CN113252091A - On-spot data acquisition device based on geological environment monitoring - Google Patents

Abstract

The invention discloses a field data acquisition device based on geological environment monitoring, which relates to the technical field of environment monitoring and solves the problems that the existing environment monitoring data acquisition device cannot well adjust the height in use, only can acquire data from one height position and cannot simultaneously test a plurality of height positions, and comprises an installation base; a group of driving pieces are fixedly connected above the lower part of the mounting base; the left side and the right side of the mounting base are both rotatably connected with a group of lifting driving screw rods; the rear part of the mounting base is connected with a group of two-stage telescopic rods in a sliding mode. The invention realizes the simultaneous extension and retraction of the two-stage telescopic rod and the three-stage telescopic rod, realizes the detection of environmental field data through the two-stage telescopic rod, the three-stage telescopic rod and the data acquisition assembly arranged at the top of the mounting base, can detect data at different height positions according to requirements, and simultaneously ensures that the three groups of data acquisition assemblies are uniformly distributed in height positions, and has strong extension and retraction capability and simple use.

Description

On-spot data acquisition device based on geological environment monitoring

Technical Field

The invention relates to the technical field of environmental monitoring, in particular to a field data acquisition device based on geological environment monitoring.

Background

Environmental monitoring refers to the activities of environmental monitoring mechanisms to monitor and measure environmental quality conditions. The environmental monitoring is to monitor and measure the index reflecting the environmental quality to determine the environmental pollution condition and the environmental quality, the content of the environmental monitoring mainly comprises the monitoring of physical index, the monitoring of chemical index and the monitoring of ecosystem, and the data acquisition device is generally adopted to monitor in the process of environmental monitoring.

For example, application No.: this utility model of CN201920193295.7 discloses an air quality monitoring appearance, it includes: the box, fix temperature and humidity sensor, particulate matter sampling device in the box top to and fix the wind speed sensor and the wind direction sensor in the box top through fixing wind speed sensor mounting panel, the wind direction sensor mounting panel in the box both sides, still including setting up the circuit wiring aviation plug and be used for installing the recess form aviation plug mount pad that circuit wiring aviation plug was inserted at box both sides wind speed sensor mounting panel and wind direction sensor mounting panel below.

Based on the above, the height of the existing environment monitoring data acquisition device is generally a fixed height, and when the environment data is acquired, only one height of data can be detected, and because the environment data at different height positions affected by the ground may be different, the height cannot be well adjusted in use, only one height position can be subjected to data acquisition, and a plurality of height positions cannot be simultaneously tested; therefore, the existing requirements are not met, and the field data acquisition device based on geological environment monitoring is provided for the requirements.

Disclosure of Invention

The invention aims to provide a field data acquisition device based on geological environment monitoring, which aims to solve the problems that the height of the existing environment monitoring data acquisition device in the background art is generally fixed, only one height of data can be detected in the process of acquiring environment data, the height cannot be well adjusted in use due to different height position environment data influenced by the ground, only one height position can be subjected to data acquisition, and a plurality of height positions cannot be simultaneously tested.

In order to achieve the purpose, the invention provides the following technical scheme: a field data acquisition device based on geological environment monitoring comprises an installation base; a group of driving pieces are fixedly connected above the lower part of the mounting base; the left side and the right side of the mounting base are both rotatably connected with a group of lifting driving screw rods; the rear part of the mounting base is connected with a group of two-stage telescopic rods in a sliding manner; the rear part of the second-stage telescopic rod is connected with a group of third-stage telescopic rods in a sliding manner; a group of telescopic driving shafts is rotatably connected in front of the lower part of the inner side of the two-stage telescopic rod; and the rear part of the upper part of the inner side of the two-stage telescopic rod is rotatably connected with a group of telescopic driven shafts.

Preferably, the second-stage telescopic rod further comprises a second-stage telescopic guide groove, a set of second-stage telescopic guide groove is formed in the left side and the right side of the second-stage telescopic rod, and the second-stage telescopic rod is connected with the installation base in a sliding mode through the second-stage telescopic guide groove.

