide cylinder 4, can restrict the direction of first steel cable 2 through guide cylinder 4, realize the direction, pulley 3 is used for avoiding first steel cable 2 and guide cylinder 4 long-time friction and impaired.
Furthermore, the weight 5 comprises an upper section and a lower section which are integrally connected, wherein the upper section is cylindrical, the lower section is conical, and the large end of the lower section is fixedly connected with the upper section. This weight 5 is more steady when getting into the aquatic, and difficult emergence is rocked to can keep the stability of sampling mechanism 7.
Further, in order to conveniently discharge the sample in the sample cavity 13, the sample cavity 13 penetrates through the bottom of the base body 12, a plurality of grooves corresponding to the sample cavity 13 in a one-to-one manner are fixedly formed in the bottom of the base body 12, a third motor 16 is arranged in each groove, an output shaft of the third motor 16 is vertically arranged downwards and extends out of each groove, the third motor 16 is in driving connection with a baffle 15, and the baffle 15 is used for opening or closing the sample cavity 13. During sampling, the third motor 16 drives the baffle 15 to close the lower end of the sample cavity 13, and after data collection is completed, the third motor 16 drives the baffle 15 to open the lower end of the sample cavity 13, so that the sample can flow downwards out of the sample cavity 13.
Further, a filter screen 17 is fixedly arranged inside the lower end of the sampling tube 11. The filter screen 17 can prevent impurities in water resource from entering the sampling tube 11 to cause the blockage of the sampling tube 11.
Further, the plurality of connecting rods 19 are uniformly distributed in the circumferential direction of the second motor 8. This distribution of the connecting rods 19 ensures that the sampling device 7 is stable.
The utility model discloses a concrete embodiment, a water resource intelligence data acquisition system, including actuating mechanism and sampling mechanism 7.
Actuating mechanism includes first motor 1, and the winding is equipped with first steel cable 2 on first motor 1's the output shaft, 2 fixedly connected with weights 5 of first steel cable, and weights 5 include integrative upper segment and hypomere that connects, and the upper segment is cylindricly, and the hypomere is coniform, the main aspects and the upper segment fixed connection of hypomere, the little end fixed connection of hypomere has second steel cable 6. The driving mechanism further comprises a guide cylinder 4, the guide cylinder 4 is vertically arranged above the water surface, the upper end of the guide cylinder 4 is connected with a pulley 3, and the first steel rope 2 bypasses the pulley 3 and penetrates through the guide cylinder 4 to be fixedly connected with a heavy hammer 5.
When the water resource sampler is used, firstly, the sampling mechanism 7 is downwards placed into a water resource to be detected by using the driving mechanism, specifically, the first motor 1 is started to detach the first steel rope 2 from the first motor 1, the heavy hammer 5, the second steel rope 6 and the sampling mechanism 7 downwards move under the action of the gravity of the heavy hammer 5 until the sampling mechanism 7 enters the water resource, and the guide cylinder 4 can guide the first steel rope 2 to avoid the inclination of the sampling mechanism 7. Before the sampling mechanism 7 enters water resources, the third motor 16 drives the baffle plate 15 to close the lower end of the sample cavity 13, after the sampling mechanism 7 enters the water resources, water enters the sampling tube 11 and flows upwards in the sampling tube 11 along with the downward movement of the sampling mechanism 7, meanwhile, the original air in the sampling tube 11 is extruded out from the air outlet 9, after the water enters the sleeve 10, the second motor 8 starts to drive the sleeve 10 to rotate, so that the water inlet 18 is communicated with the sample cavity 13 to enable the water to enter the sample cavity 13, and meanwhile, the original air in the sample cavity 13 is discharged through the water inlet 18 and the air outlet 9; then the driving mechanism drives the sampling mechanism 7 to move downwards continuously, water in the sampling tube 11 gradually becomes deep water resource, at the moment, the second motor 8 drives the sleeve 10 to rotate again, so that the water in the sampling tube 11 flows into the other sample cavity 13 through the water inlet hole 18, and the rest is done in sequence, so that a plurality of samples with different depths can be obtained at one time. The drive mechanism can then be reversed to lift the sampling mechanism 7 out of the water supply and to take a sample for data acquisition using the sensor 14 in the sample chamber 13. After the data collection is completed, the third motor 16 drives the shutter 15 to open the lower end of the sample chamber 13, so that the sample in the sample chamber 13 is discharged to prepare for the next collection.
