CN220930755U - Environment detection device for building engineering - Google Patents

Abstract

The utility model discloses an environment detection device for constructional engineering, comprising: the device comprises a bottom plate, wherein a hinge slot is fixedly arranged in the middle of the upper portion of the bottom plate, a mounting seat is movably arranged in the hinge slot, a guide sleeve rod is fixedly arranged on the mounting seat in a mounting manner, a lifting rod is movably inserted on the guide sleeve rod, a supporting plate is fixedly arranged at the upper end of the lifting rod, a detector is arranged above the supporting plate, clamping parts capable of clamping the detector are symmetrically arranged above the supporting plate, a solar part is arranged above the detector, an adjusting mechanism capable of adjusting the angle of the mounting seat is arranged on the bottom plate, driving mechanisms capable of driving the clamping parts to operate are arranged on the left side and the right side of the supporting plate.

Description

Environment detection device for building engineering

Technical Field

The utility model relates to the technical field of environment detection, in particular to an environment detection device for constructional engineering.

Background

The environment detection is to design an environment detection network by using a GIS technology, and information collected by the environment detection can be timely stored and displayed by the GIS and the selected evaluation area can be monitored and analyzed in detail.

Environmental protection is increasingly emphasized, and environmental monitoring markets are expanding, so that the traditional environmental monitoring stations cannot fully meet the environmental monitoring demands of society, and the existing detection equipment is usually integrated in the use process and can only be integrally conveyed when being detected in different places, so that a user cannot conveniently convey the detection equipment, meanwhile, the existing detection equipment needs to be installed on an uneven surface to operate, the balance of the equipment cannot be maintained, and the areas with different heights cannot be detected.

Disclosure of utility model

The utility model aims to provide an environment detection device for constructional engineering, which can solve at least one of the technical problems, and the technical scheme of the utility model is as follows:

An environment detection device for construction engineering, comprising: the device comprises a bottom plate, wherein a hinge slot is fixedly arranged in the middle of the upper portion of the bottom plate, a mounting seat is movably arranged in the hinge slot, a guide sleeve rod is fixedly arranged on the mounting seat in a mounting mode, a lifting rod is movably inserted on the guide sleeve rod, a supporting plate is fixedly arranged at the upper end of the lifting rod, a detector is arranged above the supporting plate, clamping portions capable of clamping the detector are symmetrically arranged above the supporting plate, a solar portion is arranged above the detector, an adjusting mechanism capable of adjusting the angle of the mounting seat is arranged on the bottom plate, driving mechanisms capable of driving the clamping portions to operate are arranged on the left side and the right side of the supporting plate, a moving mechanism capable of driving the lifting rod to move upwards is arranged on the left side of the guide sleeve rod, and a rotating mechanism capable of driving the solar portion to rotate is arranged above the detector.

Further, the clamping part comprises guide rods symmetrically fixed above the support plate, sliding blocks are symmetrically movably inserted on each guide rod, an L-shaped clamping plate is fixed between every two symmetrically arranged sliding blocks, and a plurality of reinforcing ribs are fixed on each L-shaped clamping plate.

Further, the solar energy portion includes a plurality of nut sleeve posts of fixing in the detector top, is equipped with the mounting panel in a plurality of nut sleeve posts top the mounting panel middle part is fixed with the rotation cover the rotation is sheathe in the activity and is equipped with the dwang tip is fixed with solar panel.

Further, the adjustment mechanism comprises guide rails uniformly distributed and fixed on the bottom plate, a moving block is movably inserted in each guide rail, screw holes are transversely formed in the moving blocks, first screw rods are movably sleeved in two guide rails and are in threaded fit with the screw holes, connecting rods are movably hinged to the periphery of the mounting seat, hinge joints are movably sleeved at the end portions of the connecting rods, and the hinge joints are movably hinged to the moving blocks.

Further, the driving mechanism comprises a first motor fixed at the left side and the right side of the supporting plate, a second screw rod is fixed at the output end of the first motor, levers are movably hinged to the sliding blocks, every two adjacent levers are movably hinged to each other, a first thread sleeve is movably sleeved at the hinged end of each two adjacent levers, and the first thread sleeve is in threaded fit with the second screw rod.

Further, the moving mechanism comprises a second motor fixed on the left side of the guide sleeve rod, a first bevel gear is fixed at the output end of the second motor, a second thread bush is fixed in the lifting rod, a third screw rod is movably sleeved in the guide sleeve rod, a second bevel gear meshed with the first bevel gear is fixed at the end part of the third screw rod, and the third screw rod is in threaded fit with the second thread bush.