Preferably, the second grade telescopic link is still including the flexible guide way of tertiary, and a set of three-level flexible guide way has all been seted up to the left and right sides of second grade telescopic link, and three-level telescopic link passes through three-level flexible guide way and second grade telescopic link sliding connection.

Preferably, the driving piece is including lead screw drive sprocket, a set of lead screw drive sprocket of coaxial fixedly connected with in the bottom pivot of driving piece, and the lift drive lead screw is still including lead screw driven sprocket, a set of lead screw driven sprocket of the coaxial fixedly connected with in bottom of lift drive lead screw, is connected through the drive chain transmission between lead screw drive sprocket and the two sets of lead screw driven sprockets, constitutes drive chain drive mechanism between lead screw drive sprocket and the lead screw driven sprocket jointly.

Preferably, the two groups of lifting driving screw rods are in threaded transmission connection with the two-stage telescopic rods, and a screw rod nut transmission pair is formed between the lifting driving screw rods and the two-stage telescopic rods.

Preferably, flexible driving shaft is still including flexible driven gear, and the coaxial fixedly connected with a set of flexible driven gear in left side of flexible driving shaft, installation base are still including flexible drive rack, and the rear portion fixedly connected with of installation base is a set of flexible drive rack, and flexible driven gear constitutes rack and pinion drive mechanism with flexible drive rack meshing jointly.

Preferably, flexible driving shaft is still including flexible drive sprocket, and the coaxial fixedly connected with in right side of flexible driving shaft a set of flexible drive sprocket, and flexible driven shaft is still including flexible driven sprocket, and the coaxial fixedly connected with in right side of flexible driven shaft a set of flexible driven sprocket connects through the drive chain transmission between flexible drive sprocket and the flexible driven sprocket and constitutes drive chain drive mechanism jointly.

Preferably, flexible driven shaft is still including flexible driving gear, and the coaxial fixedly connected with a set of flexible driving gear in right side of flexible driven shaft, and tertiary telescopic link is still including flexible driven rack, and the anterior fixedly connected with a set of flexible driven rack of tertiary telescopic link, flexible driving gear constitutes rack and pinion drive mechanism jointly with flexible driven rack meshing.

Preferably, the mounting base further comprises a data acquisition assembly, and the tops of the second-stage telescopic rod, the third-stage telescopic rod and the mounting base are respectively and fixedly connected with the data acquisition assembly.

Compared with the prior art, the invention has the beneficial effects that:

when the invention is used, the driving piece drives two groups of lifting driving screws to synchronously rotate through a transmission chain transmission mechanism jointly formed by the screw driving chain wheels and the screw driven chain wheels, the lifting driving screws drive the secondary telescopic rods to slide up and down through screw nut transmission pairs jointly formed by the lifting driving screws and the telescopic rods, the secondary telescopic rods drive the telescopic driving shafts to slide up and down, the telescopic driving shafts are driven to rotate under the action of a gear rack transmission mechanism jointly formed by the engagement of the telescopic driven gears and the telescopic driving racks, the telescopic driving shafts drive the telescopic driven shafts to rotate through the transmission chain transmission mechanism jointly formed by the engagement of the telescopic driving chain wheels and the telescopic driven chain wheels, the telescopic driven shafts drive the three-stage telescopic rods to slide up and down through the gear rack transmission mechanism jointly formed by the engagement of the telescopic driving gears and the telescopic driven racks, and the extension and retraction of the three-stage telescopic rods are realized, the data acquisition assembly at the top of the installation base can detect the environmental field data through the two-stage telescopic rod, the three-stage telescopic rod and can detect data of different height positions as required.

The invention realizes the simultaneous extension and retraction of the two-stage telescopic rod and the three-stage telescopic rod, realizes the detection of environmental field data through the two-stage telescopic rod, the three-stage telescopic rod and the data acquisition assembly arranged at the top of the mounting base, can detect data at different height positions according to requirements, and simultaneously ensures that the three groups of data acquisition assemblies are uniformly distributed in height positions, and has strong extension and retraction capability and simple use.