The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.
The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
Claims (6)
1. The utility model provides a water resource intelligence data acquisition system which characterized in that: comprises a driving mechanism and a sampling mechanism (7);
the driving mechanism comprises a first motor (1), a first steel rope (2) is wound on an output shaft of the first motor (1), a heavy hammer (5) is fixedly connected to the first steel rope (2), and a second steel rope (6) is fixedly connected to the heavy hammer (5);
the sampling mechanism (7) comprises a second motor (8) fixedly connected with the second steel rope (6), the shell of the second motor (8) is fixedly connected with a base body (12) through a plurality of connecting rods (19), a sampling pipe (11) penetrates through the base body (12), a plurality of sample cavities (13) uniformly distributed along the circumferential direction of the sampling pipe (11) are formed in the base body (12), a sensor (14) is arranged in each sample cavity (13), the base body (12) is rotatably connected with a sleeve (10), the upper end of the sleeve (10) is closed and is fixedly connected with an output shaft of the second motor (8), an air outlet (9) is formed in the upper end of the sleeve (10), the sampling pipe (11) extends into the sleeve (10), and a water inlet (18) is formed in the wall of the sleeve (10), the water inlet hole (18) is communicated with one of the sample cavities (13).
2. The intelligent water resource data acquisition system as claimed in claim 1, wherein: the driving mechanism comprises a guide cylinder (4), the guide cylinder (4) is vertically arranged above the water surface, the upper end of the guide cylinder (4) is connected with a pulley (3), and the first steel rope (2) bypasses the pulley (3) and penetrates through the guide cylinder (4) and then is fixedly connected with the heavy hammer (5).
3. The intelligent water resource data acquisition system as claimed in claim 1, wherein: the heavy hammer (5) comprises an upper section and a lower section which are integrally connected, the upper section is cylindrical, the lower section is conical, and the large end of the lower section is fixedly connected with the upper section.
4. The intelligent water resource data acquisition system as claimed in claim 1, wherein: the sample cavity (13) penetrates through the bottom of the base body (12), a plurality of grooves corresponding to the sample cavity (13) in a one-to-one mode are fixedly formed in the bottom of the base body (12), a third motor (16) is arranged in each groove, an output shaft of the third motor (16) is vertically arranged downwards and extends out of each groove, a baffle (15) is connected to the third motor (16) in a driving mode, and the baffle (15) is used for opening or closing the sample cavity (13).
5. The intelligent water resource data acquisition system as claimed in claim 1, wherein: a filter screen (17) is fixedly arranged in the lower end of the sampling tube (11).
6. The intelligent water resource data acquisition system as claimed in claim 1, wherein: the connecting rods (19) are uniformly distributed along the circumferential direction of the second motor (8).
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CN202022255780.8U CN212964167U (en) | 2020-10-12 | 2020-10-12 | Water resource intelligent data acquisition system |
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CN202022255780.8U CN212964167U (en) | 2020-10-12 | 2020-10-12 | Water resource intelligent data acquisition system |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN116718425A (en) * | 2023-06-13 | 2023-09-08 | 宁波市盛甬海洋技术有限公司 | Multi-functional marine environment pollutes sampling device with adjustable |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN116718425A (en) * | 2023-06-13 | 2023-09-08 | 宁波市盛甬海洋技术有限公司 | Multi-functional marine environment pollutes sampling device with adjustable |
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