Further, the rotating mechanism comprises a third motor fixed above the mounting plate, a first straight gear is fixed at the output end of the third motor, a second straight gear is fixed on the rotating rod, and the first straight gear is meshed with the second straight gear.

In summary, compared with the prior art, the utility model has the following beneficial effects:

The utility model provides an environment detection device for construction engineering, which is characterized in that a bottom plate is fixed on the ground through a fixed nail when in use, then an installation seat is movably sleeved in a hinge groove, meanwhile, a guide sleeve rod is installed and fixed on the installation seat by a user, the angle of the installation seat is adjusted by driving an adjusting mechanism by the user, the installation seat is adapted to the angle of the ground, then a lifting rod is installed and arranged in the guide sleeve rod by the user, a clamping part is driven by the driving mechanism to operate, the detector is clamped and arranged above a supporting plate by the clamping part, then a solar part is arranged above the detector, the solar part is connected with a power supply for driving the detector, the lifting rod is driven by a moving mechanism to move upwards in use, the detector detects environments with different heights, and the solar part is driven by the rotating mechanism to rotate, so that the solar part collects solar energy with different angles to be conveyed to the power supply for the connection of the detector.

Drawings

Fig. 1 is a perspective view of the present utility model.

Fig. 2 is a schematic representation of the present utility model in semi-section.

Fig. 3 is an exploded view of the present utility model.

Reference numerals illustrate: 1. a bottom plate; 2. a hinge groove; 3. a mounting base; 4. a guide sleeve rod; 5. a lifting rod; 6. a support plate; 7. a detector; 8. a clamping part; 9. a solar energy section; 100. an adjusting mechanism; 200. a driving mechanism; 300. a moving mechanism; 400. a rotating mechanism; 81. a guide rod; 82. a slide block; 83. an L-shaped clamping plate; 84. reinforcing ribs; 91. a nut sleeve column; 92. a mounting plate; 93. a rotating sleeve; 94. a rotating lever; 95. a solar panel; 101. a guide rail; 102. a moving block; 103. a screw hole; 104. a first screw; 105. a connecting rod; 106. a hinge joint; 201. a first motor; 202. a second screw; 203. a lever; 204. a first threaded sleeve; 301. a second motor; 302. a first bevel gear; 303. a second threaded sleeve; 304. a third screw; 305. a second bevel gear; 401. a third motor; 402. a first straight gear; 403. a second spur gear.

Detailed Description

The utility model is further described in the following description and detailed description with reference to the drawings:

An environment detection device for construction engineering as shown in fig. 1 to 3, comprising: the bottom plate 1 the fixed articulated slot 2 that is equipped with in bottom plate 1 top middle part articulated slot 2 in-activity be equipped with mount pad 3 the mount pad 3 installs and is fixed with guide sleeve pole 4 go up the activity grafting and have ascending rod 5 upper end is fixed with backup pad 6 be equipped with detector 7 backup pad 6 top symmetry is equipped with the clamping part 8 that can centre gripping detector 7 be equipped with solar energy portion 9 on the detector 7 be equipped with on the bottom plate 1 can adjust the adjustment mechanism 100 of mount pad 3 angle the actuating mechanism 200 that the actuating mechanism of clamping part 8 operation is equipped with in backup pad 6 left and right sides the guide sleeve pole 4 left side is equipped with the mobile mechanism 300 that can drive ascending rod 5 upward movement be equipped with the rotary mechanism 400 that can drive solar energy portion 9 pivoted above the detector 7.

According to the environment detection device for the constructional engineering, when the environment detection device is used, a base plate 1 is fixed on the ground through a fixed nail by a user, then a mounting seat 3 is movably sleeved in a hinge groove 2, a guide sleeve rod 4 is mounted and fixed on the mounting seat 3 by the user, at the moment, an adjusting mechanism 100 is driven by the user, the angle of the mounting seat 3 is adjusted, the mounting seat 3 is adapted to the angle of the ground, a lifting rod 5 is mounted in the guide sleeve rod 4 by the user, a clamping part 8 is driven by a driving mechanism 200 to operate, the clamping part 8 clamps the detector 7 above a supporting plate 6, then a solar part 9 is mounted above the detector 7, the solar part 9 is connected with a power supply for driving the detector 7, the lifting rod 5 is driven to move upwards in use by a moving mechanism 300, the detector 7 detects environments of different heights, the solar part 9 is driven by a rotating mechanism 400 to rotate, the solar part 9 is used for collecting solar energy of different angles and conveying the detector 7 to a power supply connected with the detector, compared with the prior art, the detector is convenient to carry the detector, and the detector is dismounted from the whole device to the detection device, and the detector is convenient to use and can be mounted on the detection device and can be dismounted in the detection area.