Drawings

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

FIG. 2 is a schematic side view of the driving shaft of the elevating screw according to the present invention;

FIG. 3 is a schematic side view of the shaft of the two-stage telescopic rod of the present invention;

FIG. 4 is a schematic side view of the rear shaft of the two-stage telescopic rod of the present invention;

FIG. 5 is a schematic side view of the mounting base of the present invention;

FIG. 6 is a schematic side view of the three-stage telescopic rod of the present invention;

FIG. 7 is a schematic side view of the drive shaft of the telescopic driven shaft of the present invention;

FIG. 8 is a schematic cross-sectional view of the present invention;

in the figure: 1. installing a base; 101. a data acquisition component; 102. a telescopic driving rack; 2. a drive member; 201. the lead screw drives the sprocket; 3. lifting the driving screw; 301. a lead screw driven sprocket; 4. a secondary telescopic rod; 401. a secondary telescopic guide groove; 402. a three-stage telescopic guide groove; 5. a three-stage telescopic rod; 501. a telescopic driven rack; 6. a telescopic driving shaft; 601. a telescopic drive sprocket; 602. a telescopic driven gear; 7. a telescopic driven shaft; 701. a telescopic driven sprocket; 702. the flexible driving gear.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1 to 8, an embodiment of the present invention includes: a field data acquisition device based on geological environment monitoring comprises an installation base 1; a group of driving pieces 2 are fixedly connected above the lower part of the mounting base 1; the left side and the right side of the mounting base 1 are both rotatably connected with a group of lifting driving screw rods 3; the rear part of the mounting base 1 is connected with a group of two-stage telescopic rods 4 in a sliding way; the rear part of the second-stage telescopic rod 4 is connected with a group of third-stage telescopic rods 5 in a sliding manner; a group of telescopic driving shafts 6 are rotatably connected in front of the lower part of the inner side of the two-stage telescopic rod 4; the rear part of the upper part of the inner side of the two-stage telescopic rod 4 is rotatably connected with a group of telescopic driven shafts 7.

Further, second grade telescopic rod 4 is still including the flexible guide way 401 of second grade, and the flexible guide way 401 of a set of second grade has all been seted up to second grade telescopic rod 4's the left and right sides, and second grade telescopic rod 4 passes through the flexible guide way 401 of second grade and installs 1 sliding connection of base, and in use has realized the direction to second grade telescopic rod 4 through the flexible guide way 401 of second grade.

Further, second grade telescopic link 4 is still including tertiary flexible guide way 402, and a set of tertiary flexible guide way 402 has all been seted up to second grade telescopic link 4's the left and right sides, and tertiary telescopic link 5 has realized the direction to tertiary telescopic link 5 through tertiary flexible guide way 402 and second grade telescopic link 4 sliding connection, in use through tertiary flexible guide way 402.

Further, the driving member 2 is still including lead screw driving sprocket 201, a set of lead screw driving sprocket 201 of coaxial fixedly connected with in the bottom pivot of driving member 2, the lift driving lead screw 3 is still including lead screw driven sprocket 301, a set of lead screw driven sprocket 301 of coaxial fixedly connected with in the bottom of lift driving lead screw 3, be connected through the drive chain transmission between lead screw driving sprocket 201 and the two sets of lead screw driven sprocket 301, constitute drive chain drive mechanism between lead screw driving sprocket 201 and the lead screw driven sprocket 301 jointly, in use, driving member 2 drives two sets of lift driving lead screw 3 synchronous rotations through the drive chain drive mechanism who constitutes jointly between lead screw driving sprocket 201 and the lead screw driven sprocket 301.

Further, two sets of lifting drive lead screws 3 are connected with the second-stage telescopic rod 4 in a threaded transmission mode, a lead screw nut transmission pair is formed between each lifting drive lead screw 3 and the corresponding second-stage telescopic rod 4, and when the two sets of lifting drive lead screws 3 rotate synchronously in use, the lifting drive lead screws 3 drive the second-stage telescopic rods 4 to slide up and down through the lead screw nut transmission pair formed between the lifting drive lead screws 3 and the second-stage telescopic rods 4.

Further, flexible driving shaft 6 still includes flexible driven gear 602, the coaxial fixedly connected with a set of flexible driven gear 602 in left side of flexible driving shaft 6, installation base 1 still includes flexible drive rack 102, the rear portion fixedly connected with a set of flexible drive rack 102 of installation base 1, flexible driven gear 602 constitutes rack and pinion drive mechanism with flexible drive rack 102 meshing jointly, in use, second grade telescopic link 4 slides from top to bottom, second grade telescopic link 4 drives flexible driving shaft 6 and slides from top to bottom, drive flexible driving shaft 6 rotatory under the rack and pinion drive mechanism effect of constituting jointly by flexible driven gear 602 and flexible drive rack 102 meshing.

Further, flexible driving shaft 6 is still including flexible driving sprocket 601, the coaxial fixedly connected with a set of flexible driving sprocket 601 in the right side of flexible driving shaft 6, flexible driven shaft 7 is still including flexible driven sprocket 701, the coaxial fixedly connected with a set of flexible driven sprocket 701 in the right side of flexible driven shaft 7, connect through the drive chain transmission between flexible driving sprocket 601 and the flexible driven sprocket 701 and constitute drive chain drive mechanism jointly, in use, when flexible driving shaft 6 is rotatory, flexible driving shaft 6 drives flexible driven shaft 7 through the drive chain drive mechanism who constitutes jointly between flexible driving sprocket 601 and the flexible driven sprocket 701 and rotates.

Further, flexible driven shaft 7 is still including flexible driving gear 702, a set of flexible driving gear 702 of the coaxial fixedly connected with in right side of flexible driven shaft 7, tertiary telescopic link 5 is still including flexible driven rack 501, a set of flexible driven rack 501 of the anterior fixedly connected with of tertiary telescopic link 5, flexible driving gear 702 constitutes rack and pinion drive mechanism with flexible driven rack 501 meshing jointly, in use, when flexible driven shaft 7 is rotatory, flexible driven shaft 7 drives tertiary telescopic link 5 through the rack and pinion drive mechanism who constitutes jointly by flexible driving gear 702 and flexible driven rack 501 meshing and slides from top to bottom, the flexible of tertiary telescopic link 5 has been realized.

Further, installation base 1 is still including data acquisition component 101, and second grade telescopic link 4, tertiary telescopic link 5, installation base 1's top difference fixedly connected with data acquisition component 101, and in use realizes detecting environment field data through the data acquisition component 101 at second grade telescopic link 4, tertiary telescopic link 5, installation base 1 top, can carry out data detection to different height positions as required.

The working principle is as follows: when in use, the driving piece 2 drives two groups of lifting driving screws 3 to synchronously rotate through a driving chain transmission mechanism jointly formed between the screw driving chain wheel 201 and the screw driven chain wheel 301, the lifting driving screws 3 drive the secondary telescopic rod 4 to slide up and down through a screw nut transmission pair jointly formed between the lifting driving screws 3 and the secondary telescopic rod 4, the secondary telescopic rod 4 drives the telescopic driving shaft 6 to slide up and down, the telescopic driving shaft 6 is driven to rotate under the action of a gear rack transmission mechanism jointly formed by the meshing of the telescopic driven gear 602 and the telescopic driving rack 102, the telescopic driving shaft 6 drives the telescopic driven shaft 7 to rotate through a driving chain transmission mechanism jointly formed between the telescopic driving chain wheel 601 and the telescopic driven chain wheel 701, and the telescopic driven shaft 7 drives the tertiary telescopic rod 5 to slide up and down through a gear rack transmission mechanism jointly formed by the meshing of the telescopic driving gear 702 and the telescopic driven rack 501, the telescopic of tertiary telescopic link 5 has been realized, and the data acquisition subassembly 101 through two-stage telescopic link 4, tertiary telescopic link 5, installation base 1 top realizes detecting environment field data, can carry out data detection to not co-altitude position as required.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (9)

1. The utility model provides an on-spot data acquisition device based on geological environment monitoring which characterized in that: comprises a mounting base (1); a group of driving pieces (2) are fixedly connected above the lower part of the mounting base (1); the left side and the right side of the mounting base (1) are both rotatably connected with a group of lifting driving screw rods (3); the rear part of the mounting base (1) is connected with a group of two-stage telescopic rods (4) in a sliding manner; the rear part of the second-stage telescopic rod (4) is connected with a group of third-stage telescopic rods (5) in a sliding manner; a group of telescopic driving shafts (6) are rotatably connected in front of the lower part of the inner side of the two-stage telescopic rod (4); the rear part of the upper part of the inner side of the two-stage telescopic rod (4) is rotatably connected with a group of telescopic driven shafts (7).