As shown in fig. 3, in some embodiments of the present utility model, the clamping portion 8 includes guide rods 81 symmetrically fixed above the support plate 6, sliding blocks 82 are movably inserted on each guide rod 81 symmetrically, L-shaped clamping plates 83 are fixed between each two symmetrically arranged sliding blocks 82, a plurality of reinforcing ribs 84 are fixed on each L-shaped clamping plate 83, and the driving mechanism 200 moves along the guide rods 81 with the sliding blocks 82, so that each two symmetrically arranged sliding blocks 82 drive the L-shaped clamping plates 83 to move towards the detector 7 to clamp the detector 7, and the reinforcing ribs 84 strengthen the strength of the L-shaped clamping plates 83.

As shown in fig. 3, in some embodiments of the present utility model, the solar unit 9 includes a plurality of nut sockets 91 fixed above the detector 7, a mounting plate 92 is disposed above the plurality of nut sockets 91, a rotating sleeve 93 is fixed in the middle of the mounting plate 92, a rotating rod 94 is movably sleeved on the rotating sleeve 93, a solar panel 95 is fixed at an end of the rotating rod 94, solar energy is collected by the solar panel 95, and when the rotating mechanism 400 operates, the rotating rod 94 can be driven to rotate, so that the rotating rod 94 sleeved on the rotating sleeve 93 drives the solar panel 95 to rotate, and a user fixedly mounts the mounting plate 92 on the detector 7 through the nut sockets 91.

As shown in fig. 3, in some embodiments of the present utility model, in order to achieve the effect of adjusting the angle of the mounting seat 3, the adjusting mechanism 100 includes guide rails 101 uniformly fixed on the bottom plate 1, moving blocks 102 movably inserted in each guide rail 101, screw holes 103 transversely provided on the moving blocks 102, first screws 104 movably sleeved in two guide rails 101, the first screws 104 and the screw holes 103 are in threaded fit, connecting rods 105 movably hinged around the mounting seat 3, and hinges 106 movably sleeved at ends of each connecting rod 105, where the hinges 106 and the moving blocks 102 are movably hinged.

When the environment detection device for construction engineering with the structure is used, a user rotates the first screw rod 104 sleeved in the guide rail 101 to rotate, so that the first screw rod 104 drives the moving block 102 to move along the guide rail 101, the articulated joint 106 drives the connecting rod 105 to swing when the moving block 102 moves, the connecting rod 105 changes the angle of the mounting seat 3 movably arranged in the hinge groove 2, and meanwhile, the articulated joint 106 movably sleeved at the end part of the connecting rod 105 can enable the mounting seat 3 to adapt to more angle changes.

As shown in fig. 3, in some embodiments of the present utility model, in order to achieve the effect of driving the clamping portion 8, the driving mechanism 200 includes a first motor 201 fixed on the left and right sides of the supporting plate 6, a second screw 202 is fixed at the output end of the first motor 201, a lever 203 is movably hinged on each sliding block 82, each two adjacent levers 203 are movably hinged with each other, a first threaded sleeve 204 is movably sleeved at the hinged end of each two adjacent levers 203, and the first threaded sleeve 204 and the second screw 202 are in threaded fit.

When the environment detection device for construction engineering with the structure is operated, the first motor 201 is driven by the power supply, so that the output end of the first motor 201 drives the second screw 202 to rotate, the sliding block 82 is driven to move upwards when the second screw 202 rotates, the lever 203 movably hinged to the sliding block 82 is driven to swing upwards when the sliding block 82 moves, the lever 203 is opened or contracted, the lever 203 drives the sliding block 82 to move, and the sliding block 82 clamps the detector 7 through the L-shaped clamping plate 83.

As shown in fig. 2 and 3, in some embodiments of the present utility model, in order to achieve the effect of driving the lifting rod 5 to move upwards, the moving mechanism 300 includes a second motor 301 fixed on the left side of the guide sleeve rod 4, a first bevel gear 302 fixed on the output end of the second motor 301, a second threaded sleeve 303 fixed in the lifting rod 5, a third screw 304 movably sleeved in the guide sleeve rod 4, a second bevel gear 305 engaged with the first bevel gear 302 fixed on the end of the third screw 304, and the third screw 304 and the second threaded sleeve 303 are in threaded engagement.

When the environment detection device for construction engineering with the structure is operated, the second motor 301 is driven by the power supply, so that the second motor 301 drives the first bevel gear 302 to rotate, the second bevel gear 305 is driven to rotate when the first bevel gear 302 rotates, the third screw 304 is driven to rotate when the second bevel gear 305 rotates, and the third screw 304 drives the lifting rod 5 to move upwards along the guide sleeve rod 4 through the second thread sleeve 303.