2. The field data acquisition device based on geological environment monitoring as claimed in claim 1, wherein: two-stage telescopic rod (4) are still including the flexible guide way of second grade (401), and a set of flexible guide way of second grade (401) has all been seted up to the left and right sides of two-stage telescopic rod (4), and two-stage telescopic rod (4) are through flexible guide way of second grade (401) and installation base (1) sliding connection.

3. The field data acquisition device based on geological environment monitoring as claimed in claim 1, wherein: two-stage telescopic rod (4) are still including tertiary flexible guide way (402), and a set of tertiary flexible guide way (402) have all been seted up to two-stage telescopic rod's (4) the left and right sides, and tertiary telescopic rod (5) are through tertiary flexible guide way (402) and two-stage telescopic rod (4) sliding connection.

4. The field data acquisition device based on geological environment monitoring as claimed in claim 1, wherein: the driving part (2) is further provided with a lead screw driving chain wheel (201), a group of lead screw driving chain wheels (201) is coaxially and fixedly connected to the bottom rotating shaft of the driving part (2), the lifting driving lead screw (3) is further provided with a lead screw driven chain wheel (301), a group of lead screw driven chain wheels (301) is coaxially and fixedly connected to the bottom of the lifting driving lead screw (3), the lead screw driving chain wheels (201) and the two groups of lead screw driven chain wheels (301) are connected through a transmission chain in a transmission mode, and a transmission chain transmission mechanism is jointly formed between the lead screw driving chain wheels (201) and the lead screw driven chain wheels (301).

5. The field data acquisition device based on geological environment monitoring as claimed in claim 1, wherein: the two groups of lifting driving screw rods (3) are in threaded transmission connection with the two-stage telescopic rods (4), and a screw rod nut transmission pair is formed between the lifting driving screw rods (3) and the two-stage telescopic rods (4).

6. The field data acquisition device based on geological environment monitoring as claimed in claim 1, wherein: the telescopic driving shaft (6) further comprises a telescopic driven gear (602), a group of telescopic driven gears (602) are coaxially and fixedly connected to the left side of the telescopic driving shaft (6), the mounting base (1) further comprises a telescopic driving rack (102), a group of telescopic driving racks (102) are fixedly connected to the rear portion of the mounting base (1), and the telescopic driven gears (602) and the telescopic driving racks (102) are meshed to form a gear-rack transmission mechanism together.

7. The field data acquisition device based on geological environment monitoring as claimed in claim 1, wherein: the telescopic driving shaft (6) is further provided with a telescopic driving chain wheel (601), the right side of the telescopic driving shaft (6) is coaxially and fixedly connected with a group of telescopic driving chain wheels (601), the telescopic driven shaft (7) is further provided with a telescopic driven chain wheel (701), the right side of the telescopic driven shaft (7) is coaxially and fixedly connected with a group of telescopic driven chain wheels (701), and the telescopic driving chain wheels (601) and the telescopic driven chain wheels (701) are connected through a transmission chain to form a transmission chain transmission mechanism.

8. The field data acquisition device based on geological environment monitoring as claimed in claim 1, wherein: the telescopic driven shaft (7) is characterized by further comprising a telescopic driving gear (702), a group of telescopic driving gears (702) are coaxially and fixedly connected to the right side of the telescopic driven shaft (7), the three-stage telescopic rod (5) is further comprising a telescopic driven rack (501), a group of telescopic driven racks (501) are fixedly connected to the front portion of the three-stage telescopic rod (5), and the telescopic driving gear (702) and the telescopic driven rack (501) are meshed to form a gear-rack transmission mechanism together.

9. The field data acquisition device based on geological environment monitoring as claimed in claim 1, wherein: the mounting base (1) further comprises a data acquisition assembly (101), and the tops of the second-stage telescopic rod (4), the third-stage telescopic rod (5) and the mounting base (1) are fixedly connected with the data acquisition assembly (101) respectively.

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