As shown in fig. 2 and 3, in some embodiments of the present utility model, to achieve the effect of driving the solar unit 9 to rotate, the rotation mechanism 400 includes a third motor 401 fixed above the mounting plate 92, a first spur gear 402 is fixed at an output end of the third motor 401, and a second spur gear 403 is fixed on the rotation rod 94, where the first spur gear 402 and the second spur gear 403 are meshed.

When the environment detection device for construction engineering with the structure is in operation, the third motor 401 is driven by the power supply, so that the output end of the third motor 401 drives the first straight gear 402 to rotate, the first straight gear 402 drives the second straight gear 403 to rotate, and the second straight gear 403 drives the rotating rod 94 to rotate.

While there has been shown and described what is at present considered to be the fundamental principles and the main features of the utility model and the advantages thereof, it will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, but is described in the foregoing description merely illustrates the principles of the utility model, and various changes and modifications may be made therein without departing from the spirit and scope of the utility model as hereinafter claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (7)

1. An environment detection device for construction engineering, comprising: bottom plate (1) top middle part is fixed be equipped with hinge groove (2) internal motion is equipped with mount pad (3) installation is fixed with direction loop bar (4) go up the activity and peg graft and have ascending rod (5) upper end is fixed with backup pad (6) top is equipped with detector (7) backup pad (6) top symmetry is equipped with clamping part (8) that can centre gripping detector (7) be equipped with solar energy portion (9) above detector (7) be equipped with adjustment mechanism (100) that can adjust mount pad (3) angle backup pad (6) left and right sides is equipped with actuating mechanism (200) that can drive clamping part (8) operation upward moving guide loop bar (4) left side is equipped with and can drives ascending rod (5) detector (7) top is equipped with rotation mechanism (400) that can drive solar energy portion (9).

2. The environment detection device for construction engineering according to claim 1, wherein the clamping portion (8) comprises guide rods (81) symmetrically fixed above the support plate (6), sliding blocks (82) are symmetrically movably inserted into the guide rods (81), L-shaped clamping plates (83) are fixed between every two symmetrically arranged sliding blocks (82), and a plurality of reinforcing ribs (84) are fixed on the L-shaped clamping plates (83).

3. The environmental detection device for construction engineering according to claim 1, wherein the solar energy portion (9) comprises a plurality of nut sleeves (91) fixed above the detector (7), a mounting plate (92) is arranged above the plurality of nut sleeves (91), a rotating sleeve (93) is fixed in the middle of the mounting plate (92), a rotating rod (94) is movably sleeved on the rotating sleeve (93), and a solar panel (95) is fixed at the end of the rotating rod (94).

4. The environment detection device for construction engineering according to claim 1, wherein the adjusting mechanism (100) comprises guide rails (101) uniformly fixed on the base plate (1), moving blocks (102) are movably inserted in the guide rails (101), screw holes (103) are transversely formed in the moving blocks (102), first screws (104) are movably sleeved in two of the guide rails (101), the first screws (104) are in threaded fit with the screw holes (103), connecting rods (105) are movably hinged around the mounting seat (3), hinge joints (106) are movably sleeved at the end parts of the connecting rods (105), and the hinge joints (106) are movably hinged with the moving blocks (102).

5. The environment detection device for construction engineering according to claim 2, wherein the driving mechanism (200) comprises a first motor (201) fixed at the left side and the right side of the supporting plate (6), a second screw (202) is fixed at the output end of the first motor (201), levers (203) are movably hinged on the sliding blocks (82), every two adjacent levers (203) are movably hinged with each other, a first thread bush (204) is movably sleeved at the hinged end of each two adjacent levers (203), and the first thread bush (204) and the second screw (202) are in threaded fit.

6. The environment detection device for construction engineering according to claim 1, wherein the moving mechanism (300) comprises a second motor (301) fixed on the left side of a guide sleeve rod (4), a first bevel gear (302) fixed at the output end of the second motor (301), a second threaded sleeve (303) fixed in the ascending rod (5), a third screw (304) movably sleeved in the guide sleeve rod (4), a second bevel gear (305) meshed with the first bevel gear (302) fixed at the end of the third screw (304), and the third screw (304) and the second threaded sleeve (303) are in threaded fit.

7. A construction environment detecting device according to claim 3, wherein the rotating mechanism (400) comprises a third motor (401) fixed above the mounting plate (92), a first spur gear (402) is fixed to an output end of the third motor (401), a second spur gear (403) is fixed to the rotating rod (94), and the first spur gear (402) and the second spur gear (403) are meshed.